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? 2007-2011 microchip technology inc. ds70289j-page 1 pic24hj32gp202/204 and pic24hj16gp304 operating conditions ? 3.0v to 3.6v, -40oc to +150oc, dc to 20 mips ? 3.0v to 3.6v, -40oc to +125oc, dc to 40 mips core: 16-bit pic24h cpu ? code-efficient (c and assembly) architecture ? single-cycle mixed-sign mul plus hardware divide clock management ? 2% internal oscillator ? programmable plls and oscillator clock sources ? fail-safe clock monitor (fscm) ? independent watchdog timer (wdt) ? fast wake-up and start-up power management ? low-power management modes (sleep, idle, doze) ? integrated power-on reset and brown-out reset ? 1.35 ma/mhz dynamic current (typical) ? 55 a ipd current (typical) advanced analog features ? adc module: - configurable as 10-bit, 1.1 msps with four s&h or 12-bit, 500 ksps with one s&h - ten analog inputs on 28-pin devices and up to 13 analog inputs on 44-pin devices ? flexible and independent adc trigger sources timers/output compare/input capture ? three 16-bit timers/counters. can pair up two to make one 32-bit. ? two output capture modules configurable as timers/counters ? four input capture modules ? peripheral pin select (pps) to allow function remap communication interfaces ? one uart module (10 mbps) - with support for lin 2.0 protocols and irda ? ? one 4-wire spi module (15 mbps) ? one i 2 c? module (up to 1 mbaud) with smbus support ? pps to allow function remap input/output ? sink/source up to 10 ma (pin specific) for stan- dard voh/vol, up to 16 ma (pin specific) for non-standard voh1 ? 5v-tolerant pins ? selectable open drain, pull-ups, and pull-downs ? up to 5 ma overvoltage clamp current ? external interrupts on all i/o pins qualification and class b support ? aec-q100 revg (grade 0 -40oc to +150oc) ? class b safety library, iec 60730 debugger development support ? in-circuit and in-application programming ? two program and two complex data breakpoints ? ieee 1149.2-compatible (jtag) boundary scan ? trace and run-time watch packages type spdip soic ssop qfn-s qfn tqfp pin count 28 28 28 28 44 44 contact lead/pitch .100'' 1.27 0.65 0.65 0.65 0.80 i/o pins 21 21 21 21 35 35 dimensions 1.365x.285x.135'' 17.9xx7.50x2.05 10. 2x5.3x1.75 6x6x0.9 8x8x0.9 10x10x1 note: all dimensions are in millimeters (mm) unless specified. 16-bit microcontrollers (up to 32 kb flash and 2 kb sram) with advanced analog
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 2 ? 2007-2011 microchip technology inc. pic24hj32gp202/204 and pic24hj16gp304 product families the device names, pin counts, memory sizes and peripheral availability of each family are listed in table 1 , followed by their pinout diagrams. table 1: pic24hj32gp202/204 and pi c24hj16gp304 controller families device pins program flash memory (kbytes) ram remappable peripherals 10/12-bit adc i 2 c? i/o pins (maximum) packages remappable pins 16-bit timer input capture output compare standard pwm uart external interrupts (2) spi pic24hj32gp202 28 32 2 16 3 (1) 421 3 1 1 adc, 10 ch 121 spdip soic ssop qfn-s PIC24HJ32GP204 44 32 2 26 3 (1) 4 2 1 3 1 1 adc, 13 ch 135 qfn tqfp pic24hj16gp304 44 16 2 26 3 (1) 4 2 1 3 1 1 adc, 13 ch 135 qfn tqfp note 1: only two out of three timers are remappable. 2: only two out of three interrupts are remappable.
? 2007-2011 microchip technology inc. ds70289j-page 3 pic24hj32gp202/204 and pic24hj16gp304 pin diagrams note 1: the rpn pins can be used by any remappable peripheral. see tab l e 1 for the list of available peripherals. 2: the metal plane at the bottom of the device is not connecte d to any pins and is recommended to be connected to v ss externally. 3: refer to section 2.3 ?cpu logic filter capacitor connection (v cap )? for proper connection to this pin. pic24hj32gp202 mclr v ss v dd an0/v ref +/cn2/ra0 an1/v ref -/cn3/ra1 av dd av ss pged1/an2/c2in-/rp0 (1) /cn4/rb0 pgec3/ascl1/rp6 (1) /cn24/rb6 sosco/t1ck/cn0/ra4 sosci/rp4 (1) /cn1/rb4 v ss osc2/clko/cn29/ra3 osc1/clki/cn30/ra2 v cap (3) int0/rp7/cn23/rb7 tdo/sda1/rp9 (1) /cn21/rb9 tck/scl1/rp8 (1) /cn22/rb8 an5/rp3 (1) /cn7/rb3 an4/rp2 (1) /cn6/rb2 pgec1/an3/c2in+/rp1 (1) /cn5/rb1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 28 27 26 25 24 23 22 21 20 19 18 17 16 15 an9/rp15 (1) /cn11/rb15 an10/rp14 (1) /cn12/rb14 an11/rp13 (1) /cn13/rb13 an12/rp12 (1) /cn14/rb12 pged2/tdi/rp10 (1) /cn16/rb10 pgec2/tms/rp11 (1) /cn15/rb11 pged3/asda1/rp5 (1) /cn27/rb5 28-pin spdip, soic, ssop = pins are up to 5v tolerant 28-pin qfn-s (2) 10 11 2 3 6 1 18 19 20 21 22 12 13 14 15 8 7 16 17 23 24 25 26 27 28 9 pic24hj32gp202 5 4 mclr v ss v dd an0/v ref +/cn2/ra0 an1/v ref -/cn3/ra1 av dd av ss pged1/an2/c2in-/rp0 (1) /cn4/rb0 pgec3/ascl1/rp6/cn24/rb6 sosco/t1ck/cn0/ra4 sosci/rp4/cn1/rb4 vss osc2/clko/cn29/ra3 osc1/clki/cn30/ra2 v cap (3) int0/rp7 (1(1)) /cn23/rb7 tdo/sda1/rp9 (1) /cn21/rb9 tck/scl1/rp8 (1) /cn22/rb8 an5/rp3 (1) /cn7/rb3 an4/rp2 (1) /cn6/rb2 pgec1/an3/c2in+/rp1 (1) /cn5/rb1 an9/rp15 (1) /cn11/rb15 an10/rp14 (1) /cn12/rb14 an11/rp13 (1) /cn13/rb13 an12/rp12 (1) /cn14/rb12 pged2/tdi/rp10/cn16/rb10 pgec2/tms/rp11 (1) /cn15/rb11 pged3/asda1/rp5 (1) /cn27/rb5 = pins are up to 5v tolerant
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 4 ? 2007-2011 microchip technology inc. pin diagrams (continued) note 1: the rpn pins can be used by any remappable peripheral. see ta b l e 1 for the list of available peripherals. 2: the metal plane at the bottom of the device is not con nected to any pins and is recommended to be connected to v ss externally. 3: refer to section 2.3 ?cpu logic filter capacitor connection (v cap )? for proper connection to this pin. scl1/rp8 (1) /cn22/rb8 int0/rp7 (1) /cn23/rb7 pgec3/ascl1/rp6 (1) /cn24/rb6 pged3/asda1/rp5 (1) /cn27/rb5 v dd tdi/ra9 sosco/t1ck/cn0/ra4 v ss rp21 (1) /cn26/rc5 rp20 (1) /cn25/rc4 rp19 (1) /cn28/rc3 pgec1/an3/c2in+/rp1 (1) /cn5/rb1 pged1/an2/c2in-/rp0 (1) /cn4/rb0 an1/v ref -/cn3/ra1 an0/v ref +/cn2/ra0 mclr tms/ra10 av dd av ss an9/rp15 (1) /cn11/rb15 an10/rp14 (1) /cn12/rb14 an12/rp12 (1) /cn14/rb12 pgec2/rp11 (1) /cn15/rb11 pged2/rp10 (1) /cn16/rb10 v cap (3) rp25 (1) /cn19/rc9 rp24 (1) /cn20/rc8 rp23 (1) /cn17/rc7 rp22 (1) /cn18/rc6 sda1/rp9 (1) /cn21/rb9 an4/rp2 (1) /cn6/rb2 an5/rp3 (1) /cn7/rb3 an6/rp16 (1) /cn8/rc0 an7/rp17 (1) /cn9/rc1 an8/rp18 (1) /cn10/rc2 sosci/rp4 (1) /cn1/rb4 v dd v ss osc1/clki/cn30/ra2 osc2/clko/cn29/ra3 tdo/ra8 44-pin qfn (2) an11/rp13 (1) /cn13/rb13 tck/ra7 PIC24HJ32GP204 pic24hj16gp304 44 43 42 41 40 39 38 37 36 35 12 13 14 15 16 17 18 19 20 21 3 30 29 28 27 26 25 24 23 4 5 7 8 9 10 11 1 2 32 31 6 22 33 34 v ss = pins are up to 5v tolerant
? 2007-2011 microchip technology inc. ds70289j-page 5 pic24hj32gp202/204 and pic24hj16gp304 pin diagrams (continued) note 1: the rpn pins can be used by any rema ppable peripheral. see tab l e 1 for the list of available peripherals. 2: refer to section 2.3 ?cpu logic filter capacitor connection (v cap )? for proper connection to this pin. 10 11 2 3 4 5 6 1 18 19 20 21 22 12 13 14 15 38 8 7 44 43 42 41 40 39 16 17 29 30 31 32 33 23 24 25 26 27 28 36 34 35 9 37 scl1/rp8 (1) /cn22/rb8 int0/ rp7 (1) /cn23/rb7 pgec3/ascl1/rp6 (1) /cn24/rb6 pged3/asda1/rp5 (1) /cn27/rb5 v dd tdi/ra9 sosco/t1ck/cn0/ra4 v ss rp21 (1) /cn26/rc5 rp20 (1) /cn25/rc4 rp19 (1) /cn28/rc3 pgec1/an3/c2in+/rp1 (1) /cn5/rb1 pged1/an2/c2in-/rp0 (1) /cn4/rb0 an1/v ref -/cn3/ra1 an0/v ref +/cn2/ra0 mclr tms/ra10 av dd av ss an9/rp15 (1) /cn11/rb15 an10/rp14 (1) /cn12/rb14 an12/rp12 (1) /cn14/rb12 pgec2/rp11 (1) /cn15/rb11 pged2/rp10 (1) /cn16/rb10 v cap (2) v ss rp25 (1) /cn19/rc9 rp24 (1) /cn20/rc8 rp23 (1) /cn17/rc7 rp22/cn18/rc6 sda1 (1) /rp9 (1) /cn21/rb9 an4/rp2 (1) /cn6/rb2 an5/rp3 (1) /cn7/rb3 an6/rp16 (1) /cn8/rc0 an7/rp17 (1) /cn9/rc1 an8/rp18 (1) /cn10/rc2 sosci/rp4 (1) /cn1/rb4 v dd v ss osc1/clki/cn30/ra2 osc2/clko/cn29/ra3 tdo/ra8 44-pin tqfp an11/rp13 (1) /cn13/rb13 tck/ra7 PIC24HJ32GP204 pic24hj16gp304 = pins are up to 5v tolerant
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 6 ? 2007-2011 microchip technology inc. table of contents 1.0 device overview ............................................................................................................. ............................................................. 9 2.0 guidelines for getting started wi th 16-bit microcontrollers ................................................................. ....................................... 13 3.0 cpu......................................................................................................................... ................................................................... 17 4.0 memory organization ......................................................................................................... ........................................................ 25 5.0 flash program memory ........................................................................................................ ...................................................... 47 6.0 resets ..................................................................................................................... .................................................................. 53 7.0 interrupt controller ........................................................................................................ ............................................................. 63 8.0 oscillator configuration .................................................................................................... .......................................................... 89 9.0 power-saving features....................................................................................................... ....................................................... 99 10.0 i/o ports .................................................................................................................. ................................................................. 105 11.0 timer1 ..................................................................................................................... ................................................................. 127 12.0 timer2/3 feature........................................................................................................... ........................................................... 131 13.0 input capture.............................................................................................................. .............................................................. 137 14.0 output compare............................................................................................................. .......................................................... 141 15.0 serial peripheral interface (spi).......................................................................................... ..................................................... 145 16.0 inter-integrated circuit? (i 2 c?) ............................................................................................................................ .................. 151 17.0 universal asynchronous rece iver transmitter (uart) ......................................................................... .................................. 159 18.0 10-bit/12-bit analog-to-digital converter (adc) ............................................................................ ........................................... 165 19.0 special features ........................................................................................................... ........................................................... 179 20.0 instruction set summary .................................................................................................... ...................................................... 187 21.0 development support........................................................................................................ ....................................................... 195 22.0 electrical characteristics ................................................................................................. ......................................................... 199 23.0 high temperature electrical characteristics ................................................................................ ............................................ 245 24.0 dc and ac device characteristics graphs.................................................................................... .......................................... 255 25.0 packaging information...................................................................................................... ........................................................ 259 appendix a: revision history................................................................................................... .......................................................... 271 index .......................................................................................................................... ....................................................................... 281 the microchip web site ......................................................................................................... ............................................................ 285 customer change notification service ........................................................................................... ................................................... 285 customer support ............................................................................................................... ............................................................... 285 reader response ................................................................................................................ .............................................................. 286 product identification system.................................................................................................. ........................................................... 287 to our valued customers it is our intention to provide our valued cu stomers with the best documentation possible to ensure successful use of your micro chip products. to this end, we will continue to improve our publicati ons to better suit your needs. our publications will be refined and enhanced as new volumes and updates are introduced. if you have any questions or comments regar ding this publication, please contact the marketing communications department via e-mail at docerrors@microchip.com or fax the reader response form in the back of this data sheet to (480) 792-4150. we wel- come your feedback. most current data sheet to obtain the most up-to-date version of this data s heet, please register at our worldwide web site at: http://www.microchip.com you can determine the version of a data sheet by examining its literature number found on the bottom outside corner of any page . the last character of the literature number is the vers ion number, (e.g., ds30000a is version a of document ds30000). errata an errata sheet, describing minor operational differences from the data sheet and recommended workarounds, may exist for curren t devices. as device/docum entation issues become known to us, we will publish an errata sheet. t he errata will s pecify the revisi on of silicon and revision of document to which it applies. to determine if an errata sheet exists for a partic ular device, please check with one of the following: ? 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? 2007-2011 microchip technology inc. ds70289j-page 7 pic24hj32gp202/204 and pic24hj16gp304 referenced sources this device data sheet is based on the following individual chapters of the ?dspic33f/pic24h family reference manual? . these documents should be considered as the general re ference for the operation of a particular module or device feature. ? section 1. ?introduction? (ds70197) ? section 2. ?cpu? (ds70204) ? section 3. ?data memory? (ds70202) ? section 4. ?program memory? (ds70202) ? section 5. ?flash programming? (ds70191) ? section 6. ?interrupts (ds70184) ? section 7. ?oscillator? (ds70186) ? section 8. ?reset? (ds70192) ? section 9. ?watchdog timer and power-saving modes? (ds70196) ? section 10. ?i/o ports? (ds70193) ? section 11. ?timers? (ds70205) ? section 12. ?input capture? (ds70198) ? section 13. ?output compare? (ds70209) ? section 16. ?analog-to-digital converter (adc)? (ds70183) ? section 17. ?uart? (ds70188) ? section 18. ?serial peri pheral interface (spi)? (ds70206) ? section 19. ?inter-integrated circuit? (i 2 c?)? (ds70195) ? section 23. ?codeguard? security? (ds70199) ? section 25. ?device configuration? (ds70194) note 1: to access the documents listed below, browse to the documentation section of the PIC24HJ32GP204 product page of the microchip web site ( www.microchip.com ) or select a family reference manual section from the following list. in addition to parameters, features, and other documentation, the resulting page provides links to the related family reference manual sections.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 8 ? 2007-2011 microchip technology inc. notes:
? 2007-2012 microchip technology inc. ds70289j-page 9 pic24hj32gp202/204 and pic24hj16gp304 1.0 device overview this document contains devic e-specific information for the following devices: ? pic24hj32gp202 ? PIC24HJ32GP204 ? pic24hj16gp304 figure 1-1 shows a general block diagram of the core and peripheral modules in the pic24hj32gp202/204 and pic24hj16gp304 family of devices. table 1-1 lists the functions of the various pins shown in the pinout diagrams. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 devices. it is not intended to be a comprehensive refer- ence source. to complement the infor- mation in this data sheet, refer to the ?dspic33f/pic24h family reference manual? . please see the microchip web site ( www.microchip.com ) for the latest dspic33f/pic24h family reference manual sections. 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 10 ? 2007-2012 microchip technology inc. figure 1-1: pic24hj32gp202/204 an d pic24hj16gp304 block diagram 16 osc1/clki osc2/clko v dd , v ss timing generation mclr power-up timer oscillator start-up timer power-on reset watchdog timer brown-out reset precision reference band gap frc/lprc oscillators regulator voltage v cap uart1 ic1,2,7,8 oc/ spi1 i2c1 porta note: not all pins or features are implement ed on all device pinout configurations. see ?pin diagrams? for the specific pins and features present on each device. pwm1,2 cnx instruction decode and control pch pcl 16 program counter 16-bit alu 23 23 24 23 instruction reg pcu 16 x 16 w register array rom latch 16 ea mux 16 8 interrupt controller psv and table data access control block stack control logic loop control logic address latch program memory data latch literal data 16 16 16 16 data latch address latch 16 x ram data bus 17 x 17 multiplier divide support 16 control signals to various blocks adc1 timers portb remappable address generator units 1-3 pins portc
? 2007-2012 microchip technology inc. ds70289j-page 11 pic24hj32gp202/204 and pic24hj16gp304 table 1-1: pinout i/o descriptions pin name pin type buffer type pps description an0-an12 i analog no analog input channels. clki clko i o st/cmos ? no no external clock source input. always associated with osc1 pin function. oscillator crystal output. connects to crystal or resonator in crystal oscillator mode. optionally func tions as clko in rc and ec modes. always associated with osc2 pin function. osc1 osc2 i i/o st/cmos ? no no oscillator crystal input. st buffer when configured in rc mode; cmos otherwise. oscillator crystal output. connects to crystal or resonator in crystal oscillator mode. optionally func tions as clko in rc and ec modes. sosci sosco i o st/cmos ? no no 32.768 khz low-power oscillator crystal input; cmos otherwise. 32.768 khz low-power oscillator crystal output. cn0-cn30 i st no change notification inputs. can be software programmed for internal weak pull-ups on all inputs. ic1-ic2 ic7-ic8 istyes yes capture inputs 1/2. capture inputs 7/8. ocfa oc1-oc2 i o st ? yes yes compare fault a input (for compare channels 1 and 2). compare outputs 1 through 2. int0 int1 int2 i i i st st st no yes yes external interrupt 0. external interrupt 1. external interrupt 2. ra0-ra4 ra7-ra10 i/o st no no porta is a bidirectional i/o port. rb0-rb15 i/o st no portb is a bidirectional i/o port. rc0-rc9 i/o st no portc is a bidirectional i/o port. t1ck t2ck t3ck i i i st st st no yes yes timer1 external clock input. timer2 external clock input. timer3 external clock input. u1cts u1rts u1rx u1tx i o i o st ? st ? yes yes yes yes uart1 clear to send. uart1 ready to send. uart1 receive. uart1 transmit. sck1 sdi1 sdo1 ss1 i/o i o i/o st st ? st yes yes yes yes synchronous serial clock input/output for spi1. spi1 data in. spi1 data out. spi1 slave synchronization or frame pulse i/o. scl1 sda1 ascl1 asda1 i/o i/o i/o i/o st st st st no no no no synchronous serial clock input/output for i2c1. synchronous serial data input/output for i2c1. alternate synchronous serial clock input/output for i2c1. alternate synchronous serial data input/output for i2c1. tms tck tdi tdo i i i o st st st ? no no no no jtag test mode select pin. jtag test cl ock input pin. jtag test data input pin. jtag test data output pin. pged pgec1 pged2 pgec2 pged3 pgec3 i/o i i/o i i/o i st st st st st st no no no no no no data i/o pin for programming/debugging communication channel 1. clock input pin for programming/debugging communication channel 1. data i/o pin for programming/debugging communication channel 2. clock input pin for programming/debugging communication channel 2. data i/o pin for programming/debugging communication channel 3. clock input pin for programming/debugging communication channel 3. legend: cmos = cmos compatible input or output analog = analog input o = output st = schmitt trigger input with cmos levels i = input p = power pps = peripheral pin select
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 12 ? 2007-2012 microchip technology inc. v cap p ? no cpu logic filter capacitor connection. v ss p ? no ground reference for logic and i/o pins. v ref + i analog no analog voltage reference (high) input. v ref - i analog no analog voltage reference (low) input. a vdd p p no positive supply for analog modules. this pin must be connected at all times. mclr i/p st no master clear (reset) input. this pin is an active-low reset to the device. a vss p p no ground reference for analog modules. v dd p ? no positive supply for peripheral logic and i/o pins. table 1-1: pinout i/o descriptions (continued) pin name pin type buffer type pps description legend: cmos = cmos compatible input or output analog = analog input o = output st = schmitt trigger input with cmos levels i = input p = power pps = peripheral pin select
? 2007-2011 microchip technology inc. ds70289j-page 13 pic24hj32gp202/204 and pic24hj16gp304 2.0 guidelines for getting started with 16-bit microcontrollers 2.1 basic connection requirements getting started with the pic24hj32gp202/204 and pic24hj16gp304 family of 16-bit microcontrollers requires attention to a minimal set of device pin connections before proceeding with development. the following is a list of pin names, which must always be connected: ? all v dd and v ss pins (see section 2.2 ?decoupling capacitors? ) ? all av dd and av ss pins (even if the adc module is not used) (see section 2.2 ?decoupling capacitors? ) ?v cap (see section 2.3 ?cpu logic filter capacitor connection (v cap )? ) ?mclr pin (see section 2.4 ?master clear (mclr) pin? ) ? pgecx/pgedx pins used for in-circuit serial programming? (icsp?) and debugging purposes (see section 2.5 ?icsp pins? ) ? osc1 and osc2 pins when external oscillator source is used (see section 2.6 ?externa l oscillator pins? ) additionally, the following pins may be required: ?v ref +/v ref - pins are used when external voltage reference for the adc module is implemented 2.2 decoupling capacitors the use of decoupling capacitors on every pair of power supply pins, such as v dd , v ss , av dd and av ss is required. consider the following criteria when using decoupling capacitors: ? value and type of capacitor: recommendation of 0.1 f (100 nf), 10-20v. this capacitor should be a low-esr and have a resonance frequency in the range of 20 mhz and higher. it is recommended that ceramic capacitors be used. ? placement on the printed circuit board: the decoupling capacitors should be placed as close to the pins as possible. it is recommended to place the capacitors on the same side of the board as the microcontroller. if space is con- stricted, the capacitor can be placed on another layer on the pcb using a via; however, ensure that the trace length from the pin to the capacitor is within one-quarter inch (6 mm) in length. ? handling high frequency noise: if the board is experiencing high frequency noise, upward of tens of mhz, add a second ceramic-type capacitor in parallel to the above described decoupling capacitor. the value of the second capacitor can be in the range of 0.01 f to 0.001 f. place this second capacitor next to the primary decoupling capacitor. in high-speed circuit designs, consider implementing a decade pair of capacitances as close to the power and ground pins as possible. for example, 0.1 f in parallel with 0.001 f. ? maximizing performance: on the board layout from the power supply circuit, run the power and return traces to the decoupling capacitors first, and then to the microcontroller pins. this ensures that the decoupling capacitors are first in the power chain. equally important is to keep the trace length between the capacitor and the power pins to a minimum thereby reducing pcb track inductance. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. it is not intended to be a comprehensive ref- erence source. to complement the infor- mation in this data sheet, refer to the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: the av dd and av ss pins must be connected independent of the adc voltage reference source.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 14 ? 2007-2011 microchip technology inc. figure 2-1: recommended minimum connection 2.2.1 tank capacitors on boards with power traces running longer than six inches in length, it is suggested to use a tank capacitor for integrated circuits including microcontrollers to supply a local power source. the value of the tank capacitor should be determined based on the trace resistance that connects the power supply source to the microcontroller, and t he maximum current drawn by the microcontroller in the application. in other words, select the tank capacitor so that it meets the acceptable voltage sag at the device. typical values range from 4.7 f to 47 f. 2.3 cpu logic filter capacitor connection (v cap ) a low-esr (< 5 ohms) capacitor is required on the v cap pin, which is used to stabilize the voltage regulator output voltage. the v cap pin must not be connected to v dd , and must have a capacitor between 4.7 f and 10 f, 16v connected to ground. the type can be ceramic or tantalum. refer to section 22.0 ?electrical characteristics? for additional information. the placement of this capacitor should be close to the v cap . it is recommended that the trace length not exceed one-quarter inch (6 mm). refer to section 19.2 ?on-chip voltage regulator? for details. 2.4 master clear (mclr ) pin the mclr pin provides for two specific device functions: ? device reset ? device programming and debugging during device programming and debugging, the resistance and capacitance that can be added to the pin must be considered. device programmers and debuggers drive the mclr pin. consequently, specific voltage levels (v ih and v il ) and fast signal transitions must not be adve rsely affected. therefore, specific values of r and c will need to be adjusted based on the application and pcb requirements. for example, as shown in figure 2-2 , it is recommended that capacitor c is isolated from the mclr pin during programming and debugging operations. place the components shown in figure 2-2 within one-quarter inch (6 mm) from the mclr pin. figure 2-2: example of mclr pin connections pic24h v dd v ss v dd v ss v ss v dd av dd av ss v dd v ss 0.1 f ceramic 0.1 f ceramic 0.1 f ceramic 0.1 f ceramic c r v dd mclr 0.1 f ceramic v cap l1 (1) r1 10 f tantalum note 1: as an option, instead of a hard-wired connection, an inductor (l1) can be substituted between v dd and av dd to improve adc noise rejection. the inductor impedance should be less than 1 and the inductor capacity greater than 10 ma. where: f f cnv 2 ------------- - = f 1 2 lc () ----------------------- = l 1 2 fc () --------------------- - ?? ?? 2 = (i.e., adc conversion rate/2) note 1: r 10 k is recommended. a suggested starting value is 10 k . ensure that the mclr pin v ih and v il specifications are met. 2: r1 470w will limit any current flowing into mclr from the external capacitor c, in the event of mclr pin breakdown, due to elec- trostatic discharge (esd) or electrical overstress (eos). ensure that the mclr pin v ih and v il specifications are met. c r1 (2) r (1) v dd mclr pic24h jp
? 2007-2011 microchip technology inc. ds70289j-page 15 pic24hj32gp202/204 and pic24hj16gp304 2.5 icsp pins the pgecx and pgedx pins are used for in-circuit serial programming? (icsp)? and debugging pur- poses. it is recommended to keep the trace length between the icsp connector and the icsp pins on the microcontroller as short as possible. if the icsp con- nector is expected to experience an esd event, a series resistor is recommended, with the value in the range of a few tens of ohms, not to exceed 100 ohms. pull-up resistors, series diodes and capacitors on the pgecx and pgedx pins are not recommended as they will interfere with the programmer/debugger communi- cations to the device. if such discrete components are an application requirement, they should be removed from the circuit during programming and debugging. alternatively, refer to t he ac/dc characteristics and timing requirements information in the respective device flash programming spec ification for information on capacitive loading limits and pin input voltage high (v ih ) and input low (v il ) requirements. ensure that the ?communication channel select? (i.e., pgecx/pgedx pins) programmed into the device matches the physical con nections for the icsp to mplab ? icd 3 or mplab real ice? in-circuit emu- lator for more information on mplab icd 3 or mplab real ice in-circuit emulator connection requirements, refer to the following documents that are available on the microchip website. ? ?using mplab ? icd 3? (poster) ds51765 ? ?mplab ? icd 3 design advisory? ds51764 ? ?mplab ? real ice? in-circuit emulator user?s guide? ds51616 ? ?using mplab ? real ice? in-circuit emulator? (poster) ds51749 2.6 external oscillator pins many microcontrollers have options for at least two oscillators: a high-frequency primary oscillator and a low-frequency secondary oscillator (refer to section 8.0 ?oscillator configuration? for details). the oscillator circuit should be placed on the same side of the board as the microcontroller. also, place the oscillator circuit close to the respective oscillator pins, not exceeding one-half inch (12 mm) distance between them. the load capacitors should be placed next to the oscillator itself, on the same side of the board. use a grounded copper pour around the oscillator circuit to isolate them from surrounding circuits. the grounded copper pour should be routed directly to the mcu ground. do not run any signal traces or power traces inside the ground pour. also, if using a two-sided board, avoid any traces on the other side of the board wher e the crystal is placed. a suggested layout is shown in figure 2-3 . figure 2-3: suggested placement of the oscillator circuit 13 main oscillator guard ring guard trace secondary oscillator 14 15 16 17 18 19 20
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 16 ? 2007-2011 microchip technology inc. 2.7 oscillator value conditions on device start-up if the pll of the target device is enabled and configured for the device start-up oscillator, the maximum oscillator source frequency must be limited to 8 mhz for start-up with pll enabled. this means that if the external oscillator frequency is outside this range, the application must start-up in frc mode first. the default pll settings after a por with an oscillator frequency outside this range will violate the device operating speed. once the device powers up, the application firmware can initialize the pll sfrs, clkdiv and plldbf to a suitable value, and then perform a clock switch to the oscillator + pll clock source . note that clock switching must be enabled in the device configuration word. 2.8 configuration of analog and digital pins during icsp operations if mplab icd 3 or mplab real ice in-circuit emulator is selected as a debugger, it automatically initializes all of the a/d input pins (anx) as ?digital? pins, by setting all bits in the ad1pcfgl registers. the bits in the registers th at correspond to the a/d pins that are initialized by mplab icd 3 or mplab real ice in-circuit emulator, must not be cleared by the user application firmware; otherwise, communication errors will result between the debugger and the device. if your application needs to use certain a/d pins as analog input pins during the debug session, the user application must clear the corresponding bits in the ad1pcfgl register during initialization of the adc module. when the mplab icd 3 or mplab real ice in-circuit emulator is used as a programmer, the user application firmware must correctly configure the ad1pcfgl register. automatic initialization of this register is only done during debugger operation. failure to correctly configure the register(s) will result in all a/d pins being recognized as analog input pins, resulting in the port value being read as a logic ? 0 ?, which may affect user application functionality. 2.9 unused i/os unused i/o pins should be configured as outputs and driven to a logic low state. alternatively, connect a 1k to 10k resistor between v ss and the unused pins.
? 2007-2011 microchip technology inc. ds70289j-page 17 pic24hj32gp202/204 and pic24hj16gp304 3.0 cpu the pic24hj32gp202/204 and pic24hj16gp304 cpu modules have a 16-bit (data) modified harvard architecture with an enhanced instruction set and addressing modes. the cpu has a 24-bit instruction word with a variable length opcode field. the program counter (pc) is 23 bits wide and addresses up to 4m x 24 bits of user program memory space. the actual amount of program memory implemented varies by device. a single-cycl e instruction prefetch mechanism is used to help maintain throughput and provides predictable executi on. all instructions execute in a single cycle, with the exc eption of instructions that change the program flow, the double word move ( mov.d ) instruction and the table instructions. overhead-free, single-cycle program loop constructs are supported using the repeat instruction, which is interruptible at any time. the pic24hj32gp202/204 and pic24hj16gp304 devices have sixteen, 16-bit working registers in the programmer?s model. each of the working registers can serve as a data, address or address offset register. the 16th working register (w15) operates as a software stack pointer (sp) for interrupts and calls. the instruction set includes many addressing modes and is designed for optimum c compiler efficiency. for most instructions, the devices are capable of executing a data (or program data) memory read, a working register (data) read, a data memory write and a program (instruction) memory read per instruction cycle. as a result, three pa rameter instructions can be supported, allowing a + b = c operations to be executed in a single cycle. a block diagram of the cpu is shown in figure 3-1 . the programmer?s model for the pic24hj32gp202/204 and pic24hj16gp304 is shown in figure 3-2 . 3.1 data addressing overview the data space can be linearly addressed as 32k words or 64 kbytes using an addr ess generation unit (agu). the upper 32 kbytes of the data space memory map can optionally be mapped into program space at any 16k pro- gram word boundary defined by the 8-bit program space visibility page register (psv pag). the program to data space mapping feature lets any instruction access pro- gram space as if it were data space. the data space also includes 2 kbytes of dma ram, which is primarily used for dma data transfers, but this may be used as general purpose ram. 3.2 special mcu features the pic24hj32gp202/204 and pic24hj16gp304 devices feature a 17-bit by 17-bit, single-cycle multiplier. the multiplier can perform signed, unsigned and mixed-sign multiplication. using a 17-bit by 17-bit multiplier for 16-bit by 16-bit multiplication makes mixed-sign multiplication possible. the pic24hj32gp202/204 and pic24hj16gp304 devices support 16/16 and 32/16 integer divide operations. all divide in structions are iterative operations. they must be executed within a repeat loop, resulting in a total execution time of 19 instruction cycles. the divide operation can be interru pted during any of those 19 cycles without loss of data. a multi-bit data shifter is used to perform up to a 16-bit, left or right shift in a single cycle. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 2. cpu? (ds70204) of the ?dspic33f/pic24h family refer- ence manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 18 ? 2007-2011 microchip technology inc. figure 3-1: pic24hj32gp202/204 and pi c24hj16gp304 cpu core block diagram instruction decode and control pch pcl program counter 16-bit alu 24 23 instruction reg pcu 16 x 16 w register array rom latch ea mux interrupt controller stack control logic loop control logic control signals to various blocks literal data 16 16 16 to peripheral modules data latch address latch 16 x ram address generator units x data bus 17 x 17 divide support 16 16 23 23 16 8 psv and table data access control block 16 16 16 program memory data latch address latch multiplier
? 2007-2011 microchip technology inc. ds70289j-page 19 pic24hj32gp202/204 and pic24hj16gp304 figure 3-2: pic24hj32gp202/204 and pic24hj16gp304 programmer?s model pc22 pc0 7 0 d0 d15 program counter data table page address status register working registers w1 w2 w3 w4 w5 w6 w7 w8 w9 w10 w11 w12 w13 w14/frame pointer w15/stack pointer 7 0 program space visib ility page address z 0 ? ? ?? rcount 15 0 repeat loop counter ipl2 ipl1 splim stack pointer limit register srl push.s shadow do shadow ?? 15 0 core configuration register legend corcon ? dc ra n tblpag psvpag ipl0 ov w0/wreg srh c
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 20 ? 2007-2011 microchip technology inc. 3.3 cpu resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 3.3.1 key resources ? section 2. ?cpu? (ds70204) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 21 pic24hj32gp202/204 and pic24hj16gp304 3.4 cpu control registers register 3-1: sr: cpu status register u-0 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 ? ? ? ? ? ? ?dc bit 15 bit 8 r/w-0 (1) r/w-0 (2) r/w-0 (2) r-0 r/w-0 r/w-0 r/w-0 r/w-0 ipl<2:0> (2) ra n ov z c bit 7 bit 0 legend: c = clear only bit r = readable bit u = unimplemented bit, read as ?0? s = set only bit w = writable bit -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-9 unimplemented: read as ? 0 ? bit 8 dc: mcu alu half carry/borrow bit 1 = a carry-out from the 4th low-order bit (for byte si zed data) or 8th low-order bit (for word sized data) of the result occurred 0 = no carry-out from the 4th low-order bit (for byte sized data) or 8th low-order bit (for word sized data) of the result occurred bit 7-5 ipl<2:0>: cpu interrupt priority level status bits (2) 111 = cpu interrupt priority level is 7 (15), user interrupts disabled 110 = cpu interrupt priority level is 6 (14) 101 = cpu interrupt priority level is 5 (13) 100 = cpu interrupt priority level is 4 (12) 011 = cpu interrupt priority level is 3 (11) 010 = cpu interrupt priority level is 2 (10) 001 = cpu interrupt priority level is 1 (9) 000 = cpu interrupt priority level is 0 (8) bit 4 ra: repeat loop active bit 1 = repeat loop in progress 0 = repeat loop not in progress bit 3 n: mcu alu negative bit 1 = result was negative 0 = result was non-negative (zero or positive) bit 2 ov: mcu alu overflow bit this bit is used for signed arithmetic (2?s complem ent). it indicates an overflow of the magnitude which causes the sign bit to change state. 1 = overflow occurred for signed arit hmetic (in this arithmetic operation) 0 = no overflow occurred bit 1 z: mcu alu zero bit 1 = an operation which affects the z bit has set it at some time in the past 0 = the most recent operation which affects the z bit has cleared it (i.e., a non-zero result) bit 0 c: mcu alu carry/borrow bit 1 = a carry-out from the most significa nt bit (msb) of the result occurred 0 = no carry-out from the most sign ificant bit of the result occurred note 1: the ipl<2:0> bits are concatenated with the ipl<3> bi t (corcon<3>) to form the cpu interrupt priority level. the value in parentheses indicates the ipl if ipl<3> = 1 . user interrupts are disabled when ipl<3> = 1 . 2: the ipl<2:0> status bits are read-onl y when the nstdis bit (intcon1<15>) = 1 .
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 22 ? 2007-2011 microchip technology inc. register 3-2: corcon: core control register u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 r/c-0 r/w-0 u-0 u-0 ? ? ? ?ipl3 (1) psv ? ? bit 7 bit 0 legend: c = clear only bit r = readable bit w = writable bit -n = value at por ?1? = bit is set 0? = bit is cleared ?x = bit is unknow n u = unimplemented bit, read as ?0? bit 15-4 unimplemented: read as ? 0 ? bit 3 ipl3: cpu interrupt priority level status bit 3 (1) 1 = cpu interrupt priority level is greater than 7 0 = cpu interrupt priority level is 7 or less bit 2 psv: program space visibility in data space enable bit 1 = program space visible in data space 0 = program space not visible in data space bit 1-0 unimplemented: read as ? 0 ? note 1: the ipl3 bit is concatenated with t he ipl<2:0> bits (sr<7:5>) to form the cpu interrupt priority level.
? 2007-2011 microchip technology inc. ds70289j-page 23 pic24hj32gp202/204 and pic24hj16gp304 3.5 arithmetic logic unit (alu) the arithmetic logic unit (alu) is 16 bits wide and is capable of addition, subtraction, bit shifts and logic operations. unless otherwis e mentioned, arithmetic operations are 2?s complement in nature. the alu may affect the values of the ca rry (c), zero (z), negative (n), overflow (ov) and digit carry (dc) status bits in the sr register depending on the operation. the c and dc status bits operate as borrow and digit borrow bits respectively, for subtraction operations. the alu can perform 8-bit or 16-bit operations depending on the mode of t he instruction that is used. data for the alu operation can come from the w register array, or data memory depending on the addressing mode of the instruction. likewise, output data from the alu can be writte n to the w register array or a data memory location. refer to the ?16-bit mcu and dsc programmer?s ref- erence manual? (ds70157) for more information on the sr bits affected by each instruction. the cpu incorporates hardware support for both multiplication and division. this includes a dedicated hardware multiplier and a support hardware for 16-bit divisor division. 3.5.1 multiplier using the high-speed 17-bit x 17-bit multiplier, the alu supports unsigned, signed or mixed-sign operation in several multiplication modes: ? 16-bit x 16-bit signed ? 16-bit x 16-bit unsigned ? 16-bit signed x 5-bit (literal) unsigned ? 16-bit unsigned x 16-bit unsigned ? 16-bit unsigned x 5-bit (literal) unsigned ? 16-bit unsigned x 16-bit signed ? 8-bit unsigned x 8-bit unsigned 3.5.2 divider the divide block supports 32-bit/16-bit and 16-bit/16-bit signed and unsigned integer divide operations with the following data sizes. ? 32-bit signed/16-bit signed divide ? 32-bit unsigned/16-bit unsigned divide ? 16-bit signed/16-bit signed divide ? 16-bit unsigned/16-bit unsigned divide the quotient for all divide instructions ends up in w0 and the remainder in w1. a 16-bit signed and unsigned div instructions can s pecify any w register for both the 16-bit divisor (wn) and any w register (aligned) pair (w(m + 1):wm) for the 32-bit dividend. the divide algorithm ta kes one cycle per bit of divisor, so both 32-bit/16-bit and 16-bit/16-bit instructions take the same number of cycles to execute. 3.5.3 multi-bit data shifter the multi-bit data shifter is capable of performing up to 16-bit arithmetic or logic righ t shifts, or up to 16-bit left shifts in a single cycle. th e source can be either a working register or a memory location. the shifter requires a signed binary value to determine both the magnitude (number of bits) and direction of the shift operation. a positive value shifts the operand right. and a negative value shifts the operand left. a value of ? 0 ? does not modify the operand.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 24 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 25 pic24hj32gp202/204 and pic24hj16gp304 4.0 memory organization the pic24hj32gp202/2 04 and pic24hj16gp304 architecture features separate program and data memory spaces and buses. this architecture also allows the direct access of program memory from the data space during code execution. 4.1 program address space the devices program addre ss memory space is 4m instructions. the space is addressable by a 24-bit value derived either from the 23-bit program counter (pc) during program execution, or from table operation or data space remapping as described in section 4.6 ?interfacing program and data memory spaces? . user application access to the program memory space is restricted to the lowe r half of the address range (0x000000 to 0x7fffff). the exception is the use of tblrd/tblwt operations, which use tblpag<7> to permit access to the configuration bits and device id sections of the config uration memory space. the memory maps for the pic24hj32gp202/204 and pic24hj16gp304 devices are shown in figure 4-1 . figure 4-1: program memory for pic24hj 32gp202/204 and pic24h j16gp304 devices note: this data sheet summarizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a comprehensive reference source. to complement the information in this data sheet, refer to the ?dspic33f / pic24h family reference manual? , ?section 4. program memory? (ds70202), which is available from the microchip website ( www.microchip.com ). reset address 0x000000 0x0000fe 0x000002 0x000100 device configuration user program flash memory 0x005800 0x0057fe (11264 instructions) 0x800000 0xf80000 registers 0xf80017 0xf80018 devid (2) 0xfefffe 0xff0000 0xfffffe 0xf7fffe unimplemented (read ? 0 ?s) goto instruction 0x000004 reserved 0x7ffffe reserved 0x000200 0x0001fe 0x000104 alternate vector table reserved interrupt vector table pic24hj32gp202/204 configuration memory space user memory space reset address 0x000000 0x0000fe 0x000002 0x000100 device configuration user program flash memory 0x002c00 0x002bfe (5632 instructions) 0x800000 0xf80000 registers 0xf80017 0xf80018 devid (2) 0xfefffe 0xff0000 0xfffffe 0xf7fffe unimplemented (read ? 0 ?s) goto instruction 0x000004 reserved 0x7ffffe reserved 0x000200 0x0001fe 0x000104 alternate vector table reserved interrupt vector table pic24hj16gp304 configuration memory space user memory space
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 26 ? 2007-2011 microchip technology inc. 4.1.1 program memory organization the program memory space is organized in word-addressable blocks. al though it is treated as 24 bits wide, it is more appropriate to think of each address of the program memory as a lower and upper word, with the upper byte of the upper word being unimplemented. the lower word always has an even address, while the upper word has an odd address (see figure 4-2 ). program memory addresses are always word-aligned on the lower word, and addresses are incremented or decremented by two during code execution. this arrangement provides compatibility with data memory space addressing and makes data in the program memory space accessible. 4.1.2 interrupt and trap vectors all devices reserve the addresses between 0x00000 and 0x000200 for hard-coded program execution vec- tors. a hardware reset vector is provided to redirect code execution from the de fault value of the pc on device reset to the actual start of code. a goto instruction is programmed by the user application at 0x000000, with the actual add ress for the start of code at 0x000002. the devices also have two interrupt vector tables, located from 0x000004 to 0x0000ff and 0x000100 to 0x0001ff. these vector tables allow each of the many device interrupt sources to be handled by separate interrupt service routines (isrs). section 7.1 ?interrupt vector table? provides a more detailed discussion of the interrupt vector tables. figure 4-2: program memory organization 0 8 16 pc address 0x000000 0x000002 0x000004 0x000006 23 00000000 00000000 00000000 00000000 program memory ?phantom? byte (read as ? 0 ?) least significant word most significant word instruction width 0x000001 0x000003 0x000005 0x000007 msw address (lsw address)
? 2007-2011 microchip technology inc. ds70289j-page 27 pic24hj32gp202/204 and pic24hj16gp304 4.2 data address space the cpu has a separate 16 bit wide data memory space. the data space is accessed using separate address generation units (a gus) for read and write operations. the data memory maps is shown in figure 4-3 . all effective addresses (eas) in the data memory space are 16 bits wide and point to the bytes within the data space. this arrangement gives a data space address range of 64 kbytes or 32k words. the lower half of the data memory space (that is, when ea<15> = 0 ) is used for implemented memory addresses, while the upper half (ea<15> = 1 ) is reserved for the program space visibility area (see section 4.6.3 ?reading data from program memory using program space visibility? ). pic24hj32gp202/204 and pic24hj16gp304 devices implement up to 2 kbytes of data memory. should an ea point to a location outside of this area, an all-zero word or byte will be returned. 4.2.1 data space width the data memory space is organized in byte addressable, 16 bit wide blocks. data is aligned in data memory and registers as 16-bit words, but all data space eas resolve to bytes. the least significant bytes (lsbs) of each word have even addresses, while the most significant bytes (msbs) have odd addresses. 4.2.2 data memory organization and alignment to maintain backward compatibility with pic ? devices and improve data space memory usage efficiency, the pic24hj32gp202/204 and pic24hj16gp304 instruc- tion set supports both word and byte operations. as a consequence of byte accessibi lity, all effective address calculations are internally scaled to step through word-aligned memory. for ex ample, the core recog- nizes that post-modified re gister indirect addressing mode [w s ++] will result in a value of ws + 1 for byte operations and ws + 2 for word operations. data byte reads will read the complete word that contains the byte, using the lsb of any ea to determine which byte to select. the selected byte is placed onto the lsb of the data path. that is, data memory and registers are organized as two parallel byte-wide entities with shar ed (word) address decode, but separate write lines. data byte writes only write to the corresponding side of the array or register that matches the byte address. all word accesses must be aligned to an even address. misaligned word data fetches are not supported, so care must be taken when mixing byte and word operations, or when translat ing from 8-bit mcu code. if a misaligned read or write is attempted, an address error trap is generated. if the error occurred on a read, the instruction underway is co mpleted. if the instruction occurred on a write, the instruction is executed but the write does not occur. in either case, a trap is then executed, allowing the system and/or user application to examine the machine state prior to execution of the address fault. all byte loads into any w register are loaded into the least significant byte. the most significant byte is not modified. a sign-extend instruction ( se ) is provided to allow users to translate 8-bit signed data to 16-bit signed values. alternatively, for 16-bit unsigned data, user applications can clear the msb of any w register by executing a zero-extend ( ze ) instruction on the appropriate address. 4.2.3 sfr space the first 2 kbytes of the near data space, from 0x0000 to 0x07ff, is primarily occupied by special function registers (sfrs). these are used by the pic24hj32gp202/204 and pic24hj16gp304 core and peripheral modules to control the operation of the device. sfrs are distributed amon g the modules that they control, and are generally grouped together by module. much of the sfr space contains unused addresses; these are read as ? 0 ?. a complete listing of implemented sfrs, including their addresses, is shown in table 4-1 through ta b l e 4 - 2 2 . 4.2.4 near data space the 8 kbyte area between 0x0000 and 0x1fff is referred to as the near data space. locations in this space are directly addressable via 13-bit absolute address field within all memory direct instructions. additionally, the whole data space is addressable using mov instructions, which support memory direct addressing mode with a 16-bit address field, or by using indirect addressing mode using a working register as an address pointer. note: the actual set of peripheral features and interrupts varies by the device. refer to the corresponding device tables and pinout diagrams for device-specific information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 28 ? 2007-2011 microchip technology inc. figure 4-3: data memory map for pic2 4hj32gp202/204 and pic24hj16gp304 devices with 2 kb ram 4.3 program memory resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 4.3.1 key resources ? section 4. ?program memory? (ds70202) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools 0x0000 0x07fe 0x0ffe 0xfffe lsb address 16 bits lsb msb msb address 0x0001 0x07ff 0xffff optionally mapped into program memory 0x0801 0x0800 0x1000 2 kbyte sfr space 2 kbyte sram space 0x8001 0x8000 sfr space x data ram (x) x data unimplemented (x) 0x0fff 0x1001 0x1fff 0x1ffe 0x2001 0x2000 8 kbyte near data space note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 29 pic24hj32gp202/204 and pic24hj16gp304 4.4 special function register maps table 4-1: cpu core registers map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets wreg0 0000 working register 0 0000 wreg1 0002 working register 1 0000 wreg2 0004 working register 2 0000 wreg3 0006 working register 3 0000 wreg4 0008 working register 4 0000 wreg5 000a working register 5 0000 wreg6 000c working register 6 0000 wreg7 000e working register 7 0000 wreg8 0010 working register 8 0000 wreg9 0012 working register 9 0000 wreg10 0014 working register 10 0000 wreg11 0016 working register 11 0000 wreg12 0018 working register 12 0000 wreg13 001a working register 13 0000 wreg14 001c working register 14 0000 wreg15 001e working register 15 0800 splim 0020 stack pointer limit register xxxx pcl 002e program counter low word register 0000 pch 0030 ? ? ? ? ? ? ? ? program counter high byte register 0000 tblpag 0032 ? ? ? ? ? ? ? ? table page address pointer register 0000 psvpag 0034 ? ? ? ? ? ? ? ? program memory visibility page address pointer register 0000 rcount 0036 repeat loop counter register xxxx sr 0042 ? ? ? ? ? ? ? dc ipl2 ipl1 ipl0 ra n ov z c 0000 corcon 0044 ? ? ? ? ? ? ? ? ? ? ? ? ipl3 psv ? ? 0000 disicnt 0052 ? ? disable interrupts counter register xxxx legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 30 ? 2007-2011 microchip technology inc. table 4-2: change notification re gister map for pic24hj32gp202 sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets cnen1 0060 cn15ie cn14ie cn13ie cn12ie cn11ie ?- ? ? cn7ie cn6ie cn5ie cn4ie cn3ie cn2ie cn1ie cn0ie 0000 cnen2 0062 ? cn30ie cn29ie ? cn27ie ? ? cn24ie cn23ie cn22ie cn21ie ? ? ? ? cn16ie 0000 cnpu1 0068 cn15pue cn14pue cn13pue cn12pue cn11pue ? ? ? cn7pue cn6pue cn5pue cn4pue cn3pue cn2pue cn1pue cn0pue 0000 cnpu2 006a ? cn30pue cn29pue ? cn27pue ? ? cn24pue cn23pue cn22pue cn21pue ? ? ? ? cn16pue 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-3: change notification register map for PIC24HJ32GP204 and pic24hj16gp304 sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets cnen1 0060 cn15ie cn14ie cn13ie cn12ie cn11ie cn10ie cn9ie cn8ie cn7ie cn6ie cn5ie cn4ie cn3ie cn2ie cn1ie cn0ie 0000 cnen2 0062 ? cn30ie cn29ie cn28ie cn27ie cn26ie cn25ie cn24ie cn23ie cn22ie cn21ie cn20ie cn19ie cn18ie cn17ie cn16ie 0000 cnpu1 0068 cn15pue cn14pue cn13pue cn12pue cn11pue cn10pue cn9pue cn8pue cn7pue cn6pue cn5pue cn4pue cn3pue cn2pue cn1pue cn0pue 0000 cnpu2 006a ? cn30pue cn29pue cn28pue cn27pue cn26pue cn25pue cn24pue cn23pue cn22pue cn21pue cn20pue cn19pue cn18pue cn17pue cn16pue 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
? 2007-2011 microchip technology inc. ds70289j-page 31 pic24hj32gp202/204 and pic24hj16gp304 table 4-4: interrupt controller register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets intcon1 0080 nstdis ? ? ? ? ? ? ? ? div0err ? matherr addrerr stkerr oscfail ? 0000 intcon2 0082 altivt disi ? ? ? ? ? ? ? ? ? ? ? int2ep int1ep int0ep 0000 ifs0 0084 ? ? ad1if u1txif u1rxif spi1if spi1eif t3if t2if oc2if ic2if ? t1if oc1if ic1if int0if 0000 ifs1 0086 ? ?int2if ? ? ? ? ?ic8ific7if ? int1if cnif ? mi2c1if si2c1if 0000 ifs4 008c ? ? ? ? ? ? ? ? ? ? ? ? ? ?u1eif ? 0000 iec0 0094 ? ? ad1ie u1txie u1rxie spi1ie spi1eie t3ie t2ie oc2ie ic2ie ? t1ie oc1ie ic1ie int0ie 0000 iec1 0096 ? ?int2ie ? ? ? ? ?ic8ieic7ie ? int1ie cnie ? mi2c1ie si2c1ie 0000 iec4 009c ? ? ? ? ? ? ? ? ? ? ? ? ? ?u1eie ? 0000 ipc0 00a4 ? t1ip<2:0> ?oc1ip<2:0> ?ic1ip<2:0> ? int0ip<2:0> 4444 ipc1 00a6 ? t2ip<2:0> ?oc2ip<2:0> ?ic2ip<2:0> ? ? ? ? 4440 ipc2 00a8 ? u1rxip<2:0> ? spi1ip<2:0> ? spi1eip<2:0> ? t3ip<2:0> 4444 ipc3 00aa ? ? ? ? ? ? ? ? ? ad1ip<2:0> ? u1txip<2:0> 0044 ipc4 00ac ? cnip<2:0> ? ? ? ? ? mi2c1ip<2:0> ? si2c1ip<2:0> 4044 ipc5 00ae ?ic8ip<2:0> ?ic7ip<2:0> ? ? ? ? ? int1ip<2:0> 4404 ipc7 00b2 ? ? ? ? ? ? ? ? ? int2ip<2:0> ? ? ? ? 0040 ipc16 00c4 ? ? ? ? ? ? ? ? ? u1eip<2:0> ? ? ? ? 0040 inttreg 00e0 ? ? ? ?ilr<3:0> ? vecnum<6:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 32 ? 2007-2011 microchip technology inc. table 4-5: timer register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets tmr1 0100 timer1 register 0000 pr1 0102 period register 1 ffff t1con 0104 ton ? tsidl ? ? ? ? ? ? tgate tckps<1:0> ? tsync tcs ? 0000 tmr2 0106 timer2 register 0000 tmr3hld 0108 timer3 holding register (for 32-bit timer operations only) xxxx tmr3 010a timer3 register 0000 pr2 010c period register 2 ffff pr3 010e period register 3 ffff t2con 0110 ton ? tsidl ? ? ? ? ? ? tgate tckps<1:0> t32 ? tcs ? 0000 t3con 0112 ton ? tsidl ? ? ? ? ? ? tgate tckps<1:0> ? ? tcs ? 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-6: input capture register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets ic1buf 0140 input 1 capture register xxxx ic1con 0142 ? ? icsidl ? ? ? ? ? ictmr ici<1:0> icov icbne icm<2:0> 0000 ic2buf 0144 input 2 capture register xxxx ic2con 0146 ? ? icsidl ? ? ? ? ? ictmr ici<1:0> icov icbne icm<2:0> 0000 ic7buf 0158 input 7 capture register xxxx ic7con 015a ? ? icsidl ? ? ? ? ? ictmr ici<1:0> icov icbne icm<2:0> 0000 ic8buf 015c input 8capture register xxxx ic8con 015e ? ? icsidl ? ? ? ? ? ictmr ici<1:0> icov icbne icm<2:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-7: output compare register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets oc1rs 0180 output compare 1 secondary register xxxx oc1r 0182 output compare 1 register xxxx oc1con 0184 ? ? ocsidl ? ? ? ? ? ? ? ? ocflt octsel ocm<2:0> 0000 oc2rs 0186 output compare 2 secondary register xxxx oc2r 0188 output compare 2 register xxxx oc2con 018a ? ? ocsidl ? ? ? ? ? ? ? ? ocflt octsel ocm<2:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
? 2007-2011 microchip technology inc. ds70289j-page 33 pic24hj32gp202/204 and pic24hj16gp304 table 4-8: i2c1 register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets i2c1rcv 0200 ? ? ? ? ? ? ? ? receive register 0000 i2c1trn 0202 ? ? ? ? ? ? ? ? transmit register 00ff i2c1brg 0204 ? ? ? ? ? ? ? baud rate generator register 0000 i2c1con 0206 i2cen ? i2csidl sclrel ipmien a10m disslw smen gcen stren ackdt acken rcen pen rsen sen 1000 i2c1stat 0208 ackstat trstat ? ? ? bcl gcstat add10 iwcol i2cov d_a p s r_w rbf tbf 0000 i2c1add 020a ? ? ? ? ? ? address register 0000 i2c1msk 020c ? ? ? ? ? ? address mask register 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-9: uart1 register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bi t 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets u1mode 0220 uarten ? usidl iren rtsmd ? uen1 uen0 wake lpback abaud urxinv brgh pdsel<1:0> stsel 0000 u1sta 0222 utxisel1 utxinv utxisel0 ? utxbrk utxen utxbf trmt urxisel<1:0> adden ridle perr ferr oerr urxda 0110 u1txreg 0224 ? ? ? ? ? ? ? uart transmit register xxxx u1rxreg 0226 ? ? ? ? ? ? ? uart receive register 0000 u1brg 0228 baud rate generator prescaler 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-10: spi1 register map sfr name sfr addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets spi1stat 0240 spien ? spisidl ? ? ? ? ? ?spirov ? ? ? ? spitbf spirbf 0000 spi1con1 0242 ? ? ? dissck dissdo mode16 smp cke ssen ckp msten spre<2:0> ppre<1:0> 0000 spi1con2 0244 frmen spifsd frmpol ? ? ? ? ? ? ? ? ? ? ? frmdly ? 0000 spi1buf 0248 spi1 transmit and receive buffer register 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 34 ? 2007-2011 microchip technology inc. table 4-11: peripheral pin select input register map file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10bit 9bit 8bit 7bit 6bit 5bit 4bit 3bit 2bit 1bit 0 all resets rpinr0 0680 ? ? ? int1r<4:0> ? ? ? ? ? ? ? ? 1f00 rpinr1 0682 ? ? ? ? ? ? ? ? ? ? ?int2r<4:0> 001f rpinr3 0686 ? ? ?t3ckr<4:0> ? ? ?t2ckr<4:0> 1f1f rpinr7 068e ? ? ? ic2r<4:0> ? ? ? ic1r<4:0> 1f1f rpinr10 0694 ? ? ? ic8r<4:0> ? ? ? ic7r<4:0> 1f1f rpinr11 0696 ? ? ? ? ? ? ? ? ? ? ?ocfar<4:0> 001f rpinr18 06a4 ? ? ? u1ctsr<4:0> ? ? ?u1rxr<4:0> 1f1f rpinr20 06a8 ? ? ?sck1r<4:0> ? ? ?sdi1r<4:0> 1f1f rpinr21 06aa ? ? ? ? ? ? ? ? ? ? ? ss1r<4:0> 001f legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-12: peripheral pin select outp ut register map for pic24hj32gp202 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets rpor0 06c0 ? ? ? rp1r<4:0> ? ? ? rp0r<4:0> 0000 rpor1 06c2 ? ? ?rp3r<4:0> ? ? ? rp2r<4:0> 0000 rpor2 06c4 ? ? ?rp5r<4:0> ? ? ? rp4r<4:0> 0000 rpor3 06c6 ? ? ?rp7r<4:0> ? ? ? rp6r<4:0> 0000 rpor4 06c8 ? ? ?rp9r<4:0> ? ? ? rp8r<4:0> 0000 rpor5 06ca ? ? ?rp11r<4:0> ? ? ? rp10r<4:0> 0000 rpor6 06cc ? ? ? rp13r<4:0> ? ? ? rp12r<4:0> 0000 rpor7 06ce ? ? ? rp15r<4:0> ? ? ? rp14r<4:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
? 2007-2011 microchip technology inc. ds70289j-page 35 pic24hj32gp202/204 and pic24hj16gp304 table 4-13: peripheral pin select output regist er map for pic24hj32g p204 and pic24hj16gp304 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets rpor0 06c0 ? ? ? rp1r<4:0> ? ? ? rp0r<4:0> 0000 rpor1 06c2 ? ? ?rp3r<4:0> ? ? ? rp2r<4:0> 0000 rpor2 06c4 ? ? ?rp5r<4:0> ? ? ? rp4r<4:0> 0000 rpor3 06c6 ? ? ?rp7r<4:0> ? ? ? rp6r<4:0> 0000 rpor4 06c8 ? ? ?rp9r<4:0> ? ? ? rp8r<4:0> 0000 rpor5 06ca ? ? ?rp11r<4:0> ? ? ? rp10r<4:0> 0000 rpor6 06cc ? ? ? rp13r<4:0> ? ? ? rp12r<4:0> 0000 rpor7 06ce ? ? ? rp15r<4:0> ? ? ? rp14r<4:0> 0000 rpor8 06d0 ? ? ? rp17r<4:0> ? ? ?rp16r<4:0> 0000 rpor9 06d2 ? ? ? rp19r<4:0> ? ? ?rp18r<4:0> 0000 rpor10 06d4 ? ? ?rp21r<4:0> ? ? ?rp20r<4:0> 0000 rpor11 06d6 ? ? ?rp23r<4:0> ? ? ?rp22r<4:0> 0000 rpor12 06d8 ? ? ?rp25r<4:0> ? ? ?rp24r<4:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 36 ? 2007-2011 microchip technology inc. table 4-14: adc1 register map for PIC24HJ32GP204 and pic24hj16gp304 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets adc1buf0 0300 adc data buffer 0 xxxx adc1buf1 0302 adc data buffer 1 xxxx adc1buf2 0304 adc data buffer 2 xxxx adc1buf3 0306 adc data buffer 3 xxxx adc1buf4 0308 adc data buffer 4 xxxx adc1buf5 030a adc data buffer 5 xxxx adc1buf6 030c adc data buffer 6 xxxx adc1buf7 030e adc data buffer 7 xxxx adc1buf8 0310 adc data buffer 8 xxxx adc1buf9 0312 adc data buffer 9 xxxx adc1bufa 0314 adc data buffer 10 xxxx adc1bufb 0316 adc data buffer 11 xxxx adc1bufc 0318 adc data buffer 12 xxxx adc1bufd 031a adc data buffer 13 xxxx adc1bufe 031c adc data buffer 14 xxxx adc1buff 031e adc data buffer 15 xxxx ad1con1 0320 adon ?adsidl ? ? ad12b form<1:0> ssrc<2:0> ? simsam asam samp done 0000 ad1con2 0322 vcfg<2:0> ? ? cscna chps<1:0> bufs ?smpi<3:0>bufmalts 0000 ad1con3 0324 adrc ? ? samc<4:0> adcs<7:0> 0000 ad1chs123 0326 ? ? ? ? ? ch123nb<1:0> ch123sb ? ? ? ? ? ch123na<1:0> ch123sa 0000 ad1chs0 0328 ch0nb ? ? ch0sb<4:0> ch0na ? ? ch0sa<4:0> 0000 ad1pcfgl 032c ? ? ? pcfg12 pcfg11 pcfg10 pcfg9 pcfg8 pcfg7 pc fg6 pcfg5 pcfg4 pcfg3 pcfg2 pcfg1 pcfg0 0000 ad1cssl 0330 ? ? ? css12 css11 css10 css9 css8 css7 css6 css5 css4 css3 css2 css1 css0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
? 2007-2011 microchip technology inc. ds70289j-page 37 pic24hj32gp202/204 and pic24hj16gp304 table 4-15: adc1 register map for pic24hj32gp202 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets adc1buf0 0300 adc data buffer 0 xxxx adc1buf1 0302 adc data buffer 1 xxxx adc1buf2 0304 adc data buffer 2 xxxx adc1buf3 0306 adc data buffer 3 xxxx adc1buf4 0308 adc data buffer 4 xxxx adc1buf5 030a adc data buffer 5 xxxx adc1buf6 030c adc data buffer 6 xxxx adc1buf7 030e adc data buffer 7 xxxx adc1buf8 0310 adc data buffer 8 xxxx adc1buf9 0312 adc data buffer 9 xxxx adc1bufa 0314 adc data buffer 10 xxxx adc1bufb 0316 adc data buffer 11 xxxx adc1bufc 0318 adc data buffer 12 xxxx adc1bufd 031a adc data buffer 13 xxxx adc1bufe 031c adc data buffer 14 xxxx adc1buff 031e adc data buffer 15 xxxx ad1con1 0320 adon ?adsidl ? ? ad12b form<1:0> ssrc<2:0> ? simsam asam samp done 0000 ad1con2 0322 vcfg<2:0> ? ? cscna chps<1:0> bufs ? smpi<3:0> bufm alts 0000 ad1con3 0324 adrc ? ? samc<4:0> adcs<7:0> 0000 ad1chs123 0326 ? ? ? ? ? ch123nb<1:0> ch123sb ? ? ? ? ? ch123na<1:0> ch123sa 0000 ad1chs0 0328 ch0nb ? ? ch0sb<4:0> ch0na ? ? ch0sa<4:0> 0000 ad1pcfgl 032c ? ? ? pcfg12 pcfg11 pcfg10 pcfg9 ? ? ? pcfg5 pcfg4 pcfg3 pcfg2 pcfg1 pcfg0 0000 ad1cssl 0330 ? ? ? css12 css11 css10 css9 ? ? ? css5 css4 css3 css2 css1 css0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 38 ? 2007-2011 microchip technology inc. table 4-16: porta register map for pic24hj32gp202 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets trisa 02c0 ? ? ? ? ? ? ? ? ? ? ? trisa4 trisa3 trisa2 trisa1 trisa0 001f porta 02c2 ? ? ? ? ? ? ? ? ? ? ? ra4 ra3 ra2 ra1 ra0 xxxx lata 02c4 ? ? ? ? ? ? ? ? ? ? ? lata4 lata3 lata2 lata1 lata0 xxxx odca 02c6 ? ? ? ? ? ? ? ? ? ? ? odca4 odca3 odca2 odca1 odca0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-17: porta register map for PIC24HJ32GP204 and pic24hj16gp304 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets trisa 02c0 ? ? ? ? ? trisa10 trisa9 trisa8 trisa7 ? ? trisa4 trisa3 trisa2 trisa1 trisa0 001f porta 02c2 ? ? ? ? ? ra10 ra9 ra8 ra7 ? ? ra4 ra3 ra2 ra1 ra0 xxxx lata 02c4 ? ? ? ? ? lata10 lata9 lata8 lata7 ? ? lata4 lata3 lata2 lata1 lata0 xxxx odca 02c6 ? ? ? ? ? odca10 odca9 odca8 odca7 ? ? odca4 odca3 odca2 odca1 odca0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. table 4-18: portb register map file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets trisb 02c8 trisb15 trisb14 trisb13 trisb12 trisb11 trisb10 trisb9 trisb8 trisb7 trisb6 trisb5 trisb4 trisb3 trisb2 trisb1 trisb0 ffff portb 02ca rb15 rb14 rb13 rb12 rb11 rb10 rb9 rb8 rb7 rb6 rb5 rb4 rb3 rb2 rb1 rb0 xxxx latb 02cc latb15 latb14 latb13 latb12 latb11 latb10 latb9 latb8 latb7 latb6 latb5 latb4 latb3 latb2 latb1 latb0 xxxx odcb 02ce odcb15 odcb14 odcb13 odcb12 odcb11 odcb10 odcb9 odcb8 odcb7 odcb6 odcb5 odcb4 odcb3 odcb2 odcb1 odcb0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal for pinhigh devices. table 4-19: portc register map for PIC24HJ32GP204 and pic24hj16gp304 file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets trisc 02d0 ? ? ? ? ? ? trisc9 trisc8 trisc7 trisc6 trisc5 t risc4 trisc3 trisc2 trisc1 trisc0 03ff portc 02d2 ? ? ? ? ? ? rc9 rc8 rc7 rc6 rc5 rc4 rc4 rc2 rc1 rc0 xxxx latc 02d4 ? ? ? ? ? ? latc9 latc8 latc7 latc6 latc5 latc4 latc4 latc2 latc1 latc0 xxxx odcc 02d6 ? ? ? ? ? ? odcc9 odcc8 odcc7 odcc6 odcc5 odcc4 odcc4 odcc2 odcc1 odcc0 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
? 2007-2011 microchip technology inc. ds70289j-page 39 pic24hj32gp202/204 and pic24hj16gp304 table 4-20: system control register map file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets rcon 0740 trapr iopuwr ? ? ? ? cm vregs extr swr swdten wdto sleep idle bor por xxxx (1) osccon 0742 ? cosc<2:0> ? nosc<2:0> clklock iolock lock ?cf ? lposcen oswen 0300 (2) clkdiv 0744 roi doze<2:0> dozen frcdiv<2:0> pllpost<1:0> ? pllpre<4:0> 3040 pllfbd 0746 ? ? ? ? ? ? ? plldiv<8:0> 0030 osctun 0748 ? ? ? ? ? ? ? ? ? ?tun<5:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. note 1: rcon register reset values dependent on type of reset. 2: osccon register reset values dependent on the fo sc configuration bits and by type of reset. table 4-21: nvm register map file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets nvmcon 0760 wr wren wrerr ? ? ? ? ? ?erase ? ?nvmop<3:0> 0000 (1) nvmkey 0766 ? ? ? ? ? ? ? ? nvmkey<7:0> 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal. note 1: reset value shown is for por only. value on other reset states is dependent on the state of memory write or erase operations at the time of reset. table 4-22: pmd register map file name addr bit 15 bit 14 bit 13 bit 12 bit 11 bit 10 bit 9 bit 8 bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 all resets pmd1 0770 ? ? t3md t2md t1md ? ? ? i2c1md ? u1md ? spi1md ? ? ad1md 0000 pmd2 0772 ic8md ic7md ? ? ? ?ic2mdic1md ? ? ? ? ? ?oc2mdoc1md 0000 legend: x = unknown value on reset, ? = unimplemented, read as ? 0 ?. reset values are shown in hexadecimal.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 40 ? 2007-2011 microchip technology inc. 4.4.1 software stack in addition to its use as a working register, the w15 register is also used as a software stack pointer. the stack pointer always points to the first available free word and grows from lower to higher addresses. it pre-decrements for stack pops and post-increments for stack pushes, as shown in figure 4-4 . for a pc push during any call instruction, the msb of the pc is zero-extended before the push, ensuring that the msb is always clear. the stack pointer limit r egister (splim) associated with the stack pointer sets an upper address boundary for the stack. splim is uninitialized at reset. similarly, the stack pointer, splim<0> is forced to ? 0 ? because all stack operations must be word aligned. when an ea is generated using w15 as a source or destination pointer, the resulting address is compared with the value in splim. if the contents of the stack pointer (w15) and the splim register are equal and a push operation is performed, a stack error trap will not occur. the stack error trap will occur on a subsequent push operation. for example, to cause a stack error trap when the stack grows beyond address 0x1000 in ram, initialize the splim with the value 0x0ffe. similarly, a stack pointer underflow (stack error) trap is generated when the stack pointer address is found to be lesser than 0x0800. this prevents the stack from interfering with the special function register (sfr) space. a write to the splim register should not be immediately followed by an indirect read operation using w15. figure 4-4: call stack frame 4.4.2 data ram protection feature the pic24h product family supports data ram protection features that enable segments of ram to be protected when used in conjunction with boot and secure code segment security. bsram (secure ram segment for bs) is accessible only from the boot segment flash code when enabled. ssram (secure ram segment for ram) is accessible only from the secure segment flash code when enabled. see table 4-1 for an overview of the bsram and ssram sfrs. 4.5 instruction addressing modes the addressing modes shown in table 4-23 form the basis of the addressing modes optimized to support the specific features of i ndividual instructions. the addressing modes provided in the mac class of instructions differ from th ose in the other instruction types. 4.5.1 file register instructions most file register instructions use a 13-bit address field (f) to directly address data present in the first 8192 bytes of data memory (near data space). most file register instructions employ a working register, w0, which is denoted as wreg in these instructions. the destination is typically either the same file register or wreg (with the exception of the mul instruction), which writes the result to a register or register pair. the mov instruction allows additional flexibility and can access the entire data space. 4.5.2 mcu instructions the three-operand mcu instru ctions are of the form: operand 3 = operand 1 operand 2 where: operand 1 is always a working register (that is, the addressing mode can only be register direct), which is referred to as wb. operand 2 can be a w register, fetched from data memory, or a 5-bit literal. the result location can be either a w register or a data memory location. the fol- lowing addressing modes are supported by mcu instructions: ? register direct ? register indirect ? register indirect post-modified ? register indirect pre-modified ? 5-bit or 10-bit literal note: a pc push during exception processing concatenates the srl register to the msb of the pc prior to the push. pc<15:0> 000000000 0 15 w15 (before call ) w15 (after call ) stack grows toward higher address 0x0000 pc<22:16> pop : [--w15] push : [w15++] note: not all instructions support all the addressing modes given above. individual instructions can support different subsets of these addressing modes.
? 2007-2011 microchip technology inc. ds70289j-page 41 pic24hj32gp202/204 and pic24hj16gp304 table 4-23: fundamental addressing modes supported 4.5.3 move ( mov ) instruction move instructions provide a greater degree of addressing flexibility than the other instructions. in addition to the addressing modes supported by most mcu instructions, mov instructions also support register indirect with r egister offset addressing mode. this is also referred to as register indexed mode. in summary, move instructi ons support the following addressing modes: ? register direct ? register indirect ? register indirect post-modified ? register indirect pre-modified ? register indirect with register offset (indexed) ? register indirect with literal offset ? 8-bit literal ? 16-bit literal 4.5.4 other instructions besides the addressing modes outlined previously, some instructions use literal constants of various sizes. for example, bra (branch) instructions use 16-bit signed literals to specify the branch destination directly, whereas the disi instruction uses a 14-bit unsigned literal field. in some instructions, such as add acc , the source of an operand or result is implied by the opcode itself. certain operations, such as nop , do not have any operands. addressing mode description file register direct the address of the file register is specified explicitly. register direct the contents of a register are accessed directly. register indirect the contents of wn forms the effective address (ea.) register indirect post-modified the contents of wn forms the ea. wn is post-modified (incremented or decremented) by a constant value. register indirect pre-modified wn is pre-modified (inc remented or decremented) by a signed constant value to form the ea. register indirect with register offset (register indexed) the sum of wn and wb forms the ea. register indirect with literal offset the sum of wn and a literal forms the ea. note: for the mov instructions, the addressing mode specified in the instruction can differ for the source and the destination ea. however, the 4-bit wb (register offset) field is shared by both source and destination (but typically only used by one). note: not all instructions support all the addressing modes given above. individual instructions may support different subsets of these addressing modes.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 42 ? 2007-2011 microchip technology inc. 4.6 interfacing program and data memory spaces the device architecture us es a 24-bit-wide program space and a 16 bit wide data space. the architecture is also a modified harvard sc heme, which means that the data can also be present in the program space. to use this data successfully, it mu st be accessed in a way that preserves the alignment of information in both spaces. aside from normal execution, the architecture provides two methods by which program space can be accessed during operation: ? using table instructions to access individual bytes or words anywhere in the program space ? remapping a portion of the program space into the data space (program space visibility) table instructions allow an application to read or write to small areas of the program memory. this capability makes the method ideal for accessing data tables that need to be updated periodically. it also allows access to all bytes of the program word. the remapping method allows an application to access a large block of data on a read-only basis, which is ideal for look ups from a large table of static data. the application can only access the least significant word of the program word. 4.6.1 addressing program space since the address ranges for the data and program spaces are 16 and 24 bits, respectively, a method is needed to create a 23-bit or 24-bit program address from 16-bit data registers. the solution depends on the interface method to be used. for table operations, the 8-bit table page register (tblpag) is used to define a 32k word region within the program space. this is concatenated with a 16-bit ea to arrive at a full 24-bit program space address. in this format, the most significant bit of tblpag is used to determine if the operation occurs in the user memory (tblpag<7> = 0 ) or the configuration memory (tblpag<7> = 1 ). for remapping operations, the 8-bit program space visibility register (psvp ag) is used to define a 16k word page in the program space. when the most significant bit of the ea is ? 1 ?, psvpag is concatenated with the lower 15 bits of the ea to form a 23-bit program space address. unlike table operations, this limits remapping operations strictly to the user memory area. table 4-24 and figure 4-5 show how the program ea is created for table operations and remapping accesses from the data ea. here, p<23:0> refers to a program space word, and d<15:0> refers to a data space word. table 4-24: program sp ace address construction access type access space program space address <23> <22:16> <15> <14:1> <0> instruction access (code execution) user 0 pc<22:1> 0 0xx xxxx xxxx xxxx xxxx xxx0 tblrd/tblwt (byte/word read/write) user tblpag<7:0> data ea<15:0> 0xxx xxxx xxxx xxxx xxxx xxxx configuration tblpag<7:0> data ea<15:0> 1xxx xxxx xxxx xxxx xxxx xxxx program space visibility (block remap/read) user 0 psvpag<7:0> data ea<14:0> (1) 0 xxxx xxxx xxx xxxx xxxx xxxx note 1: data ea<15> is always ? 1 ? in this case, but is not used in calculating the program space address. bit 15 of the address is psvpag<0>.
? 2007-2011 microchip technology inc. ds70289j-page 43 pic24hj32gp202/204 and pic24hj16gp304 figure 4-5: data acc ess from program spac e address generation 0 program counter 23 bits 1 psvpag 8 bits ea 15 bits program counter (1) select tblpag 8 bits ea 16 bits byte select 0 0 1/0 user/configuration table operations (2) program space visibility (1) space select 24 bits 23 bits (remapping) 1/0 0 note 1: the least significant bit (lsb) of program space addresses is always fixed as ? 0 ? to maintain word alignment of data in the program and data spaces. 2: table operations are not required to be word -aligned. table read operations are permitted in the configuration memory space.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 44 ? 2007-2011 microchip technology inc. 4.6.2 data access from program memory using table instructions the tblrdl and tblwtl instructions offer a direct method to read or write the lower word of any address within the program space without going through data space. the tblrdh and tblwth instructions are the only methods to read or write the upper 8 bits of a program space word as data. the pc is incremented by 2 for each successive 24-bit program word. this allows program memory addresses to directly map to data space addresses. program memory can thus be regarded as two 16 bit wide word address spaces, residing side by side, each with the same address range. tblrdl and tblwtl access the space that contains the le ast significant data word. tblrdh and tblwth access the space that contains the upper data byte. two table instructions are provided to move byte or word sized (16-bit) data to and from program space. both function as either byte or word operations. ? tblrdl (table read low): in word mode, this instruction maps the lower word of the program space location (p<15:0>) to a data address (d<15:0>). in byte mode, either the upper or lower byte of the lower program word is mapped to the lower byte of a data address. the upper byte is selected when byte select is ? 1 ?; the lower byte is selected when it is ? 0 ?. ? tblrdh ( table read high): in word mode, this instruction maps the entire upper word of a program address (p<23:16>) to a data address. note that d<15:8>, the ?phantom by te?, will always be ? 0 ?. in byte mode, this instruction maps the upper or lower byte of the program word to d<7:0> of the data address, as in the tblrdl instruction. note that the data will always be ? 0 ? when the upper ?phantom? byte is selected (byte select = 1 ). in a similar fashion, two table instructions, tblwth and tblwtl , are used to write individual bytes or words to a program space address. the details of their operation are explained in section 5.0 ?flash program memory? . for all table operations, the area of program memory space to be accessed is determined by the table page register (tblpag). tblpag covers the entire program memory space of the device, including user and configuration spaces. when tblpag<7> = 0 , the table page is located in the user memory space. when tblpag<7> = 1 , the page is located in configuration space. figure 4-6: accessing program memory with table instructions 0 8 16 23 00000000 00000000 00000000 00000000 ?phantom? byte tblrdh.b (wn<0> = 0 ) tblrdl.w tblrdl.b (wn<0> = 1 ) tblrdl.b (wn<0> = 0 ) 23 15 0 tblpag 02 0x000000 0x800000 0x020000 0x030000 program space the address for the table operation is determined by the data ea within the page defined by the tblpag register. only read operations are shown; write operations are also valid in the user memory area.
? 2007-2011 microchip technology inc. ds70289j-page 45 pic24hj32gp202/204 and pic24hj16gp304 4.6.3 reading data from program memory using program space visibility the upper 32 kbytes of data space may optionally be mapped into any 16k word page of the program space. this option provides transparent access to the stored constant data from the data space without the need to use special instructions (such as tblrdl/h ). program space access through the data space occurs if the most significant bit of the data space ea is ? 1 ? and program space visibility is enabled by setting the psv bit in the core control register (corcon<2>). the location of the program memory space to be mapped into the data space is determined by the program space visibility page register (psvpag). this 8-bit register defines any one of 256 possible pages of 16k words in program space. in effect, psvpag functions as the upper 8 bits of the program memory address, with the 15 bits of the ea functioning as the lower bits. by incrementing the pc by 2 for each program memory word, the lower 15 bits of data space addresses directly map to the lower 15 bits in the cor- responding program space addresses. data reads to this area ad d a cycle to the instruction being executed, since two program memory fetches are required. although each data space address 0x8000 and higher maps directly into a corresponding program memory address (see figure 4-7 ), only the lower 16 bits of the 24-bit program word are us ed to contain the data. the upper 8 bits of any program space location used as data should be programmed with ? 1111 1111 ? or ? 0000 0000 ? to force a nop . this prevents possible issues should the area of code ever be accidentally executed. for operations that use psv and are executed outside a repeat loop, the mov and mov.d instructions require one instruction cycle in addition to the specified execution time. all other instructions require two instruction cycles in addition to the specified execution time. for operations that use psv, and are executed inside a repeat loop, these instances require two instruction cycles in addition to the spec ified execution time of the instruction: ? execution in th e first iteration ? execution in the last iteration ? execution prior to exiting the loop due to an interrupt ? execution upon re-entering the loop after an interrupt is serviced any other iteration of the repeat loop will allow the instruction using psv to a ccess data to execute in a single cycle. figure 4-7: program space visibility operation note: psv access is temporar ily disabled during table reads/writes. 23 15 0 psvpag data space program space 0x0000 0x8000 0xffff 02 0x000000 0x800000 0x010000 0x018000 when corcon<2> = 1 and ea<15> = 1 : the data in the page designated by psvpag is mapped into the upper half of the data memory space... data ea<14:0> ...while the lower 15 bits of the ea specify an exact address within the psv area. this corresponds exactly to the same lower 15 bits of the actual program space address. psv area
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 46 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 47 pic24hj32gp202/204 and pic24hj16gp304 5.0 flash program memory the pic24hj32gp202/204 and pic24hj16gp304 devices contain internal flash program memory to store and execute application code. the memory is readable, writable and erasable during normal operation over the entire v dd range. flash memory can be programmed in two ways: ? in-circuit serial programming? (icsp?) programming capability ? run-time self-programming (rtsp) icsp allows a device to be serially programmed while in the end application circuit. this is done with two lines for programming clock and programming data (one of the alternate programming pi n pairs: pgecx/pgedx), and three other lines for power (v dd ), ground (v ss ) and master clear (mclr ). this allows customers to manufacture boards with unprogrammed devices and then program the microcontroll er just before shipping the product. this also allows the most recent firmware or a custom firmware to be programmed. rtsp is accomplished using tblrd (table read) and tblwt (table write) instructions. with rtsp, the user application can write program memory data either in ?blocks? or ?rows? of 64 instru ctions (192 bytes) at a time or a single program memory word, and erase program memory in blocks or ?pages? of 512 instructions (1536 bytes) at a time. 5.1 table instructions and flash programming regardless of the method used, all programming of flash memory is done with the table read and table write instructions. these al low direct read and write access to the program memory space from the data memory while the device is in normal operating mode. the 24-bit target address in the program memory is formed using bits <7:0> of the tblpag register and the effective address (ea) from a w register specified in the table instruction, as shown in figure 5-1 . the tblrdl and the tblwtl instructions are used to read or write to the bits<15:0> of program memory. tblrdl and tblwtl can access program memory in both word and byte modes. the tblrdh and tblwth instructions are used to read or write to bits<23:16> of program memory. tblrdh and tblwth can also access program memory in word or byte mode. figure 5-1: addressing for table registers note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 4. program memory? (ds70202) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. 0 program counter 24 bits program counter tblpag reg 8 bits working reg ea 16 bits byte 24-bit ea 0 1/0 select using table instruction using user/configuration space select
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 48 ? 2007-2011 microchip technology inc. 5.2 rtsp operation the flash program memory array is organized into rows of 64 instructions or 192 bytes. rtsp allows the user application to erase a page of memory, which con- sists of eight rows (512 instructions) at a time, and to program one row or one word at a time. the 8-row erase pages and single row write rows are edge-aligned from the beginning of program memory, on boundaries of 1536 bytes and 192 bytes, respectively. the program memory implements holding buffers that can contain 64 instructions of programming data. prior to the actual programming operation, the write data must be loaded into the buffers sequentially. the instruction words loaded must always be from a group of 64 boundary. the basic sequence for rtsp programming is to set up a table pointer, then do a series of tblwt instructions to load the buffers. programming is performed by setting the control bits in the nvmcon register. a total of 64 tblwtl and tblwth instructions are required to load the instructions. all table write operations are single-word writes (two instruction cycles) because onl y the buffers are written. a programming cycle is required for programming each row. 5.3 programming operations a complete programming sequence is necessary for programming or erasing the internal flash in rtsp mode. the processor stalls (waits) until the programming operation is finished. the programming time depends on the frc accuracy (see table 22-18 ) and the value of the frc oscillator tuning register (see register 8-4 ). use the following formula to calculate the minimum and maximum values for the row write time, page erase time, and word write cycle time parameters (see table 22-12 ). equation 5-1: programming time for example, if the dev ice is operating at +125 c, the frc accuracy will be 5%. if the tun<5:0> bits (see register 8-4 ) are set to ?b111111 , the minimum row write time is equal to equation 5-2 . equation 5-2: minimum row write time the maximum row write time is equal to equation 5-3 . equation 5-3: maximum row write time setting the wr bit (nvmcon<15>) starts the operation, and the wr bit is automatically cleared when the operation is finished. 5.4 flash memory resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 5.4.1 key resources ? section 5. ?flash programming? (ds70191) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools 5.5 control registers the two sfrs that are used to read and write the program flash memory are: ? nvmcon: flash memory control register ? nvmkey: nonvolatile memory key register the nvmcon register ( register 5-1 ) controls which blocks need to be erased, which memory type is to be programmed and the start of the programming cycle. nvmkey ( register 5-2 ) is a write-only register that is used for write protection. to start a programming or erase sequence, the user application must consecutively write 0x55 and 0xaa to the nvmkey register. refer to section 5.3 ?programming operations? for further details. t 7.37 mhz frc accuracy () % frc tuning () % ------------------------------------------------------------------------------------------------------------------------- - t rw 11064 cycles 7.37 mhz 10.05 + () 1 0.00375 ? () ---------------------------------------------------------------------------------------------- 1.435 ms = = note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271 t rw 11064 cycles 7.37 mhz 10.05 ? () 1 0.00375 ? () --------------------------------------------------------------------------------------------- - 1.586 ms = =
? 2007-2011 microchip technology inc. ds70289j-page 49 pic24hj32gp202/204 and pic24hj16gp304 5.6 flash memory control registers register 5-1: nvmcon: flash memory control register r/so-0 (1) r/w-0 (1) r/w-0 (1) u-0 u-0 u-0 u-0 u-0 wr wren wrerr ? ? ? ? ? bit 15 bit 8 u-0 r/w-0 (1) u-0 u-0 r/w-0 (1) r/w-0 (1) r/w-0 (1) r/w-0 (1) ? erase ? ?nvmop<3:0> (2) bit 7 bit 0 legend: so = settable only bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 wr: write control bit 1 = initiates a flash memory program or erase oper ation. the operation is self-timed and the bit is cleared by hardware once operation is complete 0 = program or erase operation is complete and inactive bit 14 wren: write enable bit 1 = enable flash program/erase operations 0 = inhibit flash program/erase operations bit 13 wrerr: write sequence error flag bit 1 = an improper program or erase sequence attempt or termination has occurred (bit is set automatically on any set attempt of the wr bit) 0 = the program or erase operation completed normally bit 12-7 unimplemented: read as ? 0 ? bit 6 erase: erase/program enable bit 1 = perform the erase operation specifi ed by nvmop<3:0> on the next wr command 0 = perform the program operation specifi ed by nvmop<3:0> on the next wr command bit 5-4 unimplemented: read as ? 0 ? bit 3-0 nvmop<3:0>: nvm operation select bits (2) if erase = 1 : 1111 = memory bulk erase operation 1101 = erase general segment 1100 = erase secure segment 0011 = no operation 0010 = memory page erase operation 0001 = no operation 0000 = erase a single configuration register byte if erase = 0 : 1111 = no operation 1101 = no operation 1100 = no operation 0011 = memory word program operation 0010 = no operation 0001 = memory row program operation 0000 = program a single configuration register byte note 1: these bits can only be reset on a power-on reset (por). 2: all other combinations of nv mop<3:0> are unimplemented.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 50 ? 2007-2011 microchip technology inc. register 5-2: nvmkey: nonvolatile memory key register u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 w-0 w-0 w-0 w-0 w-0 w-0 w-0 w-0 nvmkey<7:0> bit 7 bit 0 legend: so = settable only bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-8 unimplemented: read as ? 0 ? bit 7-0 nvmkey<7:0>: key register (w rite-only) bits
? 2007-2011 microchip technology inc. ds70289j-page 51 pic24hj32gp202/204 and pic24hj16gp304 5.6.1 programming algorithm for flash program memory programmers can program one row of program flash memory at a time. to do this, it is necessary to erase the 8-row erase page that contains the desired row. the general process is: 1. read eight rows of program memory (512 instructions) and store in data ram. 2. update the program data in ram with the desired new data. 3. erase the block (see example 5-1 ): a) set the nvmop bits (nvmcon<3:0>) to ? 0010 ? to configure for block erase. set erase (nvmcon<6>) and wren (nvmcon<14>) bits. b) write the starting address of the page to be erased into the tblpag and w registers. c) write 0x55 to nvmkey. d) write 0xaa to nvmkey. e) set the wr bit (nvmcon<15>). the erase cycle begins and the cpu stalls for the duration of the erase cycle. when the erase is done, the wr bit is cleared automatically. 4. write the first 64 instructions from data ram into the program memory buffers (see example 5-2 ). 5. write the program block to flash memory: a) set the nvmop bits to ? 0001 ? to configure for row programming. clear the erase bit and set the wren bit. b) write 0x55 to nvmkey. c) write 0xaa to nvmkey. d) set the wr bit. the programming cycle begins and the cpu stalls for the duration of the write cycle. when the write to flash memory is done, the wr bit is cleared automatically. 6. repeat steps 4 and 5, using the next available 64 instructions from the block in data ram by incrementing the value in tblpag, until all 512 instructions are written back to flash memory. to protect against accidental operations, the write initiate sequence for nvmkey must be used to allow any erase or program operation to proceed. after the programming command has been executed, the user application must wait for the programming time until programming is complete. the two instructions following the start of the programming sequence should be nop s, as shown in example 5-3 . example 5-1: erasing a program memory page ; set up nvmcon for block erase operation mov #0x4042, w0 ; mov w0, nvmcon ; initialize nvmcon ; init pointer to row to be erased mov #tblpage(prog_addr), w0 ; mov w0, tblpag ; initialize pm page boundary sfr mov #tbloffset(prog_addr), w0 ; initialize in-page ea[15:0] pointer tblwtl w0, [w0] ; set base address of erase block disi #5 ; block all interrupts with priority less than 7 ; for next 5 instructions mov #0x55, w0 mov w0, nvmkey ; write the 55 key mov #0xaa, w1 ; mov w1, nvmkey ; write the aa key bset nvmcon, #wr ; start the erase sequence nop ; insert two nops after the erase nop ; command is asserted
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 52 ? 2007-2011 microchip technology inc. example 5-2: loading the write buffers example 5-3: initiating a programming sequence ; set up nvmcon for row programming operations mov #0x4001, w0 ; mov w0, nvmcon ; initialize nvmcon ; set up a pointer to the first program memory location to be written ; program memory selected, and writes enabled mov #0x0000, w0 ; mov w0, tblpag ; initialize pm page boundary sfr mov #0x6000, w0 ; an example program memory address ; perform the tblwt instructions to write the latches ; 0th_program_word mov #low_word_0, w2 ; mov #high_byte_0, w3 ; tblwtl w2, [w0] ; write pm low word into program latch tblwth w3, [w0++] ; write pm high byte into program latch ; 1st_program_word mov #low_word_1, w2 ; mov #high_byte_1, w3 ; tblwtl w2, [w0] ; write pm low word into program latch tblwth w3, [w0++] ; write pm high byte into program latch ; 2nd_program_word mov #low_word_2, w2 ; mov #high_byte_2, w3 ; tblwtl w2, [w0] ; write pm low word into program latch tblwth w3, [w0++] ; write pm high byte into program latch ? ? ? ; 63rd_program_word mov #low_word_31, w2 ; mov #high_byte_31, w3 ; tblwtl w2, [w0] ; write pm low word into program latch tblwth w3, [w0++] ; write pm high byte into program latch disi #5 ; block all interrupts with priority less than 7 ; for next 5 instructions mov #0x55, w0 mov w0, nvmkey ; write the 55 key mov #0xaa, w1 ; mov w1, nvmkey ; write the aa key bset nvmcon, #wr ; start the erase sequence nop ; insert two nops after the nop ; erase command is asserted
? 2007-2011 microchip technology inc. ds70289j-page 53 pic24hj32gp202/204 and pic24hj16gp304 6.0 resets the reset module combines all reset sources and controls the device mast er reset signal, sysrst . the following is a list of device reset sources: ? por: power-on reset ? bor: brown-out reset ?mclr : master clear pin reset ?swr: reset instruction ? wdto: watchdog timer reset ? cm: configuration mismatch reset ? trapr: trap conflict reset ? iopuwr: illegal condition device reset - illegal opcode reset - uninitialized w register reset - security reset a simplified block diagram of the reset module is shown in figure 6-1 . any active source of reset will make the sysrst signal active. on system rese t, some of the registers associated with the cpu and peripherals are forced to a known reset state and some are unaffected. all types of device reset sets a corresponding status bit in the rcon register to indicate the type of reset (see register 6-1 ). a por clears all the bits, except for the por bit (rcon<0>), that are set. th e user application can set or clear any bit at any time during code execution. the rcon bits only serve as status bits. setting a particular reset status bit in software does not cause a device reset to occur. the rcon register also has other bits associated with the watchdog timer and device power-saving states. the function of these bits is discussed in other sections of this manual. figure 6-1: reset system block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. it is not intended to be a comprehensive ref- erence source. to complement the infor- mation in this data sheet, refer to ?section 8. reset? (ds70192) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: refer to the specific peripheral section or section 3.0 ?cpu? of this manual for register reset states. note: the status bits in the rcon register should be cleared after they are read so that the next rcon register value after a device reset is meaningful. mclr v dd internal regulator bor sleep or idle reset instruction wdt module glitch filter trap conflict illegal opcode uninitialized w register sysrst v dd rise detect por configuration mismatch
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 54 ? 2007-2011 microchip technology inc. 6.1 resets resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 6.1.1 key resources ? section 8. ?reset? (ds70192) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 55 pic24hj32gp202/204 and pic24hj16gp304 6.2 reset control registers register 6-1: rcon: re set control register (1) r/w-0 r/w-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 trapr iopuwr ? ? ? ?cmvregs bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-1 r/w-1 extr swr swdten (2) wdto sleep idle bor por bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 trapr: trap reset flag bit 1 = a trap conflict reset has occurred 0 = a trap conflict reset has not occurred bit 14 iopuwr: illegal opcode or uninitialized w access reset flag bit 1 = an illegal opcode detection, an illegal address mode or uninitialized w register used as an address pointer caused a reset 0 = an illegal opcode or uninitialized w reset has not occurred bit 13-10 unimplemented: read as ? 0 ? bit 9 cm: configuration mismatch flag bit 1 = a configuration mismatch reset has occurred 0 = a configuration mismatch reset has not occurred bit 8 vregs: voltage regulator standby during sleep bit 1 = voltage regulator is active during sleep 0 = voltage regulator goes into standby mode during sleep bit 7 extr: external reset (mclr ) pin bit 1 = a master clear (pin) reset has occurred 0 = a master clear (pin) reset has not occurred bit 6 swr: software reset (instruction) flag bit 1 = a reset instruction has been executed 0 = a reset instruction has not been executed bit 5 swdten: software enable/disable of wdt bit (2) 1 = wdt is enabled 0 = wdt is disabled bit 4 wdto: watchdog timer time-out flag bit 1 = wdt time-out has occurred 0 = wdt time-out has not occurred bit 3 sleep: wake-up from sleep flag bit 1 = device has been in sleep mode 0 = device has not been in sleep mode bit 2 idle: wake-up from idle flag bit 1 = device was in idle mode 0 = device was not in idle mode note 1: all of the reset status bits can be set or cleared in software. setting one of these bits in software does not cause a device reset. 2: if the fwdten configuration bit is ? 1 ? (unprogrammed), the wdt is always enabled, regardless of the swdten bit setting.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 56 ? 2007-2011 microchip technology inc. bit 1 bor: brown-out reset flag bit 1 = a brown-out reset has occurred 0 = a brown-out reset has not occurred bit 0 por: power-on reset flag bit 1 = a power-on reset has occurred 0 = a power-on reset has not occurred register 6-1: rcon: re set control register (1) (continued) note 1: all of the reset status bits can be set or cleared in software. setting one of these bits in software does not cause a device reset. 2: if the fwdten configuration bit is ? 1 ? (unprogrammed), the wdt is always enabled, regardless of the swdten bit setting.
? 2007-2011 microchip technology inc. ds70289j-page 57 pic24hj32gp202/204 and pic24hj16gp304 6.3 system reset the pic24hj32gp202/204 and pic24hj16gp304 family of devices have two types of reset: ? cold reset ? warm reset a cold reset is the result of a power-on reset (por) or a brown-out reset (bor). on a cold reset, the fnosc configuration bits in the fosc device configuration register selects the device clock source. a warm reset is the result of all other reset sources, including the reset instruction. on warm reset, the device will continue to operate from the current clock source as indicated by the current oscillator selection bits (cosc<2:0>) in the oscillator control register (osccon<14:12>). the device is kept in a reset state until the system power supplies have stabilized at appropriate levels and the oscillator clock is ready. the sequence in which this occurs is shown in figure 6-2 . table 6-1: oscillator delay oscillator mode oscillator start-up delay oscillator start-up timer pll lock time total delay frc, frcdiv16, frcdivn t oscd ??t oscd frcpll t oscd ?t lock t oscd + t lock xt t oscd t ost ?t oscd + t ost hs t oscd t ost ?t oscd + t ost ec ???? xtpll t oscd t ost t lock t oscd + t ost + t lock hspll t oscd t ost t lock t oscd + t ost + t lock ecpll ? ? t lock t lock sosc t oscd t ost ?t oscd + t ost lprc t oscd ??t oscd note 1: t oscd = oscillator start-up delay (1.1 s max for frc, 70 s max for lprc). crystal oscillator start-up times vary with crystal characteristics, load capacitance, etc. 2: t ost = oscillator start-up timer delay (1024 oscillator clock period). for example, t ost = 102.4 s for a 10 mhz crystal and t ost = 32 ms for a 32 khz crystal. 3: t lock = pll lock time (1.5 ms nominal), if pll is enabled.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 58 ? 2007-2011 microchip technology inc. figure 6-2: system reset timing reset run device status v dd v por vbor v bor por bor sysrst t pwrt t por t bor oscillator clock t oscd t ost t lock time fscm t fscm 1 2 3 4 5 6 note 1: por: a por circuit holds the device in reset when the pow er supply is turned on. the por circuit is active until v dd crosses the v por threshold and the delay t por has elapsed. 2: bor: the on-chip voltage regulator has a bor circ uit that keeps the device in reset until v dd crosses the v bor threshold and the delay t bor has elapsed. the delay t bor ensures the voltage regulator output becomes stable. 3: pwrt timer: the programmable power-up timer continues to hold the processor in reset for a specific period of time (t pwrt ) after a bor. the delay t pwrt ensures that the system power supplies have stabilized at the appropriate level for full-speed operation. after the delay t pwrt has elapsed, the sysrst becomes inactive, which in turn enables the selected oscillator to start generating clock cycles. 4: oscillator delay: the total delay for the clock to be ready for various clock source se lections are given in table 6-1 . refer to section 8.0 ?oscillator configuration? for more information. 5: when the oscillator cloc k is ready, the processor begins exec ution from location 0x000000. the user application programs a goto instruction at the reset address, which redirects program execution to the appropriate start-up routine. 6: the fail-safe clock monitor (fscm), if enabled, begins to monitor the system cl ock when the system clock is ready and the delay t fscm elapsed.
? 2007-2011 microchip technology inc. ds70289j-page 59 pic24hj32gp202/204 and pic24hj16gp304 6.4 power-on reset (por) a power-on reset (por) circuit ensures the device is reset from power-on. the por circuit is active until v dd crosses the v por threshold and the delay t por has elapsed. the delay t por ensures the internal device bias circuits become stable. the device supply voltage characteristics must meet the specified starting voltage and rise rate requirements to generate the por. refer to section 22.0 ?electrical characteristics? for details. the por status bit in the reset control register (rcon<0>) is set to indicate the power-on reset. 6.4.1 brown-out reset (bor) and power-up timer (pwrt) the on-chip regulator has a brown-out reset (bor) circuit that resets the device when the v dd is too low (v dd < v bor ) for proper device operation. the bor circuit keeps the device in reset until v dd crosses v bor threshold and the delay t bor has elapsed. the delay t bor ensures the voltage regulator output becomes stable. the bor status bit in t he reset control register (rcon<1>) is set to indicate the brown-out reset. the device will not run at full speed after a bor as the v dd should rise to acceptab le levels for full-speed operation. the pwrt provides power-up time delay (t pwrt ) to ensure that the system power supplies have stabilized at the appropriate levels for full-speed operation before the sysrst is released. the power-up timer delay (t pwrt ) is programmed by the power-on reset timer value select (fpwrt<2:0>) bits in the por configuration (fpor<2:0>) register, which provides eight settings (from 0 ms to 128 ms). refer to section 19.0 ?special features? for further details. figure 6-3 shows the typical brown-out scenarios. the reset delay (t bor + t pwrt ) is initiated each time v dd rises above the v bor trip point table 6-2: oscillator parameters symbol parameter value v por por threshold 1.8v nominal t por por extension time 30 s maximum v bor bor threshold 2.5v nominal t bor bor extension time 100 s maximum t pwrt programmable power-up time delay 0-128 ms nominal t fscm fail-safe clock monitor delay 900 s maximum note: when the device exits the reset condi- tion (begins normal operation), the device operating parameters (voltage, frequency, temperat ure, etc.) must be within their operating ranges, otherwise the device may not function correctly. the user application must ensure that the delay between the time power is first applied, and the time sysrst becomes inactive, is long enough to get all operating parameters within specification.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 60 ? 2007-2011 microchip technology inc. figure 6-3: brown-out situations 6.5 external reset (extr) the external reset is generated by driving the mclr pin low. the mclr pin is a schmitt trigger input with an additional glitch filter. reset pulses that are longer than the minimum pulse-width will generate a reset. refer to section 22.0 ?electri cal characteristics? for minimum pulse-width specifications. the external reset (mclr ) pin (extr) bit in the reset control (rcon) register is set to indicate the mclr reset. 6.5.1 external super visory circuit many systems have external supervisory circuits that generate reset signals to reset multiple devices in the system. this external reset signal can be directly con- nected to the mclr pin to reset the device when the rest of system is reset. 6.5.2 internal supervisory circuit when using the internal power supervisory circuit to reset the device, the external reset pin (mclr ) should be tied directly or resistively to v dd . in this case, the mclr pin will not be used to generate a reset. the external reset pin (mclr ) does not have an internal pull-up and must not be left unconnected. 6.6 software reset instruction (swr) whenever the reset instruction is executed, the device will assert sysrst , placing the device in a special reset state. this reset state will not re-initialize the clock. the clock source in effect prior to the reset instruction will remain. sysrst is released at the next instruction cycle, and the reset vector fetch will commence. the software reset (instruction) flag (swr) bit in the reset control register (rco n<6>) is set to indicate the software reset. 6.7 watchdog time-out reset (wdto) whenever a watchdog time-out occurs, the device will asynchronously assert sysrst . the clock source will remain unchanged. a wdt time-out during sleep or idle mode will wake-up the processor, but will not reset the processor. the watchdog timer time-out flag bit (wdto) in the reset control register (rco n<4>) is set to indicate the watchdog reset. refer to section 19.4 ?watchdog timer (wdt)? for more information on watchdog reset. 6.8 trap conflict reset if a lower-priority hard trap occurs while a higher-priority trap is being processed, a hard trap conflict reset occurs. the hard traps include exceptions of priority level 13 through level 15, inclusive. the address error (level 13) and oscillator error (level 14) traps fall into this category. the trap reset flag bit (trapr) in the reset control register (rcon<15>) is set to indicate the trap conflict reset. refer to section 7.0 ?interrupt controller? for more information on tr ap conflict resets. v dd sysrst v bor v dd sysrst v bor v dd sysrst v bor t bor + t pwrt v dd dips before pwrt expires t bor + t pwrt t bor + t pwrt
? 2007-2011 microchip technology inc. ds70289j-page 61 pic24hj32gp202/204 and pic24hj16gp304 6.9 configuration mismatch reset to maintain the integrity of the peripheral pin select control registers, they ar e constantly monitored with shadow registers in hardware. if an unexpected change in any of the registers occur (such as cell dis- turbances caused by esd or other external events), a configuration mismatch reset occurs. the configuration mismatch flag bit (cm) in the reset control register (rcon<9>) is set to indicate the configuration mismatch reset. refer to section 10.0 ?i/o ports? for more information on the configuration mismatch reset. 6.10 illegal condition device reset an illegal condition device reset occurs due to the following sources: ? illegal opcode reset ? uninitialized w register reset ? security reset the illegal opcode or uninitialized w access reset flag bit (iopuwr) in the reset control register (rcon<14>) is set to indicate the illegal condition device reset. 6.10.1 illegal opcode reset a device reset is generated if the device attempts to execute an illegal opcode va lue that is fetched from program memory. the illegal opcode reset function can prevent the device from executing progr am memory sections that are used to store constant data. to take advantage of the illegal opcode reset, use only the lower 16 bits of each program memory section to store the data values. the upper 8 bits should be programmed with 0x3f, which is an illegal opcode value. 6.10.2 uninitialized w register reset any attempts to use the uninitialized w register as an address pointer will reset the device. the w register array (with the exception of w15) is cleared during all resets and is considered unin itialized until written to. 6.10.3 security reset if a program flow change (pfc) or vector flow change (vfc) targets a restricted location in a protected segment (boot and secure segment), that operation will cause a security reset. the pfc occurs when the program counter is reloaded as a result of a call, jump, computed jump, return, return from subroutine, or other form of branch instruction. the vfc occurs when the program counter is reloaded with an interrupt or trap vector. refer to section 19.6 ?code protection and codeguard? security? for more information on security reset. 6.11 using the rcon status bits the user application can read the reset control (rcon) register after any device reset to determine the cause of the reset. table 6-3 provides a summary of the reset flag bit operation. table 6-3: reset flag bit operation note: the configuration mi smatch feature and associated reset flag is not available on all devices. note: the status bits in the rcon register should be cleared after they are read so that the next rcon register value after a device reset will be meaningful. flag bit set by: cleared by: trapr (rcon<15>) trap conflict event por, bor iopwr (rcon<14>) illegal opcode or uninitialized w register access or security reset por, bor cm (rcon<9>) configuration mi smatch por, bor extr (rcon<7>) mclr reset por swr (rcon<6>) reset instruction por, bor wdto (rcon<4>) wdt time-out pwrsav instruction, clrwdt instruction, por, bor sleep (rcon<3>) pwrsav #sleep instruction por, bor idle (rcon<2>) pwrsav #idle instruction por, bor bor (rcon<1>) por, bor ? por (rcon<0>) por ? note: all reset flag bits can be set or cleared by user software.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 62 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 63 pic24hj32gp202/204 and pic24hj16gp304 7.0 interrupt controller the pic24hj32gp202/204 and pic24hj16gp304 interrupt controllers reduce the numerous peripheral interrupt request signals to a single interrupt request signal to the pic24hj32gp202/204 and pic24hj16gp304 cpu. it has the following features: ? up to eight processor exceptions and software traps ? seven user-selectable priority levels ? interrupt vector table (i vt) with up to 118 vectors ? a unique vector for each interrupt or exception source ? fixed priority within a specified user priority level ? alternate interrupt vector table (aivt) for debug support ? fixed interrupt entry and return latencies 7.1 interrupt vector table figure 7-1 shows the interrupt vector table. the ivt resides in program memory , starting at location 0x000004. the ivt contains 126 vectors consisting of eight nonmaskable trap vectors and up to 118 sources of interrupt. in general, each interrupt source has its own vector. each interrupt vector contains a 24 bit wide address. the value programmed into each interrupt vector location is the starting address of the associated interrupt service routine (isr). interrupt vectors are prioritized in terms of their natural priority; this priority is li nked to their position in the vector table. lower addresses generally have a higher natural priority. for example, the interrupt associated with vector 0 will take priority over interrupts at any other vector address. pic24hj32gp202/204 and pic24hj16gp304 devices implement up to 21 unique interrupts and 4 nonmaskable traps. these are summarized in table 7-1 and ta b l e 7 - 2 . 7.1.1 alternate interrupt vector ta b l e the alternate interrupt vector table (aivt) is located after the ivt, as shown in figure 7-1 . access to the aivt is provided by the altivt control bit (intcon2<15>). if the altivt bit is set, all interrupt and exception processes use the alternate vectors instead of the default vector s. the alternate vectors are organized in the same manner as the default vectors. the aivt supports debugging by providing a means to switch between an application and a support environment without requiring the interrupt vectors to be reprogrammed. this feat ure also enables switching between applications for evaluation of different software algorithms at run time. if the aivt is not needed, the aivt should be programmed with the same addresses used in the ivt. 7.2 reset sequence a device reset is not a true exception because the interrupt controller is not involved in the reset process. the device clear its register s in response to a reset, which forces the pc to zero. the microcontroller then begins the program execution at location 0x000000. the user application can use a goto instruction at the reset address which redirects program execution to the appropriate start-up routine. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 6. interrupts? (ds70184) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: any unimplemented or unused vector locations in the ivt and aivt should be programmed with the address of a default interrupt handler routine that contains a reset instruction.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 64 ? 2007-2011 microchip technology inc. figure 7-1: pic24hj32gp202/204 and pi c24hj16gp304 interrupt vector table reset ? goto instruction 0x000000 reset ? goto address 0x000002 reserved 0x000004 oscillator fail trap vector address error trap vector stack error trap vector math error trap vector reserved reserved reserved interrupt vector 0 0x000014 interrupt vector 1 ~ ~ ~ interrupt vector 52 0x00007c interrupt vector 53 0x00007e interrupt vector 54 0x000080 ~ ~ ~ interrupt vector 116 0x0000fc interrupt vector 117 0x0000fe reserved 0x000100 reserved 0x000102 reserved oscillator fail trap vector address error trap vector stack error trap vector math error trap vector reserved reserved reserved interrupt vector 0 0x000114 interrupt vector 1 ~ ~ ~ interrupt vector 52 0x00017c interrupt vector 53 0x00017e interrupt vector 54 0x000180 ~ ~ ~ interrupt vector 116 interrupt vector 117 0x0001fe start of code 0x000200 decreasing natural order priority interrupt vector table (ivt) (1) alternate interrupt vector table (aivt) (1) note 1: see table 7-1 for the list of implement ed interrupt vectors.
? 2007-2011 microchip technology inc. ds70289j-page 65 pic24hj32gp202/204 and pic24hj16gp304 table 7-2: trap vectors table 7-1: interrupt vectors vector number interrupt request (irq) number ivt address aivt address interrupt source 8 0 0x000014 0x000114 int0 ? external interrupt 0 9 1 0x000016 0x000116 ic1 ? input capture 1 10 2 0x000018 0x000118 oc1 ? output compare 1 11 3 0x00001a 0x00011a t1 ? timer1 12 4 0x00001c 0x00011c reserved 13 5 0x00001e 0x00011e ic2 ? input capture 2 14 6 0x000020 0x000120 oc2 ? output compare 2 15 7 0x000022 0x000122 t2 ? timer2 16 8 0x000024 0x000124 t3 ? timer3 17 9 0x000026 0x000126 spi1e ? spi1 error 18 10 0x000028 0x000128 spi1 ? spi1 transfer done 19 11 0x00002a 0x00012a u1rx ? uart1 receiver 20 12 0x00002c 0x00012c u1tx ? uart1 transmitter 21 13 0x00002e 0x00012e adc1 ? adc1 22 14 0x000030 0x000130 reserved 23 15 0x000032 0x000132 reserved 24 16 0x000034 0x000134 si2c1 ? i2c1 slave events 25 17 0x000036 0x000136 mi2c1 ? i2c1 master events 26 18 0x000038 0x000138 reserved 27 19 0x00003a 0x00013a change notification interrupt 28 20 0x00003c 0x00013c int1 ? external interrupt 1 29 21 0x00003e 0x00013e reserved 30 22 0x000040 0x000140 ic7 ? input capture 7 31 23 0x000042 0x000142 ic8 ? input capture 8 32-36 24-28 0x000044-0x00004c 0x000144-0x00014c reserved 37 29 0x00004e 0x00014e int2 ? external interrupt 2 38-72 30-64 0x000050-0x000094 0x000150-0x000194 reserved 73 65 0x000096 0x000196 u1e ? uart1 error 74-125 66-117 0x000098-0x0000fe 0x000198-0x0001fe reserved vector number ivt address aivt address trap source 0 0x000004 0x000104 reserved 1 0x000006 0x000106 oscillator failure 2 0x000008 0x000108 address error 3 0x00000a 0x00010a stack error 4 0x00000c 0x00010c math error 5 0x00000e 0x00010e reserved 6 0x000010 0x000110 reserved 7 0x000012 0x000112 reserved
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 66 ? 2007-2011 microchip technology inc. 7.3 interrupt resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 7.3.1 key resources ? section 6. ?interrupts? (ds70184) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools 7.4 interrupt control and status registers pic24hj32gp202/204 and pic24hj16gp304 devices implement a total of 17 registers for the interrupt controller: ? interrupt control register 1 (intcon1) ? interrupt control register 2 (intcon2) ? interrupt flag status registers (ifsx) ? interrupt enable control registers (iecx) ? interrupt priority control registers (ipcx) ? interrupt control and st atus register (inttreg) 7.4.1 intcon1 and intcon2 global interrupt control functions are controlled from intcon1 and intcon2. intcon1 contains the interrupt nesting disable bit (nstdis) as well as the control and status flags for the processor trap sources. the intcon2 register contro ls the external interrupt request signal behavior and the use of the alternate interrupt vector table. 7.4.2 ifsx the ifs registers maintain all the interrupt request flags. each source of interrupt has a status bit, which is set by the respective peripherals or external signal and this is cleared via software. 7.4.3 iecx the iec registers maintain all the interrupt enable bits. these control bits are used individually to enable interrupts from the peripherals or external signals. 7.4.4 ipcx the ipc registers are used to set the interrupt priority level for each source of interrupt. each user interrupt source can be assigned to one of the eight priority levels. 7.4.5 inttreg the inttreg register contains the associated interrupt vector number and the new cpu interrupt priority level, which are latched into vector number (vecnum<6:0>) and interrupt level (ilr<3:0>) bit fields in the inttreg register. the new interrupt priority level is the priority of the pending interrupt. the interrupt sources are assigned to the ifsx, iecx and ipcx registers in the same sequence that they are listed in ta b l e 7 - 1 . for example, the int0 (external interrupt 0) is shown as having vector number 8 and a natural order priority of 0. thus, the int0if bit is found in ifs0<0>, the int0ie bit in iec0<0>, and the int0ip bits in the first position of ipc0 (ipc0<2:0>). 7.4.6 status registers although these are not specific ally part of the interrupt control hardware, two of the cpu control registers contain bits that contro l interrupt functionality: ? the cpu status register, sr, contains the ipl<2:0> bits (sr<7:5>). these bits indicate the current cpu interrupt priority level. the user can change the current cpu priority level by writing to the ipl bits. ? the corcon register contains the ipl3 bit which, together with ipl<2:0>, also indicates the current cpu priority level. ipl3 is a read-only bit, so that trap events cannot be masked by the user software. all interrupt registers are described in register 7-1 through register 7-19 . note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 67 pic24hj32gp202/204 and pic24hj16gp304 register 7-1: sr: cpu status register (1) u-0 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 ? ? ? ? ? ? ?dc bit 15 bit 8 r/w-0 (3) r/w-0 (3) r/w-0 (3) r-0 r/w-0 r/w-0 r/w-0 r/w-0 ipl2 (2) ipl1 (2) ipl0 (2) ra n ov z c bit 7 bit 0 legend: c = clear only bit r = readable bit u = unimplemented bit, read as ?0? s = set only bit w = writable bit -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 7-5 ipl<2:0>: cpu interrupt priority level status bits (2) 111 = cpu interrupt priority level is 7 (15), user interrupts disabled 110 = cpu interrupt priority level is 6 (14) 101 = cpu interrupt priority level is 5 (13) 100 = cpu interrupt priority level is 4 (12) 011 = cpu interrupt priority level is 3 (11) 010 = cpu interrupt priority level is 2 (10) 001 = cpu interrupt priority level is 1 (9) 000 = cpu interrupt priority level is 0 (8) note 1: for complete register details, see register 3-1 . 2: the ipl<2:0> bits are concatenated with the ipl<3> bi t (corcon<3>) to form the cpu interrupt priority level. the value in parentheses indicates the ipl if ipl<3> = 1 . user interrupts are disabled when ipl<3> = 1 . 3: the ipl<2:0> status bits are read-only when the nstdis bit (intcon1<15>) = 1 .
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 68 ? 2007-2011 microchip technology inc. register 7-2: corcon: core control register (1) u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 r/c-0 r/w-0 u-0 u-0 ? ? ? ? ipl3 (2) psv ? ? bit 7 bit 0 legend: c = clear only bit r = readable bit w = writable bit -n = value at por ?1? = bit is set 0? = bit is cleared ?x = bit is unknow n u = unimplemented bit, read as ?0? bit 3 ipl3: cpu interrupt priority level status bit 3 (2) 1 = cpu interrupt priority level is greater than 7 0 = cpu interrupt priority level is 7 or less note 1: for complete register details, see register 3-2 . 2: the ipl3 bit is concatenated with t he ipl<2:0> bits (sr<7:5>) to form the cpu interrupt priority level.
? 2007-2011 microchip technology inc. ds70289j-page 69 pic24hj32gp202/204 and pic24hj16gp304 register 7-3: intcon1: interrupt control register 1 r/w-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 nstdis ? ? ? ? ? ? ? bit 15 bit 8 u-0 r/w-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 u-0 ?div0err ? matherr addrerr stkerr oscfail ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 nstdis: interrupt nesting disable bit 1 = interrupt nesting is disabled 0 = interrupt nesting is enabled bit 14-7 unimplemented: read as ? 0 ? bit 6 div0err: arithmetic error status bit 1 = math error trap was caused by a divide by zero 0 = math error trap was not caused by a divide by zero bit 5 unimplemented: read as ? 0 ? bit 4 matherr: arithmetic error status bit 1 = math error trap has occurred 0 = math error trap has not occurred bit 3 addrerr: address error trap status bit 1 = address error trap has occurred 0 = address error trap has not occurred bit 2 stkerr: stack error trap status bit 1 = stack error trap has occurred 0 = stack error trap has not occurred bit 1 oscfail: oscillator failure trap status bit 1 = oscillator failure trap has occurred 0 = oscillator failure trap has not occurred bit 0 unimplemented: read as ? 0 ?
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 70 ? 2007-2011 microchip technology inc. register 7-4: intcon2: interrupt control register 2 r/w-0 r-0 u-0 u-0 u-0 u-0 u-0 u-0 altivt disi ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 ? ? ? ? ? int2ep int1ep int0ep bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 altivt: enable alternate interrupt vector table bit 1 = use alternate vector table 0 = use standard (default) vector table bit 14 disi: disi instruction status bit 1 = disi instruction is active 0 = disi instruction is not active bit 13-3 unimplemented: read as ? 0 ? bit 2 int2ep: external interrupt 2 edge detect polarity select bit 1 = interrupt on negative edge 0 = interrupt on positive edge bit 1 int1ep: external interrupt 1 edge detect polarity select bit 1 = interrupt on negative edge 0 = interrupt on positive edge bit 0 int0ep: external interrupt 0 edge detect polarity select bit 1 = interrupt on negative edge 0 = interrupt on positive edge
? 2007-2011 microchip technology inc. ds70289j-page 71 pic24hj32gp202/204 and pic24hj16gp304 register 7-5: ifs0: interrupt flag status register 0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ad1if u1txif u1rxif spi1if spi1eif t3if bit 15 bit 8 r/w-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 t2if oc2if ic2if ? t1if oc1if ic1if int0if bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-4 unimplemented: read as ? 0 ? bit 13 ad1if: adc1 conversion complete interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 12 u1txif: uart1 transmitter interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 11 u1rxif: uart1 receiver interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 10 spi1if: spi1 event interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 9 spi1eif: spi1 fault interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 8 t3if: timer3 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 7 t2if: timer2 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 6 oc2if: output compare channel 2 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 5 ic2if: input capture channel 2 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 4 unimplemented: read as ? 0 ? bit 3 t1if: timer1 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 2 oc1if: output compare channel 1 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 72 ? 2007-2011 microchip technology inc. bit 1 ic1if: input capture channel 1 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 0 int0if: external interrupt 0 flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred register 7-5: ifs0: interrupt flag status register 0 (continued)
? 2007-2011 microchip technology inc. ds70289j-page 73 pic24hj32gp202/204 and pic24hj16gp304 register 7-6: ifs1: interrupt flag status register 1 u-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ? ?int2if ? ? ? ? ? bit 15 bit 8 r/w-0 r/w-0 u-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 ic8if ic7if ? int1if cnif ? mi2c1if si2c1if bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-4 unimplemented: read as ? 0 ? bit 13 int2if: external interrupt 2 flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 12-8 unimplemented: read as ? 0 ? bit 7 ic8if: input capture channel 8 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 6 ic7if: input capture channel 7 interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 5 unimplemented: read as ? 0 ? bit 4 int1if: external interrupt 1 flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 3 cnif: input change notification interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 2 unimplemented: read as ? 0 ? bit 1 mi2c1if: i2c1 master events in terrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 0 si2c1if: i2c1 slave events interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 74 ? 2007-2011 microchip technology inc. register 7-7: ifs4: interrupt flag status register 4 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 u-0 ? ? ? ? ? ?u1eif ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-2 unimplemented: read as ? 0 ? bit 1 u1eif: uart1 error interrupt flag status bit 1 = interrupt request has occurred 0 = interrupt request has not occurred bit 0 unimplemented: read as ? 0 ?
? 2007-2011 microchip technology inc. ds70289j-page 75 pic24hj32gp202/204 and pic24hj16gp304 register 7-8: iec0: interrupt enable control register 0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ad1ie u1txie u1rxie spi1ie spi1eie t3ie bit 15 bit 8 r/w-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 t2ie oc2ie ic2ie ? t1ie oc1ie ic1ie int0ie bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-4 unimplemented: read as ? 0 ? bit 13 ad1ie: adc1 conversion complete interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 12 u1txie: uart1 transmitter interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 11 u1rxie: uart1 receiver interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 10 spi1ie: spi1 event interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 9 spi1eie: spi1 error interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 8 t3ie: timer3 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 7 t2ie: timer2 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 6 oc2ie: output compare channel 2 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 5 ic2ie: input capture channel 2 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 4 unimplemented: read as ? 0 ? bit 3 t1ie: timer1 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 2 oc1ie: output compare channel 1 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 76 ? 2007-2011 microchip technology inc. bit 1 ic1ie: input capture channel 1 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 0 int0ie: external interrupt 0 enable bit 1 = interrupt request enabled 0 = interrupt request not enabled register 7-8: iec0: interrupt enable control register 0 (continued)
? 2007-2011 microchip technology inc. ds70289j-page 77 pic24hj32gp202/204 and pic24hj16gp304 register 7-9: iec1: interrupt enable control register 1 u-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ? ?int2ie ? ? ? ? ? bit 15 bit 8 r/w-0 r/w-0 u-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 ic8ie ic7ie ? int1ie cnie ?mi2c1iesi2c1ie bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-14 unimplemented: read as ? 0 ? bit 13 int2ie: external interrupt 2 enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 12-8 unimplemented: read as ? 0 ? bit 7 ic8ie: input capture channel 8 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 6 ic7ie: input capture channel 7 interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 5 unimplemented: read as ? 0 ? bit 4 int1ie: external interrupt 1 enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 3 cnie: input change notification interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 2 unimplemented: read as ? 0 ? bit 1 mi2c1ie: i2c1 master events interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 0 si2c1ie: i2c1 slave events interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 78 ? 2007-2011 microchip technology inc. register 7-10: iec4: interrupt enable control register 4 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 u-0 ? ? ? ? ? ?u1eie ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-2 unimplemented: read as ? 0 ? bit 1 u1eie: uart1 error interrupt enable bit 1 = interrupt request enabled 0 = interrupt request not enabled bit 0 unimplemented: read as ? 0 ?
? 2007-2011 microchip technology inc. ds70289j-page 79 pic24hj32gp202/204 and pic24hj16gp304 register 7-11: ipc0: interrupt priority control register 0 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ? t1ip<2:0> ?oc1ip<2:0> bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ?ic1ip<2:0> ? int0ip<2:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 t1ip<2:0>: timer1 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 11 unimplemented: read as ? 0 ? bit 10-8 oc1ip<2:0>: output compare channel 1 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 7 unimplemented: read as ? 0 ? bit 6-4 ic1ip<2:0>: input capture channel 1 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3 unimplemented: read as ? 0 ? bit 2-0 int0ip<2:0>: external interrupt 0 priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 80 ? 2007-2011 microchip technology inc. register 7-12: ipc1: interrupt priority control register 1 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ? t2ip<2:0> ?oc2ip<2:0> bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 u-0 u-0 u-0 ?ic2ip<2:0> ? ? ? ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 t2ip<2:0>: timer2 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 11 unimplemented: read as ? 0 ? bit 10-8 oc2ip<2:0>: output compare channel 2 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 7 unimplemented: read as ? 0 ? bit 6-4 ic2ip<2:0>: input capture channel 2 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3-0 unimplemented: read as ? 0 ?
? 2007-2011 microchip technology inc. ds70289j-page 81 pic24hj32gp202/204 and pic24hj16gp304 register 7-13: ipc2: interrupt priority control register 2 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ? u1rxip<2:0> ? spi1ip<2:0> bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ? spi1eip<2:0> ? t3ip<2:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 u1rxip<2:0>: uart1 receiver interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 11 unimplemented: read as ? 0 ? bit 10-8 spi1ip<2:0>: spi1 event interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 7 unimplemented: read as ? 0 ? bit 6-4 spi1eip<2:0>: spi1 error interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3 unimplemented: read as ? 0 ? bit 2-0 t3ip<2:0>: timer3 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 82 ? 2007-2011 microchip technology inc. register 7-14: ipc3: interrupt priority control register 3 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ?ad1ip<2:0> ? u1txip<2:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-7 unimplemented: read as ? 0 ? bit 6-4 ad1ip<2:0>: adc1 conversion complete interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3 unimplemented: read as ? 0 ? bit 2-0 u1txip<2:0>: uart1 transmitter interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled
? 2007-2011 microchip technology inc. ds70289j-page 83 pic24hj32gp202/204 and pic24hj16gp304 register 7-15: ipc4: interrupt priority control register 4 u-0 r/w-1 r/w-0 r/w-0 u-0 u-0 u-0 u-0 ? cnip<2:0> ? ? ? ? bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ? mi2c1ip<2:0> ? si2c1ip<2:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 cnip<2:0>: change notification interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 11-7 unimplemented: read as ? 0 ? bit 6-4 mi2c1ip<2:0>: i2c1 master events interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3 unimplemented: read as ? 0 ? bit 2-0 si2c1ip<2:0>: i2c1 slave events interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 84 ? 2007-2011 microchip technology inc. register 7-16: ipc5: interrupt priority control register 5 u-0 r/w-1 r/w-0 r/w-0 u-0 r/w-1 r/w-0 r/w-0 ?ic8ip<2:0> ? ic7ip<2:0> bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 r/w-1 r/w-0 r/w-0 ? ? ? ? ? int1ip<2:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 ic8ip<2:0>: input capture channel 8 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 11 unimplemented: read as ? 0 ? bit 10-8 ic7ip<2:0>: input capture channel 7 interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 7-3 unimplemented: read as ? 0 ? bit 2-0 int1ip<2:0>: external interrupt 1 priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled
? 2007-2011 microchip technology inc. ds70289j-page 85 pic24hj32gp202/204 and pic24hj16gp304 register 7-17: ipc7: interrupt priority control register 7 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 u-0 u-0 u-0 ? int2ip<2:0> ? ? ? ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-7 unimplemented: read as ? 0 ? bit 6-4 int2ip<2:0>: external interrupt 2 priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3-0 unimplemented: read as ? 0 ?
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 86 ? 2007-2011 microchip technology inc. register 7-18: ipc16: interrupt priority control register 16 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 r/w-1 r/w-0 r/w-0 u-0 u-0 u-0 u-0 ?u1eip<2:0> ? ? ? ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-7 unimplemented: read as ? 0 ? bit 6-4 u1eip<2:0>: uart1 error interrupt priority bits 111 = interrupt is priority 7 (highest priority interrupt) ? ? ? 001 = interrupt is priority 1 000 = interrupt source is disabled bit 3-0 unimplemented: read as ? 0 ?
? 2007-2011 microchip technology inc. ds70289j-page 87 pic24hj32gp202/204 and pic24hj16gp304 register 7-19: inttreg: interrup t control and status register u-0 u-0 u-0 u-0 r-0 r-0 r-0 r-0 ? ? ? ?ilr<3:0> bit 15 bit 8 u-0 r-0 r-0 r-0 r-0 r-0 r-0 r-0 ? vecnum<6:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-12 unimplemented: read as ? 0 ? bit 11-8 ilr<3:0>: new cpu interrupt priority level bits 1111 = cpu interrupt priority level is 15 ? ? ? 0001 = cpu interrupt priority level is 1 0000 = cpu interrupt priority level is 0 bit 7 unimplemented: read as ? 0 ? bit 6-0 vecnum<6:0>: vector number of pending interrupt bits 0111111 = interrupt vector pending is number 135 ? ? ? 0000001 = interrupt vector pending is number 9 0000000 = interrupt vector pending is number 8
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 88 ? 2007-2011 microchip technology inc. 7.5 interrupt setup procedures 7.5.1 initialization to configure an interrupt source at initialization: 1. set the nstdis bit (intcon1<15>) if nested interrupts are not desired. 2. select the user-assigned priority level for the interrupt source by writing the control bits in the appropriate ipcx register. the priority level will depend on the specific application and type of interrupt source. if multiple priority levels are not desired, the ipcx register control bits for all enabled interrupt sources can be programmed to the same non-zero value. 3. clear the interrupt flag status bit associated with the peripheral in the associated ifsx register. 4. set the interrupt enable control bit associated with the source in the app ropriate iecx register to enable the interrupt source. 7.5.2 interrupt service routine the method used to declare an interrupt service rou- tine (isr) and initialize the ivt with the correct vector address depends on the programming language (c or assembler) and the language development toolsuite used to develop the application. in general, the user application must clear the interrupt flag in the appropriate ifsx register for the source of interrupt that the isr handles. otherwise, the program will re-enter the isr immediately after exiting the routine. if the isr is coded in assembly language, it must be terminated using a retfie instruction to unstack the saved pc value, srl value and old cpu priority level. 7.5.3 trap service routine a trap service routine (tsr) is coded like an isr, except that the appropriate trap status flag in the intcon1 register must be cleared to avoid re-entry into the tsr. 7.5.4 interrupt disable all user interrupts can be disabled using this proce- dure: 1. push the current sr value onto the software stack using the push instruction. 2. force the cpu to priority level 7 by inclusive oring the value oeh with srl. to enable user interrupts, the pop instruction can be used to restore the previous sr value. the disi instruction provides a convenient way to disable interrupts of priority levels 1-6 for a fixed period of time. level 7 interrupt sources are not disabled by the disi instruction. note: at a device reset, the ipcx registers are initialized such that all user interrupt sources are assigned to priority level 4. note: only user interrupts with a priority level of 7 or lower can be disabled. trap sources (level 8-level 15) cannot be disabled.
? 2007-2011 microchip technology inc. ds70289j-page 89 pic24hj32gp202/204 and pic24hj16gp304 8.0 oscillator configuration the oscillator system provides: ? external and internal oscillator options as clock sources ? an on-chip pll to scale the internal operating frequency to the required system clock frequency ? an internal frc oscillator that can also be used with the pll, thereby allowing full speed operation without any external clock generation hardware ? clock switching between various clock sources ? programmable clock post scaler for system power savings ? a fail-safe clock monitor (fscm) that detects clock failure and takes fail-safe measures ? an oscillator control register (osccon) ? nonvolatile configuration bits for main oscillator selection a simplified diagram of the oscillator system is shown in figure 8-1 . figure 8-1: pic24hj32gp2 02/204 and pic24h j16gp304 oscillator system diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 7. oscillator? (ds70186) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note 1: see figure 8-2 for pll details. 2: if the oscillator is used with xt or hs modes, an external parallel resistor with the value of 1 m must be connected. 3: the term f p refers to the clock source for all of the peripherals, while f cy refers to the clock source for the cpu. throughout this document, f cy and f p are used interchangeably, except in the case of doze mode. f p and f cy will be different when doze mode is used with any ratio other than 1:1 which is the default. secondary oscillator (s osc ) lposcen sosco timer 1 xtpll, hspll, xt, hs, ec frcdiv<2:0> wdt, pwrt, fscm frcdivn sosc frcdiv16 ecpll, frcpll nosc<2:0> fnosc<2:0> reset frc oscillator lprc oscillator doze<2:0> s3 s1 s2 s1/s3 s7 s6 frc lprc s0 s5 s4 16 clock switch s7 clock fail 2 tun<5:0> pll (1) f cy (3) f osc frcdiv doze osc2 osc1 primary oscillator (p osc ) r (2) poscmd<1:0> f p (3) sosci
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 90 ? 2007-2011 microchip technology inc. 8.1 cpu clocking system the pic24hj32gp202/204 and pic24hj16gp304 devices provide the following seven system clock options. ? fast rc (frc) oscillator ? frc oscillator with pll ? primary (xt, hs or ec) oscillator ? primary oscillator with pll ? secondary (lp) oscillator ? low-power rc (lprc) oscillator ? frc oscillator with postscaler 8.1.1 system clock sources 8.1.1.1 fast rc the fast rc (frc) internal oscillator runs at a nominal frequency of 7.37 mhz. user software can tune the frc frequency. user software can optionally specify a factor (ranging from 1:2 to 1:256) by which the frc clock frequency is divided. th is factor is selected using the frcdiv<2:0> bits (clkdiv<10:8>). 8.1.1.2 primary the primary oscillator can use one of the following as its clock source: ? crystal (xt): crystals a nd ceramic resonators in the range of 3.5 mhz to 10 mhz. the crystal is connected to the osc1 and osc2 pins. ? hs (high-speed crystal): crystals in the range of 10 mhz to 40 mhz. the crystal is connected to the osc1 and osc2 pins. ? ec (external clock): the external clock signal is directly applied to the osc1 pin. 8.1.1.3 secondary the secondary (lp) oscillator is designed for low power and uses a 32.768 khz crystal or ceramic resonator. the lp oscillator uses sosci and sosco pins. 8.1.1.4 low-power rc the low-power rc (lprc) inter nal oscillator runs at a nominal frequency of 32.768 khz. it is also used as a reference clock by the watchdog timer (wdt) and fail-safe clock monitor (fscm). 8.1.1.5 frc the clock signals generated by the frc and primary oscillators can be optionally applied to an on-chip phase-locked loop (pll) to provide a wide range of output frequencies for device operation. pll configuration is described in section 8.1.3 ?pll configuration? . the frc frequency depends on the frc accuracy (see table 22-18 ) and the value of the frc oscillator tuning register (see register 8-4 ). 8.1.2 system clock selection the oscillator source used at a device power-on reset event is selected using configuration bit settings. the oscillator configuration bit settings are located in the configuration registers in the program memory. (refer to section 19.1 ?configuration bits? for further details.) the initial oscillator selection configuration bits, fnosc<2:0> (foscsel<2:0>), and the primary oscillator mode select configuration bits, poscmd<1:0> (fosc<1:0>), select the oscillator source that is used at a power-on reset. the frc primary oscillator is the default (unprogrammed) selection. the configuration bits allow users to choose among 12 different clock modes, shown in ta b l e 8 - 1 . the output of the oscillator (or the output of the pll if a pll mode has been selected) f osc is divided by 2 to generate the device instruction clock (f cy ) and the peripheral clock time base (f p ). f cy defines the operating speed of the dev ice, and speeds up to 40 mhz are supported by the pic24hj32gp202/204 and pic24hj16gp304 architecture. instruction execution speed or device operating frequency, f cy , is given by: equation 8-1: device operating frequency 8.1.3 pll configuration the primary oscillator and internal frc oscillator can optionally use on-chip pll to obtain higher speeds of operation. the pll provides significant flexibility in selecting the device operating speed. a block diagram of the pll is shown in figure 8-2 . the output of the pr imary oscillator or frc, denoted as ?f in ? is divided down by a prescale factor (n1) of 2, 3, ... or 33 before it is being provided to the pll?s voltage controlled oscillator (vco). the input to the vco must be selected in the range of 0.8 mhz to 8 mhz. the prescale factor ?n1? is selected using the pllpre<4:0> bits (clkdiv<4:0>). the pll feedback divisor, selected using the plldiv<8:0> bits (pllfbd<8:0>), provides a factor ?m?, by which the input to the vco is multiplied. this factor must be selected such that the resulting vco output frequency is in the range of 100 mhz to 200 mhz. the vco output is further divided by a postscale factor ?n2.? this factor is selected using the pllpost<1:0> bits (clkdiv<7:6>). ?n2? can be 2, 4 or 8, and must be selected such that the pll output frequency (f osc ) is in the range of 12.5 mhz to 80 mhz, which generates device operating speeds of 6.25-40 mips. f cy f osc 2 ------------- =
? 2007-2011 microchip technology inc. ds70289j-page 91 pic24hj32gp202/204 and pic24hj16gp304 for a primary oscillator or frc oscillator, output ?f in ?, the pll output ?f osc ? is given by: equation 8-2: f osc calculation for example, when a 10 mhz crystal is being used, with ?xt with pll? being the se lected oscillator mode. ? if pllpre<4:0> = 0 , then n1 = 2. this yields a vco input of 10/2 = 5 mhz, which is within the acceptable range of 0.8-8 mhz. ? if plldiv<8:0> = 0x1e, then m = 32. this yields a vco output of 5 x 32 = 160 mhz, which is within the 100 mhz to 200 mhz range, which is needed. ? if pllpost<1:0> = 0 , then n2 = 2. this provides a fosc of 160/2 = 80 mhz. the resultant device operating speed is 80/2 = 40 mips. equation 8-3: xt with pll mode example figure 8-2: pic24hj32gp202/204 and pic24hj16gp304 pll block diagram table 8-1: configuration bi t values for clock selection f osc f in m n 1 n 2 ? ------------------ - ?? ?? ? = f cy f osc 2 ------------- 1 2 -- - 10000000 32 ? 22 ? ---------------------------------- ?? ?? 40 mips = ? == oscillator mode oscillator source poscmd<1:0> fnosc<2:0> see note fast rc oscillator with divide-by-n (frcdivn) internal xx 111 1, 2 fast rc oscillator with divide-by-16 (frcdiv16) internal xx 110 1 low-power rc oscillator (lprc) internal xx 101 1 secondary (timer1) oscillator (sosc) secondary xx 100 1 primary oscillator (hs) with pll (hspll) primary 10 011 ? primary oscillator (xt) with pll (xtpll) primary 01 011 ? primary oscillator (ec) with pll (ecpll) primary 00 011 1 primary oscillator (hs) primary 10 010 ? primary oscillator (xt) primary 01 010 ? primary oscillator (ec) primary 00 010 1 fast rc oscillator with pll (frcpll) internal xx 001 1 fast rc oscillator (frc) internal xx 000 1 note 1: osc2 pin function is determined by the osciofnc configuration bit. 2: this is the default oscillator mode for an unprogrammed (erased) device. 0.8-8.0 mhz (1) 100-200 mhz (1) divide by 2, 4, 8 divide by 2-513 divide by 2-33 source (crystal, external clock pllpre x vco plldiv pllpost or internal rc) 12.5-80 mhz (1) f osc note 1: this frequency range must be satisfied at all times. f vco n1 m n2
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 92 ? 2007-2011 microchip technology inc. 8.2 oscillator resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 8.2.1 key resources ? section 7. ?oscillator? (ds70186) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 93 pic24hj32gp202/204 and pic24hj16gp304 8.3 oscillator control registers register 8-1: osccon: os cillator control register (1,3) u-0 r-0 r-0 r-0 u-0 r/w-y r/w-y r/w-y ? cosc<2:0> ? nosc<2:0> (2) bit 15 bit 8 r/w-0 r/w-0 r-0 u-0 r/c-0 u-0 r/w-0 r/w-0 clklock iolock lock ?cf ? lposcen oswen bit 7 bit 0 legend: y = value set from configuration bits on por c = clear only bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 unimplemented: read as ? 0 ? bit 14-12 cosc<2:0>: current oscillator selection bits (read-only) 111 = fast rc oscillator (frc) with divide-by-n 110 = fast rc oscillator (frc) with divide-by-16 101 = low-power rc oscillator (lprc) 100 = secondary oscillator (sosc) 011 = primary oscillator (xt, hs, ec) with pll 010 = primary oscillator (xt, hs, ec) 001 = fast rc oscillator (frc) with pll 000 = fast rc oscillator (frc) bit 11 unimplemented: read as ? 0 ? bit 10-8 nosc<2:0>: new oscillator selection bits (2) 111 = fast rc oscillator (frc) with divide-by-n 110 = fast rc oscillator (frc) with divide-by-16 101 = low-power rc oscillator (lprc) 100 = secondary oscillator (sosc) 011 = primary oscillator (xt, hs, ec) with pll 010 = primary oscillator (xt, hs, ec) 001 = fast rc oscillator (frc) with pll 000 = fast rc oscillator (frc) bit 7 clklock: clock lock enable bit if clock switching is enabled and fscm is disabled (fosc = 0b01 ) 1 = clock switching is disabled, system clock source is locked 0 = clock switching is enabled, system clock s ource can be modified by clock switching bit 6 iolock: peripheral pin select lock bit 1 = peripherial pin select is locked, write to peripheral pin select register is not allowed 0 = peripherial pin select is unlocked, write to peripheral pin select register is allowed bit 5 lock: pll lock status bit (read-only) 1 = indicates that pll is in lock, or pll start-up timer is satisfied 0 = indicates that pll is out of lock, start-up timer is in progress or pll is disabled bit 4 unimplemented: read as ? 0 ? note 1: writes to this register require an unlock sequence. refer to section 7. ?oscillator? (ds70186) in the ?dspic33f/pic24h family reference manual? for details. 2: direct clock switches between any primary oscillator mode with pll and frcpll mode are not permitted. this applies to clock switches in either direction. in these instances, the application must switch to frc mode as a transition clock source between the two pll modes. 3: this register is reset only on a power-on reset (por).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 94 ? 2007-2011 microchip technology inc. bit 3 cf: clock fail detect bit (read/clear by application) 1 = fscm has detect ed clock failure 0 = fscm has not dete cted clock failure bit 2 unimplemented: read as ? 0 ? bit 1 lposcen: secondary (lp) oscillator enable bit 1 = enable secondary oscillator 0 = disable secondary oscillator bit 0 oswen: oscillator switch enable bit 1 = request oscillator switch to se lection specified by nosc<2:0> bits 0 = oscillator switch is complete register 8-1: osccon: os cillator control register (1,3) (continued) note 1: writes to this register require an unlock sequence. refer to section 7. ?oscillator? (ds70186) in the ?dspic33f/pic24h family reference manual? for details. 2: direct clock switches between any primary oscillator mode with pll and frcpll mode are not permitted. this applies to clock switches in either direction. in these instances, the applic ation must switch to frc mode as a transition clock source between the two pll modes. 3: this register is reset only on a power-on reset (por).
? 2007-2011 microchip technology inc. ds70289j-page 95 pic24hj32gp202/204 and pic24hj16gp304 register 8-2: clkdiv: clock divisor register (2) r/w-0 r/w-0 r/w-1 r/w-1 r/w-0 r/w-0 r/w-0 r/w-0 roi doze<2:0> dozen (1) frcdiv<2:0> bit 15 bit 8 r/w-0 r/w-1 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 pllpost<1:0> ? pllpre<4:0> bit 7 bit 0 legend: y = value set from configuration bits on por r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 roi: recover on interrupt bit 1 = interrupts will clear the dozen bit and the proce ssor clock/peripheral clock ratio is set to 1:1 0 = interrupts have no effect on the dozen bit bit 14-12 doze<2:0>: processor clock reduction select bits 111 = f cy /128 110 = f cy /64 101 = f cy /32 100 = f cy /16 011 = f cy /8 (default) 010 = f cy /4 001 = f cy /2 000 = f cy /1 bit 11 dozen: doze mode enable bit (1) 1 = doze<2:0> field specifies the ratio between the peripheral clocks and the processor clocks 0 = processor clock/peripheral clock ratio forced to 1:1 bit 10-8 frcdiv<2:0>: internal fast rc osci llator postscaler bits 111 = frc divide by 256 110 = frc divide by 64 101 = frc divide by 32 100 = frc divide by 16 011 = frc divide by 8 010 = frc divide by 4 001 = frc divide by 2 000 = frc divide by 1 (default) bit 7-6 pllpost<1:0>: pll vco output divider select bits (also denoted as ?n2?, pll postscaler) 11 = output/8 10 = reserved 01 = output/4 (default) 00 = output/2 bit 5 unimplemented: read as ? 0 ? bit 4-0 pllpre<4:0>: pll phase detector input divider bits (also denoted as ?n1?, pll prescaler) 11111 = input/33 ? ? ? 00001 = input/3 00000 = input/2 (default) note 1: this bit is cleared when the roi bit is set and an interrupt occurs. 2: this register is reset only on a power-on reset (por).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 96 ? 2007-2011 microchip technology inc. register 8-3: pllfbd: pll feedback divisor register (1) u-0 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 ? ? ? ? ? ? ?plldiv<8> bit 15 bit 8 r/w-0 r/w-0 r/w-1 r/w-1 r/w-0 r/w-0 r/w-0 r/w-0 plldiv<7:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-9 unimplemented: read as ? 0 ? bit 8-0 plldiv<8:0>: pll feedback divisor bits (also denoted as ?m?, pll multiplier) 111111111 = 513 ? ? ? 000110000 = 50 (default) ? ? ? 000000010 = 4 000000001 = 3 000000000 = 2 note 1: this register is reset only on a power-on reset (por).
? 2007-2011 microchip technology inc. ds70289j-page 97 pic24hj32gp202/204 and pic24hj16gp304 register 8-4: osctun: frc os cillator tuning register (2) u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? tun<5:0> (1) bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-6 unimplemented: read as ? 0 ? bit 5-0 tun<5:0>: frc oscillator tuning bits (1) 111111 = center frequency - 0.375% (7.345 mhz) ? ? ? 100001 = center frequency - 11.625% (6.52 mhz) 100000 = center frequency - 12% (6.49 mhz) 011111 = center frequency + 11.625% (8.23 mhz) 011110 = center frequency + 11.25% (8.20 mhz) ? ? ? 000001 = center frequency + 0.375% (7.40 mhz) 000000 = center frequency (7.37 mhz nominal) note 1: osctun functionality has been provided to help cu stomers compensate for temperature effects on the frc frequency over a wide range of temperatures. the t uning step size is an approximation and is neither characterized nor tested. 2: this register is reset only on a power-on reset (por).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 98 ? 2007-2011 microchip technology inc. 8.4 clock switching operation applications are free to s witch among any of the four clock sources (primary, lp, frc and lprc) under software control at any time . to limit the possible side effects of this flexibility, devices have a safeguard lock built into the switch process. 8.4.1 enabling clock switching to enable clock switching, the fcksm1 configuration bit in the configuration register must be programmed to ? 0 ?. (refer to section 19.1 ?configuration bits? for further details.) if the fcksm1 configuration bit is unprogrammed (? 1 ?), the clock switching function and fail-safe clock monitor function are disabled. this is the default setting. the nosc control bits (osccon<10:8>) do not control the clock selecti on when clock switching is disabled. however, the cosc bits (osccon<14:12>) reflect the clock source selected by the fnosc configuration bits. the oswen control bit (osccon<0>) has no effect when clock switching is disabled. it is held at ? 0 ? at all times. 8.4.2 oscillato r switching sequence performing a clock switch requires the following basic sequence: 1. read the cosc bits (osccon<14:12>) to determine the current oscillator source, if desired. 2. perform the unlock sequence to allow a write to the osccon register high byte. 3. write the appropriate value to the nosc control bits (osccon<10:8>) for the new oscillator source. 4. perform the unlock sequence to allow a write to the osccon register low byte. 5. set the oswen bit to initiate the oscillator switch. once the basic sequence is completed, the system clock hardware responds automatically as follows: 1. the clock switching hardware compares the cosc status bits with the new value of the nosc control bits. if both of them are the same, the clock switch is a redundant operation. in this case, the oswen bit is cleared automatically and the clock switch is aborted. 2. if a valid clock switch has been initiated, the sta- tus bits, lock (osccon<5>) and cf (osccon<3>) are cleared. 3. the new oscillator is turned on by the hardware if it is not currently running. if a crystal oscillator has to be turned on, the hardware waits until the oscillator start-up timer (ost) expires. if the new source is using the pll, the hardware waits until a pll lock is detected (lock = 1 ). 4. the hardware waits for 10 clock cycles from the new clock source and then performs the clock switch. 5. the hardware clears the oswen bit to indicate a successful clock transition. in addition, the nosc bit values are transferred to the cosc status bits. 6. the old clock source is turned off at this time, with the exception of lprc (if wdt or fscm are enabled) or lp (if lposcen remains set). 8.5 fail-safe clock monitor (fscm) the fail-safe clock monitor (fscm) allows the device to continue to operate even in the event of an oscillator failure. the fscm function is enabled by programming. if the fscm function is enabled, the lprc internal oscillator runs at all times (except during sleep mode) and is not subject to control by the watchdog timer. in the event of an oscillator failure, the fscm generates a clock failure tr ap event and switches the system clock over to the frc oscillator. then the application program can either attempt to restart the oscillator or execute a controlled shutdown. the trap can be treated as a warm reset by simply loading the reset address into the os cillator fail trap vector. if the pll multiplier is us ed to scale the system clock, the internal frc is also multiplied by the same factor on clock failure. es sentially, the device switches to frc with pll on a clock failure. note: primary oscillator mode has three different submodes (xt, hs and ec), which are determined by the poscmd<1:0> configuration bits. while an application can switch to and from primary oscillator mode in software, it cannot switch among the different primary submodes without reprogramming the device. note 1: the processor continues to execute code throughout the clock switching sequence. timing-sensitive code should not be executed during this time. 2: direct clock switches between any pri- mary oscillator mode with pll and frc- pll mode are not permitted. this applies to clock switches in either direction. in these instances, the application must switch to frc mode as a transition clock source between the two pll modes. 3: refer to section 7. ?oscillator? (ds70186) in the ?dspic33f/pic24h family reference manual? for details.
? 2007-2011 microchip technology inc. ds70289j-page 99 pic24hj32gp202/204 and pic24hj16gp304 9.0 power-saving features the pic24hj32gp202/204 and pic24hj16gp304 devices provide the ability to manage power consumption by selectively managing clocking to the cpu and the peripherals. in general, a lower clock frequency and a reduction in the number of circuits being clocked constitutes lower consumed power. pic24hj32gp202/204 and pic24hj16gp304 devices can manage power consumption in four different ways: ? clock frequency ? instruction-based sleep and idle modes ? software-controlled doze mode ? selective peripheral control in software combinations of the above methods can be used to selectively customize an application?s power consumption while still maintaining critical application features, such as timing-sensitive communications. 9.1 clock frequency and clock switching pic24hj32gp202/204 and pic24hj16gp304 devices allow a wide range of clock frequencies to be selected under applicati on control. if the system clock configuration is not locked, users can choose low-power or high-precision oscillators by simply changing the nosc bits (osccon<10:8>). the process of changing a syst em clock during operation, as well as limitations to the process, are discussed in more detail in section 8.0 ?oscillator configuration? . 9.2 instruction-based power-saving modes pic24hj32gp202/204 and pic24hj16gp304 devices have two special power-saving modes that are entered through the execution of a special pwrsav instruction. sleep mode stops clock operation and halts all code execution. idle mode halts the cpu and code execution, but allows peri pheral modules to continue operation. example 9-1 shows the assembler syntax of the pwrsav instruction. sleep and idle modes can be exited as a result of an enabled interrupt, wdt time-out or a device reset. when the device exits these modes, it is said to wake-up. 9.2.1 sleep mode in the sleep mode: ? the system clock source is shut down. if an on-chip oscillator is used, it is turned off. ? the device current consumption is reduced to a minimum, provided that no i/o pin is sourcing current ? the fail-safe clock monitor does not operate, since the system clock source is disabled ? the lprc clock continues to run if the wdt is enabled ? the wdt, if enabled, is automatically cleared prior to entering sleep mode ? some device features or peripherals may continue to operate. this includes items such as the input change notification on the i/o ports, or peripherals that use an external clock input. ? any peripheral that r equires the system clock source for its operation is disabled the device will wake-up from sleep mode on any of these events: ? any interrupt source that is individually enabled ? any form of device reset ? a wdt time-out on wake-up from sleep mode, the processor restarts with the same clock source th at was active when sleep mode was entered. example 9-1: pwrsav instruction syntax note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 9. watchdog timer and power savings modes? (ds70196) of the ?dspic33f/pic24h family refer- ence manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: sleep_mode and idle_mode are constants defined in the assembler include file for the selected device. pwrsav #sleep_mode ; put the device into sleep mode pwrsav #idle_mode ; put the device into idle mode
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 100 ? 2007-2011 microchip technology inc. 9.2.2 idle mode the following occur in idle mode: ? the cpu stops executing instructions ? the wdt is automatically cleared ? the system clock sour ce remains active. by default, all peripheral modules continue to operate normally from the system clock source, but can also be selectively disabled (see section 9.4 ?peripheral module disable? ). ? if the wdt or fscm is enabled, the lprc also remains active the device will wake from idle mode on any of these events: ? any interrupt that is individually enabled ? any device reset ? a wdt time-out on wake-up from idle mode, the clock is reapplied to the cpu and instruction execution will begin (2-4 cycles later), starting wit h the instruction following the pwrsav instruction, or the fi rst instruction in the isr. 9.2.3 interrupts coincident with power save instructions any interrupt that coincides with the execution of a pwrsav instruction is held off until entry into sleep or idle mode is completed. the device then wakes up from sleep or idle mode. 9.3 doze mode the preferred strategies for reducing power consumption are changing clock speed and invoking one of the power-saving modes. in some circumstances, however, these are not practical. for example, it may be necessary for an application to maintain uninterrupted synchronous communication, even while it is doing nothing else. reducing system clock speed can introduce communication errors, while using a power-saving mode can stop communications completely. doze mode is a simple and effective alternative method to reduce power consumption while the device is still executing code. in this mode, the system clock continues to operate from th e same source and at the same speed. peripheral modules continue to be clocked at the same speed, while the cpu clock speed is reduced. synchronization between the two clock domains is maintained, allowing the peripherals to access the sfrs while the cpu executes code at a slower rate. doze mode is enabled by setting the dozen bit (clkdiv<11>). the ratio between peripheral and core clock speed is determined by the doze<2:0> bits (clkdiv<14:12>). there are eight possible configurations, from 1:1 to 1:128, with 1:1 being the default setting. programs can use doze mode to selectively reduce power consumption in event-driven applications. this allows clock-sensitive func tions, such as synchronous communications, to continue without interruption while the cpu idles, waiting for something to invoke an interrupt routine. an automatic return to full-speed cpu operation on interrupts can be enabled by setting the roi bit (clkdiv<15>). by default, interrupt events have no effect on doze mode operation. for example, suppose the device is operating at 20 mips and the can module has been configured for 500 kbps based on this device operating speed. if the device is placed in doze mode with a clock frequency ratio of 1:4, the can module continues to communicate at the required bit rate of 500 kbps, but the cpu now starts executing instructions at a frequency of 5 mips. 9.4 peripheral module disable the peripheral module disable (pmd) registers provide a method to disable a peripheral module by stopping all clock sources supplied to that module. when a peripheral is disabl ed using the appropriate pmd control bit, the peripheral is in a minimum power consumption state. the control and status registers associated with the peripheral are also disabled. so writes to those registers will have no effect and read values will be invalid. a peripheral module is enabled only if both the associated bit in the pmd r egister are cleared and the peripheral is supported by the specific pic24h variant. if the peripheral is present in the device, it is enabled in the pmd register by default. note: if a pmd bit is set, the corresponding module is disabled after a delay of one instruction cycle. simila rly, if a pmd bit is cleared, the corresponding module is enabled after a delay of one instruction cycle (assuming the module control registers are already configured to enable module operation).
? 2007-2011 microchip technology inc. ds70289j-page 101 pic24hj32gp202/204 and pic24hj16gp304 9.5 power-saving resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 9.5.1 key resources ? section 9. ?watchdog timer and power-saving modes? (ds70196) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 102 ? 2007-2011 microchip technology inc. 9.6 power-saving control registers register 9-1: pmd1: peripheral mo dule disable control register 1 u-0 u-0 r/w-0 r/w-0 r/w-0 u-0 u-0 u-0 ? ? t3md t2md t1md ? ? ? bit 15 bit 8 r/w-0 u-0 r/w-0 u-0 r/w-0 u-0 u-0 r/w-0 i2c1md ?u1md ?spi1md ? ?ad1md (1) bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-14 unimplemented: read as ? 0 ? bit 13 t3md: timer3 module disable bit 1 = timer3 module is disabled 0 = timer3 module is enabled bit 12 t2md: timer2 module disable bit 1 = timer2 module is disabled 0 = timer2 module is enabled bit 11 t1md: timer1 module disable bit 1 = timer1 module is disabled 0 = timer1 module is enabled bit 10-8 unimplemented: read as ? 0 ? bit 7 i2c1md: i2c1 module disable bit 1 = i2c1 module is disabled 0 = i2c1 module is enabled bit 6 unimplemented: read as ? 0 ? bit 5 u1md: uart1 module disable bit 1 = uart1 module is disabled 0 = uart1 module is enabled bit 4 unimplemented: read as ? 0 ? bit 3 spi1md: spi1 module disable bit 1 = spi1 module is disabled 0 = spi1 module is enabled bit 2-1 unimplemented: read as ? 0 ? bit 0 ad1md: adc1 module disable bit (1) 1 = adc1 module is disabled 0 = adc1 module is enabled note 1: pcfgx bits have no effect if the adc module is disabled by setting this bit. in this case, all port pins multiplexed with anx will be in digital mode.
? 2007-2011 microchip technology inc. ds70289j-page 103 pic24hj32gp202/204 and pic24hj16gp304 register 9-2: pmd2: peripheral mo dule disable control register 2 r/w-0 r/w-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 ic8md ic7md ? ? ? ?ic2mdic1md bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 ? ? ? ? ? ?oc2mdoc1md bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ic8md: input capture 8 module disable bit 1 = input capture 8 module is disabled 0 = input capture 8 module is enabled bit 14 ic7md: input capture 2 module disable bit 1 = input capture 7 module is disabled 0 = input capture 7 module is enabled bit 13-10 unimplemented: read as ? 0 ? bit 9 ic2md: input capture 2 module disable bit 1 = input capture 2 module is disabled 0 = input capture 2 module is enabled bit 8 ic1md: input capture 1 module disable bit 1 = input capture 1 module is disabled 0 = input capture 1 module is enabled bit 7-2 unimplemented: read as ? 0 ? bit 1 oc2md: output compare 2 module disable bit 1 = output compare 2 module is disabled 0 = output compare 2 module is enabled bit 0 oc1md: output compare 1 module disable bit 1 = output compare 1 module is disabled 0 = output compare 1 module is enabled
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 104 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 105 pic24hj32gp202/204 and pic24hj16gp304 10.0 i/o ports all of the device pins (except v dd , v ss , mclr and osc1/clki) are shared am ong the peripherals and the parallel i/o ports. all i/o input ports feature schmitt trigger inputs for improved noise immunity. 10.1 parallel i/o (pio) ports a parallel i/o port that shares a pin with a peripheral is generally subservient to the peripheral. the peripheral?s output buffer data and control signals are provided to a pair of multiplexers. the multiplexers select whether the peripher al or the associated port has ownership of the output data and control signals of the i/o pin. the logic also prevents ?loop through?, in which a port?s digital output can drive the input of a peripheral that shares the same pin. figure 10-1 shows how ports are shared with other peripherals and the associated i/o pin to which they are connected. when a peripheral is enabled and the peripheral is actively driving an associated pin, the use of the pin as a general purpose output pin is disabled. the i/o pin can be read, but the output driver for the parallel port bit is disabled. if a peripheral is enabled, but the peripheral is not actively driving a pin, that pin can be driven by a port. all port pins have three registers directly associated with their operation as digital i/o. the data direction register (trisx) determines whether the pin is an input or an output. if the data direction bit is ? 1 ?, then the pin is an input. all port pins are defined as inputs after a reset. reads from the latch (latx) read the latch. writes to the latch, write t he latch. reads from the port (portx) read the port pins, while writes to the port pins write the latch. any bit and its associated data and control registers that are not valid for a particular device will be disabled. this means that the corresponding latx and trisx registers and the port pin will read as zeros. when a pin is shared wit h another peripheral or function that is defined as an input only, it is nevertheless regarded as a dedicated port because there is no other compet ing source of outputs. figure 10-1: block diagram of a typical shared port structure note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a comprehensive reference source. to complement the information in this data sheet, refer to ?section 10. i/o ports? (ds70193) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. q d ck wr lat + tris latch i/o pin wr port data bus q d ck data latch read port read tris 1 0 1 0 wr tris peripheral output data output enable peripheral input data i/o peripheral module peripheral output enable pio module output multiplexers output data input data peripheral module enable read lat
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 106 ? 2007-2011 microchip technology inc. 10.2 open-drain configuration in addition to the port, lat and tris registers for data control, some port pins can also be individually configured for either digital or open-drain output. this is controlled by the open-drain control register, odcx, associated with each port. setting any of the bits con- figures the corresponding pin to act as an open-drain output. the open-drain feature a llows the generation of outputs higher than v dd (e.g., 5v) on any desired 5v tolerant pins by using external pull-up resistors. the maximum open-drain voltage allowed is the same as the maximum v ih specification. see the ? pin diagrams ? section for the available pins and their functionality. 10.3 configuring analog port pins the ad1pcfg and tris registers control the operation of the analog-to-digital (a/d) port pins. the port pins that are desired as analog inputs must have their corresponding tris bit set (input). if the tris bit is cleared (output), the digital output level (v oh or v ol ) will be converted. the ad1pcfgl register has a default value of 0x0000; therefore, all pins that s hare anx functions are analog (not digital) by default. when the port register is read, all pins configured as analog input channels will read as cleared (a low level). pins configured as digital inputs will not convert an analog input. analog levels on any pin that is defined as a digital input (including the anx pins) can cause the input buffer to consume current that exceeds the device specifications. 10.4 i/o port write/read timing one instruction cycle is required between a port direction change or port write operation and a read operation of the same port. typically this instruction would be a nop . examples are shown in example 10-1 and example 10-2 . this also applies to port bit oper- ations, such as bset portb, # rb0 , which are single cycle read-modify-write. all port bit operations, such as mov portb, w0 or bset portb, # rbx , read the pin and not the latch. 10.5 input change notification the input change notification function of the i/o ports allows the pic24hj32gp202/204 and pic24hj16gp304 devices to generate interrupt requests to the processor in response to a change-of-state on selected input pins. this feature can detect input change-of-states even in sleep mode, when the clocks are disabled. depending on the device pin count, up to 31 external signals (cnx pin) can be selected (enabled) for generating an interrupt request on a change-of-state. four control registers are associated with the cn module. the cnen1 and cnen2 registers contain the interrupt enable control bits for each of the cn input pins. setting any of these bits enables a cn interrupt for the corresponding pins. each cn pin also has a weak pull-up connected to it. the pull-ups act as a current source connected to the pin, and eliminate the need for external resistors when push button or keypad devices are connected. the pull-ups are enabled separately using the cnpu1 and cnpu2 registers, which contain the control bits for each of the cn pins. sett ing any of the control bits enables the weak pull-ups for the corresponding pins. example 10-1: port write/read example example 10-2: port bit operations note: pull-ups on change notification pins should always be disabled when the port pin is configured as a digital output. mov 0xff00, w0 ; configure portb<15:8> as inputs mov w0, trisbb ; and portb<7:0> as outputs nop ; delay 1 cycle btss portb, #13 ; next instruction incorrect: bset portb, #rb1 ;set portb high bset portb, #rb6 ;set portb high correct: bset portb, #rb1 ;set portb high nop bset portb, #rb6 ;set portb high nop preferred: bset latb, latb1 ;set portb high bset latb, latb6 ;set portb high
? 2007-2011 microchip technology inc. ds70289j-page 107 pic24hj32gp202/204 and pic24hj16gp304 10.6 peripheral pin select a major challenge in general purpose devices is providing the largest possible set of peripheral features while minimizing the conflict of features on i/o pins. the challenge is even greater on low-pin count devices. in an application where more than one peripheral must be assigned to a single pin, inconve- nient workarounds in application code or a complete redesign may be the only option. peripheral pin select configuration enables peripheral set selection and placement on a wide range of i/o pins. by increasing the pinout options available on a particular device, programmers can better tailor the microcontroller to their ent ire application, rather than trimming the application to fit the device. the peripheral pin select configuration feature operates over a fixed subset of digital i/o pins. programmers can independently map the input and/or output of most digital peripherals to any one of these i/o pins. peripheral pin select is performed in software, and generally does not require the device to be reprogrammed. hardware safeguards are included that prevent accidental or spurious changes to the peripheral mapping, once it has been established. 10.6.1 available pins the peripheral pin select feature is used with a range of up to 26 pins. the number of available pins depends on the particular device and its pin count. pins that support the peripheral pin se lect feature include the designation ?rpn? in their full pin designation, where ?rp? designates a remappable peripheral and ?n? is the remappable pin number. 10.6.2 controlling peripheral pin select peripheral pin select features are controlled through two sets of special function registers to map peripherals and to map outputs. since they are separately controlled, a particular peripheral?s input and output (if the peripheral has both) can be placed on any selectable function pin without constraint. the association of a peripheral to a peripheral selectable pin is handled in two different ways, depending on whether an in put or output is being mapped. 10.6.2.1 input mapping the inputs of the peripheral pin select options are mapped on the basis of the peripheral. a control register associated with a peripheral dictates the pin it will be mapped to. the rpinrx registers are used to configure peripheral input mapping (see register 10-1 through register 10-9 ). each register contains sets of 5-bit fields, with each set associated with one of the remappable peripherals. programming a given peripheral?s bit field with an appropriate 5-bit value maps the rpn pin with that value to that peripheral. for any given device, the valid range of values for any bit field corresponds to the maximum number of peripheral pin selections supported by the device. figure 10-2 illustrates remappab le pin selection for u1rx input. figure 10-2: remappable mux input for u1rx note: for input mapping only, the peripheral pin select (pps) functio nality does not have priority over the trisx settings. there- fore, when configuring the rpn pin for input, the corresponding bit in the trisx register must also be configured for input (i.e., set to ? 1 ?). rp0 rp1 rp2 rp 25 0 25 1 2 u1rx input u1rxr<4:0> to peripheral
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 108 ? 2007-2011 microchip technology inc. table 10-1: remappable peripheral inputs (1) 10.6.2.2 output mapping in contrast to inputs, the outputs of the peripheral pin select options are mapped on the basis of the pin. in this case, a control register associated with a particular pin dictates the peripheral output to be mapped. the rporx registers are used to control output mapping. like the rpinrx registers, each register contains sets of 5-bit fields, with each set associated with one rpn pin (see register 10-10 through register 10-22 ). the value of the bit field corresponds to one of the periph- erals, and that peripheral?s output is mapped to the pin (see table 10-2 and figure 10-3 ). the list of peripherals for output mapping also includes a null value of ? 00000 ? because of the mapping technique. this permits any given pin to remain unconnected from the outpu t of any of the pin selectable peripherals. figure 10-3: multiplexing of remappable output for rpn input name function name register configuration bits external interrupt 1 int1 rpinr0 int1r<4:0> external interrupt 2 int2 rpinr1 int2r<4:0> timer 2 external clock t2ck rpinr3 t2ckr<4:0> timer 3 external clock t3ck rpinr3 t3ckr<4:0> input capture 1 ic1 rpinr7 ic1r<4:0> input capture 2 ic2 rpinr7 ic2r<4:0> input capture 7 ic7 rpinr10 ic7r<4:0> input capture 8 ic8 rpinr10 ic8r<4:0> output compare fault a ocfa rpinr11 ocfar<4:0> uart 1 receive u1rx rpinr18 u1rxr<4:0> uart 1 clear to send u1cts rpinr18 u1ctsr<4:0> spi 1 data input sdi1 rpinr20 sdi1r<4:0> spi 1 clock input sck1in rpinr20 sck1r<4:0> spi 1 slave select inpu t ss1in rpinr21 ss1r<4:0> note 1: unless otherwise noted, all inputs use the schmitt input buffers. 0 19 3 rpnr<4:0> default u1tx output enable u1rts output enable 4 18 oc1 output enable 0 19 3 default u1tx output u1rts output 4 oc2 output 18 oc1 output output enable output data rpn oc2 output enable
? 2007-2011 microchip technology inc. ds70289j-page 109 pic24hj32gp202/204 and pic24hj16gp304 table 10-2: output selection for remappable pin (rpn) 10.6.3 controllin g configuration changes because peripheral remapping can be changed during run time, some restrictions on peripheral remapping are needed to prevent accidental configuration changes. pic24h devices include three features to prevent alterations to the peripheral map: ? control register lock sequence ? continuous state monitoring ? configuration bit pin select lock 10.6.3.1 control register lock under normal operation, writ es to the rpinrx and rporx registers are not al lowed. attempted writes appear to execute normally, but the contents of the registers remain unchanged. to change these registers, they must be unlocked in hardware. the register lock is contro lled by the iolock bit (osccon<6>). setting t he iolock bit prevents writes to the control regist ers; clearing this bit allows writes. to set or clear the iolock bit, a specific command sequence must be executed: 1. write 0x46 to osccon<7:0>. 2. write 0x57 to osccon<7:0>. 3. clear (or set) iolock as a single operation. unlike the similar sequence with the oscillator?s lock bit, iolock remains in one state until changed. this allows all the peripheral pin selects to be configured with a single unlock sequence followed by an update to all control registers, then locked with a second lock sequence. 10.6.3.2 continuous state monitoring in addition to being protect ed from direct writes, the contents of the rpinrx and rporx registers are constantly monitored in hardware by shadow registers. if an unexpected change in any of the registers occurs (such as cell disturbances caused by esd or other external events), a configuration mismatch reset will be triggered. 10.6.3.3 configuration bit pin select lock as an additional level of safety, the device can be configured to prevent more than one write session to the rpinrx and rporx regi sters. the iol1way con- figuration bit (fosc<5>) blocks the iolock bit from being cleared after it has been set once. in the default (unprogramm ed) state, iol1way is set restricting the users to one write session. programming iol1way allows user applications unlimited access (with the proper use of the unlock sequence) to the peripheral pin select registers. function rpnr<4:0> output name null 00000 rpn tied to default port pin u1tx 00011 rpn tied to uart1 transmit u1rts 00100 rpn tied to uart1 ready to send sdo1 00111 rpn tied to spi1 data output sck1out 01000 rpn tied to spi1 clock output ss1out 01001 rpn tied to spi1 slave select output oc1 10010 rpn tied to output compare 1 oc2 10011 rpn tied to output compare 2 note: mplab ? c30 provides built-in c language functions for unlocking the osccon register: __builtin_write_oscconl(value) __builtin_write_oscconh(value) see mplab help for more information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 110 ? 2007-2011 microchip technology inc. 10.7 i/o helpful tips 1. in some cases, certain pins as defined in table 22-9: ?dc characteristics: i/o pin input speci- fications? under ?injection current?, have internal protection diodes to v dd and v ss . the term ?injection current? is al so referred to as ?clamp current?. on designated pins, with sufficient exter- nal current limiting precautions by the user, i/o pin input voltages are allowed to be greater or less than the data sheet absolute maximum ratings with nominal v dd with respect to the v ss and v dd supplies. note that when the user application for- ward biases either of the high or low side internal input clamp diodes, that the resulting current being injected into the device that is clamped internally by the v dd and v ss power rails, may affect the adc accuracy by four to six counts. 2. i/o pins that are shared with any analog input pin, (i.e., anx), are always analog pins by default after any reset. consequently, any pin(s) configured as an analog input pin, automatically disables the dig- ital input pin buffer. as such, any attempt to read a digital input pin will always return a ? 0 ? regardless of the digital logic level on the pin if the analog pin is configured. to use a pin as a digital i/o pin on a shared anx pin, the user application needs to con- figure the analog pin configuration registers in the adc module, (i.e., adxpcfgl, ad1pcfgh), by setting the appropriate bit that corresponds to that i/o port pin to a ? 1 ?. on devices with more than one adc, both analog pin conf igurations for both adc modules must be configured as a digital i/o pin for that pin to function as a digital i/o pin. 3. most i/o pins have multiple functions. referring to the device pin diagrams in the data sheet, the pri- orities of the functions allocated to any pins are indicated by reading the pin name from left-to-right. the left most function name takes pre- cedence over any function to its right in the naming convention. for exampl e: an16/t2ck/t7ck/rc1. this indicates that an16 is the highest priority in this example and will supersede all other functions to its right in the list. those other functions to its right, even if enabled, w ould not work as long as any other function to its left was enabled. this rule applies to all of the functions listed for a given pin. 4. each cn pin has a configurable internal weak pull-up resistor. the pull-ups act as a current source connected to the pin, and eliminates the need for external resistors in certain applica- tions. the internal pull-up is to ~(v dd -0.8) not v dd . this is still above the minimum v ih of cmos and ttl devices. 5. when driving leds directly, the i/o pin can source or sink more current than what is specified in the v oh /i oh and v ol /i ol dc characteristic specifica- tion. the respective i oh and i ol current rating only applies to maintaining the corresponding output at or above the v oh and at or below the v ol levels. however, for leds unlike digital inputs of an exter- nally connected device, they are not governed by the same minimum v ih /v il levels. an i/o pin out- put can safely sink or s ource any current less than that listed in the absolute maximum rating section of the data sheet. for example: v oh = 2.4v @ i oh = -8 ma and v dd = 3.3v the maximum output current sourced by any 8 ma i/o pin = 12 ma. led source current < 12 ma is technically permitted. refer to the v oh /i oh graphs in section 22.0 ?electri cal characteristics? for additional information. 10.8 i/o resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 10.8.1 key resources ? section 10. ?i/o ports? (ds70193) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: although it is not possible to use a digital input pin when its analog function is enabled, it is possible to use the digital i/o output function, tris x = 0x0, while the analog function is also enabled. however, this is not recommended , particularly if the analog input is connected to an external analog voltage source, which would cre- ate signal contention between the analog signal and the output pin driver. note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 111 pic24hj32gp202/204 and pic24hj16gp304 10.9 peripheral pin select registers the pic24hj32gp202/204 and pic24hj16gp304 devices implement 17 registers for remappable peripheral configuration: ? input remappable peripheral registers (9) ? output remappable peripheral registers (8) note: input and output register values can only be changed if the iolock bit (osc- con<6>) = 0 . see section 10.6.3.1 ?control register lock? for a specific command sequence.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 112 ? 2007-2011 microchip technology inc. register 10-1: rpinr0: peripheral pin select input register 0 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?int1r<4:0> bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 int1r<4:0>: assign external interrupt 1 (intr1) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-0 unimplemented: read as ? 0 ? register 10-2: rpinr1: peripheral pin select input register 1 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?int2r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-5 unimplemented: read as ? 0 ? bit 4-0 int2r<4:0>: assign external interrupt 2 (intr2) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
? 2007-2011 microchip technology inc. ds70289j-page 113 pic24hj32gp202/204 and pic24hj16gp304 register 10-3: rpinr3: peripheral pin select input register 3 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?t3ckr<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?t2ckr<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 t3ckr<4:0>: assign timer3 external clock (t3c k) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-5 unimplemented: read as ? 0 ? bit 4-0 t2ckr<4:0>: assign timer2 external clock (t2c k) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 114 ? 2007-2011 microchip technology inc. register 10-4: rpinr7: peripheral pin select input register 7 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? ic2r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? ic1r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 ic2r<4:0>: assign input capture 2 (ic2) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-5 unimplemented: read as ? 0 ? bit 4-0 ic1r<4:0>: assign input capture 1 (ic1) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
? 2007-2011 microchip technology inc. ds70289j-page 115 pic24hj32gp202/204 and pic24hj16gp304 register 10-5: rpir10: periphera l pin select input register 10 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? ic8r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? ic7r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 ic8r<4:0>: assign input capture 8 (ic8) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-5 unimplemented: read as ? 0 ? bit 4-0 ic7r<4:0>: assign input capture 7 (ic7) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 116 ? 2007-2011 microchip technology inc. register 10-6: rpinr11: peripheral pin select input register 11 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?ocfar<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-5 unimplemented: read as ? 0 ? bit 4-0 ocfar<4:0>: assign output capture a (ocfa) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
? 2007-2011 microchip technology inc. ds70289j-page 117 pic24hj32gp202/204 and pic24hj16gp304 register 10-7: rpinr18: peripheral pin select input register 18 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? u1ctsr<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?u1rxr<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 u1ctsr<4:0>: assign uart 1 clear to send (u1cts ) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-5 unimplemented: read as ? 0 ? bit 4-0 u1rxr<4:0>: assign uart 1 receive (u1rx) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 118 ? 2007-2011 microchip technology inc. register 10-8: rpinr20: peripheral pin select input register 20 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?sck1r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ?sdi1r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 sck1r<4:0>: assign spi 1 clock input (sck1in) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 bit 7-5 unimplemented: read as ? 0 ? bit 4-0 sdi1r<4:0>: assign spi 1 data input (sdi1) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0
? 2007-2011 microchip technology inc. ds70289j-page 119 pic24hj32gp202/204 and pic24hj16gp304 register 10-9: rpinr21: peripheral pin select input register 21 u-0 u-0 u-0 u-0 u-0 u-0 u-0 u-0 ? ? ? ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 r/w-1 r/w-1 r/w-1 r/w-1 r/w-1 ? ? ? ss1r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-5 unimplemented: read as ? 0 ? bit 4-0 ss1r<4:0>: assign spi1 slave select input ( ss1in) to the corresponding rpn pin 11111 = input tied to vss 11001 = input tied to rp25 ? ? ? 00001 = input tied to rp1 00000 = input tied to rp0 register 10-10: rpor0: peripheral pin select output register 0 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp1r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp0r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp1r<4:0>: peripheral output function is assigned to rp1 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp0r<4:0>: peripheral output function is assigned to rp0 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 120 ? 2007-2011 microchip technology inc. register 10-11: rpor1: peripheral pin select output register 1 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp3r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp2r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp3r<4:0>: peripheral output function is assigned to rp3 output pin (see table 10-2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp2r<4:0>: peripheral output function is assigned to rp2 output pin (see table 10-2 for peripheral function numbers) register 10-12: rpor2: peripheral pin select output register 2 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp5r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp4r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp5r<4:0>: peripheral output function is assigned to rp5 output pin (see table 10-2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp4r<4:0>: peripheral output function is assigned to rp4 output pin (see table 10-2 for peripheral function numbers)
? 2007-2011 microchip technology inc. ds70289j-page 121 pic24hj32gp202/204 and pic24hj16gp304 register 10-13: rpor3: peripheral pin select output register 3 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp7r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp6r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp7r<4:0>: peripheral output function is assigned to rp7 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp6r<4:0>: peripheral output function is assigned to rp6 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) register 10-14: rpor4: peripheral pin select output register 4 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp9r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp8r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp9r<4:0>: peripheral output function is assigned to rp9 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp8r<4:0>: peripheral output function is assigned to rp8 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 122 ? 2007-2011 microchip technology inc. register 10-15: rpor5: peripheral pin select output register 5 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ?rp11r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp10r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp11r<4:0>: peripheral output function is assigned to rp11 output pin (see table 10-2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp10r<4:0>: peripheral output function is assigned to rp10 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) register 10-16: rpor6: peripheral pin select output register 6 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp13r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp12r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp13r<4:0>: peripheral output function is a ssigned to rp13 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp12r<4:0>: peripheral output function is assigned to rp12 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
? 2007-2011 microchip technology inc. ds70289j-page 123 pic24hj32gp202/204 and pic24hj16gp304 register 10-17: rpor7: peripheral pin select output register 7 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp15r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp14r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp15r<4:0>: peripheral output function is a ssigned to rp15 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp14r<4:0>: peripheral output function is assigned to rp14 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) register 10-18: rpor8: peripheral pin select output register 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp17r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp16r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp17r<4:0>: peripheral output function is a ssigned to rp15 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp16r<4:0>: peripheral output function is assigned to rp14 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 124 ? 2007-2011 microchip technology inc. register 10-19: rpor9: peripheral pin select output register 9 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp19r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp18r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp19r<4:0>: peripheral output function is a ssigned to rp19 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp18r<4:0>: peripheral output function is assigned to rp18 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) register 10-20: rpor10: periphera l pin select output register 10 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp21r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp20r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp21r<4:0>: peripheral output function is a ssigned to rp21 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp20r<4:0>: peripheral output function is assigned to rp20 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
? 2007-2011 microchip technology inc. ds70289j-page 125 pic24hj32gp202/204 and pic24hj16gp304 register 10-21: rpor11: periphera l pin select output register 11 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp23r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp22r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp23r<4:0>: peripheral output function is a ssigned to rp23 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp22r<4:0>: peripheral output function is assigned to rp22 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) register 10-22: rpor12: periphera l pin select output register 12 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp25r<4:0> bit 15 bit 8 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? rp24r<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-8 rp25r<4:0>: peripheral output function is a ssigned to rp25 output pin (see ta b l e 1 0 - 2 for peripheral function numbers) bit 7-5 unimplemented: read as ? 0 ? bit 4-0 rp24r<4:0>: peripheral output function is assigned to rp24 output pin (see ta b l e 1 0 - 2 for peripheral function numbers)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 126 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 127 pic24hj32gp202/204 and pic24hj16gp304 11.0 timer1 the timer1 module is a 16- bit timer, which can serve as the time counter for the real-time clock, or operate as a free-running interval timer/counter. timer1 can operate in three modes: ? 16-bit timer ? 16-bit synchronous counter ? 16-bit asynchronous counter timer1 also supports these features: ? timer gate operation ? selectable prescaler settings ? timer operation during cpu idle and sleep modes ? interrupt on 16-bit period register match or falling edge of external gate signal figure 11-1 shows a block diagram of the 16-bit timer module. to configure timer1 for operation: 1. set the ton bit (= 1 ) in the t1con register. 2. select the timer prescaler ratio using the tckps<1:0> bits in the t1con register. 3. set the clock and gating modes using the tcs and tgate bits in the t1con register. 4. set or clear the tsync bit in t1con to select synchronous or asynchronous operation. 5. load the timer period value into the pr1 register. 6. if interrupts are required, set the interrupt enable bit, t1ie. use the priority bits, t1ip<2:0>, to set the interrupt priority. figure 11-1: 16-bit time r1 module block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. it is not intended to be a comprehensive ref- erence source. to complement the infor- mation in this data sheet, refer to ?section 11. timers? (ds70205) of the ?dspic33f/pic24h family reference manual?, which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. ton sosci sosco/ pr1 set t1if equal comparator tmr1 reset soscen 1 0 tsync q qd ck tckps<1:0> prescaler 1, 8, 64, 256 2 tgate t cy 1 0 t1ck tcs 1x 01 tgate 00 sync gate sync
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 128 ? 2007-2011 microchip technology inc. 11.1 timer resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 11.1.1 key resources ? section 11. ?timers? (ds70205) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 129 pic24hj32gp202/204 and pic24hj16gp304 11.2 timer1 control register register 11-1: t1con: timer1 control register r/w-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ton ?tsidl ? ? ? ? ? bit 15 bit 8 u-0 r/w-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 u-0 ? tgate tckps<1:0> ?tsynctcs ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ton: timer1 on bit 1 = starts 16-bit timer1 0 = stops 16-bit timer1 bit 14 unimplemented: read as ? 0 ? bit 13 tsidl: stop in idle mode bit 1 = discontinue module operation when device enters idle mode 0 = continue module operation in idle mode bit 12-7 unimplemented: read as ? 0 ? bit 6 tgate: timer1 gated time accumulation enable bit when t c s = 1 : this bit is ignored. when t c s = 0 : 1 = gated time accumulation enabled 0 = gated time accumulation disabled bit 5-4 tckps<1:0> timer1 input clock prescale select bits 11 = 1:256 10 = 1:64 01 = 1:8 00 = 1:1 bit 3 unimplemented: read as ? 0 ? bit 2 tsync: timer1 external clock input synchronization select bit when tcs = 1 : 1 = synchronize external clock input 0 = do not synchronize external clock input when tcs = 0 : this bit is ignored. bit 1 tcs: timer1 clock source select bit 1 = external clock from pin t1ck (on the rising edge) 0 = internal clock (f cy ) bit 0 unimplemented: read as ? 0 ?
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 130 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 131 pic24hj32gp202/204 and pic24hj16gp304 12.0 timer2/3 feature the timer2/3 feature has 32-bit timers that can also be configured as two indepen dent 16-bit timers with selectable operating modes. as a 32-bit timer, the timer2/3 feature permits operation in three modes: ? two independent 16-bit timers (timer2 and timer3) with all 16-bit operating modes (except asynchronous counter mode) ? single 32-bit timer (timer2/3) ? single 32-bit synchronous counter (timer2/3) the timer2/3 feature also supports: ? timer gate operation ? selectable prescaler settings ? timer operation during idle and sleep modes ? interrupt on a 32-bit period register match ? time base for input capture and output compare modules (timer2 and timer3 only) ? adc1 event trigger (timer2/3 only) individually, all eight of the 16-bit timers can function as synchronous timers or counters. they also offer the features that are listed above, except for the event trigger. the operating modes and enabled features are determined by setting the appropriate bit(s) in the t2con and t3con registers. t2con registers are shown in generic form in register 12-1 . t3con registers are shown in register 12-2 . for 32-bit timer/counter opera tion, timer2 is the least significant word (lsw), and timer3 is the most significant word (msw) of the 32-bit timers. 12.1 32-bit operation to configure the timer2/3 feature for 32-bit operation: 1. set the corresponding t32 control bit. 2. select the prescaler ratio for timer2 using the tckps<1:0> bits. 3. set the clock and gating modes using the corresponding tcs and tgate bits. 4. load the timer period value. pr3 contains the most significant word of the value, while pr2 contains the least significant word. 5. set the interrupt enable bit t3ie, if interrupts are required. use the priority bits t3ip<2:0> to set the interrupt priority. while timer2 controls the timer, the interrupt appears as a timer3 interrupt. 6. set the corresponding ton bit. the timer value at any point is stored in the register pair tmr3:tmr2. tmr3 always contains the most significant word of the count, while tmr2 contains the least significant word. to configure any of the timers for individual 16-bit operation: 1. clear the t32 bit corresponding to that timer. 2. select the timer prescaler ratio using the tckps<1:0> bits. 3. set the clock and gating modes using the tcs and tgate bits. 4. load the timer period value into the prx register. 5. if interrupts are required, set the interrupt enable bit, txie. use the priority bits, txip<2:0>, to set the interrupt priority. 6. set the ton bit. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. it is not intended to be a comprehensive ref- erence source. to complement the infor- mation in this data sheet, refer to ?section 11. timers? (ds70205) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: for 32-bit operation, t3con control bits are ignored. only t2con control bit is used for setup and control. timer2 clock and gate inputs are used for the 32-bit timer modules, but an interrupt is generated with the timer3 interrupt flags.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 132 ? 2007-2011 microchip technology inc. figure 12-1: timer2/3 (32-bit) block diagram (1) figure 12-2: timer2 (16-bit) block diagram set t3if equal comparator pr3 pr2 reset lsb msb note 1: the 32-bit timer control bit, t32, must be set for 32-bit time r/counter operation. all control bits are respective to the t2con register. 2: the adc event trigger is available only on timer2/3. data bus<15:0> tmr3hld read tmr2 write tmr2 16 16 16 q qd ck tgate 0 1 ton tckps<1:0> 2 t cy tcs 1x 01 tgate 00 t2ck adc event trigger (2) gate sync prescaler 1, 8, 64, 256 sync tmr3 tmr2 16 ton tckps<1:0> prescaler 1, 8, 64, 256 2 t cy tcs tgate t2ck pr2 set t2if equal comparator tmr2 reset q qd ck tgate 1 0 gate sync 1x 01 00 sync
? 2007-2011 microchip technology inc. ds70289j-page 133 pic24hj32gp202/204 and pic24hj16gp304 12.2 timer2/3 resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 12.2.1 key resources ? section 11. ?timers? (ds70205) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 134 ? 2007-2011 microchip technology inc. register 12-1: t2con control register r/w-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ton ?tsidl ? ? ? ? ? bit 15 bit 8 u-0 r/w-0 r/w-0 r/w-0 r/w-0 u-0 r/w-0 u-0 ? tgate tckps<1:0> t32 ?tcs ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ton: timer2 on bit when t32 = 1 : 1 = starts 32-bit timer2/3 0 = stops 32-bit timer2/3 when t32 = 0 : 1 = starts 16-bit timer2 0 = stops 16-bit timer2 bit 14 unimplemented: read as ? 0 ? bit 13 tsidl: stop in idle mode bit 1 = discontinue module operation when device enters idle mode 0 = continue module operation in idle mode bit 12-7 unimplemented: read as ? 0 ? bit 6 tgate: timer2 gated time accumulation enable bit when tcs = 1 : this bit is ignored. when tcs = 0 : 1 = gated time accumulation enabled 0 = gated time accumulation disabled bit 5-4 tckps<1:0>: timer2 input clock prescale select bits 11 = 1:256 10 = 1:64 01 = 1:8 00 = 1:1 bit 3 t32: 32-bit timer mode select bit 1 = timer2 and timer3 form a single 32-bit timer 0 = timer2 and timer3 act as two 16-bit timers bit 2 unimplemented: read as ? 0 ? bit 1 tcs: timer2 clock source select bit 1 = external clock from pin t2ck (on the rising edge) 0 = internal clock (f cy ) bit 0 unimplemented: read as ? 0 ?
? 2007-2011 microchip technology inc. ds70289j-page 135 pic24hj32gp202/204 and pic24hj16gp304 register 12-2: t3con control register r/w-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ton (2) ?tsidl (1) ? ? ? ? ? bit 15 bit 8 u-0 r/w-0 r/w-0 r/w-0 u-0 u-0 r/w-0 u-0 ? tgate (2) tckps<1:0> (2) ? ?tcs (2) ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ton: timer3 on bit (2) 1 = starts 16-bit timer3 0 = stops 16-bit timer3 bit 14 unimplemented: read as ? 0 ? bit 13 tsidl: stop in idle mode bit (1) 1 = discontinue timer operation when device enters idle mode 0 = continue timer operation in idle mode bit 12-7 unimplemented: read as ? 0 ? bit 6 tgate: time r 3 gated time accumulation enable bit (2) when tcs = 1 : this bit is ignored. when tcs = 0 : 1 = gated time accumulation enabled 0 = gated time accumulation disabled bit 5-4 tckps<1:0>: timer3 input clock prescale select bits (2) 11 = 1:256 prescale value 10 = 1:64 prescale value 01 = 1:8 prescale value 00 = 1:1 prescale value bit 3-2 unimplemented: read as ? 0 ? bit 1 tcs: timer3 clock source select bit (2) 1 = external clock from t3ck pin 0 = internal clock (f osc /2) bit 0 unimplemented: read as ? 0 ? note 1: when 32-bit timer operation is enabled (t32 = 1 ) in the timer control regist er (t2con<3>), the tsidl bit must be cleared to operate th e 32-bit timer in idle mode. 2: when the 32-bit timer operation is enabled (t32 = 1 ) in the timer control register (t2con<3>), these bits have no effect.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 136 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 137 pic24hj32gp202/204 and pic24hj16gp304 13.0 input capture the input capture module is useful in applications requiring frequency (period) and pulse measurement. the pic24hj32gp202/204 and pic24hj16gp304 devices support up to eight input capture channels. the input capture module captures the 16-bit value of the selected time base register when an event occurs at the icx pin. the events that cause a capture event are listed below in three categories: ? simple capture event modes: - capture timer value on every falling edge of input at icx pin - capture timer value on every rising edge of input at icx pin ? capture timer value on every edge (rising and falling). ? prescaler capture event modes: - capture timer value on every 4th rising edge of input at icx pin - capture timer value on every 16th rising edge of input at icx pin each input capture channel can select one of the two 16-bit timers (timer2 or timer3) for the time base. the selected timer can use either an internal or external clock. other operational features include: ? device wake-up from capture pin during cpu sleep and idle modes ? interrupt on input capture event ? four-word fifo buffer for capture values - interrupt optionally generated after 1, 2, 3 or 4 buffer locations are filled ? use of input capture to provide additional sources of external interrupts figure 13-1: input capture block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. it is not intended to be a comprehensive ref- erence source. to complement the infor- mation in this data sheet, refer to ?section 12. input capture? (ds70198) of the ?dspic33f/pic24h family refer- ence manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. icxbuf icx pin icm<2:0> (icxcon<2:0>) mode select 3 10 set flag icxif (in ifsn register) tmr2 tmr3 edge detection logic 16 16 fifo r/w logic icxi<1:0> icov, icbne (icxcon<4:3>) icxcon interrupt logic system bus from 16-bit timers ictmr (icxcon<7>) fifo prescaler counter (1, 4, 16) and clock synchronizer note: an ?x? in a signal, register or bit nam e denotes the number of the capture channel.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 138 ? 2007-2011 microchip technology inc. 13.1 input capture resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 13.1.1 key resources ? section 12. ?input capture? (ds70198) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 139 pic24hj32gp202/204 and pic24hj16gp304 13.2 input capture registers register 13-1: icxcon: inpu t capture x control register u-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ? ?icsidl ? ? ? ? ? bit 15 bit 8 r/w-0 r/w-0 r/w-0 r-0, hc r-0, hc r/w-0 r/w-0 r/w-0 ictmr ici<1:0> icov icbne icm<2:0> bit 7 bit 0 legend: hc = cleared in hardware r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-14 unimplemented: read as ? 0 ? bit 13 icsidl: input capture module stop in idle control bit 1 = input capture module will halt in cpu idle mode 0 = input capture module will continue to operate in cpu idle mode bit 12-8 unimplemented: read as ? 0 ? bit 7 ictmr: input capture timer select bits 1 = tmr2 contents are captured on capture event 0 = tmr3 contents are captured on capture event bit 6-5 ici<1:0>: select number of captures per interrupt bits 11 = interrupt on every fourth capture event 10 = interrupt on every third capture event 01 = interrupt on every second capture event 00 = interrupt on every capture event bit 4 icov: input capture overflow status flag bit (read-only) 1 = input capture overflow occurred 0 = no input capture overflow occurred bit 3 icbne: input capture buffer empty status bit (read-only) 1 = input capture buffer is not empty, at least one more capture value can be read 0 = input capture buffer is empty bit 2-0 icm<2:0>: input capture mode select bits 111 = input capture functions as interrupt pin only when device is in sleep or idle mode (rising edge detect only, all other control bits are not applicable.) 110 = unused (module disabled) 101 = capture mode, every 16th rising edge 100 = capture mode, every 4th rising edge 011 = capture mode, every rising edge 010 = capture mode, every falling edge 001 = capture mode, every edge (rising and falling) (ici<1:0> bits do not control inte rrupt generation for this mode.) 000 = input capture module turned off
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 140 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 141 pic24hj32gp202/204 and pic24hj16gp304 14.0 output compare the output compare module can select either timer2 or timer3 for its time ba se. the module compares the value of the timer with the value of one or two compare registers depending on the operating mode selected. the state of the output pi n changes when the timer value matches the compare register value. the output compare module generates either a single output pulse or a sequence of output pulses, by changing the state of the output pin on the compare match events. the output compare module can also generate interrupts on compare match events. the output compare module has multiple operating modes: ? active-low one-shot mode ? active-high one-shot mode ? toggle mode ? delayed one-shot mode ? continuous pulse mode ? pwm mode without fault protection ? pwm mode with fault protection figure 14-1: output compare module block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 13. output compare? (ds70209) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. ocxr comparator output logic ocm<2:0> ocx set flag bit ocxif ocxrs mode select 3 0 1 octsel 0 1 16 16 ocfa tmr2 tmr2 q s r tmr3 tmr3 rollover rollover output logic output enable enable
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 142 ? 2007-2011 microchip technology inc. 14.1 output compare modes configure the output compare modes by setting the appropriate output compare mode bits (ocm<2:0>) in the output compare contro l register (ocxcon<2:0>). table 14-1 lists the different bit settings for the output compare modes. figure 14-2 illustrates the output compare operation for various modes. the user application must disable the associated timer when writing to the output compare control registers to avoid malfunctions. table 14-1: output compare modes figure 14-2: output compare operation note: see section 13. ?output compare? (ds70209) in the ?dspic33f/pic24h family reference manual? for ocxr and ocxrs register restrictions. ocm<2:0> mode ocx pin initial state ocx interrupt generation 000 module disabled controlled by gpio register ? 001 active-low one-shot 0 ocx rising edge 010 active-high one-shot 1 ocx falling edge 011 toggle mode current output is maintained ocx rising and falling edge 100 delayed one-shot 0 ocx falling edge 101 continuous pulse mode 0 ocx falling edge 110 pwm mode without fault protection 0 , if ocxr is zero 1 , if ocxr is non-zero no interrupt 111 pwm mode with fault protection 0 , if ocxr is zero 1 , if ocxr is non-zero ocfa falling edge for oc1 to oc4 ocxrs tmry ocxr timer is reset on period match continuous pulse mode (ocm = 101 ) pwm mode (ocm = 110 or 111 ) active-low one-shot (ocm = 001 ) active-high one-shot (ocm = 010 ) toggle mode (ocm = 011 ) delayed one-shot (ocm = 100 ) output compare mode enabled
? 2007-2011 microchip technology inc. ds70289j-page 143 pic24hj32gp202/204 and pic24hj16gp304 14.2 output compare resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 14.2.1 key resources ? section 13. ?output compare? (ds70209) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 144 ? 2007-2011 microchip technology inc. 14.3 output compare register register 14-1: ocxcon: output compare x control register u-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 ? ?ocsidl ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 r-0 hc r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? ocflt octsel ocm<2:0> bit 7 bit 0 legend: hc = cleared in hardware hs = set in hardware r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-14 unimplemented: read as ? 0 ? bit 13 ocsidl: stop output compare in idle mode control bit 1 = output compare x will halt in cpu idle mode 0 = output compare x will continue to operate in cpu idle mode bit 12-5 unimplemented: read as ? 0 ? bit 4 ocflt: pwm fault condition status bit 1 = pwm fault condition has occurred (cleared in hardware only) 0 = no pwm fault condition has occurred (this bit is only used when ocm<2:0> = 111 .) bit 3 octsel: output compare timer select bit 1 = timer3 is the clock source for compare x 0 = timer2 is the clock source for compare x bit 2-0 ocm<2:0>: output compare mode select bits 111 = pwm mode on ocx, fault pin enabled 110 = pwm mode on ocx, fault pin disabled 101 = initialize ocx pin low, generate continuous output pulses on ocx pin 100 = initialize ocx pin low, generate single output pulse on ocx pin 011 = compare event toggles ocx pin 010 = initialize ocx pin high, compare event forces ocx pin low 001 = initialize ocx pin low, compare event forces ocx pin high 000 = output compare channel is disabled
? 2007-2011 microchip technology inc. ds70289j-page 145 pic24hj32gp202/204 and pic24hj16gp304 15.0 serial peripheral interface (spi) the serial peripheral inte rface (spi) module is a synchronous serial interface useful for communicating with other peripheral or microcontroller devices. these peripheral devices can be serial eeproms, shift registers, display drivers, analog-to-digital converters (adcs), and so on. the spi module is compatible with motorola ? spi and siop. each spi module consists of a 16-bit shift register, spixsr (where x = 1 or 2), used for shifting data in and out, and a buffer register, sp ixbuf. a control register, spixcon, configures the module. additionally, a status register, spixstat, indi cates status conditions. the serial interface consis ts of these four pins: ? sdix (serial data input) ? sdox (serial data output) ? sckx (shift clock input or output) ? ssx (active-low slave select) in master mode operation, sck is a clock output. in slave mode, it is a clock input. figure 15-1: spi module block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 18. serial peripheral interface (spi)? (ds70206) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. internal data bus sdix sdox ssx sckx spixsr bit 0 shift control edge select f cy primary 1:1/4/16/64 enable prescaler sync spixbuf control transfer transfer write spixbuf read spixbuf 16 spixcon1<1:0> spixcon1<4:2> master clock clock control secondary prescaler 1:1 to 1:8 spixrxb spixtxb
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 146 ? 2007-2011 microchip technology inc. 15.1 spi helpful tips 1. in frame mode, if there is a possibility that the master may not be initialized before the slave: a) if frmpol (spixcon2<13>) = 1 , use a pull-down resistor on ssx . b) if frmpol = 0 , use a pull-up resistor on ssx . 2. in non-framed 3-wire mode, (i.e., not using ssx from a master): a) if ckp (spixcon1<6>) = 1 , always place a pull-up resistor on ssx . b) if ckp = 0 , always place a pull-down resistor on ssx . 3. frmen (spixcon2<15>) = 1 and ssen (spixcon1<7>) = 1 are exclusive and invalid. in frame mode, sckx is continuous and the frame sync pulse is active on the ssx pin, which indicates the start of a data frame. 4. in master mode only, set the smp bit (spixcon1<9>) to a ? 1 ? for the fastest spi data rate possible. the smp bit can only be set at the same time or after the msten bit (spixcon1<5>) is set. 5. to avoid invalid slave read data to the master, the user?s master software must guarantee enough time for slave software to fill its write buf- fer before the user application initiates a master write/read cycle. it is always advisable to pre- load the spixbuf transmit register in advance of the next master transaction cycle. spixbuf is transferred to the spi shift register and is empty once the data transmission begins. 15.2 spi resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 15.2.1 key resources ? section 18. ?serial peripheral interface (spi)? (ds70206) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: this insures that the first frame transmission after initialization is not shifted or corrupted. note: this will insure that during power-up and initialization the master/slave will not lose sync due to an errant sck transition that would cause the slave to accumulate data shift errors for both transmit and receive appearing as corrupted data. note: not all third-party devices support frame mode timing. refer to the spi electrical characteristics for details. note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 147 pic24hj32gp202/204 and pic24hj16gp304 15.3 spi control registers register 15-1: spixstat: spix status and control register r/w-0 u-0 r/w-0 u-0 u-0 u-0 u-0 u-0 spien ? spisidl ? ? ? ? ? bit 15 bit 8 u-0 r/c-0 u-0 u-0 u-0 u-0 r-0 r-0 ? spirov ? ? ? ? spitbf spirbf bit 7 bit 0 legend: c = clearable bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 spien: spix enable bit 1 = enables module and configures sckx, sdox, sdix and ssx as serial port pins 0 = disables module bit 14 unimplemented: read as ? 0 ? bit 13 spisidl: stop in idle mode bit 1 = discontinue module operation when device enters idle mode 0 = continue module operation in idle mode bit 12-7 unimplemented: read as ? 0 ? bit 6 spirov: receive overflow flag bit 1 = a new byte/word is completely received and discarded. the user software has not read the previous data in the spixbuf register 0 = no overflow has occurred. bit 5-2 unimplemented: read as ? 0 ? bit 1 spitbf: spix transmit buffer full status bit 1 = transmit not yet started, spixtxb is full 0 = transmit started, spixtxb is empty automatically set in hardware when cpu writes spixbuf location, loading spixtxb. automatically cleared in hardware when spix modu le transfers data from spixtxb to spixsr. bit 0 spirbf: spix receive buffer full status bit 1 = receive complete, spixrxb is full 0 = receive is not comp lete, spixrxb is empty automatically set in hardware when spix transfers data from spixsr to spixrxb. automatically cleared in hardware when core reads spixbuf location, reading spixrxb.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 148 ? 2007-2011 microchip technology inc. register 15-2: spi x con1: spix control register 1 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? dissck dissdo mode16 smp cke (1) bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ssen (2) ckp msten spre<2:0> (3) ppre<1:0> (3) bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12 dissck: disable sckx pin bit (spi master modes only) 1 = internal spi clock is disabled, pin functions as i/o 0 = internal spi clock is enabled bit 11 dissdo: disable sdox pin bit 1 = sdox pin is not used by module; pin functions as i/o 0 = sdox pin is controlled by the module bit 10 mode16: word/byte communication select bit 1 = communication is word-wide (16 bits) 0 = communication is byte-wide (8 bits) bit 9 smp: spix data input sample phase bit master mode: 1 = input data sampled at end of data output time 0 = input data sampled at middle of data output time slave mode: smp must be cleared when spix is used in slave mode. bit 8 cke: spix clock edge select bit (1) 1 = serial output data changes on transition from active clock state to idle clock state (see bit 6) 0 = serial output data changes on transition from idle clock state to active clock state (see bit 6) bit 7 ssen: slave select enable bit (slave mode) (2) 1 = ssx pin used for slave mode 0 = ssx pin not used by module. pin controlled by port function bit 6 ckp: clock polarity select bit 1 = idle state for clock is a high le vel; active state is a low level 0 = idle state for clock is a low le vel; active state is a high level bit 5 msten: master mode enable bit 1 = master mode 0 = slave mode note 1: the cke bit is not used in the framed spi modes. program this bit to ? 0 ? for the framed spi modes (frmen = 1 ). 2: this bit must be cleared when frmen = 1 . 3: do not set both primary and secondary prescalers to a value of 1:1.
? 2007-2011 microchip technology inc. ds70289j-page 149 pic24hj32gp202/204 and pic24hj16gp304 bit 4-2 spre<2:0>: secondary prescale bits (master mode) (3) 111 = secondary prescale 1:1 110 = secondary prescale 2:1 ? ? ? 000 = secondary prescale 8:1 bit 1-0 ppre<1:0>: primary prescale bits (master mode) (3) 11 = primary prescale 1:1 10 = primary prescale 4:1 01 = primary prescale 16:1 00 = primary prescale 64:1 register 15-2: spi x con1: spix control register 1 (continued) note 1: the cke bit is not used in the framed spi modes. program this bit to ? 0 ? for the framed spi modes (frmen = 1 ). 2: this bit must be cleared when frmen = 1 . 3: do not set both primary and secondary prescalers to a value of 1:1.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 150 ? 2007-2011 microchip technology inc. register 15-3: spixcon2: spix control register 2 r/w-0 r/w-0 r/w-0 u-0 u-0 u-0 u-0 u-0 frmen spifsd frmpol ? ? ? ? ? bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 u-0 ? ? ? ? ? ? frmdly ? bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 frmen: framed spix support bit 1 = framed spix support enabled (ssx pin used as frame sync pulse input/output) 0 = framed spix support disabled bit 14 spifsd: frame sync pulse direction control bit 1 = frame sync pulse input (slave) 0 = frame sync pulse output (master) bit 13 frmpol: frame sync pulse polarity bit 1 = frame sync pulse is active-high 0 = frame sync pulse is active-low bit 12-2 unimplemented: read as ? 0 ? bit 1 frmdly: frame sync pulse edge select bit 1 = frame sync pulse coincides with first bit clock 0 = frame sync pulse precedes first bit clock bit 0 unimplemented: this bit must not be set to ? 1 ? by the user application
? 2007-2011 microchip technology inc. ds70289j-page 151 pic24hj32gp202/204 and pic24hj16gp304 16.0 inter-integrated circuit? (i 2 c?) the inter-integrated circuit (i 2 c) module provides complete hardware support for both slave and multi-master modes of the i 2 c serial communication standard, with a 16-bit interface. the i 2 c module has a 2-pin interface: ? the sclx pin is clock ? the sdax pin is data. the i 2 c module offers the following key features: ?i 2 c interface supporting both master and slave modes of operation ?i 2 c slave mode supports 7-bit and 10-bit addressing ?i 2 c master mode supports 7-bit and 10-bit addressing ?i 2 c port allows bidirectional transfers between master and slaves ? serial clock synch ronization for i 2 c port can be used as a handshake mechanism to suspend and resume serial trans fer (sclrel control) ?i 2 c supports multi-master operation, detects bus collision and arbitrates accordingly 16.1 operating modes the hardware fully implements all the master and slave functions of the i 2 c standard and fast mode specifications, as well as 7 and 10-bit addressing. the i 2 c module can operate either as a slave or a master on an i 2 c bus. the following types of i 2 c operation are supported: ?i 2 c slave operation with 7-bit addressing ?i 2 c slave operation with 10-bit addressing ?i 2 c master operation with 7- bit or 10-bit addressing for details about the communication sequence in each of these modes, refer to the ?dspic33f/pic24h family reference manual? . note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 19. inter-integrated circuit? (i 2 c?)? (ds70195) of the ?dspic33fj/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 152 ? 2007-2011 microchip technology inc. figure 16-1: i 2 c? block diagram ( x = 1) internal data bus sclx sdax shift match detect i2cxadd start and stop bit detect clock address match clock stretching i2cxtrn lsb shift clock brg down counter reload control t cy /2 start and stop bit generation acknowledge generation collision detect i2cxcon i2cxstat control logic read lsb write read i2cxbrg i2cxrsr write read write read write read write read write read i2cxmsk i2cxrcv
? 2007-2011 microchip technology inc. ds70289j-page 153 pic24hj32gp202/204 and pic24hj16gp304 16.2 i 2 c resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 16.2.1 key resources ? section 13. ?inter-integrated circuit? (i2c?)? (ds70195) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools 16.3 i 2 c registers i2cxcon and i2cxstat are control and status registers, respectively. the i2cxcon register is readable and writable. the lower six bits of i2cxstat are read-only. the remaining bits of the i2cstat are read/write. ? i2cxrsr is the shift register used for shifting data ? i2cxrcv is the receive buffer and the register to which data bytes are written, or from which data bytes are read ? i2cxtrn is the transmit register to which bytes are written during a transmit operation ? the i2cxadd register holds the slave address ? a status bit, add10, indicates 10-bit address mode ? i2cxbrg acts as the baud rate generator (brg) reload value in receive operations, i2cxrsr and i2cxrcv together form a double-buffered receiver. when i2cxrsr receives a complete byte, it is transferred to i2cxrcv, and an interrupt pulse is generated. note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 154 ? 2007-2011 microchip technology inc. register 16-1: i2cxcon: i2cx control register r/w-0 u-0 r/w-0 r/w-1 hc r/w-0 r/w-0 r/w-0 r/w-0 i2cen ? i2csidl sclrel ipmien a10m disslw smen bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 hc r/w-0 hc r/w-0 hc r/w-0 hc r/w-0 hc gcen stren ackdt acken rcen pen rsen sen bit 7 bit 0 legend: u = unimplemented bit, read as ?0? r = readable bit w = writable bit hs = set in hardware hc = cleared in hardware -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 i2cen: i2cx enable bit 1 = enables the i2cx module and configures the sdax and sclx pins as serial port pins 0 = disables the i2cx module. all i 2 c pins are controlled by port functions bit 14 unimplemented: read as ? 0 ? bit 13 i2csidl: stop in idle mode bit 1 = discontinue module operation when device enters an idle mode 0 = continue module operation in idle mode bit 12 sclrel: sclx release control bit (when operating as i 2 c slave) 1 = release sclx clock 0 = hold sclx clock low (clock stretch) if stren = 1 : bit is r/w (i.e., software can write ? 0 ? to initiate stretch and write ? 1 ? to release clock). hardware clear at beginning of slave transmission. hard ware clear at end of slave reception. if stren = 0 : bit is r/s (i.e., software can only write ? 1 ? to release clock). hardware clear at beginning of slave transmission. bit 11 ipmien: intelligent peripheral management interface (ipmi) enable bit 1 = ipmi mode is enabled; all addresses acknowledged 0 = ipmi mode disabled bit 10 a10m: 10-bit slave address bit 1 = i2cxadd is a 10-bit slave address 0 = i2cxadd is a 7-bit slave address bit 9 disslw: disable slew rate control bit 1 = slew rate control disabled 0 = slew rate control enabled bit 8 smen: smbus input levels bit 1 = enable i/o pin thresholds co mpliant with smbus specification 0 = disable smbus input thresholds bit 7 gcen: general call enable bit (when operating as i 2 c slave) 1 = enable interrupt when a general call address is received in the i2cxrsr (module is enabled for reception) 0 = general call address disabled bit 6 stren: sclx clock stretch enable bit (when operating as i 2 c slave) used in conjunction with sclrel bit. 1 = enable software or receive clock stretching 0 = disable software or receive clock stretching
? 2007-2011 microchip technology inc. ds70289j-page 155 pic24hj32gp202/204 and pic24hj16gp304 bit 5 ackdt: acknowledge data bit (when operating as i 2 c master, applicable during master receive) value that will be transmitted when the software initiates an acknowledge sequence. 1 = send nack during acknowledge 0 = send ack during acknowledge bit 4 acken: acknowledge sequence enable bit (when operating as i 2 c master, applicable during master receive) 1 = initiate acknowledge sequence on sdax and sclx pins and transmit ackdt data bit. hardware clear at end of master acknowledge sequence 0 = acknowledge sequence not in progress bit 3 rcen: receive enable bit (when operating as i 2 c master) 1 = enables receive mode for i 2 c. hardware clear at end of eighth bit of master receive data byte 0 = receive sequence not in progress bit 2 pen: stop condition enable bit (when operating as i 2 c master) 1 = initiate stop condition on sdax and sclx pins. hardware clear at end of master stop sequence 0 = stop condition not in progress bit 1 rsen: repeated start condition enable bit (when operating as i 2 c master) 1 = initiate repeated start condition on sdax and sclx pins. hardware clear at end of master repeated start sequence 0 = repeated start condition not in progress bit 0 sen: start condition enable bit (when operating as i 2 c master) 1 = initiate start condition on sdax and sclx pins. hardware clear at end of master start sequence 0 = start condition not in progress register 16-1: i2cxcon: i2cx control register (continued)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 156 ? 2007-2011 microchip technology inc. register 16-2: i2cxstat: i2cx status register r-0 hsc r-0 hsc u-0 u-0 u-0 r/c-0 hs r-0 hsc r-0 hsc ackstat trstat ? ? ? bcl gcstat add10 bit 15 bit 8 r/c-0 hs r/c-0 hs r-0 hsc r/c-0 hsc r/c-0 hsc r-0 hsc r-0 hsc r-0 hsc iwcol i2cov d_a p s r_w rbf tbf bit 7 bit 0 legend: u = unimplemented bit, read as ?0? r = readable bit w = writable bit hs = set in hardware hsc = hardware set/cleared -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ackstat: acknowledge status bit (when operating as i 2 c master, applicable to master transmit operation) 1 = nack received from slave 0 = ack received from slave hardware set or clear at end of slave acknowledge. bit 14 trstat: transmit status bit (when operating as i 2 c master, applicable to master transmit operation) 1 = master transmit is in progress (8 bits + ack) 0 = master transmit is not in progress hardware set at beginning of master transmission . hardware clear at end of slave acknowledge. bit 13-11 unimplemented: read as ? 0 ? bit 10 bcl: master bus collision detect bit 1 = a bus collision has been detec ted during a master operation 0 = no collision hardware set at detection of bus collision. bit 9 gcstat: general call status bit 1 = general call address was received 0 = general call address was not received hardware set when address matches general call address. hardware clear at stop detection. bit 8 add10: 10-bit address status bit 1 = 10-bit address was matched 0 = 10-bit address was not matched hardware set at match of 2nd byte of matched 10 -bit address. hardware clear at stop detection. bit 7 iwcol: write collision detect bit 1 = an attempt to write the i2cx trn register failed because the i 2 c module is busy 0 = no collision hardware set at occurrence of write to i2cxtrn while busy (cleared by software). bit 6 i2cov: receive overflow flag bit 1 = a byte was received while the i2cxrcv re gister is still holding the previous byte 0 = no overflow hardware set at attempt to transfer i2cxrsr to i2cxrcv (cleared by software). bit 5 d_a: data/address bit (when operating as i 2 c slave) 1 = indicates that the last byte received was data 0 = indicates that the last byte received was device address hardware clear at device address match. hardware set by reception of slave byte. bit 4 p: stop bit 1 = indicates that a stop bit has been detected last 0 = stop bit was not detected last hardware set or clear when start, repeated start or stop detected.
? 2007-2011 microchip technology inc. ds70289j-page 157 pic24hj32gp202/204 and pic24hj16gp304 bit 3 s: start bit 1 = indicates that a start (or repeated start) bit has been detected last 0 = start bit was not detected last hardware set or clear when start, repeated start or stop detected. bit 2 r_w: read/write information bit (when operating as i 2 c slave) 1 = read ? indicates data transfer is output from slave 0 = write ? indicates data transfer is input to slave hardware set or clear after reception of i 2 c device address byte. bit 1 rbf: receive buffer full status bit 1 = receive complete, i2cxrcv is full 0 = receive not complete, i2cxrcv is empty hardware set when i2cxrcv is written with received byte. hardware clear when software reads i2cxrcv. bit 0 tbf: transmit buffer full status bit 1 = transmit in progress, i2cxtrn is full 0 = transmit complete, i2cxtrn is empty hardware set when software writes i2cxtrn. hard ware clear at completion of data transmission. register 16-2: i2cxstat: i2cx status register (continued)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 158 ? 2007-2011 microchip technology inc. register 16-3: i2cxmsk: i2cx sl ave mode address mask register u-0 u-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 ? ? ? ? ? ? amsk9 amsk8 bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 amsk7 amsk6 amsk5 amsk4 amsk3 amsk2 amsk1 amsk0 bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-10 unimplemented: read as ? 0 ? bit 9-0 amskx: mask for address bit x select bit 1 = enable masking for bit x of incoming message address; bit match not requ ired in this position 0 = disable masking for bit x; bit match required in this position
? 2007-2011 microchip technology inc. ds70289j-page 159 pic24hj32gp202/204 and pic24hj16gp304 17.0 universal asynchronous receiver transmitter (uart) the universal asynchronous receiver transmitter (uart) module is one of the serial i/o modules available in the pic24hj32gp202/204 and pic24hj16gp304 device family. the uart is a full-duplex asynchronous system that can communicate with peripheral devices, such as personal computers, lin, rs-232 and rs-485 interfaces. the module also supports a hardware flow control option with the uxcts and uxrts pins and also includes an irda ? encoder and decoder. the primary features of the uart module are: ? full-duplex 8-bit or 9-bit data transmission through the uxtx and uxrx pins ? even, odd or no parity options (for 8-bit data) ? one or two stop bits ? hardware flow control option with uxcts and uxrts pins ? fully integrated baud rate generator wi th 16-bit prescaler ? baud rates ranging from 10 mbps to 38 bps at 40 mips ? 4-deep first-in-first-out (f ifo) transmit data buffer ? 4-deep fifo receive data buffer ? parity, framing and buffer overrun error detection ? support for 9-bit mode with address detect (9th bit = 1 ) ? transmit and receive interrupts ? a separate interrupt for all uart error conditions ? loopback mode for diagnostic support ? support for sync and break characters ? support for automatic baud rate detection ?irda ? encoder and decoder logic ? 16x baud clock output for irda ? support a simplified block diagram of the uart module is shown in figure 17-1 . the uart module consists of the following key hardware elements: ? baud rate generator ? asynchronous transmitter ? asynchronous receiver figure 17-1: uart simplified block diagram note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to complement the information in this data sheet, refer to ?section 17. uart? (ds70188) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. uxrx hardware flow control uart receiver uart transmitter uxtx bclk baud rate generator uxrts irda ? uxcts
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 160 ? 2007-2011 microchip technology inc. 17.1 uart helpful tips 1. in multi-node direct-connect uart networks, uart receive inputs react to the complementary logic level defined by the urxinv bit (uxmode<4>), which defines the idle state, the default of which is logic high, (i.e., urxinv = 0 ). because remote devices do not initialize at the same time , it is likely that one of the devices, because the rx line is floating, will trigger a start bit detection and will cause the first byte received after the device has been ini- tialized to be invalid. to avoid this situation, the user should use a pull-up or pull-down resistor on the rx pin depending on the value of the urxinv bit. a) if urxinv = 0 , use a pull-up resistor on the rx pin. b) if urxinv = 1 , use a pull-down resistor on the rx pin. 2. the first character received on a wake-up from sleep mode caused by activity on the uxrx pin of the uart module will be invalid. in sleep mode, peripheral clocks are disabled. by the time the oscillator system has restarted and stabilized from sleep mode, the baud rate bit sampling clock relative to the incoming uxrx bit timing is no longer synchronized, resulting in the first character being invalid. this is to be expected. 17.2 uart resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 17.2.1 key resources ? section 17. ?uart? (ds70188) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 161 pic24hj32gp202/204 and pic24hj16gp304 17.3 uart control registers register 17-1: uxmode: uart x mode register r/w-0 u-0 r/w-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 uarten (1) ? usidl iren (2) rtsmd ?uen<1:0> bit 15 bit 8 r/w-0 hc r/w-0 r/w-0, hc r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 wake lpback abaud urxinv brgh pdsel<1:0> stsel bit 7 bit 0 legend: hc = hardware clearable r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 uarten: uartx enable bit (1) 1 = uartx is enabled; all uartx pins are controlled by uartx as defined by uen<1:0> 0 = uartx is disabled; all uartx pins are controll ed by port latches; uartx power consumption minimal bit 14 unimplemented: read as ? 0 ? bit 13 usidl: stop in idle mode bit 1 = discontinue module operation when device enters idle mode 0 = continue module operation in idle mode bit 12 iren: irda ? encoder and decoder enable bit (2) 1 =irda ? encoder and decoder enabled 0 =irda ? encoder and decoder disabled bit 11 rtsmd: mode selection for uxrts pin bit 1 =uxrts pin in simplex mode 0 =uxrts pin in flow control mode bit 10 unimplemented: read as ? 0 ? bit 9-8 uen<1:0>: uartx enable bits 11 = uxtx, uxrx and bclk pins are enabled and used; uxcts pin controlled by port latches 10 = uxtx, uxrx, uxcts and uxrts pins are enabled and used 01 = uxtx, uxrx and uxrts pins are enabled and used; uxcts pin controlled by port latches 00 = uxtx and uxrx pins are enabled and used; uxcts and uxrts /bclk pins controlled by port latches bit 7 wake: wake-up on start bit detect during sleep mode enable bit 1 = uartx will continue to sample the uxrx pin; interrupt generated on falling edge; bit cleared in hardware on following rising edge 0 = no wake-up enabled bit 6 lpback: uartx loopback mode select bit 1 = enable loopback mode 0 = loopback mode is disabled bit 5 abaud: auto-baud enable bit 1 = enable baud rate measurement on the next character ? requires reception of a sync field (55h) before other data; cleared in hardware upon completion 0 = baud rate measurement disabled or completed note 1: refer to section 17. ?uart? (ds70188) in the ?dspic33f/pic24h family reference manual? for information on enabling the uart module for receive or transmit operation. 2: this feature is only available for the 16x brg mode (brgh = 0 ).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 162 ? 2007-2011 microchip technology inc. bit 4 urxinv: receive polarity inversion bit 1 = uxrx idle state is ? 0 ? 0 = uxrx idle state is ? 1 ? bit 3 brgh: high baud rate enable bit 1 = brg generates 4 clocks per bit period (4x baud clock, high-speed mode) 0 = brg generates 16 clocks per bit period (16x baud clock, standard mode) bit 2-1 pdsel<1:0>: parity and data selection bits 11 = 9-bit data, no parity 10 = 8-bit data, odd parity 01 = 8-bit data, even parity 00 = 8-bit data, no parity bit 0 stsel: stop bit selection bit 1 = two stop bits 0 = one stop bit register 17-1: uxmode: uart x mode register (continued) note 1: refer to section 17. ?uart? (ds70188) in the ?dspic33f/pic24h family reference manual? for information on enabling the uart module for receive or transmit operation. 2: this feature is only available for the 16x brg mode (brgh = 0 ).
? 2007-2011 microchip technology inc. ds70289j-page 163 pic24hj32gp202/204 and pic24hj16gp304 register 17-2: u x sta: uart x status and control register r/w-0 r/w-0 r/w-0 u-0 r/w-0 hc r/w-0 r-0 r-1 utxisel1 utxinv utxisel0 ? utxbrk utxen (1) utxbf trmt bit 15 bit 8 r/w-0 r/w-0 r/w-0 r-1 r-0 r-0 r/c-0 r-0 urxisel<1:0> adden ridle perr ferr oerr urxda bit 7 bit 0 legend: hc = hardware cleared c = clear only bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15,13 utxisel<1:0>: transmission interrupt mode selection bits 11 = reserved; do not use 10 = interrupt when a character is transferred to the transmit shift register, and as a result, the transmit buffer becomes empty 01 = interrupt when the last character is shifted ou t of the transmit shift register; all transmit operations are completed 00 = interrupt when a character is transferred to t he transmit shift register (this implies there is at least one character open in the transmit buffer) bit 14 utxinv: transmit polarity inversion bit if iren = 0 : 1 = uxtx idle state is ? 0 ? 0 = uxtx idle state is ? 1 ? if iren = 1 : 1 =irda ? encoded uxtx idle state is ? 1 ? 0 =irda ? encoded uxtx idle state is ? 0 ? bit 12 unimplemented: read as ? 0 ? bit 11 utxbrk: transmit break bit 1 = send sync break on next transmission ? start bit, followed by twelve ? 0 ? bits, followed by stop bit; cleared by hardware upon completion 0 = sync break transmission disabled or completed bit 10 utxen: transmit enable bit (1) 1 = transmit enabled, uxtx pin controlled by uartx 0 = transmit disabled, any pending transmission is abo rted and buffer is reset. uxtx pin controlled by port bit 9 utxbf: transmit buffer full status bit (read-only) 1 = transmit buffer is full 0 = transmit buffer is not full, at least one more character can be written bit 8 trmt: transmit shift register empty bit (read-only) 1 = transmit shift register is em pty and transmit buffer is empty (the last transmission has completed) 0 = transmit shift register is not empty, a transmission is in progress or queued bit 7-6 urxisel<1:0>: receive interrupt mode selection bits 11 = interrupt is set on uxrsr transfer making the receive buffer full (i.e., has 4 data characters) 10 = interrupt is set on uxrsr transfer making the re ceive buffer 3/4 full (i.e., has 3 data characters) 0x = interrupt is set when any character is receiv ed and transferred from the uxrsr to the receive buffer. receive buffer has one or more characters note 1: refer to section 17. ?uart? (ds70188) in the ?dspic33f/pic24h family reference manual? for information on enabling the uart module for transmit operation.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 164 ? 2007-2011 microchip technology inc. bit 5 adden: address character detect bit (bit 8 of received data = 1 ) 1 = address detect mode enabled. if 9-bit mode is not selected, this does not take effect 0 = address detect mode disabled bit 4 ridle: receiver idle bit (read-only) 1 = receiver is idle 0 = receiver is active bit 3 perr: parity error status bit (read-only) 1 = parity error has been detected for the current ch aracter (character at the top of the receive fifo) 0 = parity error has not been detected bit 2 ferr: framing error status bit (read-only) 1 = framing error has been detected for the current character (character at the top of the receive fifo) 0 = framing error has not been detected bit 1 oerr: receive buffer overrun error status bit (read/clear only) 1 = receive buffer has overflowed 0 = receive buffer has not overflowed. clearing a previously set oerr bit ( 1 0 transition) will reset the receiver buffer and th e uxrsr to the empty state bit 0 urxda: receive buffer data available bit (read-only) 1 = receive buffer has data, at least one more character can be read 0 = receive buffer is empty register 17-2: u x sta: uart x status and control register (continued) note 1: refer to section 17. ?uart? (ds70188) in the ?dspic33f/pic24h family reference manual? for information on enabling the uart module for transmit operation.
? 2007-2011 microchip technology inc. ds70289j-page 165 pic24hj32gp202/204 and pic24hj16gp304 18.0 10-bit/12-bit analog-to-digital converter (adc) the pic24hj32gp202/204 and pic24hj16gp304 devices have up to 13 analog-to-digital conversion (adc) module input channels. the ad12b bit (ad1con1<10>) allows each of the adc modules to be config ured as either a 10-bit, 4-sample-and-hold adc (def ault configuration), or a 12-bit, 1- sample and hold adc. 18.1 key features the 10-bit adc configuration has the following key features: ? successive approximation (sar) conversion ? conversion speeds of up to 1.1 msps ? up to 13 analog input pins ? external voltage reference input pins ? simultaneous sampling of up to four analog input pins ? automatic channel scan mode ? selectable conversion trigger source ? selectable buffer fill modes ? operation during cpu sleep and idle modes ? 16-word conversion result buffer the 12-bit adc configurat ion supports all the above features, except: ? in the 12-bit configurati on, conversion speeds of up to 500 ksps are supported ? there is only 1 sample-and-hold amplifier in the 12-bit configuration, so simultaneous sampling of multiple channels is not supported depending on the particular device pinout, the adc can have up to 13 analog input pins, designated an0 through an12. in addition, there are two analog input pins for external voltage reference connections. these voltage reference inputs can be shared with other analog input pins. the actual number of analog input pins and external voltage reference input configuration will depend on the specific device. refer to the device data sheet for further details. a block diagram of adc for pic24hj16gp304 and PIC24HJ32GP204 devices is shown in figure 18-1 . a block diagram of the adc for the pic24hj32gp202 device is shown in figure 18-2 . 18.2 adc initialization to configure the adc module: 1. select port pins as analog inputs (ad1pcfgh<15:0> or ad1pcfgl<15:0>). 2. select voltage reference source to match expected range on analog inputs (ad1con2<15:13>). 3. select the analog conversion clock to match desired data rate with processor clock (ad1con3<7:0>). 4. determine how many sample-and-hold channels will be used (ad1con2<9:8> and ad1pcfgh<15:0> or ad1pcfgl<15:0>). 5. select the appropriate sample/conversion sequence (ad1con1<7:5> and ad1con3<12:8>). 6. select the way conversion results are presented in the buffer (ad1con1<9:8>). 7. turn on the adc module (ad1con1<15>). 8. configure adc interrupt (if required): a) clear the ad1if bit. b) select adc interrupt priority. note 1: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 family of devices. however, it is not intended to be a com- prehensive reference source. to comple- ment the information in this data sheet, refer to ?section 16. analog-to-digital converter (adc)? (ds70183) of the ?dspic33f/pic24h family reference manual? , which is available from the microchip website ( www.microchip.com ). 2: some registers and associated bits described in this section may not be available on all devices. refer to section 4.0 ?memory organization? in this data sheet for de vice-specific register and bit information. note: the adc module must be disabled before the ad12b bit can be modified.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 166 ? 2007-2011 microchip technology inc. figure 18-1: adc1 module block di agram for pic24hfj16gp304 and PIC24HJ32GP204 devices sar adc s/h0 s/h1 adc1buf0 adc1buf1 adc1buf2 adc1buff adc1bufe an0 an12 an1 v refl ch0sb<4:0> ch0na ch0nb + - an0 an3 ch123sa an9 v refl ch123sb ch123na ch123nb an6 + - s/h2 an1 an4 ch123sa an10 v refl ch123sb ch123na ch123nb an7 + - s/h3 an2 an5 ch123sa an11 v refl ch123sb ch123na ch123nb an8 + - ch1 (2) ch0 ch2 (2) ch3 (2) ch0sa<4:0> channel scan cscna alternate note 1: v ref +, v ref - inputs can be multiplexed with other analog inputs. 2: channels 1, 2 and 3 are not applicable for the 12-bit mode of operation. input selection v refh v refl av dd av ss v ref - (1) v ref + (1) vcfg<2:0>
? 2007-2011 microchip technology inc. ds70289j-page 167 pic24hj32gp202/204 and pic24hj16gp304 figure 18-2: adc1 module block diag ram for pic24hj32gp202 devices sar adc s/h0 s/h1 adc1buf0 adc1buf1 adc1buf2 adc1buff adc1bufe an0 an12 an1 v refl ch0sb<4:0> ch0na ch0nb + - an0 an3 ch123sa an9 v refl ch123sb ch123na ch123nb + - s/h2 an1 an4 ch123sa an10 v refl ch123sb ch123na ch123nb + - s/h3 an2 an5 ch123sa an11 v refl ch123sb ch123na ch123nb + - ch1 (2) ch0 ch2 (2) ch3 (2) ch0sa<4:0> channel scan cscna alternate note 1: v ref +, v ref - inputs can be multiplexed with other analog inputs. 2: channels 1, 2 and 3 are not applicable for the 12-bit mode of operation. input selection v refh v refl av dd av ss v ref - (1) v ref + (1) vcfg<2:0>
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 168 ? 2007-2011 microchip technology inc. figure 18-3: adc conversion clock period block diagram 18.3 adc helpful tips 1. the smpi<3:0> (ad1con2 <5:2>) control bits: a) determine when the adc interrupt flag is set and an interrupt is generated if enabled. b) when the cscna bit (ad1con2<10>) is set to ? 1 ?, determines when the adc analog scan channel list defined in the ad1cssl/ad1cssh registers starts over from the beginning. c) on devices without a dma peripheral, determines when adc result buffer pointer to adc1buf0-adc1buff, gets reset back to the beginning at adc1buf0. 2. on devices without a dma module, the adc has 16 result buffers. adc conversion results are stored sequentially in adc1buf0-adc1buff regardless of which analog inputs are being used subject to the smpi<3:0> bits (ad1con2<5:2>) and the condition described in 1c above. there is no relationship between the anx input being measured and which adc buffer (adc1buf0-adc1buff) that the conversion results will be placed in. 3. on devices with a dma module, the adc mod- ule has only 1 adc result buffer, (i.e., adc1buf0), per adc peripheral and the adc conversion result must be read either by the cpu or dma controller before the next adc conversion is complete to avoid overwriting the previous value. 4. the done bit (ad1con1<0>) is only cleared at the start of each conversion and is set at the completion of the conv ersion, but remains set indefinitely even through the next sample phase until the next conversion begins. if application code is monitoring the done bit in any kind of software loop, the user must consider this behavior because the cpu code execution is faster than the adc. as a result, in manual sam- ple mode, particularly where the users code is setting the samp bit (ad1con1<1>), the done bit should also be cleared by the user application just before setting the samp bit. 5. on devices with two adc modules, the adcxpcfg registers for both adc modules must be set to a logic ? 1 ? to configure a target i/o pin as a digital i/o pin. failure to do so means that any alternate digital input function will always see only a logic ? 0 ? as the digital input buffer is held in disable mode. 18.4 adc resources many useful resources are provided on the main prod- uct page of the microchip web site for the devices listed in this data sheet. this product page, which can be accessed using this link , contains the latest updates and additional information. 18.4.1 key resources ? section 16. ?analog-to-digital converter (adc)? (ds70183) ? code samples ? application notes ? software libraries ? webinars ? all related dspic33f/pic24h family reference manuals sections ? development tools 0 1 adc internal rc clock (2) t osc (1) x 2 adc conversion clock multiplier 1, 2, 3, 4, 5,..., 64 ad1con3<15> t cy t ad 6 ad1con3<5:0> note 1: refer to figure 8-2 for the derivation of f osc when the pll is enabled. if the pll is not used, f osc is equal to the clock frequency. t osc = 1/f osc . 2: see the adc electrical characteri stics for the exac t rc clock value. note: in the event you are not able to access the product page using the link above, enter this url in your browser: http://www.microchip.com/wwwproducts/ devices.aspx?ddocname=en530271
? 2007-2011 microchip technology inc. ds70289j-page 169 pic24hj32gp202/204 and pic24hj16gp304 18.5 adc control registers register 18-1: ad1con1: adc1 control register 1 r/w-0 u-0 r/w-0 u-0 u-0 r/w-0 r/w-0 r/w-0 adon ?adsidl ? ? ad12b form<1:0> bit 15 bit 8 r/w-0 r/w-0 r/w-0 u-0 r/w-0 r/w-0 r/w-0 hc,hs r/c-0 hc, hs ssrc<2:0> ? simsam asam samp done bit 7 bit 0 legend: hc = cleared by hardware hs = set by hardware c = clear only bit r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 adon: adc operating mode bit 1 = adc module is operating 0 = adc is off bit 14 unimplemented: read as ? 0 ? bit 13 adsidl: stop in idle mode bit 1 = discontinue module operation when device enters idle mode 0 = continue module operation in idle mode bit 12-11 unimplemented: read as ? 0 ? bit 10 ad12b: 10-bit or 12-bit operation mode bit 1 = 12-bit, 1-channel adc operation 0 = 10-bit, 4-channel adc operation bit 9-8 form<1:0>: data output format bits for 10-bit operation: 11 = reserved 10 = reserved 01 = signed integer (d out = ssss sssd dddd dddd , where s = .not.d<9>) 00 = integer (d out = 0000 00dd dddd dddd ) for 12-bit operation: 11 = reserved 10 = reserved 01 = signed integer (d out = ssss sddd dddd dddd , where s = .not.d<11>) 00 = integer (d out = 0000 dddd dddd dddd ) bit 7-5 ssrc<2:0>: sample clock source select bits 111 = internal counter ends sampling a nd starts conversion (auto-convert) 110 = reserved 101 = reserved 100 = reserved 011 = reserved 010 = gp timer 3 compare ends sampling and starts conversion 001 = active transition on int0 pin ends sampling and starts conversion 000 = clearing sample bit ends sampling and starts conversion bit 4 unimplemented: read as ? 0 ? bit 3 simsam: simultaneous sample select bit (applicable only when chps<1:0> = 01 or 1x ) when ad12b = 1 , simsam is: u-0, unimplemented, read as ? 0 ? 1 = samples ch0, ch1, ch2, ch3 simultaneously (when chps<1:0> = 1x ); or samples ch0 and ch1 simultaneously (when chps<1:0> = 01 ) 0 = samples multiple channels individually in sequence
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 170 ? 2007-2011 microchip technology inc. bit 2 asam: adc sample auto-start bit 1 = sampling begins immediately after last conversion. samp bit is auto-set 0 = sampling begins when samp bit is set bit 1 samp: adc sample enable bit 1 = adc sample-and-hold amplifiers are sampling 0 = adc sample-and-hold amplifiers are holding if asam = 0 , software can write ? 1 ? to begin sampling. automatically set by hardware if asam = 1 . if ssrc = 000 , software can write ? 0 ? to end sampling and start conversion. if ssrc 000 , automatically cleared by hardware to end sampling and start conversion. bit 0 done: adc conversion status bit 1 = adc conversion cycle is completed 0 = adc conversion not started or in progress automatically set by hardware when adc conversion is complete. software can write ? 0 ? to clear done status (software not allowed to write ? 1 ?). clearing this bit will not affect any operation in progress. automatically cleared by hard ware at start of a new conversion. register 18-1: ad1con1: adc1 control register 1 (continued)
? 2007-2011 microchip technology inc. ds70289j-page 171 pic24hj32gp202/204 and pic24hj16gp304 register 18-2: ad1con2: adc1 control register 2 r/w-0 r/w-0 r/w-0 u-0 u-0 r/w-0 r/w-0 r/w-0 vcfg<2:0> ? ? cscna chps<1:0> bit 15 bit 8 r-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 bufs ? smpi<3:0> bufm alts bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 vcfg<2:0>: converter voltage reference configuration bits bit 12-11 unimplemented: read as ? 0 ? bit 10 cscna: scan input selections for ch0+ during sample a bit 1 = scan inputs 0 = do not scan inputs bit 9-8 chps<1:0>: select channels utilized bits when ad12b = 1 , chps<1:0> is: u-0, unimplemented, read as ? 0 ? 1x = converts ch0, ch1, ch2 and ch3 01 = converts ch0 and ch1 00 = converts ch0 bit 7 bufs: buffer fill status bit (valid only when bufm = 1 ) 1 = adc is currently filling second half of buffer, us er application should access data in the first half 0 = adc is currently filling first half of buffer, us er application should access data in the second half bit 6 unimplemented: read as ? 0 ? bit 5-2 smpi<3:0>: sample/convert sequences per interrupt selection bits 1111 = interrupts at the completion of conversion for each 16th sample/convert sequence 1110 = interrupts at the completion of conversion for each 15th sample/convert sequence ? ? ? 0001 = interrupts at the completion of conversion for each 2nd sample/convert sequence 0000 = interrupts at the completion of conversion for each sample/convert sequence bit 1 bufm: buffer fill mode select bit 1 = starts filling first half of buffer on first interrupt and the second half of buffer on next interrupt 0 = always starts filling buffer from the beginning bit 0 alts: alternate input sample mode select bit 1 = uses channel input selects for sample a on first sample and sample b on next sample 0 = always uses channel i nput selects for sample a adref+ adref- 000 a vdd a vss 001 external v ref +a vss 010 a vdd external v ref - 011 external v ref + external v ref - 1xx a vdd avss
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 172 ? 2007-2011 microchip technology inc. register 18-3: ad1con3: adc1 control register 3 r/w-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 adrc ? ? samc<4:0> (1) bit 15 bit 8 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 adcs<7:0> (2) bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 adrc: adc conversion clock source bit 1 = adc internal rc clock 0 = clock derived from system clock bit 14-13 unimplemented: read as ? 0 ? bit 12-8 samc<4:0>: auto sample time bits (1) 11111 = 31 t ad ? ? ? 00001 = 1 t ad 00000 = 0 t ad bit 7-0 adcs<7:0>: adc conversion clock select bits (2) 11111111 = reserved ? ? ? ? 01000000 = reserved 00111111 = t cy (adcs<7:0> + 1) = 64 t cy = t ad ? ? ? 00000010 = t cy (adcs<7:0> + 1) = 3 t cy = t ad 00000001 = t cy (adcs<7:0> + 1) = 2 t cy = t ad 00000000 = t cy (adcs<7:0> + 1) = 1 t cy = t ad note 1: this bit only used if ad1con1<7:5> (ssrc<2:0>) = 111 . 2: this bit is not used if ad1con3<15> (adrc) = 1 .
? 2007-2011 microchip technology inc. ds70289j-page 173 pic24hj32gp202/204 and pic24hj16gp304 register 18-4: ad1chs123: adc1 in put channel 1, 2, 3 select register u-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 ? ? ? ? ? ch123nb<1:0> ch123sb bit 15 bit 8 u-0 u-0 u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 ? ? ? ? ? ch123na<1:0> ch123sa bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-11 unimplemented: read as ? 0 ? bit 10-9 ch123nb<1:0>: channel 1, 2, 3 negative i nput select for sample b bits pic24hj32gp202 devices only: if ad12b = 1 : 11 = reserved 10 = reserved 01 = reserved 00 = reserved if ad12b = 0 : 11 = ch1 negative input is an9, ch2 negative input is an10, ch3 negative input is an11 10 = reserved 01 = ch1, ch2, ch3 negative input is v ref - 00 = ch1, ch2, ch3 negative input is v ref - PIC24HJ32GP204 and pic24hj16gp304 devices only: if ad12b = 1 : 11 = reserved 10 = reserved 01 = reserved 00 = reserved if ad12b = 0 : 11 = ch1 negative input is an9, ch2 negative input is an10, ch3 negative input is an11 10 = ch1 negative input is an6, ch2 negative input is an7, ch3 negative input is an8 01 = ch1, ch2, ch3 negative input is v ref - 00 = ch1, ch2, ch3 negative input is v ref - bit 8 ch123sb: channel 1, 2, 3 positive input select for sample b bit if ad12b = 1 : 1 = reserved 0 = reserved if ad12b = 0 : 1 = ch1 positive input is an3, ch2 positive input is an4, ch3 positive input is an5 0 = ch1 positive input is an0, ch2 positive input is an1, ch3 positive input is an2 bit 7-3 unimplemented: read as ? 0 ?
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 174 ? 2007-2011 microchip technology inc. bit 2-1 ch123na<1:0>: channel 1, 2, 3 negative i nput select for sample a bits pic24hj32gp202 devices only: if ad12b = 1 : 11 = reserved 10 = reserved 01 = reserved 00 = reserved if ad12b = 0 : 11 = ch1 negative input is an9, ch2 negative input is an10, ch3 negative input is an11 10 = reserved 01 = ch1, ch2, ch3 negative input is v ref - 00 = ch1, ch2, ch3 negative input is v ref - PIC24HJ32GP204 and pic24hj16gp304 devices only: if ad12b = 1 : 11 = reserved 10 = reserved 01 = reserved 00 = reserved if ad12b = 0 : 11 = ch1 negative input is an9, ch2 negative input is an10, ch3 negative input is an11 10 = ch1 negative input is an6, ch2 negative input is an7, ch3 negative input is an8 01 = ch1, ch2, ch3 negative input is v ref - 00 = ch1, ch2, ch3 negative input is v ref - bit 0 ch123sa: channel 1, 2, 3 positive input select for sample a bit if ad12b = 1 : 1 = reserved 0 = reserved if ad12b = 0 : 1 = ch1 positive input is an3, ch2 positive input is an4, ch3 positive input is an5 0 = ch1 positive input is an0, ch2 positive input is an1, ch3 positive input is an2 register 18-4: ad1chs123: adc1 input channe l 1, 2, 3 select register (continued)
? 2007-2011 microchip technology inc. ds70289j-page 175 pic24hj32gp202/204 and pic24hj16gp304 register 18-5: ad1chs0: adc1 input channel 0 select register r/w-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ch0nb ? ? ch0sb<4:0> bit 15 bit 8 r/w-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ch0na ? ? ch0sa<4:0> bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15 ch0nb: channel 0 negative input select for sample b bit 1 = channel 0 negative input is an1 0 = channel 0 negative input is v ref - bit 14-13 unimplemented: read as ? 0 ? bit 12-8 ch0sb<4:0>: channel 0 positive input select for sample b bits PIC24HJ32GP204 and pic24hj16gp304 devices only: 01100 = channel 0 positive input is an12 ? ? ? 00010 = channel 0 positive input is an2 00001 = channel 0 positive input is an1 00000 = channel 0 positive input is an0 pic24hj32gp202 devices only: 01100 = channel 0 positive input is an12 ? ? ? 01000 = reserved 00111 = reserved 00110 = reserved ? ? ? 00010 = channel 0 positive input is an2 00001 = channel 0 positive input is an1 00000 = channel 0 positive input is an0 bit 7 ch0na: channel 0 negative input select for sample a bit 1 = channel 0 negative input is an1 0 = channel 0 negative input is v ref - bit 6-5 unimplemented: read as ? 0 ?
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 176 ? 2007-2011 microchip technology inc. bit 4-0 ch0sa<4:0>: channel 0 positive input select for sample a bits PIC24HJ32GP204 and pic24hj16gp304 devices only: 01100 = channel 0 positive input is an12 ? ? ? 00010 = channel 0 positive input is an2 00001 = channel 0 positive input is an1 00000 = channel 0 positive input is an0 pic24hj32gp202 devices only: 01100 = channel 0 positive input is an12 ? ? ? 01000 = reserved 00111 = reserved 00110 = reserved ? ? ? 00010 = channel 0 positive input is an2 00001 = channel 0 positive input is an1 00000 = channel 0 positive input is an0 register 18-5: ad1chs0: adc1 input channel 0 select register (continued)
? 2007-2011 microchip technology inc. ds70289j-page 177 pic24hj32gp202/204 and pic24hj16gp304 register 18-6: ad1cssl: adc1 in put scan select register low (1) u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? css12 css11 css10 css9 css8 bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 css7 css6 css5 css4 css3 css2 css1 css0 bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-0 css<12:0>: adc input scan selection bits 1 = select anx for input scan 0 = skip anx for input scan note 1: on devices without 13 analog inputs, all ad1cssl bits can be selected by the user application. however, inputs selected for scan without a corresponding input on device converts v refl . 2: cssx = anx, where x = 0 through 12. register 18-7: ad1pcfgl: adc1 po rt configuration register low (1,2,3) u-0 u-0 u-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 ? ? ? pcfg12 pcfg11 pcfg10 pcfg9 pcfg8 bit 15 bit 8 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 r/w-0 pcfg7 pcfg6 pcfg5 pcfg4 pcfg3 pcfg2 pcfg1 pcfg0 bit 7 bit 0 legend: r = readable bit w = writable bit u = unimplemented bit, read as ?0? -n = value at por ?1? = bit is set ?0? = bit is cleared x = bit is unknown bit 15-13 unimplemented: read as ? 0 ? bit 12-0 pcfg<12:0>: adc port configuration control bits 1 = port pin in digital mode, port read inpu t enabled, adc input multiplexer connected to av ss 0 = port pin in analog mode, port read input disabled, adc samples pin voltage note 1: on devices without 13 analog inputs, all pcfg bits ar e r/w by user software. however, the pcfg bits are ignored on ports without a corresponding input on device. 2: pcfgx = anx, where x = 0 through 12. 3: the pcfgx bits have no effect if the adc module is disabled by setting adxmd bit in the pmdx register. in this case, all port pins multiplexed with anx will be in digital mode.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 178 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 179 pic24hj32gp202/204 and pic24hj16gp304 19.0 special features pic24hj32gp202/204 and pic24hj16gp304 devices include several features that are intended to maximize application flexibility and reliability, and minimize cost through elimination of external components. these are: ? flexible configuration ? watchdog timer (wdt) ? code protection and codeguard? security ? jtag boundary scan interface ? in-circuit serial programming? (icsp?) ? in-circuit emulation 19.1 configuration bits pic24hj32gp202/204 and pic24hj16gp304 devices provide nonvolatile memory implementation for device configuration bits. refer to section 25. ?device configuration? (ds70194) of the ?dspic33f/pic24h family reference manual? , for more information on this implementation. the configuration bits can be programmed (read as ? 0 ?), or left unprogrammed (read as ? 1 ?), to select various device configurations. these bits are mapped starting at program memory location 0xf80000. the device configuration register map is shown in table 19-1 . the individual configuration bit descriptions for the configuration registers are shown in table 19-2 . note that address 0xf80000 is beyond the user program memory space. it belongs to the configuration memory space (0x800000-0xffffff), which can only be accessed using table reads and table writes. table 19-1: device configuration register map note: this data sheet summ arizes the features of the pic24hj32gp202/204 and pic24hj16gp304 devi ces. it is not intended to be a comprehensive reference source. to complement the information in this data sheet, refer to the ?dspic33f/pic24h family reference manual? . please see the microchip web site ( www.microchip.com ) for the latest dspic33f/pic24h family reference manual sections. address name bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 0xf80000 fbs ? ? ? ? bss<2:0> bwrp 0xf80002 reserved ? ? ? ? ? ? ? ? 0xf80004 fgs ? ? ? ? ? gss<1:0> gwrp 0xf80006 foscsel ieso ? ? ?fnosc<2:0> 0xf80008 fosc fcksm<1:0> iol1way ? ? osciofnc poscmd<1:0> 0xf8000a fwdt fwdten windis ? wdtpre wdtpost<3:0> 0xf8000c fpor reserved (1) alti2c ?fpwrt<2:0> 0xf8000e ficd reserved (2) jtagen ? ? ?ics<1:0> 0xf80010 fuid0 user unit id byte 0 0xf80012 fuid1 user unit id byte 1 0xf80014 fuid2 user unit id byte 2 0xf80016 fuid3 user unit id byte 3 legend: ? = unimplemented bit, read as ? 0 ?. note 1: these bits are reserved and always read as ? 1 ?. 2: these bits are reserved for use by devel opment tools and must be programmed as ? 1 ?.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 180 ? 2007-2011 microchip technology inc. table 19-2: configuration bits description bit field register rtsp effect description bwrp fbs immediate boot segment program flash write protection 1 = boot segment may be written 0 = boot segment is write-protected bss<2:0> fbs immediate pic24hj32gp202 and PIC24HJ32GP204 devices only boot segment program flash code protection size x11 = no boot program flash segment boot space is 768 instruction words (except interrupt vectors) 110 = standard security; boot program flash segment ends at 0x0007fe 010 = high security; boot program flash segment ends at 0x0007fe boot space is 3840 instruction words (except interrupt vectors) 101 = standard security; boot program flash segment, ends at 0x001ffe 001 = high security; boot program flash segment ends at 0x001ffe boot space is 7936 instruction words (except interrupt vectors) 100 = standard security; boot program flash segment ends at 0x003ffe 000 = high security; boot program flash segment ends at 0x003ffe bss<2:0> fbs immediate pic24hj16gp304 devices only boot segment program flash code protection size x11 = no boot program flash segment boot space is 768 instruction words (except interrupt vectors) 110 = standard security; boot program flash segment ends at 0x0007fe 010 = high security; boot program flash segment ends at 0x0007fe boot space is 3840 instruction words (except interrupt vectors) 101 = standard security; boot program flash segment, ends at 0x001ffe 001 = high security; boot program flash segment ends at 0x001ffe boot space is 5376 instruction words (except interrupt vectors) 100 = standard security; boot program flash segment ends at 0x002bfe 000 = high security; boot program flash segment ends at 0x002bfe gss<1:0> fgs immediate general segment code-protect bit 11 = user program memory is not code-protected 10 = standard security 0x = high security gwrp fgs immediate general segment write-protect bit 1 = user program memory is not write-protected 0 = user program memory is write-protected ieso foscsel immediate two-speed o scillator start-up enable bit 1 = start-up device with frc, then aut omatically switch to the user-selected oscillator source when ready 0 = start-up device with user-selected oscillator source fnosc<2:0> foscsel if clock switch is enabled, rtsp effect is on any device reset; otherwise, immediate initial oscillator source selection bits 111 = internal fast rc (frc) oscillator with postscaler 110 = internal fast rc (frc) oscillator with divide-by-16 101 = lprc oscillator 100 = secondary (lp) oscillator 011 = primary (xt, hs, ec) oscillator with pll 010 = primary (xt, hs, ec) oscillator 001 = internal fast rc (frc) oscillator with pll 000 = frc oscillator
? 2007-2011 microchip technology inc. ds70289j-page 181 pic24hj32gp202/204 and pic24hj16gp304 fcksm<1:0> fosc immediate clock switching mode bits 1x = clock switching is disabled, fail-safe clock monitor is disabled 01 = clock switching is enabled, fail-safe clock monitor is disabled 00 = clock switching is enabled, fail-safe clock monitor is enabled iol1way fosc immediate peripheral pin select configuration 1 = allow only one re-configuration 0 = allow multiple re-configurations osciofnc fosc immediate osc2 pin function bit (except in xt and hs modes) 1 = osc2 is clock output 0 = osc2 is general purpose digital i/o pin poscmd<1:0> fosc immediate primary oscillator mode select bits 11 = primary oscillator disabled 10 = hs crystal oscillator mode 01 = xt crystal oscillator mode 00 = ec (external clock) mode fwdten fwdt immediate watchdog timer enable bit 1 = watchdog timer always enabled (lprc oscillator cannot be disabled. clearing the swdten bit in the rcon register will have no effect.) 0 = watchdog timer enabled/disabled by user software (lprc can be disabled by clearing the swdten bit in the rcon register) windis fwdt immediate watchdog timer window enable bit 1 = watchdog timer in non-window mode 0 = watchdog timer in window mode wdtpre fwdt immediate watchdog timer prescaler bit 1 = 1:128 0 = 1:32 wdtpost<3:0> fwdt immediate watchdog timer postscaler bits 1111 = 1:32,768 1110 = 1:16,384 ? ? ? 0001 = 1:2 0000 = 1:1 alti2c fpor immediate alternate i 2 c? pins 1 = i 2 c mapped to sda1/scl1 pins 0 = i 2 c mapped to asda1/ascl1 pins fpwrt<2:0> fpor immediate power-on reset timer value select bits 111 = pwrt = 128 ms 110 = pwrt = 64 ms 101 = pwrt = 32 ms 100 = pwrt = 16 ms 011 = pwrt = 8 ms 010 = pwrt = 4 ms 001 = pwrt = 2 ms 000 = pwrt = disabled jtagen ficd immediate jtag enable bit 1 = jtag enabled 0 = jtag disabled table 19-2: configuration bits description (continued) bit field register rtsp effect description
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 182 ? 2007-2011 microchip technology inc. ics<1:0> ficd immediate icd communication channel select bits 11 = communicate on pgec1 and pged1 10 = communicate on pgec2 and pged2 01 = communicate on pgec3 and pged3 00 = reserved, do not use table 19-2: configuration bits description (continued) bit field register rtsp effect description
? 2007-2011 microchip technology inc. ds70289j-page 183 pic24hj32gp202/204 and pic24hj16gp304 19.2 on-chip voltage regulator all of the pic24hj32gp202/204 and pic24hj16gp304 devices power their core digital logic at a nominal 2.5v. this can create a conflict for designs that are required to operate at a higher typical voltage, such as 3.3v. to simplify system design, all devices in the pic24hj32gp202/204 and pic24hj16gp304 family incorporate an on-chip regu- lator that allows the device to run its core logic from v dd . the regulator provides power to the core from the other v dd pins. when the regulator is enabled, a low-esr (less than 5 ohms) capacitor (such as tantalum or ceramic) must be connected to the v cap pin ( figure 19-1 ). this helps to maintain the stability of the regulator. the recommended value for the filter capac- itor is provided in table 22-13 located in section 22.1 ?dc characteristics? . on a por , it takes approximately 20 s for the on-chip voltage regulator to generate an output voltage. during this time, designated as t startup , code execution is disabled. t startup is applied every time the device resumes operation after any power-down. figure 19-1: connections for the on-chip voltage regulator (1,2,3) 19.3 brown-out reset (bor) the brown-out reset (bor) module is based on an internal voltage reference circuit that monitors the regulated voltage v cap . the main purpose of the bor module is to generate a device reset when a brown-out condition occurs. brown-out conditions are generally caused by glitches on the ac mains (for example, missing portions of the ac cycle waveform due to bad power transmission lines, or voltage sags due to excessive current draw when a large inductive load is turned on). a bor generates a reset pulse, which resets the device. the bor selects the clock source, based on the device configuration bit values (fnosc<2:0> and poscmd<1:0>). if an oscillator mode is selected, the bor activates the oscillator start-up timer (o st). the system clock is held until ost expires. if the pll is used, the clock is held until the lock bit (osccon<5>) is ? 1 ?. concurrently, the pwrt time-out (tpwrt) will be applied before the internal reset is released. if tpwrt = 0 and a crystal oscillator is being used, a nominal delay of tfscm = 100 is applied. the total delay in this case is tfscm. the bor status bit (rcon<1>) is set to indicate that a bor has occurred. the bor circuit continues to operate while in sleep or idle mode and resets the device in case v dd falls below the bor threshold voltage. note: it is important for the low-esr capacitor to be placed as close as possible to the v cap pin. note 1: these are typical operating voltages. refer to table 22-13 located in section 22.1 ?dc characteristics? for the full operating ranges of v dd and v cap . 2: it is important for the low-esr capacitor to be placed as close as possible to the v cap pin. 3: typical v cap pin voltage = 2.5v when v dd v ddmin . v dd v cap v ss pic24h c efc 3.3v 10 f
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 184 ? 2007-2011 microchip technology inc. 19.4 watchdog timer (wdt) for pic24hj32gp202/204 and pic24hj16gp304 devices, the wdt is driven by the lprc oscillator. when the wdt is enabled, the clock source is also enabled. 19.4.1 prescaler/postscaler the nominal wdt clock source from lprc is 32 khz. this feeds a prescaler than can be configured for either 5-bit (divide-by-32) or 7-bit (divide-by-128) operation. the prescaler is set by the wdtpre configuration bit. with a 32 khz input, the prescaler yields a nominal wdt time-out period (t wdt ) of 1 ms in 5-bit mode, or 4 ms in 7-bit mode. a variable postscaler divides down the wdt prescaler output and allows for a wide range of time-out periods. the postscaler is controlled by the wdtpost<3:0> configuration bits (fwdt<3:0>), which allows the selection of 16 settings, from 1:1 to 1:32,768. using the prescaler and postscaler, time-out periods ranging from 1 ms to 131 seconds can be achieved. the wdt, prescaler and postscaler are reset: ? on any device reset ? on the completion of a clock switch, whether invoked by software (i.e., setting the oswen bit after changing the nosc bits) or by hardware (i.e., fail-safe clock monitor) ? when a pwrsav instruction is executed (sleep or idle mode is entered) ? when the device exits sleep or idle mode to resume normal operation ?by a clrwdt instruction during normal execution 19.4.2 sleep and idle modes if the wdt is enabled, it will continue to run during sleep or idle modes. when the wdt time-out occurs, the device will wake the dev ice and code execution will continue from where the pwrsav instruction was executed. the corresponding sleep or idle bits (rcon<3,2>) will need to be cleared in software after the device wakes up. 19.4.3 enabling wdt the wdt is enabled or disabled by the fwdten configuration bit in the fwdt configuration register. when the fwdten configuration bit is set, the wdt is always enabled. the wdt flag bit, wdto (rcon< 4>), is not automatically cleared following a wdt time-out. to detect subsequent wdt events, the flag must be cleared in software. the wdt can be optionally controlled in software when the fwdten configuration bit has been programmed to ? 0 ?. the wdt is enabled in software by setting the swdten control bit ( rcon<5>). the swdten control bit is cleared on any device reset. the software wdt option allows the user application to enable the wdt for critical code segments and disable the wdt during non-critical segments for maximum power savings. figure 19-2: wdt block diagram note: the clrwdt and pwrsav instructions clear the prescaler and postscaler counts when executed. note: if the windis bit (fwdt<6>) is cleared, the clrwdt instruction should be executed by the application software only during the last 1/4 of the wdt period. this clrwdt window can be determined by using a timer. if a clrwdt instruction is executed before this window, a wdt reset occurs. all device resets transition to new clock source exit sleep or idle mode pwrsav instruction clrwdt instruction 0 1 wdtpre wdtpost<3:0> watchdog timer prescaler (divide by n1) postscaler (divide by n2) sleep/idle wdt wdt window select windis wdt clrwdt instruction swdten fwdten lprc clock rs rs wake-up reset
? 2007-2011 microchip technology inc. ds70289j-page 185 pic24hj32gp202/204 and pic24hj16gp304 19.5 jtag interface pic24hj32gp202/204 and pic24hj16gp304 devices implement a jtag interface, which supports boundary scan device testing, as well as in-circuit programming. detailed information on this interface will be provided in future revisions of the document. 19.6 code protection and codeguard? security the pic24hj32gp202/204 and pic24hj16gp304 product family offers the intermediate implementation of codeguard security. codeguard security allows multiple parties to secure ly share resources (memory, interrupts and peripherals) on a single chip. this feature helps to protect i ndividual intellectual property in collaborative system designs. when coupled with software encryption libraries, codeguard security can be used to securely update flash even when multiple ips reside on the single chip. the code protection featur es are controlled by the configuration registers: fbs and fgs. the secure segment and ram is not implemented. table 19-3: code flash security segment sizes for 32 kbyte devices table 19-4: code flash security segment sizes for 16 kbyte devices note: refer to section 23. ?codeguard? security? (ds70199) in the ?dspic33f/pic24h family reference manual? for further information on usage, configuration and operation of codeguard security. config bits bss<2:0>=x11 0k bss<2:0>=x10 256 bss<2:0>=x01 768 bss<2:0>=x00 1792 0x0057fe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 gs = 11008 iw 0x003ffe 0x004000 0x0057fe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 0x003ffe 0x004000 gs = 10240 iw bs = 768 iw 0x0057fe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 0x003ffe 0x004000 gs = 7168 iw bs = 3840 iw 0x0057fe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 gs = 3072 iw 0x003ffe 0x004000 bs = 7936 iw config bits bss<2:0>=x11 0k bss<2:0>=x10 256 bss<2:0>=x01 768 bss<2:0>=x00 1792 0x002bfe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 gs = 5376 iw 0x002bfe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 gs = 4608 iw bs = 768 iw 0x002bfe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 gs = 1536 iw bs = 3840 iw 0x002bfe 0x0001fe 0x000200 0x000000 vs = 256 iw 0x0007fe 0x000800 0x001ffe 0x002000 bs = 5376 iw
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 186 ? 2007-2011 microchip technology inc. 19.7 in-circuit serial programming pic24hj32gp202/204 and pic24hj16gp304 family microcontrollers can be serially programmed while in the end application circuit. this is done with two lines for clock and data, and three other lines for power, ground and the programming sequence. serial pro- gramming allows customers to manufacture boards with unprogrammed devices and then program the microcontroller just before shipping the product. serial programming also allows the most recent firmware or a custom firmware to be programmed. refer to the ?dspic33f/pic24h flash programming specification? (ds70152) document for details about in-circuit serial programming? (icsp)?. any of the following three pairs of programming clock/data pins can be used: ? pgec1 and pged1 ? pgec2 and pged2 ? pgec3 and pged3 19.8 in-circuit debugger when mplab ? icd 2 is selected as a debugger, the in-circuit debugging functionality is enabled. this function allows simple debugging functions when used with mplab ide. debugging functionality is controlled through the emulation/debug clock (pgecx) and emulation/debug data (pgedx) pin functions. any of the following three pairs of debugging clock/data pins can be used: ? pgec1 and pged1 ? pgec2 and pged2 ? pgec3 and pged3 to make use of the in-cir cuit debugger function of the device, the design must implement icsp connections to mclr , v dd , v ss and pgecx/pgedx pin pair. in addition, when the feature is enabled, some of the resources are not available for general use. these resources include the first 80 bytes of data ram and two i/o pins.
? 2007-2011 microchip technology inc. ds70289j-page 187 pic24hj32gp202/204 and pic24hj16gp304 20.0 instruction set summary the pic24h instruction set is identical to that of the pic24f, and is a subset of the dspic30f/33f instruction set. most instructions are a single program memory word (24 bits). only three instructions require two program memory locations. each single-word instruction is a 24-bit word, divided into an 8-bit opcode, which specifies the instruction type and one or more oper ands, which further specify the operation of the instruction. the instruction set is highly orthogonal and is grouped into five basic categories: ? word or byte-oriented operations ? bit-oriented operations ? literal operations ? control operations table 20-1 shows the general symbols used in describing the instructions. the pic24h instruct ion set summary in ta b l e 2 0 - 2 lists all the instructions, along with the status flags affected by each instruction. most word or byte-oriente d w register instructions (including barrel shift instructions) have three operands: ? the first source operand which is typically a register ?wb? without any address modifier ? the second source operand which is typically a register ?ws? with or without an address modifier ? the destination of the result which is typically a register ?wd? with or wit hout an address modifier however, word or byte-oriented file register instructions have two operands: ? the file register specified by the value ?f? ? the destination, which c ould either be the file register ?f? or the w0 regi ster, which is denoted as ?wreg? most bit-oriented instructions (including simple rotate/shift instructions) have two operands: ? the w register (with or without an address modifier) or file register (specified by the value of ?ws? or ?f?) ? the bit in the w register or file register (specified by a literal value or indirectly by the contents of register ?wb?) the literal instructions that involve data movement may use some of the following operands: ? a literal value to be loaded into a w register or file register (specified by the value of ?k?) ? the w register or file register where the literal value is to be loaded (specified by ?wb? or ?f?) however, literal instructions that involve arithmetic or logical operations use some of the following operands: ? the first source operand which is a register ?wb? without any address modifier ? the second source operand which is a literal value ? the destination of the result (only if not the same as the first source operand) which is typically a register ?wd? with or without an address modifier the control instructions may use some of the following operands: ? a program memory address ? the mode of the table read and table write instructions all instructions are single word. certain double-word instructions are designed to provide all of the required information in these 48 bits. in the second word, the 8 msbs are ? 0 ?s. if this second word is executed as an instruction (by itself), it will execute as a nop . most single-word instructions are executed in a single instruction cycle, unless a conditional test is true, or the program counter is chang ed as a result of the instruction. in these cases, the execution takes two instruction cycles with the additional instruction cycle(s) executed as a nop . notable exceptions are the bra (unconditional/computed branch), indirect call/goto , all table reads and writes and return/retfie instructions, which are single-word instructions but take two or three cycles. certain in structions that involve skip- ping over the subsequent inst ruction require either two or three cycles if the skip is performed, depending on whether the instruction being skipped is a single-word or double word instruction. moreover, double word moves require two cycles. the double word instructions execute in two instruction cycles. note: this data sheet summ arizes the features of this group of pic24hj32gp202/204 and pic24hj16gp304 devices. it is not intended to be a comprehensive refer- ence source. to comp lement the informa- tion in this data sheet, refer to the ?dspic33f/pic24h family reference manual? . please see the microchip web site ( www.microchip.com ) for the latest dspic33f/pic24h family reference manual sections. note: for more details on the instruction set, refer to the ?16-bit mcu and dsc programmer?s reference manual? (ds70157).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 188 ? 2007-2011 microchip technology inc. table 20-1: symbols used in opcode descriptions field description #text means literal defined by ? text ? (text) means ?content of text ? [text] means ?the location addressed by text ? { } optional field or operation register bit field .b byte mode selection .d double word mode selection .s shadow register select .w word mode selection (default) bit4 4-bit bit selection field (us ed in word addressed instructions) {0...15} c, dc, n, ov, z mcu status bits: carry, digit carry, negative, overflow, sticky zero expr absolute address, label or ex pression (resolved by the linker) f file register address {0x0000...0x1fff} lit1 1-bit unsigned literal {0,1} lit4 4-bit unsigned literal {0...15} lit5 5-bit unsigned literal {0...31} lit8 8-bit unsigned literal {0...255} lit10 10-bit unsigned literal {0...255} for byte mode, {0:1023} for word mode lit14 14-bit unsigned literal {0...16384} lit16 16-bit unsigned literal {0...65535} lit23 23-bit unsigned literal {0...8388608}; lsb must be ? 0 ? none field does not require an entry, may be blank pc program counter slit10 10-bit signed literal {-512...511} slit16 16-bit signed literal {-32768...32767} slit6 6-bit signed literal {-16...16} wb base w register {w0..w15} wd destination w register { wd, [wd], [wd++], [wd--], [++wd], [--wd] } wdo destination w register { wnd, [wnd], [wnd++], [wnd--], [++wnd], [--wnd], [wnd+wb] } wm,wn dividend, divisor working register pair (direct addressing) wm*wm multiplicand and multiplier working register pair for square instructions {w4 * w4,w5 * w5,w6 * w6,w7 * w7} wn one of 16 working registers {w0..w15} wnd one of 16 destination working registers {w0...w15} wns one of 16 source working registers {w0...w15} wreg w0 (working register used in file register instructions) ws source w register { ws, [ws], [ws++], [ws- -], [++ws], [--ws] } wso source w register { wns, [wns], [wns++], [wns--], [++wns], [--wns], [wns+wb] }
? 2007-2011 microchip technology inc. ds70289j-page 189 pic24hj32gp202/204 and pic24hj16gp304 table 20-2: instruction set overview base instr # assembly mnemonic assembly syntax description # of words # of cycles status flags affected 1add add f f = f + wreg 1 1 c,dc,n,ov,z add f,wreg wreg = f + wreg 1 1 c,dc,n,ov,z add #lit10,wn wd = lit10 + wd 1 1 c,dc,n,ov,z add wb,ws,wd wd = wb + ws 1 1 c,dc,n,ov,z add wb,#lit5,wd wd = wb + lit5 1 1 c,dc,n,ov,z 2 addc addc f f = f + wreg + (c) 1 1 c,dc,n,ov,z addc f,wreg wreg = f + wreg + (c) 1 1 c,dc,n,ov,z addc #lit10,wn wd = lit10 + wd + (c) 1 1 c,dc,n,ov,z addc wb,ws,wd wd = wb + ws + (c) 1 1 c,dc,n,ov,z addc wb,#lit5,wd wd = wb + lit5 + (c) 1 1 c,dc,n,ov,z 3and and f f = f .and. wreg 1 1 n,z and f,wreg wreg = f .and. wreg 1 1 n,z and #lit10,wn wd = lit10 .and. wd 1 1 n,z and wb,ws,wd wd = wb .and. ws 1 1 n,z and wb,#lit5,wd wd = wb .and. lit5 1 1 n,z 4 asr asr f f = arithmetic right shift f 1 1 c,n,ov,z asr f,wreg wreg = arithmetic right shift f 1 1 c,n,ov,z asr ws,wd wd = arithmetic right shift ws 1 1 c,n,ov,z asr wb,wns,wnd wnd = arithmetic right shift wb by wns 1 1 n,z asr wb,#lit5,wnd wnd = arithmetic right shift wb by lit5 1 1 n,z 5bclr bclr f,#bit4 bit clear f 1 1 none bclr ws,#bit4 bit clear ws 1 1 none 6bra bra c,expr branch if carry 1 1 (2) none bra ge,expr branch if greater than or equal 1 1 (2) none bra geu,expr branch if unsigned greater than or equal 1 1 (2) none bra gt,expr branch if greater than 1 1 (2) none bra gtu,expr branch if unsigned greater than 1 1 (2) none bra le,expr branch if less than or equal 1 1 (2) none bra leu,expr branch if unsigned less than or equal 1 1 (2) none bra lt,expr branch if less than 1 1 (2) none bra ltu,expr branch if unsigned less than 1 1 (2) none bra n,expr branch if negative 1 1 (2) none bra nc,expr branch if not carry 1 1 (2) none bra nn,expr branch if not negative 1 1 (2) none bra nz,expr branch if not zero 1 1 (2) none bra expr branch unconditionally 1 2 none bra z,expr branch if zero 1 1 (2) none bra wn computed branch 1 2 none 7 bset bset f,#bit4 bit set f 1 1 none bset ws,#bit4 bit set ws 1 1 none 8 bsw bsw.c ws,wb write c bit to ws 1 1 none bsw.z ws,wb write z bit to ws 1 1 none 9btg btg f,#bit4 bit toggle f 1 1 none btg ws,#bit4 bit toggle ws 1 1 none 10 btsc btsc f,#bit4 bit test f, skip if clear 1 1 (2 or 3) none btsc ws,#bit4 bit test ws, skip if clear 1 1 (2 or 3) none 11 btss btss f,#bit4 bit test f, skip if set 1 1 (2 or 3) none btss ws,#bit4 bit test ws, skip if set 1 1 (2 or 3) none
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 190 ? 2007-2011 microchip technology inc. 12 btst btst f,#bit4 bit test f 1 1 z btst.c ws,#bit4 bit test ws to c 1 1 c btst.z ws,#bit4 bit test ws to z 1 1 z btst.c ws,wb bit test ws to c 1 1 c btst.z ws,wb bit test ws to z 1 1 z 13 btsts btsts f,#bit4 bit test then set f 1 1 z btsts.c ws,#bit4 bit test ws to c, then set 1 1 c btsts.z ws,#bit4 bit test ws to z, then set 1 1 z 14 call call lit23 call subroutine 2 2 none call wn call indirect subroutine 1 2 none 15 clr clr f f = 0x0000 1 1 none clr wreg wreg = 0x0000 1 1 none clr ws ws = 0x0000 1 1 none 16 clrwdt clrwdt clear watchdog timer 1 1 wdto,sleep 17 com com f f = f 11 n,z com f,wreg wreg = f 11 n,z com ws,wd wd = ws 11 n,z 18 cp cp f compare f with wreg 1 1 c,dc,n,ov,z cp wb,#lit5 compare wb with lit5 1 1 c,dc,n,ov,z cp wb,ws compare wb with ws (wb ? ws) 1 1 c,dc,n,ov,z 19 cp0 cp0 f compare f with 0x0000 1 1 c,dc,n,ov,z cp0 ws compare ws with 0x0000 1 1 c,dc,n,ov,z 20 cpb cpb f compare f with wreg, with borrow 1 1 c,dc,n,ov,z cpb wb,#lit5 compare wb with lit5, wit h borrow 1 1 c,dc,n,ov,z cpb wb,ws compare wb with ws, with borrow (wb - ws - c ) 1 1 c,dc,n,ov,z 21 cpseq cpseq wb, wn compare wb with wn, skip if = 1 1 (2 or 3) none 22 cpsgt cpsgt wb, wn compare wb with wn, skip if > 1 1 (2 or 3) none 23 cpslt cpslt wb, wn compare wb with wn, skip if < 1 1 (2 or 3) none 24 cpsne cpsne wb, wn compare wb with wn, skip if ? 1 1 (2 or 3) none 25 daw daw wn wn = decimal adjust wn 1 1 c 26 dec dec f f = f - 1 1 1 c,dc,n,ov,z dec f,wreg wreg = f - 1 1 1 c,dc,n,ov,z dec ws,wd wd = ws - 1 1 1 c,dc,n,ov,z 27 dec2 dec2 f f = f - 2 1 1 c,dc,n,ov,z dec2 f,wreg wreg = f - 2 1 1 c,dc,n,ov,z dec2 ws,wd wd = ws - 2 1 1 c,dc,n,ov,z 28 disi disi #lit14 disable interrupts for k instruction cycles 1 1 none 29 div div.s wm,wn signed 16/16-bit integer divide 1 18 n,z,c,ov div.sd wm,wn signed 32/16-bit integer divide 1 18 n,z,c,ov div.u wm,wn unsigned 16/16-bit integer divide 1 18 n,z,c,ov div.ud wm,wn unsigned 32/16-bit integer divide 1 18 n,z,c,ov 30 exch exch wns,wnd swap wns with wnd 1 1 none 31 fbcl fbcl ws,wnd find bit change from left (msb) side 1 1 c 32 ff1l ff1l ws,wnd find first one from left (msb) side 1 1 c 33 ff1r ff1r ws,wnd find first one from right (lsb) side 1 1 c 34 goto goto expr go to address 2 2 none goto wn go to indirect 1 2 none table 20-2: instruction set overview (continued) base instr # assembly mnemonic assembly syntax description # of words # of cycles status flags affected
? 2007-2011 microchip technology inc. ds70289j-page 191 pic24hj32gp202/204 and pic24hj16gp304 35 inc inc f f = f + 1 1 1 c,dc,n,ov,z inc f,wreg wreg = f + 1 1 1 c,dc,n,ov,z inc ws,wd wd = ws + 1 1 1 c,dc,n,ov,z 36 inc2 inc2 f f = f + 2 1 1 c,dc,n,ov,z inc2 f,wreg wreg = f + 2 1 1 c,dc,n,ov,z inc2 ws,wd wd = ws + 2 1 1 c,dc,n,ov,z 37 ior ior f f = f .ior. wreg 1 1 n,z ior f,wreg wreg = f .ior. wreg 1 1 n,z ior #lit10,wn wd = lit10 .ior. wd 1 1 n,z ior wb,ws,wd wd = wb .ior. ws 1 1 n,z ior wb,#lit5,wd wd = wb .ior. lit5 1 1 n,z 38 lnk lnk #lit14 link frame pointer 1 1 none 39 lsr lsr f f = logical right shift f 1 1 c,n,ov,z lsr f,wreg wreg = logical right shift f 1 1 c,n,ov,z lsr ws,wd wd = logical right shift ws 1 1 c,n,ov,z lsr wb,wns,wnd wnd = logical right shift wb by wns 1 1 n,z lsr wb,#lit5,wnd wnd = logical right shift wb by lit5 1 1 n,z 40 mov mov f,wn move f to wn 1 1 none mov f move f to f 1 1 n,z mov f,wreg move f to wreg 1 1 none mov #lit16,wn move 16-bit literal to wn 1 1 none mov.b #lit8,wn move 8-bit literal to wn 1 1 none mov wn,f move wn to f 1 1 none mov wso,wdo move ws to wd 1 1 none mov wreg,f move wreg to f 1 1 none mov.d wns,wd move double from w(ns):w(ns + 1) to wd 1 2 none mov.d ws,wnd move double from ws to w(nd + 1):w(nd) 1 2 none 41 mul mul.ss wb,ws,wnd {wnd + 1, wnd} = signed(wb) * signed(ws) 1 1 none mul.su wb,ws,wnd {wnd + 1, wnd} = signed(wb) * unsigned(ws) 1 1 none mul.us wb,ws,wnd {wnd + 1, wnd} = unsigned(wb) * signed(ws) 1 1 none mul.uu wb,ws,wnd {wnd + 1, wnd} = unsigned(wb) * unsigned(ws) 1 1 none mul.su wb,#lit5,wnd {wnd + 1, wnd} = signed(wb) * unsigned(lit5) 1 1 none mul.uu wb,#lit5,wnd {wnd + 1, wnd} = unsigned(wb) * unsigned(lit5) 1 1 none mul f w3:w2 = f * wreg 1 1 none 42 neg neg f f = f + 1 1 1 c,dc,n,ov,z neg f,wreg wreg = f + 1 1 1 c,dc,n,ov,z neg ws,wd wd = ws + 1 1 1 c,dc,n,ov,z 43 nop nop no operation 1 1 none nopr no operation 1 1 none 44 pop pop f pop f from top-of-stack (tos) 1 1 none pop wdo pop from top-of-stack (tos) to wdo 1 1 none pop.d wnd pop from top-of-stack (tos) to w(nd):w(nd + 1) 1 2 none pop.s pop shadow registers 1 1 all 45 push push f push f to top-of-stack (tos) 1 1 none push wso push wso to top-of-stack (tos) 1 1 none push.d wns push w(ns):w(ns + 1) to top-of-stack (tos) 1 2 none push.s push shadow registers 1 1 none 46 pwrsav pwrsav #lit1 go into sleep or idle mode 1 1 wdto,sleep table 20-2: instruction set overview (continued) base instr # assembly mnemonic assembly syntax description # of words # of cycles status flags affected
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 192 ? 2007-2011 microchip technology inc. 47 rcall rcall expr relative call 1 2 none rcall wn computed call 1 2 none 48 repeat repeat #lit14 repeat next instruction lit14 + 1 times 1 1 none repeat wn repeat next instruction (wn) + 1 times 1 1 none 49 reset reset software device reset 1 1 none 50 retfie retfie return from interrupt 1 3 (2) none 51 retlw retlw #lit10,wn return with literal in wn 1 3 (2) none 52 return return return from subroutine 1 3 (2) none 53 rlc rlc f f = rotate left through carry f 1 1 c,n,z rlc f,wreg wreg = rotate left through carry f 1 1 c,n,z rlc ws,wd wd = rotate left through carry ws 1 1 c,n,z 54 rlnc rlnc f f = rotate left (no carry) f 1 1 n,z rlnc f,wreg wreg = rotate left (no carry) f 1 1 n,z rlnc ws,wd wd = rotate left (no carry) ws 1 1 n,z 55 rrc rrc f f = rotate right through carry f 1 1 c,n,z rrc f,wreg wreg = rotate right through carry f 1 1 c,n,z rrc ws,wd wd = rotate right through carry ws 1 1 c,n,z 56 rrnc rrnc f f = rotate right (no carry) f 1 1 n,z rrnc f,wreg wreg = rotate right (no carry) f 1 1 n,z rrnc ws,wd wd = rotate right (no carry) ws 1 1 n,z 57 se se ws,wnd wnd = sign-extended ws 1 1 c,n,z 58 setm setm f f = 0xffff 1 1 none setm wreg wreg = 0xffff 1 1 none setm ws ws = 0xffff 1 1 none 59 sl sl f f = left shift f 1 1 c,n,ov,z sl f,wreg wreg = left shift f 1 1 c,n,ov,z sl ws,wd wd = left shift ws 1 1 c,n,ov,z sl wb,wns,wnd wnd = left shift wb by wns 1 1 n,z sl wb,#lit5,wnd wnd = left shift wb by lit5 1 1 n,z 60 sub sub f f = f - wreg 1 1 c,dc,n,ov,z sub f,wreg wreg = f - wreg 1 1 c,dc,n,ov,z sub #lit10,wn wn = wn - lit10 1 1 c,dc,n,ov,z sub wb,ws,wd wd = wb - ws 1 1 c,dc,n,ov,z sub wb,#lit5,wd wd = wb - lit5 1 1 c,dc,n,ov,z 61 subb subb f f = f - wreg - (c ) 1 1 c,dc,n,ov,z subb f,wreg wreg = f - wreg - (c ) 1 1 c,dc,n,ov,z subb #lit10,wn wn = wn - lit10 - (c ) 1 1 c,dc,n,ov,z subb wb,ws,wd wd = wb - ws - (c ) 1 1 c,dc,n,ov,z subb wb,#lit5,wd wd = wb - lit5 - (c ) 1 1 c,dc,n,ov,z 62 subr subr f f = wreg - f 1 1 c,dc,n,ov,z subr f,wreg wreg = wreg - f 1 1 c,dc,n,ov,z subr wb,ws,wd wd = ws - wb 1 1 c,dc,n,ov,z subr wb,#lit5,wd wd = lit5 - wb 1 1 c,dc,n,ov,z 63 subbr subbr f f = wreg - f - (c ) 1 1 c,dc,n,ov,z subbr f,wreg wreg = wreg - f - (c ) 1 1 c,dc,n,ov,z subbr wb,ws,wd wd = ws - wb - (c ) 1 1 c,dc,n,ov,z subbr wb,#lit5,wd wd = lit5 - wb - (c ) 1 1 c,dc,n,ov,z 64 swap swap.b wn wn = nibble swap wn 1 1 none swap wn wn = byte swap wn 1 1 none 65 tblrdh tblrdh ws,wd read prog<23:16> to wd<7:0> 1 2 none table 20-2: instruction set overview (continued) base instr # assembly mnemonic assembly syntax description # of words # of cycles status flags affected
? 2007-2011 microchip technology inc. ds70289j-page 193 pic24hj32gp202/204 and pic24hj16gp304 66 tblrdl tblrdl ws,wd read prog<15:0> to wd 1 2 none 67 tblwth tblwth ws,wd write ws<7:0> to prog<23:16> 1 2 none 68 tblwtl tblwtl ws,wd write ws to prog<15:0> 1 2 none 69 ulnk ulnk unlink frame pointer 1 1 none 70 xor xor f f = f .xor. wreg 1 1 n,z xor f,wreg wreg = f .xor. wreg 1 1 n,z xor #lit10,wn wd = lit10 .xor. wd 1 1 n,z xor wb,ws,wd wd = wb .xor. ws 1 1 n,z xor wb,#lit5,wd wd = wb .xor. lit5 1 1 n,z 71 ze ze ws,wnd wnd = zero-extend ws 1 1 c,z,n table 20-2: instruction set overview (continued) base instr # assembly mnemonic assembly syntax description # of words # of cycles status flags affected
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 194 ? 2007-2011 microchip technology inc. notes:
? 2012 microchip technology inc. advance information ds00000a-page 195 pic32sk4xx/5xx 21.0 development support the pic ? microcontrollers and dspic ? digital signal controllers are supported with a full range of software and hardware development tools: ? integrated development environment - mplab ? ide software ? compilers/assemblers/linkers - mplab c compiler for various device families - hi-tech c ? for various device families - mpasm tm assembler -mplink tm object linker/ mplib tm object librarian - mplab assembler/link er/librarian for various device families ? simulators - mplab sim software simulator ? emulators - mplab real ice? in-circuit emulator ? in-circuit debuggers - mplab icd 3 - pickit? 3 debug express ? device programmers - pickit? 2 programmer - mplab pm3 device programmer ? low-cost demonstratio n/development boards, evaluation kits, and starter kits 21.1 mplab integrated development environment software the mplab ide software brings an ease of software development previously unseen in the 8/16/32-bit microcontroller market. the mplab ide is a windows ? operating system-based app lication that contains: ? a single graphical interface to all debugging tools - simulator - programmer (sold separately) - in-circuit emulator (sold separately) - in-circuit debugger (sold separately) ? a full-featured editor with color-coded context ? a multiple project manager ? customizable data windows with direct edit of contents ? high-level source code debugging ? mouse over variable inspection ? drag and drop variables from source to watch windows ? extensive on-line help ? integration of select thir d party tools, such as iar c compilers the mplab ide allows you to: ? edit your source files (either c or assembly) ? one-touch compile or assemble, and download to emulator and simulator tools (automatically updates all project information) ? debug using: - source files (c or assembly) - mixed c and assembly - machine code mplab ide supports multiple debugging tools in a single development paradigm, from the cost-effective simulators, through low-cost in-circuit debuggers, to full-featured emulators. this eliminates the learning curve when upgrading to tools with increased flexibility and power.
pic32sk4xx/5xx ds00000a-page 196 advance information ? 2012 microchip technology inc. 21.2 mplab c compilers for various device families the mplab c compiler code development systems are complete ansi c compilers for microchip?s pic18, pic24 and pic32 families of microcontrollers and the dspic30 and dspic33 families of digital signal control- lers. these compilers provide powerful integration capabilities, superior code optimization and ease of use. for easy source level debugging, the compilers provide symbol information that is optimized to the mplab ide debugger. 21.3 hi-tech c for various device families the hi-tech c compiler code development systems are complete ansi c comp ilers for microchip?s pic family of microcontrollers and the dspic family of digital signal controllers. these compilers provide powerful integration capabilities, omniscient code generation and ease of use. for easy source level debugging, the compilers provide symbol information that is optimized to the mplab ide debugger. the compilers include a macro assembler, linker, pre- processor, and one-step driver, and can run on multiple platforms. 21.4 mpasm assembler the mpasm assembler is a full-featured, universal macro assembler for pic10/12/16/18 mcus. the mpasm assembler generates relocatable object files for the mplink object linker, intel ? standard hex files, map files to detail memory usage and symbol reference, absolute lst files that contain source lines and generated machine code and coff files for debugging. the mpasm assembler features include: ? integration into mplab ide projects ? user-defined macros to streamline assembly code ? conditional assembly for multi-purpose source files ? directives that allow complete control over the assembly process 21.5 mplink object linker/ mplib object librarian the mplink object linker combines relocatable objects created by the mpasm assembler and the mplab c18 c compiler. it can link relocatable objects from precompiled libraries, using directives from a linker script. the mplib object librarian manages the creation and modification of library files of precompiled code. when a routine from a library is called from a source file, only the modules that contain that routine will be linked in with the application. this allows large libraries to be used efficiently in many different applications. the object linker/libra ry features include: ? efficient linking of single libraries instead of many smaller files ? enhanced code maintainability by grouping related modules together ? flexible creation of libraries with easy module listing, replacement, deletion and extraction 21.6 mplab assembler, linker and librarian for various device families mplab assembler produces relocatable machine code from symbolic assembly language for pic24, pic32 and dspic devices. mplab c compiler uses the assembler to produce its object file. the assembler generates relocatable objec t files that can then be archived or linked with other relocatable object files and archives to create an execut able file. notable features of the assembler include: ? support for the entire device instruction set ? support for fixed-point and floating-point data ? command line interface ? rich directive set ? flexible macro language ? mplab ide compatibility
? 2012 microchip technology inc. advance information ds00000a-page 197 pic32sk4xx/5xx 21.7 mplab sim software simulator the mplab sim software simulator allows code development in a pc-hosted environment by simulat- ing the pic mcus and dspic ? dscs on an instruction level. on any given instruction, the data areas can be examined or modified and stimuli can be applied from a comprehensive stimulus c ontroller. registers can be logged to files for further run-time analysis. the trace buffer and logic analyzer display extend the power of the simulator to record and track program execution, actions on i/o, most peripherals and internal registers. the mplab sim software simulator fully supports symbolic debugging using the mplab c compilers, and the mpasm and mplab assemblers. the soft- ware simulator offers the flexibility to develop and debug code outside of the hardware laboratory envi- ronment, making it an excellent, economical software development tool. 21.8 mplab real ice in-circuit emulator system mplab real ice in-circuit emulator system is microchip?s next generation high-speed emulator for microchip flash dsc and mcu devices. it debugs and programs pic ? flash mcus and dspic ? flash dscs with the easy-to-use, powerful graphical user interface of the mplab integrated devel opment environment (ide), included with each kit. the emulator is connected to the design engineer?s pc using a high-speed usb 2.0 interface and is connected to the target with either a connector compatible with in- circuit debugger systems (rj11) or with the new high- speed, noise tolerant, low-voltage differential signal (lvds) interconnection (cat5). the emulator is field upgradable through future firmware downloads in mplab ide. in upcoming releases of mplab ide, new devices will be supported, and new features will be added. mplab real ice offers significant advantages over competitive emulators including low-cost, full-speed emulation, run-time variable watches, trace analysis, complex breakpoints, a ruggedized probe interface and long (up to three meters) interconnection cables. 21.9 mplab icd 3 in-circuit debugger system mplab icd 3 in-circuit debugger system is micro- chip's most cost effective high-speed hardware debugger/programmer for microchip flash digital sig- nal controller (dsc) and microcontroller (mcu) devices. it debugs and programs pic ? flash microcon- trollers and dspic ? dscs with the powerful, yet easy- to-use graphical user interface of mplab integrated development environment (ide). the mplab icd 3 in-circuit debugger probe is con- nected to the design engineer's pc using a high-speed usb 2.0 interface and is connected to the target with a connector compatible with the mplab icd 2 or mplab real ice systems (rj-11). mplab icd 3 supports all mplab icd 2 headers. 21.10 pickit 3 in-circuit debugger/ programmer and pickit 3 debug express the mplab pickit 3 allows debugging and program- ming of pic ? and dspic ? flash microcontrollers at a most affordable price point using the powerful graphical user interface of the mp lab integrated development environment (ide). the mplab pickit 3 is connected to the design engineer's pc using a full speed usb interface and can be connec ted to the target via an microchip debug (rj-11) connector (compatible with mplab icd 3 and mplab real ice). the connector uses two device i/o pins and the reset line to imple- ment in-circuit debugging and in-circuit serial pro- gramming?. the pickit 3 debug express include the pickit 3, demo board and microcontroller, hookup cables and cdrom with user?s guide, lessons, tutorial, compiler and mplab ide software.
pic32sk4xx/5xx ds00000a-page 198 advance information ? 2012 microchip technology inc. 21.11 pickit 2 development programmer/debugger and pickit 2 debug express the pickit? 2 development programmer/debugger is a low-cost development tool with an easy to use inter- face for programming and debugging microchip?s flash families of microcontrollers. the full featured windows ? programming interface supports baseline (pic10f, pic12f5xx, pic16f5xx), midrange (pic12f6xx, pic16f), pic18f, pic24, dspic30, dspic33, and pic32 families of 8-bit, 16-bit, and 32-bit microcontrollers, and many microchip serial eeprom products. with microchip?s powerful mplab integrated development environmen t (ide) the pickit? 2 enables in-circuit debugging on most pic ? microcon- trollers. in-circuit-debugging runs, halts and single steps the program while the pic microcontroller is embedded in the applicatio n. when halted at a break- point, the file registers ca n be examined and modified. the pickit 2 debug express include the pickit 2, demo board and microcontroller, hookup cables and cdrom with user?s guide, lessons, tutorial, compiler and mplab ide software. 21.12 mplab pm3 device programmer the mplab pm3 device programmer is a universal, ce compliant device programmer with programmable voltage verification at v ddmin and v ddmax for maximum reliability. it features a large lcd display (128 x 64) for menus and error messages and a modu- lar, detachable socket asse mbly to support various package types. the icsp? ca ble assembly is included as a standard item. in stand-alone mode, the mplab pm3 device programmer can read, verify and program pic devices without a pc co nnection. it can also set code protection in this mode. the mplab pm3 connects to the host pc via an rs-232 or usb cable. the mplab pm3 has high-speed communications and optimized algorithms for quick programming of large memory devices and incorpor ates an mmc card for file storage and data applications. 21.13 demonstration/development boards, evaluation kits, and starter kits a wide variety of demons tration, development and evaluation boards for various pic mcus and dspic dscs allows quick application development on fully func- tional systems. most boards include prototyping areas for adding custom circuitry and provide application firmware and source code for examination and modification. the boards support a variety of features, including leds, temperature sensors, sw itches, speakers, rs-232 interfaces, lcd displays, potentiometers and additional eeprom memory. the demonstration and development boards can be used in teaching environments, for prototyping custom circuits and for learning about various microcontroller applications. in addition to the picdem? and dspicdem? demon- stration/development board series of circuits, microchip has a line of evaluation kits and demonstration software for analog filter design, k ee l oq ? security ics, can, irda ? , powersmart battery management, seeval ? evaluation system, sigma-delta adc, flow rate sensing, plus many more. also available are starter kits that contain everything needed to experience the specified device. this usually includes a single application and debug capability, all on one board. check the microchip web page ( www.microchip.com ) for the complete list of demonstration, development and evaluation kits.
? 2007-2011 microchip technology inc. ds70289j-page 199 pic24hj32gp202/204 and pic24hj16gp304 22.0 electrical characteristics this section provides an overview of pic24hj32gp2 02/204 and pic24hj16gp304 el ectrical characteristics. additional information will be provided in future re visions of this document as it becomes available. absolute maximum ratings for the pic24hj32gp202/204 and pic24hj16gp304 family are listed below. exposure to these maximum rating conditions for extended periods can affe ct device reliability. functional operation of the device at these or any other conditions above the parameters indicated in the operation listings of this specification is not implied. absolute maximum ratings (1) ambient temperature under bias................................................................................................. ............-40c to +125c storage temperature ............................................................................................................ .................. -65c to +160c voltage on v dd with respect to v ss ......................................................................................................... -0.3v to +4.0v voltage on any pin that is not 5v tolerant with respect to v ss (4) .................................................... -0.3v to (v dd + 0.3v) voltage on any 5v tolerant pin with respect to v ss when v dd < 3.0v (4) ...................................................... -0.3v to 3.6v voltage on any 5v tolerant pin with respect to vss when v dd 3.0v (4) .................................................... -0.3v to +5.6v maximum current out of v ss pin ........................................................................................................................... 300 ma maximum current into v dd pin (2) ...........................................................................................................................250 ma maximum current sourced/sunk by any 2x i/o pin (3) ................................................................................................8 ma maximum current sourced/sunk by any 4x i/o pin (3) ..............................................................................................15 ma maximum current sourced/sunk by any 8x i/o pin (3) ..............................................................................................25 ma maximum current sunk by all ports ......................... ..................................................................... .........................200 ma maximum current sourced by all ports (2) ...............................................................................................................200 ma note 1: stresses above those listed under ?absolute maximu m ratings? may cause permanent damage to the device. this is a stress rating only, and functional o peration of the device at th ose or any other conditions above those indicated in the operation listings of this specification is not implied. exposure to maximum rating conditions for extended periods may affect device reliability. 2: maximum allowable current is a function of device maximum power dissipation (see table 22-2 ). 3: exceptions are clkout, which is abl e to sink/source 25 ma, and the v ref +, v ref -, sclx, sdax, pgecx and pgedx pins, which are able to sink/source 12 ma. 4: refer to the ? pin diagrams ? section for 5v tolerant pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 200 ? 2007-2011 microchip technology inc. 22.1 dc characteristics table 22-1: operating mips vs. voltage characteristic v dd range (in volts) temp range (in c) max mips pic24hj32gp202/204 and pic24hj16gp304 ? v bor -3.6v (1) -40c to +85c 40 ? v bor -3.6v (1) -40c to +125c 40 note 1: device is functional at v bormin < v dd < v ddmin . analog modules such as the adc will have degraded performance. device functionality is tested but not characterized. refer to parameter bo10 in table 22-11 for the minimum and maximum bor values. table 22-2: thermal operating conditions rating symbol min typ max unit industrial temperature devices operating junction temperature range t j -40 ? +125 c operating ambient temperature range t a -40 ? +85 c extended temperature devices operating junction temperature range t j -40 ? +155 c operating ambient temperature range t a -40 ? +125 c power dissipation: internal chip power dissipation: p int = v dd x (i dd - i oh ) p d p int + p i / o w i/o pin power dissipation: i/o = ({v dd - v oh } x i oh ) + (v ol x i ol ) maximum allowed power dissipation p dmax (t j - t a )/ ja w table 22-3: thermal packaging characteristics characteristic symbol typ max unit notes package thermal resi stance, 44-pin qfn ja 32 ? c/w 1 package thermal resi stance, 44-pin tfqp ja 45 ? c/w 1 package thermal resi stance, 28-pin spdip ja 45 ? c/w 1 package thermal resistance, 28-pin soic ja 50 ? c/w 1 package thermal resi stance, 28-pin ssop ja 71 ? c/w 1 package thermal resist ance, 28-pin qfn-s ja 35 ? c/w 1 note 1: junction to ambient thermal resistance, theta- ja ( ja ) numbers are achieved by package simulations.
? 2007-2011 microchip technology inc. ds70289j-page 201 pic24hj32gp202/204 and pic24hj16gp304 table 22-4: dc temperature and voltage specifications dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (1) max units conditions operating voltage dc10 supply voltage v dd ? 3.0 ? 3.6 v industrial and extended dc12 v dr ram data retention voltage (2) 1.8 ? ? v ? dc16 v por v dd start voltage to ensure internal power-on reset signal ??v ss v? dc17 s vdd v dd rise rate to ensure internal power-on reset signal 0.03 ? ? v/ms 0-3.0v in 0.1s note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: this is the limit to which v dd can be lowered without losing ram data.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 202 ? 2007-2011 microchip technology inc. table 22-5: dc characteristics: operating current (i dd ) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended parameter no. (3) typical (2) max units conditions operating current (i dd ) (1) dc20d 20 30 ma -40c 3.3v 10 mips (3) dc20a 19 22 ma +25c dc20b 19 25 ma +85c dc20c 19 30 ma +125c dc21d 28 40 ma -40c 3.3v 16 mips (3) dc21a 27 30 ma +25c dc21b 27 32 ma +85c dc21c 27 36 ma +125c dc22d 33 50 ma -40c 3.3v 20 mips (3) dc22a 33 40 ma +25c dc22b 33 40 ma +85c dc22c 33 50 ma +125c dc23d 44 60 ma -40c 3.3v 30 mips (3) dc23a 43 50 ma +25c dc23b 42 55 ma +85c dc23c 41 65 ma +125c dc24d 55 75 ma -40c 3.3v 40 mips dc24a 54 65 ma +25c dc24b 52 70 ma +85c dc24c 51 80 ma +125c note 1: i dd is primarily a function of the operating voltage and frequency. other factors, such as i/o pin loading and switching rate, oscillator type, internal code exec ution pattern and temperatur e, also have an impact on the current consumption. t he test conditions for all i dd measurements are as follows: ? oscillator is configured in ec mode with pll, osc1 is driven with external square wave from rail-to- rail (ec clock overshoot/undershoot < 250 mv required) ? clko is configured as an i/o input pin in the configuration word ? all i/o pins are configured as inputs and pulled to v ss ?mclr = v dd , wdt and fscm are disabled ? cpu, sram, program memory and data memory are operational ? no peripheral modules are operating; however, ever y peripheral is being clocked (defined pmdx bits are set to zero and unimplemented pmdx bits are set to one) ? cpu executing while(1) statement ? jtag is disabled 2: these parameters are characterized but not tested in manufacturing. 3: data in ?typ? column is at 3.3v, +25oc unless otherwise stated.
? 2007-2011 microchip technology inc. ds70289j-page 203 pic24hj32gp202/204 and pic24hj16gp304 table 22-6: dc characteristics: idle current (i idle ) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended parameter no. (3) typical (2) max units conditions idle current (i idle ): core off clock on base current (1) dc40d 7 20 ma -40c 3.3v 10 mips (3) dc40a 6 7 ma +25c dc40b 6 10 ma +85c dc40c 6 20 ma +125c dc41d 10 20 ma -40c 3.3v 16 mips (3) dc41a 8 ma +25c 9 dc41b 8 10 ma +85c dc41c 8 20 ma +125c dc42d 11 20 ma -40c 3.3v 20 mips (3) dc42a 10 10 ma +25c dc42b 10 12 ma +85c dc42c 10 20 ma +125c dc43d 14 25 ma -40c 3.3v 30 mips (3) dc43a 13 14 ma +25c dc43b 13 15 ma +85c dc43c 13 25 ma +125c dc44d 14 25 ma -40c 3.3v 40 mips dc44a 17 20 ma +25c dc44b 17 20 ma +85c dc44c 18 30 ma +125c note 1: base i idle current is measured as follows: ? cpu core is off, oscillator is configured in ec mode and external clock active, osc1 is driven with external square wave from rail-to-rail (ec clock overshoot/ undershoot < 250 mv required) ? clko is configured as an i/o input pin in the configuration word ? all i/o pins are configured as inputs and pulled to v ss ?mclr = v dd , wdt and fscm are disabled ? no peripheral modules are operating; however, ever y peripheral is being clocked (defined pmdx bits are set to zero and unimplemented pmdx bits are set to one) ? the nvmsidl bit (nvmcon<12>) = 1 (i.e., flash regulator is set to stand-by while the device is in idle mode) ? jtag is disabled 2: these parameters are characterized but not tested in manufacturing. 3: data in ?typ? column is at 3.3v, +25oc unless otherwise stated.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 204 ? 2007-2011 microchip technology inc. table 22-7: dc characteristics: power-down current (i pd ) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended parameter no. (3) typical (2) max units conditions power-down current (i pd ) (1) dc60d 55 500 a-40c 3.3v base power-down current (3,4) dc60a 63 300 a+25c dc60b 85 350 a+85c dc60c 146 600 a +125c dc61d 8 15 a-40c 3.3v watchdog timer current: i wdt (3,5) dc61a 2 3 a+25c dc61b 2 2 a+85c dc61c 3 5 a +125c note 1: i pd (sleep) current is measured as follows: ? cpu core is off, oscillator is configured in ec m ode and external clock active, osc1 is driven with external square wave from rail-to-rail (ec clock overshoot/unders hoot < 250 mv required) ? clko is configured as an i/o input pin in the configuration word ? all i/o pins are configured as inputs and pulled to v ss ?mclr = v dd , wdt and fscm are disabled, all peripheral modules are disabled (pmdx bits are all ones) ? vregs bit (rcon<8>) = 0 (i.e., core regulator is set to stand-by while the device is in sleep mode) ? rtcc is disabled. ? the vregsf bit (rcon<11>) = 0 (i.e., flash regulator is set to stand-by while the device is in sleep mode) ? jtag is disabled 2: data in the ?typ? column is at 3.3v, +25oc unless otherwise stated. 3: the watchdog timer current is the additional current consumed when the wdt module is enabled. this current should be added to the base i pd current. 4: these currents are measured on the device c ontaining the most memory in this family. 5: these parameters are characterized, but are not tested in manufacturing.
? 2007-2011 microchip technology inc. ds70289j-page 205 pic24hj32gp202/204 and pic24hj16gp304 table 22-8: dc characteristics: doze current (i doze ) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended parameter no. (3) typical (2) max doze ratio units conditions doze current (i doze ) (1) dc73a 41 51 1:2 ma -40c 3.3v 40 mips dc73f 20 28 1:64 ma dc73g 19 24 1:128 ma dc70a 40 46 1:2 ma +25c 3.3v 40 mips dc70f 18 20 1:64 ma dc70g 18 20 1:128 ma dc71a 40 46 1:2 ma +85c 3.3v 40 mips dc71f 18 25 1:64 ma dc71g 18 20 1:128 ma dc72a 39 55 1:2 ma +125c 3.3v 40 mips dc72f 18 30 1:64 ma dc72g 18 25 1:128 ma note 1: i doze is primarily a function of the operating voltage and frequency. other factors, such as i/o pin loading and switching rate, oscillato r type, internal code execution pattern and temperature, also have an impact on the current consumption. t he test conditions for all i doze measurements are as follows: ? oscillator is configured in ec mode and external clock active, osc1 is driven with external square wave from rail-to-rail with overshoot/undershoot < 250 mv ? clko is configured as an i/o input pin in the configuration word ? all i/o pins are configured as inputs and pulled to v ss ?mclr = v dd , wdt and fscm are disabled ? cpu, sram, program memory and data memory are operational ? no peripheral modules are operating; however, ever y peripheral is being clocked (defined pmdx bits are set to zero and unimplemented pmdx bits are set to one) ? cpu executing while(1) statement ? jtag is disabled 2: data in the ?typ? column is at 3.3v, +25oc unless otherwise stated.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 206 ? 2007-2011 microchip technology inc. table 22-9: dc characteristics: i/o pin input specifications dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (1) max units conditions v il input low voltage di10 i/o pins v ss ?0.2v dd v di15 mclr v ss ?0.2v dd v di16 i/o pins with osc1 or sosci v ss ?0.2v dd v di18 sdax, sclx v ss ? 0.3 v dd v smbus disabled di19 sdax, sclx v ss ? 0.8 v smbus enabled v ih input high voltage di20 i/o pins not 5v tolerant (4) i/o pins 5v tolerant (4) 0.7 v dd 0.7 v dd ? ? v dd 5.5 v v ? di28 sdax, sclx 0.7 v dd ? 5.5 v smbus disabled di29 sdax, sclx 2.1 ? 5.5 v smbus enabled i cnpu cnx pull-up current di30 50 250 400 av dd = 3.3v, v pin = v ss note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: the leakage current on the mclr pin is strongly dependent on the applied voltage level. the specified levels represent normal operating conditions. higher le akage current may be measured at different input voltages. 3: negative current is defined as current sourced by the pin. 4: see the ? pin diagrams ? section for a list of digital-only and analog pins. 5: v il source < (v ss ? 0.3). characterized but not tested. 6: non-5v tolerant pins v ih source > (v dd + 0.3), 5v tolerant pins v ih source > 5v or devices with usb, ?d+? and ?d-? v ih source > (v usb + 0.3). characterized but not tested. 7: digital 5v tolerant pins cannot tolerate any ?posit ive? input injection current from input sources > 5v. 8: injection currents > | 0 | can affect the adc results by approximately 4-6 counts. 9: any number and/or combination of i/o pins not excluded under i icl or i ich conditions are permitted pro- vided the mathematical ?absolute instantaneous? sum of the input injection currents from all pins do not exceed the specified limit. characterized but not tested.
? 2007-2011 microchip technology inc. ds70289j-page 207 pic24hj32gp202/204 and pic24hj16gp304 i il input leakage current (2,3) di50 i/o pins 5v tolerant (4) ??2 av ss v pin v dd , pin at high-impedance di51 i/o pins not 5v tolerant (4) ??1 av ss v pin v dd , pin at high-impedance, -40c t a +85c di51a i/o pins not 5v tolerant (4) ??2 a shared with external refer- ence pins, -40c t a +85c di51b i/o pins not 5v tolerant (4) ??3.5 av ss v pin v dd , pin at high-impedance, -40c t a +125c di51c i/o pins not 5v tolerant (4) ??8 a analog pins shared with external reference pins, -40c t a +125c di55 mclr ??2 av ss v pin v dd di56 osc1 ? ? 2 av ss v pin v dd , xt and hs modes table 22-9: dc characteristics: i/o pi n input specifications (continued) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (1) max units conditions note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: the leakage current on the mclr pin is strongly dependent on the app lied voltage level. the specified levels represent normal operating co nditions. higher leakage current may be measured at different input voltages. 3: negative current is defined as current sourced by the pin. 4: see the ? pin diagrams ? section for a list of digital-only and analog pins. 5: v il source < (v ss ? 0.3). characterized but not tested. 6: non-5v tolerant pins v ih source > (v dd + 0.3), 5v tolerant pins v ih source > 5v or devices with usb, ?d+? and ?d-? v ih source > (v usb + 0.3). characterized but not tested. 7: digital 5v tolerant pins cannot tolerate any ?posit ive? input injection current from input sources > 5v. 8: injection currents > | 0 | can affect the adc results by approximately 4-6 counts. 9: any number and/or combination of i/o pins not excluded under i icl or i ich conditions are permitted pro- vided the mathematical ?absolute instantaneous? sum of the input injection currents from all pins do not exceed the specified limit. characterized but not tested.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 208 ? 2007-2011 microchip technology inc. i icl input low injection current di60a 0?-5 (5,8) ma all pins except v dd , v ss , av dd , av ss , mclr , v cap , sosci, sosco, and rb14 i ich input high injection current di60b 0?+5 (6,7,8) ma all pins except v dd , v ss , av dd , av ss , mclr , v cap , sosci, sosco, rb14, and digital 5v-tolerant designated pins i ict total input injection current di60c (sum of all i/o and control pins) -20 (9) ?+20 (9) ma absolute instantaneous sum of all input injection currents from all i/o pins (| i icl + | i ich |) i ict table 22-9: dc characteristics: i/o pin input specifications (continued) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (1) max units conditions note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: the leakage current on the mclr pin is strongly dependent on the applied voltage level. the specified levels represent normal operating conditions. higher le akage current may be measured at different input voltages. 3: negative current is defined as current sourced by the pin. 4: see the ? pin diagrams ? section for a list of digital-only and analog pins. 5: v il source < (v ss ? 0.3). characterized but not tested. 6: non-5v tolerant pins v ih source > (v dd + 0.3), 5v tolerant pins v ih source > 5v or devices with usb, ?d+? and ?d-? v ih source > (v usb + 0.3). characterized but not tested. 7: digital 5v tolerant pins cannot tolerate any ?posit ive? input injection current from input sources > 5v. 8: injection currents > | 0 | can affect the adc results by approximately 4-6 counts. 9: any number and/or combination of i/o pins not excluded under i icl or i ich conditions are permitted pro- vided the mathematical ?absolute instantaneous? sum of the input injection currents from all pins do not exceed the specified limit. characterized but not tested.
? 2007-2011 microchip technology inc. ds70289j-page 209 pic24hj32gp202/204 and pic24hj16gp304 table 22-10: dc characteristics: i/o pin output specifications dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param. symbol characteristic mi n. typ. max. units conditions do10 v ol output low voltage i/o pins: 2x sink driver pins - all pins not defined by 4x or 8x driver pins ??0.4v i ol 3 ma, v dd = 3.3v output low voltage i/o pins: 4x sink driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 ??0.4v i ol 6 ma, v dd = 3.3v output low voltage i/o pins: 8x sink driver pins - osco, clko, ra3 ??0.4vi ol 10 ma, v dd = 3.3v do20 v oh output high voltage i/o pins: 2x source driver pins - all pins not defined by 4x or 8x driver pins 2.4 ? ? v i ol -3 ma, v dd = 3.3v output high voltage i/o pins: 4x source driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 2.4 ? ? v i ol -6 ma, v dd = 3.3v output high voltage i/o pins: 8x source driver pins - osco, clko, ra3 2.4 ? ? v i ol -10 ma, v dd = 3.3v do20a v oh 1 output high voltage i/o pins: 2x source driver pins - all pins not defined by 4x or 8x driver pins 1.5 ? ? v i oh -6 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -5 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -2 ma, v dd = 3.3v see note 1 output high voltage 4x source driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 1.5 ? ? v i oh -12 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -11 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -3 ma, v dd = 3.3v see note 1 output high voltage 8x source driver pins - osco, clko, ra3 1.5 ? ? v i oh -16 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -12 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -4 ma, v dd = 3.3v see note 1 note 1: parameters are characterized, but not tested.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 210 ? 2007-2011 microchip technology inc. table 22-11: electrical characteristics: bor dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ max units conditions bo10 v bor bor event on v dd transition high-to-low 2.40 ? 2.55 v see note 2 note 1: parameters are for design guidance only and are not tested in manufacturing. 2: device is functional at v bormin < v dd < v ddmin . analog modules such as the adc will have degraded performance. device functionality is tested but not characterized. table 22-12: dc characteristics: program memory dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (3) min typ (1) max units conditions program flash memory d130 e p cell endurance 10,000 ? ? e/w -40 c to +125 c d131 v pr v dd for read v min ?3.6vv min = minimum operating voltage d132b v pew v dd for self-timed write v min ?3.6vv min = minimum operating voltage d134 t retd characteristic retention 20 ? ? year provided no other specifications are violated, -40 c to +125 c d135 i ddp supply current during programming ?10 ?ma d136a t rw row write time 1.32 ? 1.74 ms t rw = 11064 frc cycles, t a = +85c, see note 2 d136b t rw row write time 1.28 ? 1.79 ms t rw = 11064 frc cycles, t a = +150c, see note 2 d137a t pe page erase time 20.1 ? 26.5 ms t pe = 168517 frc cycles, t a = +85c, see note 2 d137b t pe page erase time 19.5 ? 27.3 ms t pe = 168517 frc cycles, t a = +150c, see note 2 d138a t ww word write cycle time 42.3 ? 55.9 st ww = 355 frc cycles, t a = +85c, see note 2 d138b t ww word write cycle time 41.1 ? 57.6 st ww = 355 frc cycles, t a = +150c, see note 2 note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: other conditions: frc = 7.37 mhz, tun<5:0> = b'011111 (for min), tun<5:0> = b'100000 (for max). this parameter depends on the frc accuracy (see table 22-18 ) and the value of the frc oscillator tun- ing register (see register 8-4 ). for complete details on calculatin g the minimum and maximum time see section 5.3 ?programming operations? . 3: these parameters are assured by design, but are not characterized or tested in manufacturing.
? 2007-2011 microchip technology inc. ds70289j-page 211 pic24hj32gp202/204 and pic24hj16gp304 table 22-13: internal voltage regulator specifications standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristics min typ max units comments ? c efc external filter capacitor value (1) 4.7 10 ? f capacitor must be low series resistance (< 5 ohms) note 1: typical v cap voltage = 2.5v when v dd v ddmin .
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 212 ? 2007-2011 microchip technology inc. 22.2 ac characteristics and timing parameters the information contained in this section defines pic24hj32gp202/204 and pic24hj16gp304 ac characteristics and timing parameters. table 22-14: temperature and voltage specifications ? ac figure 22-1: load conditions for device timing specifications table 22-15: capacitive loading requirements on output pins ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended operating voltage v dd range as described in table 22-1 . param no. symbol characteristic min typ max units conditions do50 c osc 2 osc2/sosc2 pin ? ? 15 pf in xt and hs modes when external clock is used to drive osc1 do56 c io all i/o pins and osc2 ? ? 50 pf ec mode do58 c b sclx, sdax ? ? 400 pf in i 2 c? mode v dd /2 c l r l pin pin v ss v ss c l r l =464 c l = 50 pf for all pins except osc2 15 pf for osc2 output load condition 1 ? for all pins except osc2 load condition 2 ? for osc2
? 2007-2011 microchip technology inc. ds70289j-page 213 pic24hj32gp202/204 and pic24hj16gp304 figure 22-2: external clock timing table 22-16: external clock timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symb characteristic min typ (1) max units conditions os10 f in external clki frequency (external clocks allowed only in ec and ecpll modes) (4) dc ? 40 mhz ec oscillator crystal frequency (5) 3.5 10 ? ? ? 10 40 33 mhz mhz khz xt hs sosc os20 t osc t osc = 1/f osc (4) 12.5 ? dc ns ? os25 t cy instruction cycle time (2,4) 25 ? dc ns ? os30 tosl, to s h external clock in (osc1) (5) high or low time 0.375 x t osc ? 0.625 x t osc ns ec os31 tosr, to s f external clock in (osc1) (5) rise or fall time ??20nsec os40 tckr clko rise time (3,5) ?5.2?ns ? os41 tckf clko fall time (3,5) ?5.2?ns ? os42 g m external oscillator transconductance (6) 14 16 18 ma/v v dd = 3.3v t a = +25oc note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: instruction cycle period (t cy ) equals two times the input oscillator time-base period. all specified values are based on characterization data fo r that particular oscillator type under standard operating conditions with the device executing code. exc eeding these specified limits can result in an unstable oscillator operation and/or higher than expected current consumption. all devices are tested to operate at ?min.? values with an external clock applied to the osc1/c lki pin. when an external clock input is used, the ?max.? cycle time limit is ?dc? (no clock) for all devices. 3: measurements are taken in ec mode. the cl ko signal is measured on the osc2 pin. 4: these parameters are characterized by simila rity, but are tested in manufacturing at f in = 40 mhz only. 5: these parameters are characterized by simila rity, but are not tested in manufacturing. 6: data for this parameter is preliminar y. this parameter is characterized, but is not tested in manufacturing. q1 q2 q3 q4 osc1 clko q1 q2 q3 q4 os20 os25 os30 os30 os40 os41 os31 os31
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 214 ? 2007-2011 microchip technology inc. table 22-17: pll clock timing specifications (v dd = 3.0v to 3.6v) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (1) max units conditions os50 f plli pll voltage controlled oscillator (vco) input frequency range (2) 0.8 ? 8 mhz ecpll, xtpll modes os51 f sys on-chip vco system frequency (3) 100 ? 200 mhz ? os52 t lock pll start-up time (lock time) (3) 0.9 1.5 3.1 ms ? os53 d clk clko stability (jitter) (3) -3 0.5 3 % measured over 100 ms period note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: these parameters are characterized by similarity, bu t are tested in manufacturing at 7.7 mhz input only. 3: these parameters are characterized by similarity, but ar e not tested in manufacturi ng. this specification is based on clock cycle by clock cycle meas urements. to calculate the effectiv e jitter for indivi dual time bases or communication clocks use this formula: peripheral clock jitter d clk f osc peripheral bit rate clock -------------------------------------------------------------- ?? ?? ----------------------------------------------------------------------- - = for example: fosc = 32 mhz, d clk = 3%, spi bit rate clock, (i.e., sck) is 2 mhz. spi sck jitter d clk 32 mhz 2 mhz -------------------- ?? ?? ------------------------------ 3% 16 --------- - 3% 4 ------- - 0.75% ==== table 22-18: ac characteristics: internal rc accuracy ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. characteristic min typ max units conditions internal frc accuracy @ frc frequency = 7.37 mhz (1) f20a frc -2 ? +2 % -40c t a +85c v dd = 3.0-3.6v f20b frc -5 ? +5 % -40c t a +125c v dd = 3.0-3.6v note 1: frequency calibrated at 25c and 3.3v. tun bits can be used to compensate for temperature drift. table 22-19: internal rc accuracy ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. characteristic min typ max units conditions lprc @ 32.768 khz (1,2) f21a lprc -15 6 +15 % -40c t a +85c v dd = 3.0-3.6v f21b lprc -40 ? +40 % -40c t a +125c v dd = 3.0-3.6v note 1: change of lprc frequency as v dd changes. 2: lprc accuracy impacts the watchdog timer time-out period (t wdt 1). see section 19.4 ?watchdog timer (wdt)? for more information.
? 2007-2011 microchip technology inc. ds70289j-page 215 pic24hj32gp202/204 and pic24hj16gp304 figure 22-3: i/o timing characteristics table 22-20: i/o timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (2) min typ (1) max units conditions do31 t io r port output rise time ? 10 25 ns ? do32 t io f port output fall time ? 10 25 ns ? di35 t inp intx pin high or low time (input) 25 ? ? ns ? di40 t rbp cnx high or low time (input) 2 ? ? t cy ? note 1: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 2: these parameters are characterized, but are not tested in manufacturing. note: refer to figure 22-1 for load conditions. i/o pin (input) i/o pin (output) di35 old value new value di40 do31 do32
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 216 ? 2007-2011 microchip technology inc. figure 22-4: reset, watchdog timer, oscillator start-up timer and power-up timer timing characteristics v dd mclr internal por pwrt time-out osc time-out internal reset watchdog timer reset sy11 sy10 sy20 sy13 i/o pins sy13 note: refer to figure 22-1 for load conditions. fscm delay sy35 sy30 sy12
? 2007-2011 microchip technology inc. ds70289j-page 217 pic24hj32gp202/204 and pic24hj16gp304 table 22-21: reset, watchdog timer, osci llator start-up timer, power-up timer timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min typ (2) max units conditions sy10 t mc lmclr pulse-width (low) (1) 2 ? ? s -40c to +85c sy11 t pwrt power-up timer period (1) ?2 4 8 16 32 64 128 ? ms -40c to +85c user programmable sy12 t por power-on reset delay (3) 31030 s -40c to +85c sy13 t ioz i/o high-impedance from mclr low or watchdog timer reset (1) 0.68 0.72 1.2 s? sy20 t wdt 1 watchdog timer time-out period (1) ???mssee section 19.4 ?watchdog timer (wdt)? and lprc specification f21a ( table 22-19 ). sy30 t ost oscillator start-up time ? 1024 t osc ??t osc = osc1 period sy35 t fscm fail-safe clock monitor delay (1) ? 500 900 s -40c to +85c note 1: these parameters are characterized but not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: these parameters are characterized by simila rity, but are not tested in manufacturing.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 218 ? 2007-2011 microchip technology inc. figure 22-5: timer1, 2 and 3 external clock timing characteristics table 22-22: timer1 external clock timing requirements (1) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (2) min typ max units conditions ta10 t tx h txck high time synchronous, no prescaler 0.5 t cy + 20 ? ? ns must also meet parameter ta15 synchronous, with prescaler 10 ? ? ns asynchronous 10 ? ? ns ta11 t tx l txck low time synchronous, no prescaler 0.5 t cy + 20 ? ? ns must also meet parameter ta15 synchronous, with prescaler 10 ? ? ns asynchronous 10 ? ? ns ta15 t tx p txck input period synchronous, no prescaler t cy + 40 ? ? ns ? synchronous, with prescaler greater of: 20 ns or (t cy + 40)/n ? ? ? n = prescale value (1, 8, 64, 256) asynchronous 20 ? ? ns ? os60 ft1 sosc1/t1ck oscillator input frequency range (oscillator enabled by setting bit tcs (t1con<1>)) dc ? 50 khz ? ta20 t ckextmrl delay from external txck clock edge to timer increment 0.5 t cy 1.5 t cy ?? note 1: timer1 is a type a. 2: these parameters are characterized by simila rity, but are not tested in manufacturing. note: refer to figure 22-1 for load conditions. tx11 tx15 tx10 tx20 tmrx os60 txck
? 2007-2011 microchip technology inc. ds70289j-page 219 pic24hj32gp202/204 and pic24hj16gp304 table 22-23: timer2 external clock timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ max units conditions tb10 ttxh txck high time synchronous mode greater of: 20 or (t cy + 20)/n ??ns must also meet parameter tb15 n = prescale value (1, 8, 64, 256) tb11 ttxl txck low time synchronous mode greater of: 20 or (t cy + 20)/n ? ? ns must also meet parameter tb15 n = prescale value (1, 8, 64, 256) tb15 ttxp txck input period synchronous mode greater of: 40 or (2 t cy + 40)/n ? ? ns n = prescale value (1, 8, 64, 256) tb20 t ckextmrl delay from external txck clock edge to timer incre- ment 0.75 t cy + 40 ? 1.75 t cy + 40 ns note 1: these parameters are characterized, but are not tested in manufacturing. table 22-24: timer3 external clock timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ max units conditions tc10 ttxh txck high time synchronous t cy + 20 ? ? ns must also meet parameter tc15 tc11 ttxl txck low time synchronous t cy + 20 ? ? ns must also meet parameter tc15 tc15 ttxp txck input period synchronous, with prescaler 2 t cy + 40 ? ? ns n = prescale value (1, 8, 64, 256) tc20 t ckextmrl delay from external txck clock edge to timer incre- ment 0.75 t cy + 40 ? 1.75 t cy + 40 ns note 1: these parameters are characterized, but are not tested in manufacturing.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 220 ? 2007-2011 microchip technology inc. figure 22-6: input capture (capx) timing characteristics figure 22-7: output compare module (ocx) timing characteristics table 22-25: input capture timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min max units conditions ic10 tccl icx input low time no prescaler 0.5 t cy + 20 ? ns ? with prescaler 10 ? ns ic11 tcch icx input high time no prescaler 0.5 t cy + 20 ? ns ? with prescaler 10 ? ns ic15 tccp icx input period (t cy + 40)/n ? ns n = prescale value (1, 4, 16) note 1: these parameters are characterized but not tested in manufacturing. table 22-26: output compare module timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ max units conditions oc10 tccf ocx output fall time ? ? ? ns see parameter d032 oc11 tccr ocx output rise time ? ? ? ns see parameter d031 note 1: these parameters are characterized but not tested in manufacturing. icx ic10 ic11 ic15 note: refer to figure 22-1 for load conditions. ocx oc11 oc10 (output compare note: refer to figure 22-1 for load conditions. or pwm mode)
? 2007-2011 microchip technology inc. ds70289j-page 221 pic24hj32gp202/204 and pic24hj16gp304 figure 22-8: oc/pwm module ti ming characteristics table 22-27: simple oc/pwm mode timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ max units conditions oc15 t fd fault input to pwm i/o change ??t cy + 20 ns ? oc20 t flt fault input pulse-width t cy + 20 ? ? ns ? note 1: these parameters are characterized but not tested in manufacturing. ocfa/ocfb ocx oc20 oc15
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 222 ? 2007-2011 microchip technology inc. table 22-28: spix maximum data/clock rate summary figure 22-9: spix master mode (ha lf-duplex, transmit only cke = 0 ) timing characteristics ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended maximum data rate master transmit only (half-duplex) master transmit/receive (full-duplex) slave transmit/receive (full-duplex) cke ckp smp 15 mhz table 22-29 ?? 0 , 10 , 10 , 1 9 mhz ? table 22-30 ? 10 , 11 9 mhz ? table 22-31 ? 00 , 11 15 mhz ? ? table 22-32 100 11 mhz ? ? table 22-33 110 15 mhz ? ? table 22-34 010 11 mhz ? ? table 22-35 000 sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sp10 sp21 sp20 sp35 sp20 sp21 msb lsb bit 14 - - - - - -1 sp30, sp31 sp30, sp31 note: refer to figure 22-1 for load conditions.
? 2007-2011 microchip technology inc. ds70289j-page 223 pic24hj32gp202/204 and pic24hj16gp304 figure 22-10: spix master mode (h alf-duplex, transmit only cke = 1 ) timing characteristics table 22-29: spix master mode (half-dupl ex, transmit only) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp10 tscp maximum sck frequency ? ? 15 mhz see note 3 sp20 tscf sckx output fall time ? ? ? ns see parameter do32 and note 4 sp21 tscr sckx output rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?620ns ? sp36 tdiv2sch, tdiv2scl sdox data output setup to first sckx edge 30 ? ? ns ? note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 66.7 ns. theref ore, the clock generated in master mode must not violate this specification. 4: assumes 50 pf load on all spix pins. sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sp10 sp21 sp20 sp35 sp20 sp21 msb lsb bit 14 - - - - - -1 sp30, sp31 note: refer to figure 22-1 for load conditions. sp36
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 224 ? 2007-2011 microchip technology inc. figure 22-11: spix master mode (full-duplex, cke = 1 , ckp = x , smp = 1 ) timing characteristics table 22-30: spix master mode (full-duplex, cke = 1 , ckp = x , smp = 1 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp10 tscp maximum sck frequency ? ? 9 mhz see note 3 sp20 tscf sckx output fall time ? ? ? ns see parameter do32 and note 4 sp21 tscr sckx output rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ? 6 20 ns ? sp36 tdov2sc, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 111 ns. the clock generated in master mode must not violate this specification. 4: assumes 50 pf load on all spix pins. sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sp10 sp21 sp20 sp35 sp20 sp21 msb lsb bit 14 - - - - - -1 sp30, sp31 note: refer to figure 22-1 for load conditions. sp36 sp41 msb in lsb in bit 14 - - - -1 sdix sp40
? 2007-2011 microchip technology inc. ds70289j-page 225 pic24hj32gp202/204 and pic24hj16gp304 figure 22-12: spix master mode (full-duplex, cke = 0 , ckp = x , smp = 1 ) timing characteristics table 22-31: spix master mo de (full-duplex, cke = 0 , ckp = x , smp = 1 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp10 tscp maximum sck frequency ? ? 9 mhz -40oc to +125oc and see note 3 sp20 tscf sckx output fall time ? ? ? ns see parameter do32 and note 4 sp21 tscr sckx output rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ? 6 20 ns ? sp36 tdov2sch, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 111 ns. the clock generated in master mode must not violate this specification. 4: assumes 50 pf load on all spix pins. sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sdix sp10 sp40 sp41 sp21 sp20 sp35 sp20 sp21 msb lsb bit 14 - - - - - -1 msb in lsb in bit 14 - - - -1 sp30, sp31 sp30, sp31 note: refer to figure 22-1 for load conditions.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 226 ? 2007-2011 microchip technology inc. figure 22-13: spix slave mode (full-duplex, cke = 1 , ckp = 0 , smp = 0 ) timing characteristics ssx sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sdi sp50 sp60 sdix sp30,sp31 msb bit 14 - - - - - -1 lsb sp51 msb in bit 14 - - - -1 lsb in sp35 sp52 sp73 sp72 sp72 sp73 sp70 sp40 sp41 note: refer to figure 22-1 for load conditions.
? 2007-2011 microchip technology inc. ds70289j-page 227 pic24hj32gp202/204 and pic24hj16gp304 table 22-32: spix slave mo de (full-duplex, cke = 1 , ckp = 0 , smp = 0 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp70 tscp maximum sck input frequency ? ? 15 mhz see note 3 sp72 tscf sckx input fall time ? ? ? ns see parameter do32 and note 4 sp73 tscr sckx input rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?620ns ? sp36 tdov2sch, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? sp50 tssl2sch, tssl2scl ssx to sckx or sckx input 120 ? ? ns ? sp51 tssh2doz ssx to sdox output high-impedance (4) 10 ? 50 ns ? sp52 tsch2ssh tscl2ssh ssx after sckx edge 1.5 t cy + 40 ? ? ns see note 4 sp60 tssl2dov sdox data output valid after ssx edge ??50ns ? note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 66.7 ns. ther efore, the sck clock gener ated by the master must not violate this specification. 4: assumes 50 pf load on all spix pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 228 ? 2007-2011 microchip technology inc. figure 22-14: spix slave mode (full-duplex, cke = 1 , ckp = 1 , smp = 0 ) timing characteristics ssx sckx (ckp = 0 ) sckx (ckp = 1 ) sdox sdi sp50 sp60 sdix sp30,sp31 msb bit 14 - - - - - -1 lsb sp51 msb in bit 14 - - - -1 lsb in sp35 sp52 sp52 sp73 sp72 sp72 sp73 sp70 sp40 sp41 note: refer to figure 22-1 for load conditions.
? 2007-2011 microchip technology inc. ds70289j-page 229 pic24hj32gp202/204 and pic24hj16gp304 table 22-33: spix slave mo de (full-duplex, cke = 1 , ckp = 1 , smp = 0 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp70 tscp maximum sck input frequency ? ? 11 mhz see note 3 sp72 tscf sckx input fall time ? ? ? ns see parameter do32 and note 4 sp73 tscr sckx input rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?620ns ? sp36 tdov2sch, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? sp50 tssl2sch, tssl2scl ssx to sckx or sckx input 120 ? ? ns ? sp51 tssh2doz ssx to sdox output high-impedance (4) 10 ? 50 ns ? sp52 tsch2ssh tscl2ssh ssx after sckx edge 1.5 t cy + 40 ? ? ns see note 4 sp60 tssl2dov sdox data output valid after ssx edge ??50ns ? note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 91 ns. theref ore, the sck clock generated by the master must not violate this specification. 4: assumes 50 pf load on all spix pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 230 ? 2007-2011 microchip technology inc. figure 22-15: spix slave mode (full-duplex cke = 0 , ckp = 1 , smp = 0 ) timing characteristics ss x sck x (ckp = 0 ) sck x (ckp = 1 ) sdo x sp50 sp40 sp41 sp30,sp31 sp51 sp35 msb lsb bit 14 - - - - - -1 msb in bit 14 - - - -1 lsb in sp52 sp73 sp72 sp72 sp73 sp70 note: refer to figure 22-1 for load conditions. sdi x
? 2007-2011 microchip technology inc. ds70289j-page 231 pic24hj32gp202/204 and pic24hj16gp304 table 22-34: spix slave mo de (full-duplex, cke = 0 , ckp = 1 , smp = 0 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp70 tscp maximum sck input frequency ? ? 15 mhz see note 3 sp72 tscf sckx input fall time ? ? ? ns see parameter do32 and note 4 sp73 tscr sckx input rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?620ns ? sp36 tdov2sch, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? sp50 tssl2sch, tssl2scl ssx to sckx or sckx input 120 ? ? ns ? sp51 tssh2doz ssx to sdox output high-impedance (4) 10 ? 50 ns ? sp52 tsch2ssh tscl2ssh ssx after sckx edge 1.5 t cy + 40 ? ? ns see note 4 note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 66.7 ns. ther efore, the sck clock gener ated by the master must not violate this specification. 4: assumes 50 pf load on all spix pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 232 ? 2007-2011 microchip technology inc. figure 22-16: spix slave mode (full-duplex, cke = 0 , ckp = 0 , smp = 0 ) timing characteristics ss x sck x (ckp = 0 ) sck x (ckp = 1 ) sdo x sp50 sp40 sp41 sp30,sp31 sp51 sp35 msb lsb bit 14 - - - - - -1 msb in bit 14 - - - -1 lsb in sp52 sp73 sp72 sp72 sp73 sp70 note: refer to figure 22-1 for load conditions. sdi x
? 2007-2011 microchip technology inc. ds70289j-page 233 pic24hj32gp202/204 and pic24hj16gp304 table 22-35: spix slave mo de (full-duplex, cke = 0 , ckp = 0 , smp = 0 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (1) min typ (2) max units conditions sp70 tscp maximum sck input frequency ? ? 11 mhz see note 3 sp72 tscf sckx input fall time ? ? ? ns see parameter do32 and note 4 sp73 tscr sckx input rise time ? ? ? ns see parameter do31 and note 4 sp30 tdof sdox data output fall time ? ? ? ns see parameter do32 and note 4 sp31 tdor sdox data output rise time ? ? ? ns see parameter do31 and note 4 sp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?620ns ? sp36 tdov2sch, tdov2scl sdox data output setup to first sckx edge 30 ? ? ns ? sp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 30 ? ? ns ? sp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 30 ? ? ns ? sp50 tssl2sch, tssl2scl ssx to sckx or sckx input 120 ? ? ns ? sp51 tssh2doz ssx to sdox output high-impedance (4) 10 ? 50 ns ? sp52 tsch2ssh tscl2ssh ssx after sckx edge 1.5 t cy + 40 ? ? ns see note 4 note 1: these parameters are characterized, but are not tested in manufacturing. 2: data in ?typ? column is at 3.3v, 25c unless otherwise stated. 3: the minimum clock period for sckx is 91 ns. theref ore, the sck clock generated by the master must not violate this specification. 4: assumes 50 pf load on all spix pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 234 ? 2007-2011 microchip technology inc. figure 22-17: i2cx bus start/stop bits timing characteristics (master mode) figure 22-18: i2cx bus data timing characteristics (master mode) im31 im34 sclx sdax start condition stop condition im30 im33 note: refer to figure 22-1 for load conditions. im11 im10 im33 im11 im10 im20 im26 im25 im40 im40 im45 im21 sclx sdax in sdax out note: refer to figure 22-1 for load conditions.
? 2007-2011 microchip technology inc. ds70289j-page 235 pic24hj32gp202/204 and pic24hj16gp304 table 22-36: i2cx bus data timing requirements (master mode) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic (3) min (1) max units conditions im10 t lo : scl clock low time 100 khz mode t cy /2 (brg + 1) ? s? 400 khz mode t cy /2 (brg + 1) ? s? 1 mhz mode (2) t cy /2 (brg + 1) ? s? im11 t hi : scl clock high time 100 khz mode t cy /2 (brg + 1) ? s? 400 khz mode t cy /2 (brg + 1) ? s? 1 mhz mode (2) t cy /2 (brg + 1) ? s? im20 t f : scl sdax and sclx fall time 100 khz mode ? 300 ns c b is specified to be from 10 to 400 pf 400 khz mode 20 + 0.1 c b 300 ns 1 mhz mode (2) ? 100 ns im21 t r : scl sdax and sclx rise time 100 khz mode ? 1000 ns c b is specified to be from 10 to 400 pf 400 khz mode 20 + 0.1 c b 300 ns 1 mhz mode (2) ? 300 ns im25 t su : dat data input setup time 100 khz mode 250 ? ns ? 400 khz mode 100 ? ns 1 mhz mode (2) 40 ? ns im26 t hd : dat data input hold time 100 khz mode 0 ? s? 400 khz mode 0 0.9 s 1 mhz mode (2) 0.2 ? s im30 t su : sta start condition setup time 100 khz mode t cy /2 (brg + 1) ? s only relevant for repeated start condition 400 khz mode t cy /2 (brg + 1) ? s 1 mhz mode (2) t cy /2 (brg + 1) ? s im31 t hd : sta start condition hold time 100 khz mode t cy /2 (brg + 1) ? s after this period the first clock pulse is generated 400 khz mode t cy /2 (brg + 1) ? s 1 mhz mode (2) t cy /2 (brg + 1) ? s im33 t su : sto stop condition setup time 100 khz mode t cy /2 (brg + 1) ? s? 400 khz mode t cy /2 (brg + 1) ? s 1 mhz mode (2) t cy /2 (brg + 1) ? s im34 t hd : sto stop condition 100 khz mode t cy /2 (brg + 1) ? ns ? hold time 400 khz mode t cy /2 (brg + 1) ? ns 1 mhz mode (2) t cy /2 (brg + 1) ? ns im40 t aa : scl output valid from clock 100 khz mode ? 3500 ns ? 400 khz mode ? 1000 ns ? 1 mhz mode (2) ? 400 ns ? im45 t bf : sda bus free time 100 khz mode 4.7 ? s time the bus must be free before a new transmission can start 400 khz mode 1.3 ? s 1 mhz mode (2) 0.5 ? s im50 c b bus capacitive loading ? 400 pf ? im51 t pgd pulse gobbler delay 65 390 ns see note 4 note 1: brg is the value of the i 2 c baud rate generator. refer to section 19. ?inter-integrated circuit (i 2 c?)? (ds70195) in the ?dspic33f/pic24h family reference manual?. 2: maximum pin capacitance = 10 pf for all i2cx pins (for 1 mhz mode only). 3: these parameters are characterized by simila rity, but are not tested in manufacturing. 4: typical value for this parameter is 130 ns.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 236 ? 2007-2011 microchip technology inc. figure 22-19: i2cx bus start/stop bits timing characteristics (slave mode) figure 22-20: i2cx bus data timing characteristics (slave mode) is31 is34 sclx sdax start condition stop condition is30 is33 is30 is31 is33 is11 is10 is20 is26 is25 is40 is40 is45 is21 sclx sdax in sdax out
? 2007-2011 microchip technology inc. ds70289j-page 237 pic24hj32gp202/204 and pic24hj16gp304 table 22-37: i2cx bus data timing requirements (slave mode) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param symbol characteristic (2) min max units conditions is10 t lo : scl clock low time 100 khz mode 4.7 ? s device must operate at a minimum of 1.5 mhz 400 khz mode 1.3 ? s device must operate at a minimum of 10 mhz 1 mhz mode (1) 0.5 ? s? is11 t hi : scl clock high time 100 khz mode 4.0 ? s device must operate at a minimum of 1.5 mhz 400 khz mode 0.6 ? s device must operate at a minimum of 10 mhz 1 mhz mode (1) 0.5 ? s? is20 t f : scl sdax and sclx fall time 100 khz mode ? 300 ns c b is specified to be from 10 to 400 pf 400 khz mode 20 + 0.1 c b 300 ns 1 mhz mode (1) ? 100 ns is21 t r : scl sdax and sclx rise time 100 khz mode ? 1000 ns c b is specified to be from 10 to 400 pf 400 khz mode 20 + 0.1 c b 300 ns 1 mhz mode (1) ? 300 ns is25 t su : dat data input setup time 100 khz mode 250 ? ns ? 400 khz mode 100 ? ns 1 mhz mode (1) 100 ? ns is26 t hd : dat data input hold time 100 khz mode 0 0 s? 400 khz mode 0 0.9 s 1 mhz mode (1) 00.3 s is30 t su : sta start condition setup time 100 khz mode 4.7 ? s only relevant for repeated start condition 400 khz mode 0.6 ? s 1 mhz mode (1) 0.25 ? s is31 t hd : sta start condition hold time 100 khz mode 4.0 ? s after this period, the first clock pulse is generated 400 khz mode 0.6 ? s 1 mhz mode (1) 0.25 ? s is33 t su : sto stop condition setup time 100 khz mode 4.7 ? s? 400 khz mode 0.6 ? s 1 mhz mode (1) 0.6 ? s is34 t hd : st o stop condition hold time 100 khz mode 4000 ? ns ? 400 khz mode 600 ? ns 1 mhz mode (1) 250 ns is40 t aa : scl output valid from clock 100 khz mode 0 3500 ns ? 400 khz mode 0 1000 ns 1 mhz mode (1) 0 350 ns is45 t bf : sda bus free time 100 khz mode 4.7 ? s time the bus must be free before a new transmission can start 400 khz mode 1.3 ? s 1 mhz mode (1) 0.5 ? s is50 c b bus capacitive loading ? 400 pf ? note 1: maximum pin capacitance = 10 pf for all i2cx pins (for 1 mhz mode only). 2: these parameters are characterized by simila rity, but are not tested in manufacturing.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 238 ? 2007-2011 microchip technology inc. table 22-38: adc module specifications ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min. typ max. units conditions device supply ad01 av dd module v dd supply (2) greater of v dd ? 0.3 or 3.0 ? lesser of v dd + 0.3 or 3.6 v ? ad02 av ss module v ss supply (2) v ss ? 0.3 ? v ss + 0.3 v ? reference inputs ad05 v refh reference voltage high av ss + 2.5 ? av dd v see note 1 ad05a 3.0 ? 3.6 v v refh = av dd v refl = av ss = 0, see note 2 ad06 v refl reference voltage low av ss ?av dd ? 2.5 v see note 1 ad06a 0 ? 0 v v refh = av dd v refl = av ss = 0, see note 2 ad07 v ref absolute reference voltage (2) 2.5 ? 3.6 v v ref = v refh - v refl ad08 i ref current drain ? ? 250 ? 550 10 a a adc operating, see note 1 adc off, see note 1 ad08a i ad operating current ? ? 7.0 2.7 9.0 3.2 ma ma 10-bit adc mode, see note 2 12-bit adc mode, see note 2 analog input ad12 v inh input voltage range v inh (2) v inl ?v refh v this voltage reflects sample and hold channels 0, 1, 2, and 3 (ch0-ch3), positive input ad13 v inl input voltage range v inl (2) v refl ?av ss + 1v v this voltage reflects sample and hold channels 0, 1, 2, and 3 (ch0-ch3), negative input ad17 r in recommended imped- ance of analog voltage source (3) ? ? ? ? 200 200 10-bit adc 12-bit adc note 1: these parameters are not characterized or tested in manufacturing. 2: these parameters are characterized, but are not tested in manufacturing. 3: these parameters are assured by design, but ar e not characterized or tested in manufacturing.
? 2007-2011 microchip technology inc. ds70289j-page 239 pic24hj32gp202/204 and pic24hj16gp304 table 22-39: adc module specifications (12-bit mode) (4) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min. typ max. units conditions adc accuracy (12-bit mode) ? measurements with external v ref +/v ref - (3) ad20a nr resolution (4) 12 data bits bits ? ad21a inl integral nonlinearity -2 ? +2 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad22a dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad23a g err gain error ? 3.4 10 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad24a e off offset error ? 0.9 5 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad25a ? monotonicity ? ? ? ? guaranteed (1) adc accuracy (12-bit mode) ? me asurements with internal v ref +/v ref - (3) ad20a nr resolution (4) 12 data bits bits ? ad21a inl integral nonlinearity -2 ? +2 lsb v inl = av ss = 0v, av dd = 3.6v ad22a dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = 0v, av dd = 3.6v ad23a g err gain error ? 10.5 20 lsb v inl = av ss = 0v, av dd = 3.6v ad24a e off offset error ? 3.8 10 lsb v inl = av ss = 0v, av dd = 3.6v ad25a ? monotonicity ? ? ? ? guaranteed (1) dynamic performance (12-bit mode) (2) ad30a thd total harmonic distortion ? ? -75 db ? ad31a sinad signal to noise and distortion 68.5 69.5 ? db ? ad32a sfdr spurious free dynamic range 80 ? ? db ? ad33a f nyq input signal bandwidth ? ? 250 khz ? ad34a enob effective number of bits 11.09 11.3 ? bits ? note 1: the a/d conversion result never de creases with an increase in the input voltage, and has no missing codes. 2: these parameters are characterized by simila rity, but are not tested in manufacturing. 3: these parameters are characterized, but are tested at 20 ksps only. 4: injection currents > | 0 | can affect the adc results by approximately 4-6 counts.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 240 ? 2007-2011 microchip technology inc. table 22-40: adc module specifications (10-bit mode) (4) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min. typ max. units conditions adc accuracy (10-bit mode) ? measurements with external v ref +/v ref - (3) ad20b nr resolution (4) 10 data bits bits ? ad21b inl integral nonlinearity -1.5 ? +1.5 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad22b dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad23b g err gain error ? 3 6 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad24b e off offset error ? 2 5 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v ad25b ? monotonicity ? ? ? ? guaranteed (1) adc accuracy (10-bit mode) ? me asurements with internal v ref +/v ref - (3) ad20b nr resolution (4) 10 data bits bits ? ad21b inl integral nonlinearity -1 ? +1 lsb v inl = av ss = 0v, av dd = 3.6v ad22b dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = 0v, av dd = 3.6v ad23b g err gain error ? 7 15 lsb v inl = av ss = 0v, av dd = 3.6v ad24b e off offset error ? 3 7 lsb v inl = av ss = 0v, av dd = 3.6v ad25b ? monotonicity ? ? ? ? guaranteed (1) dynamic performance (10-bit mode) (2) ad30b thd total harmonic distortion ? ? -64 db ? ad31b sinad signal to noise and distortion 57 58.5 ? db ? ad32b sfdr spurious free dynamic range 72 ? ? db ? ad33b f nyq input signal bandwidth ? ? 550 khz ? ad34b enob effective number of bits 9.16 9.4 ? bits ? note 1: the a/d conversion result never de creases with an increase in the input voltage, and has no missing codes. 2: these parameters are characterized by simila rity, but are not tested in manufacturing. 3: these parameters are characterized, but are tested at 20 ksps only. 4: injection currents > | 0 | can affect the adc results by approximately 4-6 counts.
? 2007-2011 microchip technology inc. ds70289j-page 241 pic24hj32gp202/204 and pic24hj16gp304 figure 22-21: adc conversion (12-bit mode) timing characteristics (asam = 0 , ssrc<2:0> = 000 ) table 22-41: adc conversion (12- bit mode) timing requirements ad55 t samp clear samp set samp ad61 adclk instruction samp ad60 done ad1if 1 2 3 4 5 6 8 7 1 ? software sets ad1con. samp to start sampling. 2 ? sampling starts after discharge period. t samp is described in 3 ? software clears ad1con. samp to start conversion. 4 ? sampling ends, conversion sequence starts. 5 ? convert bit 11 . 9 ? one t ad for end of conversion. ad50 9 6 ? convert bit 10 . 7 ? convert bit 1 . 8 ? convert bit 0 . execution section 16. ?analog-to-digital converter (adc)? (ds70183) in the ?dspic33f/pic24h family reference manual? . ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min. typ max. units conditions clock parameters ad50 t ad adc clock period (2) 117.6 ? ? ns ? ad51 t rc adc internal rc oscillator period (2) ? 250 ? ns ? conversion rate ad55 t conv conversion time (2) ? 14 t ad ?ns ? ad56 f cnv throughput rate (2) ??500ksps ? ad57 t samp sample time (2) 3.0 t ad ?? ? ? timing parameters ad60 t pcs conversion start from sample trigger (2) 2.0 t ad ? 3.0 t ad ? auto convert trigger not selected ad61 t pss sample start from setting sample (samp) bit (2) 2.0 t ad ? 3.0 t ad ?? ad62 t css conversion completion to sample start (asam = 1 ) (2) ? 0.5 t ad ?? ? ad63 t dpu time to stabilize analog stage from adc off to adc on (2) ??20 s? note 1: because the sample caps will eventually lose char ge, clock rates below 10 khz can affect linearity performance, especially at elevated temperatures. 2: these parameters are characterized but not tested in manufacturing.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 242 ? 2007-2011 microchip technology inc. figure 22-22: adc conversion (10-bit mode) timing characteristics (chps<1:0> = 01 , simsam = 0 , asam = 0 , ssrc<2:0> = 000 ) figure 22-23: adc conversion (10-bit mode) timing characteristics (chps<1:0> = 01 , simsam = 0 , asam = 1 , ssrc<2:0> = 111 , samc<4:0> = 00001 ) ad55 t samp clear samp set samp ad61 adclk instruction samp ad60 done ad1if buffer( 0 ) buffer( 1 ) 1 2 3 4 5 6 8 5 6 7 1 ? software sets ad1con. samp to start sampling. 2 ? sampling starts after discharge period. t samp is described in 3 ? software clears ad1con. samp to start conversion. 4 ? sampling ends, conversion sequence starts. 5 ? convert bit 9. 8 ? one t ad for end of conversion. ad50 7 ad55 8 6 ? convert bit 8. 7 ? convert bit 0. execution in the ?dspic33f/pic24h family reference manual? . section 16. ?analog-to-digital converter (adc)? (ds70183) 1 2 3 4 5 6 4 5 6 8 1 ? software sets ad1con. adon to start ad operation. 2 ? sampling starts after discharge period. t samp is described in 3 ? convert bit 9. 4 ? convert bit 8. 5 ? convert bit 0. 7 3 6 ? one t ad for end of conversion. 7 ? begin conversion of next channel. 8 ? sample for time specified by samc<4:0>. section 16. ?analog-to-digital converter (adc)? (ds70183) adclk instruction set adon execution samp t samp ad1if done ad55 ad55 t samp ad55 ad50 in the ?dspic33f/pic24h family reference manual?.
? 2007-2011 microchip technology inc. ds70289j-page 243 pic24hj32gp202/204 and pic24hj16gp304 table 22-42: adc conversion (10- bit mode) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +85c for industrial -40c t a +125c for extended param no. symbol characteristic min. typ (1) max. units conditions clock parameters ad50 t ad adc clock period (1) 76 ? ? ns ? ad51 t rc adc internal rc oscillator period (1) ? 250 ? ns ? conversion rate ad55 t conv conversion time (1) ?12 t ad ?? ? ad56 f cnv throughput rate (1) ??1.1msps ? ad57 t samp sample time (1) 2.0 t ad ??? ? timing parameters ad60 t pcs conversion start from sample trigger (1) 2.0 t ad ? 3.0 t ad ? auto-convert trigger not selected ad61 t pss sample start from setting sample (samp) bit (1) 2.0 t ad ? 3.0 t ad ?? ad62 t css conversion completion to sample start (asam = 1 ) (1) ? 0.5 t ad ?? ? ad63 t dpu time to stabilize analog stage from adc off to adc on (1) ??20 s? note 1: these parameters are characterized but not tested in manufacturing. 2: because the sample caps will eventually lose char ge, clock rates below 10 khz can affect linearity performance, especially at elevated temperatures.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 244 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 245 pic24hj32gp202/204 and pic24hj16gp304 23.0 high temperature electrical characteristics this section provides an overview of pic24hj32gp202/ 204 and pic24hj16gp304 electrical characteristics for devices operating in an ambient temperature range of -40c to +150c. the specifications between -40c to + 150c are identical to those shown in section 22.0 ?electri cal characteristics? for operation between -40c to +125c, with the exc eption of the parameters listed in this section. parameters in this section begin with an h, which den otes high temperature. for example, parameter dc10 in section 22.0 ?electrical characteristics? is the industrial and extended temperature equivalent of hdc10. absolute maximum ratings for the pic24hj32gp202/204 and pic24hj16gp304 high temperature devices are listed below. exposure to these maximum rating conditions for extended periods can affect device reliability. functional operation of the device at these or any other conditions above the parameters indicated in the operation listings of this specification is not implied. absolute maximum ratings (1) ambient temperature under bias (4) .........................................................................................................-40c to +150c storage temperature ............................................................................................................ .................. -65c to +160c voltage on v dd with respect to v ss ......................................................................................................... -0.3v to +4.0v voltage on any pin that is not 5v tolerant with respect to v ss (5) .................................................... -0.3v to (v dd + 0.3v) voltage on any 5v tolerant pin with respect to v ss when v dd < 3.0v (5) .................................................... -0.3v to 3.6v voltage on any 5v tolerant pin with respect to v ss when v dd 3.0v (5) .................................................... -0.3v to 5.6v maximum current out of v ss pin ........................................................................................................................... ..60 ma maximum current into v dd pin (2) .............................................................................................................................60 ma maximum junction temperature...... ............................................................................................. .......................... +155c maximum current sourced/sunk by any 2x i/o pin (3) ................................................................................................2 ma maximum current sourced/sunk by any 4x i/o pin (3) ................................................................................................4 ma maximum current sourced/sunk by any 8x i/o pin (3) ................................................................................................8 ma maximum current sunk by all ports combined ........... ......................................................................... ....................70 ma maximum current sourced by all ports combined (2) ................................................................................................70 ma note 1: stresses above those listed under ?absolute maxi mum ratings? can cause permanent damage to the device. this is a stress rating only, and functional o peration of the device at th ose or any other conditions above those indicated in the operation listings of this specification is not implied. exposure to maximum rating conditions for extended periods can affect device reliability. 2: maximum allowable current is a function of device maximum power dissipation (see table 23-2 ). 3: unlike devices at 125c and below, the specifications in this sect ion also apply to the clkout, v ref +, v ref -, sclx, sdax, pgcx and pgdx pins. 4: aec-q100 reliability testing for devices intended to operate at 150c is 1,000 hours. any design in which the total operating time from 125c to 150c will be greater than 1,000 hours is not warranted without prior written approval from microchip technology inc. 5: refer to the ? pin diagrams ? section for 5v tolerant pins.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 246 ? 2007-2011 microchip technology inc. 23.1 high temperature dc characteristics table 23-1: operating mips vs. voltage table 23-2: thermal operating conditions table 23-3: dc temperature and voltage specifications characteristic v dd range (in volts) temperature range (in c) max mips pic24hj32gp202/204 and pic24hj16gp304 hdc5 v bor to 3.6v (1) -40c to +150c 20 note 1: device is functional at v bormin < v dd < v ddmin . analog modules such as the adc will have degraded performance. device functionality is tested but not characterized. refer to parameter bo10 in ta b l e 2 2 - 11 for the minimum and maximum bor values. rating symbol min typ max unit high temperature devices operating junction temperature range t j -40 ? +155 c operating ambient temperature range t a -40 ? +150 c power dissipation: internal chip power dissipation: p int = v dd x (i dd - i oh ) p d p int + p i / o w i/o pin power dissipation: i/o = ({v dd - v oh } x i oh ) + (v ol x i ol ) maximum allowed power dissipation p dmax (t j - t a )/ ja w dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature parameter no. symbol characteristic min typ max units conditions operating voltage hdc10 supply voltage v dd ? 3.0 3.3 3.6 v -40c to +150c
? 2007-2011 microchip technology inc. ds70289j-page 247 pic24hj32gp202/204 and pic24hj16gp304 table 23-4: dc characteristics: power-down current (i pd ) table 23-5: dc characteristics: operating current (i dd ) table 23-6: dc characteristics: doze current (i doze ) dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature parameter no. typical max units conditions power-down current (i pd ) hdc60e 250 2000 a +150c 3.3v base power-down current (1,3) hdc61c 3 5 a +150c 3.3v watchdog timer current: i wdt (2,4) note 1: base i pd is measured with all peripheral s and clocks shut down. all i/os are configured as inputs and pulled to v ss . wdt, etc., are all switched off, and vregs (rcon<8>) = 1. 2: the current is the additional current consumed when the module is enabled. this current should be added to the base i pd current. 3: these currents are measured on the device c ontaining the most memory in this family. 4: these parameters are characterized, but are not tested in manufacturing. dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature parameter no. typical (1) max units conditions hdc20 19 35 ma +150c 3.3v 10 mips hdc21 27 45 ma +150c 3.3v 16 mips hdc22 33 55 ma +150c 3.3v 20 mips note 1: these parameters are characterized, but are not tested in manufacturing. dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature parameter no. typical (1) max doze ratio units conditions hdc72a 39 45 1:2 ma +150c 3.3v 20 mips hdc72f 18 25 1:64 ma hdc72g 18 25 1:128 ma note 1: parameters with doze ratios of 1:2 and 1:64 are c haracterized, but are not tested in manufacturing.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 248 ? 2007-2011 microchip technology inc. table 23-7: dc characteristics: i/o pin output specifications dc characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param. symbol characteristic mi n. typ. max. units conditions do10 v ol output low voltage i/o pins: 2x sink driver pins - all pins not defined by 4x or 8x driver pins ??0.4v i ol 1.8 ma, v dd = 3.3v see note 1 output low voltage i/o pins: 4x sink driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 ??0.4v i ol 3.6 ma, v dd = 3.3v see note 1 output low voltage i/o pins: 8x sink driver pins - osco, clko, ra3 ??0.4v i ol 6 ma, v dd = 3.3v see note 1 do20 v oh output high voltage i/o pins: 2x source driver pins - all pins not defined by 4x or 8x driver pins 2.4 ? ? v i ol -1.8 ma, v dd = 3.3v see note 1 output high voltage i/o pins: 4x source driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 2.4 ? ? v i ol -3 ma, v dd = 3.3v see note 1 output high voltage i/o pins: 8x source driver pins - osco, clko, ra3 2.4 ? ? v i ol -6 ma, v dd = 3.3v see note 1 do20a v oh 1 output high voltage i/o pins: 2x source driver pins - all pins not defined by 4x or 8x driver pins 1.5 ? ? v i oh -1.9 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -1.85 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -1.4 ma, v dd = 3.3v see note 1 output high voltage 4x source driver pins - ra0, ra1, rb5, rb6, rb8, rb9, rb14 1.5 ? ? v i oh -3.9 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -3.7 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -2 ma, v dd = 3.3v see note 1 output high voltage 8x source driver pins -osco, clko, ra3 1.5 ? ? v i oh -7.5 ma, v dd = 3.3v see note 1 2.0 ? ? i oh -6.8 ma, v dd = 3.3v see note 1 3.0 ? ? i oh -3 ma, v dd = 3.3v see note 1 note 1: parameters are characterized, but not tested.
? 2007-2011 microchip technology inc. ds70289j-page 249 pic24hj32gp202/204 and pic24hj16gp304 23.2 ac characteristics and timing parameters the information contained in this section defines pic24hj32gp202/204 and pic24hj16gp304 ac characteristics and timing parameters for high temperature devices. however, all ac timing specifications in this sect ion are the same as those in section 22.2 ?ac charac teristics and timing parameters? , with the exception of the parameters listed in this section. parameters in this section begin with an h, which denotes high temper ature. for example, parameter os53 in section 22.2 ?ac characteristics and timing parameters? is the industrial and extended temperature equivalent of hos53. table 23-8: temperature and voltage specifications ? ac figure 23-1: load conditions for device timing specifications table 23-9: pll clock timing specifications ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature operating voltage v dd range as described in table 23-1 . ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic mi n typ max units conditions hos53 d clk clko stability (jitter) (1) -5 0.5 5 % measured over 100 ms period note 1: these parameters are characterized by similarity, but are not tested in manufacturing. this specification is based on clock cycle by clock cycle measurements. to ca lculate the effective jitt er for individual time bases or communication clocks use this formula: v dd /2 c l r l pin pin v ss v ss c l r l =464 c l = 50 pf for all pins except osc2 15 pf for osc2 output load condition 1 ? for all pins except osc2 load condition 2 ? for osc2 peripheral clock jitter d clk f osc peripheral bit rate clock -------------------------------------------------------------- ?? ?? ----------------------------------------------------------------------- - = for example: fosc = 32 mhz, d clk = 5%, spi bit rate clock, (i.e., sck) is 2 mhz. spi sck jitter d clk 32 mhz 2 mhz -------------------- ?? ?? ------------------------------ 5% 16 --------- - 5% 4 ------- - 1.25% ====
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 250 ? 2007-2011 microchip technology inc. table 23-10: spix master mode (cke = 0 ) timing requirements table 23-11: spix module master mode (cke = 1 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic (1) min typ max units conditions hsp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?1025ns ? hsp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 28 ? ? ns ? hsp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 35 ? ? ns ? note 1: these parameters are characterized but not tested in manufacturing. ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic (1) min typ max units conditions hsp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ?1025ns ? hsp36 tdov2sc, tdov2scl sdox data output setup to first sckx edge 35 ? ? ns ? hsp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 28 ? ? ns ? hsp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 35 ? ? ns ? note 1: these parameters are characterized but not tested in manufacturing.
? 2007-2011 microchip technology inc. ds70289j-page 251 pic24hj32gp202/204 and pic24hj16gp304 table 23-12: spix module slave mode (cke = 0 ) timing requirements table 23-13: spix module slave mode (cke = 1 ) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic (1) min typ max units conditions hsp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ??35ns ? hsp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 25 ? ? ns ? hsp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 25 ? ? ns ? hsp51 tssh2doz ssx to sdox output high-impedance 15 ? 55 ns see note 2 note 1: these parameters are characterized but not tested in manufacturing. 2: assumes 50 pf load on all spix pins. ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic (1) min typ max units conditions hsp35 tsch2dov, tscl2dov sdox data output valid after sckx edge ? ? 35 ns ? hsp40 tdiv2sch, tdiv2scl setup time of sdix data input to sckx edge 25 ? ? ns ? hsp41 tsch2dil, tscl2dil hold time of sdix data input to sckx edge 25 ? ? ns ? hsp51 tssh2doz ssx to sdo x output high-impedance 15 ? 55 ns see note 2 hsp60 tssl2dov sdox data output valid after ssx edge ? ? 55 ns ? note 1: these parameters are characterized but not tested in manufacturing. 2: assumes 50 pf load on all spix pins. table 23-14: internal rc accuracy ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for extended param no. characteristic min typ max units conditions lprc @ 32.768 khz (1,2) hf21 lprc -70 ? +70 % -40c t a +150c v dd = 3.0-3.6v note 1: change of lprc frequency as v dd changes. 2: lprc accuracy impacts the watchdog timer time-out period (t wdt 1). see section 19.4 ?watchdog timer (wdt)? for more information.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 252 ? 2007-2011 microchip technology inc. table 23-15: adc module specifications table 23-16: adc module specifications (12-bit mode) (3) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic min typ max units conditions reference inputs had08 i ref current drain ? ? 250 ? 600 50 a a adc operating, see note 1 adc off, see note 1 note 1: these parameters are not characterized or tested in manufacturing. 2: these parameters are characterized, but are not tested in manufacturing. ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic min typ max units conditions adc accuracy (12-bit mode) ? measurements with external v ref +/v ref - (1) had20a nr resolution (3) 12 data bits bits ? had21a inl integral nonlinearity -2 ? +2 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had22a dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had23a g err gain error -2 ? 10 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had24a e off offset error -3 ? 5 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v adc accuracy (12-bit mode) ? measurements with internal v ref +/v ref - (1) had20a nr resolution (3) 12 data bits bits ? had21a inl integral nonlinearity -2 ? +2 lsb v inl = av ss = 0v, av dd = 3.6v had22a dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = 0v, av dd = 3.6v had23a g err gain error 2 ? 20 lsb v inl = av ss = 0v, av dd = 3.6v had24a e off offset error 2 ? 10 lsb v inl = av ss = 0v, av dd = 3.6v dynamic performance (12-bit mode) (2) had33a f nyq input signal bandwidth ? ? 200 khz ? note 1: these parameters are characterized, but are tested at 20 ksps only. 2: these parameters are characterized by simila rity, but are not tested in manufacturing. 3: injection currents > | 0 | can affect the adc results by approximately 4-6 counts.
? 2007-2011 microchip technology inc. ds70289j-page 253 pic24hj32gp202/204 and pic24hj16gp304 table 23-17: adc module specifications (10-bit mode) (3) ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic mi n typ max units conditions adc accuracy (10-bit mode) ? measurements with external v ref +/v ref - (1) had20b nr resolution (3) 10 data bits bits ? had21b inl integral nonlinearity -3 ? 3 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had22b dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had23b g err gain error -5 ? 6 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v had24b e off offset error -1 ? 5 lsb v inl = av ss = v refl = 0v, av dd = v refh = 3.6v adc accuracy (10-bit mode) ? measurements with internal v ref +/v ref - (1) had20b nr resolution (3) 10 data bits bits ? had21b inl integral nonlinearity -2 ? 2 lsb v inl = av ss = 0v, av dd = 3.6v had22b dnl differential nonlinearity > -1 ? < 1 lsb v inl = av ss = 0v, av dd = 3.6v had23b g err gain error -5 ? 15 lsb v inl = av ss = 0v, av dd = 3.6v had24b e off offset error -1.5 ? 7 lsb v inl = av ss = 0v, av dd = 3.6v dynamic performance (10-bit mode) (2) had33b f nyq input signal bandwidth ? ? 400 khz ? note 1: these parameters are characterized, but are tested at 20 ksps only. 2: these parameters are characterized by simila rity, but are not tested in manufacturing. 3: injection currents > | 0 | can affect the adc results by approximately 4-6 counts.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 254 ? 2007-2011 microchip technology inc. table 23-18: adc conversion (12- bit mode) timing requirements table 23-19: adc conversion (10- bit mode) timing requirements ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic min typ max units conditions clock parameters had50 t ad adc clock period (1) 147 ? ? ns ? conversion rate had56 f cnv throughput rate (1) ? ? 400 ksps ? note 1: these parameters are characterized but not tested in manufacturing. ac characteristics standard operating conditions: 3.0v to 3.6v (unless otherwise stated) operating temperature -40c t a +150c for high temperature param no. symbol characteristic min typ max units conditions clock parameters had50 t ad adc clock period (1) 104 ? ? ns ? conversion rate had56 f cnv throughput rate (1) ??800ksps ? note 1: these parameters are characterized but not tested in manufacturing.
? 2007-2011 microchip technology inc. ds70289j-page 255 pic24hj32gp202/204 and pic24hj16gp304 24.0 dc and ac device characteristics graphs figure 24-1: v oh ? 2x driver pins figure 24-2: v oh ? 4x driver pins figure 24-3: v oh ? 8x driver pins figure 24-4: v oh ? 16x driver pins note: the graphs provided following this note ar e a statistical summary based on a limited num ber of samples and are provided for des ign guidance purposes only. the performance characteristics listed herein are not tested or guaranteed. in some graphs, the data presented may be outside t he specified operating range (e.g., outside specified power supply range) and therefore, outside the warranted range. -0.016 -0.014 -0.012 -0.010 -0.008 -0.006 -0.004 ioh (a) -0.016 -0.014 -0.012 -0.010 -0.008 -0.006 -0.004 -0.002 0.000 0.00 0.50 1.00 1.50 2.00 2.50 3.00 3.50 4.00 ioh (a) voh (v) 3v 3.3v 3.6v -0.030 -0.025 -0.020 -0.015 -0.010 ioh (a) -0.030 -0.025 -0.020 -0.015 -0.010 -0.005 0.000 0.00 0.50 1.00 1.50 2.00 2.50 3.00 3.50 4.00 ioh (a) voh (v) 3v 3.3v 3.6v -0.040 -0.035 -0.030 -0.025 -0.020 -0.015 ioh (a) -0.040 -0.035 -0.030 -0.025 -0.020 -0.015 -0.010 -0.005 0.000 0.00 1.00 2.00 3.00 4.00 ioh (a) voh (v) 3v 3.3v 3.6v -0.080 -0.070 -0.060 -0.050 -0.040 -0.030 -0.020 ioh (a) -0.080 -0.070 -0.060 -0.050 -0.040 -0.030 -0.020 -0.010 0.000 0.00 1.00 2.00 3.00 4.00 ioh (a) voh (v) 3v 3.3v 3.6v
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 256 ? 2007-2011 microchip technology inc. figure 24-5: v ol ? 2x driver pins figure 24-6: v ol ? 4x driver pins figure 24-7: v ol ? 8x driver pins figure 24-8: v ol ? 16x driver pins 0.006 0.008 0.010 0.012 0.014 0.016 0.018 0.020 iol (a) 0.000 0.002 0.004 0.006 0.008 0.010 0.012 0.014 0.016 0.018 0.020 0.00 1.00 2.00 3.00 4.00 iol (a) vol (v) 3v 3.3v 3.6v 0.010 0.015 0.020 0.025 0.030 0.035 0.040 iol (a) 0.000 0.005 0.010 0.015 0.020 0.025 0.030 0.035 0.040 0.00 1.00 2.00 3.00 4.00 iol (a) vol (v) 3v 3.3v 3.6v 0.020 0.030 0.040 0.050 0.060 iol (a) 0.000 0.010 0.020 0.030 0.040 0.050 0.060 0.00 1.00 2.00 3.00 4.00 iol (a) vol (v) 3v 3.3v 3.6v 0.040 0.060 0.080 0.100 0.120 iol (a) 0.000 0.020 0.040 0.060 0.080 0.100 0.120 0.00 1.00 2.00 3.00 4.00 iol (a) vol (v) 3v 3.3v 3.6v
? 2007-2011 microchip technology inc. ds70289j-page 257 pic24hj32gp202/204 and pic24hj16gp304 figure 24-9: typical i pd current @ v dd = 3.3v, +85oc figure 24-10: typical i dd current @ v dd = 3.3v, +85oc figure 24-11: typical i doze current @ v dd = 3.3v, +85oc figure 24-12: typical i idle current @ v dd = 3.3v, +85oc 200 300 400 500 600 700 ipd current [a] 0 100 200 -40 -30 -20 -10 0 10 20 30 40 50 60 70 80 90 100 110 120 temperature celsius 20 30 40 50 60 average (ma) 0 10 0 102030405060 f cy (mips) pmd = 0, no pll pmd = 0, with pll 20.00 30.00 40.00 50.00 60.00 current (ma) 0.00 10.00 1:1 1:2 1:64 1:128 doze ratio 10 15 20 25 l e current (ma) 0 5 0 10203040 i id l mips
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 258 ? 2007-2011 microchip technology inc. figure 24-13: typical frc frequency @ v dd = 3.3v figure 24-14: typical lprc frequency @ v dd = 3.3v 7450 7350 7400 7300 7350 n cy (khz) 7200 7250 freque n 7150 7100 -40-30-20-10 0 102030405060708090100110120 temperature celsius 35 29 31 33 z) 25 27 29 uency (kh 21 23 l prc freq 17 19 l 15 -40-30-20-10 0 102030405060708090100110120 temperature celsius
? 2007-2011 microchip technology inc. ds70289j-page 259 pic24hj32gp202/204 and pic24hj16gp304 25.0 packaging information 25.1 package marking information legend: xx...x customer-specific information y year code (last digit of calendar year) yy year code (last 2 digits of calendar year) ww week code (week of january 1 is week ?01?) nnn alphanumeric traceability code pb-free jedec designator for matte tin (sn) * this package is pb-free. the pb-free jedec designator ( ) can be found on the outer packaging for this package. note: if the full microchip part number cannot be marked on one line, it is carried over to the next line, thus limiting the number of available characters for customer-specific information. 3 e 3 e 28-lead spdip xxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxx yywwnnn example pic24hj32gp202-i/sp 0730235 28-lead soic xxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx yywwnnn example pic24hj32gp202/so 0730235 3 e 3 e 28-lead ssop xxxxxxxxxxxx xxxxxxxxxxxx yywwnnn example 24hj32gp 202-e/ss 0730235 3 e
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 260 ? 2007-2011 microchip technology inc. 25.1 package marking information (continued) legend: xx...x customer-specific information y year code (last digit of calendar year) yy year code (last 2 digits of calendar year) ww week code (week of january 1 is week ?01?) nnn alphanumeric traceability code pb-free jedec designator for matte tin (sn) * this package is pb-free. the pb-free jedec designator ( ) can be found on the outer packaging for this package. note: if the full microchip part number cannot be marked on one line, it is carried over to the next line, thus limiting the number of available characters for customer-specific information. 3 e 3 e 28-lead qfn-s xxxxxxxx xxxxxxxx yywwnnn example 24hj32gp 202e/mm 0730235 xxxxxxxxxx 44-lead qfn xxxxxxxxxx xxxxxxxxxx yywwnnn pic24hj32 example gp204-e/ml 0730235 44-lead tqfp xxxxxxxxxx xxxxxxxxxx xxxxxxxxxx yywwnnn example pic24hj 32gp204 0730235 -e/pt 3 e 3 e 3 e
? 2007-2011 microchip technology inc. ds70289j-page 261 pic24hj32gp202/204 and pic24hj16gp304 25.2 package details 28-lead skinny plastic dual in-line (sp) ? 300 mil body [spdip] notes: 1. pin 1 visual index feature may vary, but must be located within the hatched area. 2. significant characteristic. 3. dimensions d and e1 do not include mold flash or protrusions. mold flash or protrusions shall not exceed .010" per side. 4. dimensioning and tolerancing per asme y14.5m. bsc: basic dimension. theoretically exact value shown without tolerances. note: for the most current package drawings, please see the microchip packaging specification located at http://www.microchip.com/packaging units inches dimension limits min nom max number of pins n 28 pitch e .100 bsc top to seating plane a ? ? .200 molded package thickness a2 .120 .135 .150 base to seating plane a1 .015 ? ? shoulder to shoulder width e .290 .310 .335 molded package width e1 .240 .285 .295 overall length d 1.345 1.365 1.400 tip to seating plane l .110 .130 .150 lead thickness c .008 .010 .015 upper lead width b1 .040 .050 .070 lower lead width b .014 .018 .022 overall row spacing eb ? ? .430 note 1 n 12 d e1 e b c e l a2 e b b1 a1 a 3 microchip technology drawing c04-070b
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 262 ? 2007-2011 microchip technology inc. 28-lead plastic small outline (so) ? wide, 7.50 mm body [soic] notes: 1. pin 1 visual index feature may vary, but must be located within the hatched area. 2. significant characteristic. 3. dimensions d and e1 do not include mold flash or protrusions. mold flash or protrusions shall not exceed 0.15 mm per side. 4. dimensioning and tolerancing per asme y14.5m. bsc: basic dimension. theoretically exact value shown without tolerances. ref: reference dimension, usually without tolerance, for information purposes only. note: for the most current package drawings, please see the microchip packaging specification located at http://www.microchip.com/packaging units millmeters dimension limits min nom max number of pins n 28 pitch e 1.27 bsc overall height a C C 2.65 molded package thickness a2 2.05 C C standoff a1 0.10 C 0.30 overall width e 10.30 bsc molded package width e1 7.50 bsc overall length d 17.90 bsc chamfer (optional) h 0.25 C 0.75 foot length l 0.40 C 1.27 footprint l1 1.40 ref foot angle top 0 C 8 lead thickness c 0.18 C 0.33 lead width b 0.31 C 0.51 mold draft angle top 5 C 15 mold draft angle bottom 5 C 15 c h h l l1 a2 a1 a note 1 12 3 b e e e1 d n microchip technology drawing c04-052b
? 2007-2011 microchip technology inc. ds70289j-page 263 pic24hj32gp202/204 and pic24hj16gp304
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pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 266 ? 2007-2011 microchip technology inc. 44-lead plastic quad flat, no lead package (ml) C 8x8 mm body [qfn] notes: 1. pin 1 visual index feature may vary, but must be located within the hatched area. 2. package is saw singulated. 3. dimensioning and tolerancing per asme y14.5m. bsc: basic dimension. theoretically exact value shown without tolerances. ref: reference dimension, usually without tolerance, for information purposes only. note: for the most current package drawings, please see the microchip packaging specification located at http://www.microchip.com/packaging units millimeters dimension limits min nom max number of pins n 44 pitch e 0.65 bsc overall height a 0.80 0.90 1.00 standoff a1 0.00 0.02 0.05 contact thickness a3 0.20 ref overall width e 8.00 bsc exposed pad width e2 6.30 6.45 6.80 overall length d 8.00 bsc exposed pad length d2 6.30 6.45 6.80 contact width b 0.25 0.30 0.38 contact length l 0.30 0.40 0.50 contact-to-exposed pad k 0.20 C C d exposed pad d2 e b k l e2 2 1 n note 1 2 1 e n b otto m view to p view a3 a1 a microchip technology drawing c04-103b
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pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 268 ? 2007-2011 microchip technology inc. 44-lead plastic t hin quad flatpack (p t ) C 10x10x1 mm body, 2.00 mm footprint [ t qfp] notes: 1. pin 1 visual index feature may vary, but must be located within the hatched area. 2. chamfers at corners are optional; size may vary. 3. dimensions d1 and e1 do not include mold flash or protrusions. mold flash or protrusions shall not exceed 0.25 mm per side. 4. dimensioning and tolerancing per asme y14.5m. bsc: basic dimension. theoretically exact value shown without tolerances. ref: reference dimension, usually without tolerance, for information purposes only. note: for the most current package drawings, please see the microchip packaging specification located at http://www.microchip.com/packaging units millimeters dimension limits min nom max number of leads n 44 lead pitch e 0.80 bsc overall height a C C 1.20 molded package thickness a2 0.95 1.00 1.05 standoff a1 0.05 C 0.15 foot length l 0.45 0.60 0.75 footprint l1 1.00 ref foot angle 0 3.5 7 overall width e 12.00 bsc overall length d 12.00 bsc molded package width e1 10.00 bsc molded package length d1 10.00 bsc lead thickness c 0.09 C 0.20 lead width b 0.30 0.37 0.45 mold draft angle top 11 12 13 mold draft angle bottom 11 12 13 a e e1 d d1 e b note 1 note 2 n 123 c a1 l a2 l1 microchip technology drawing c04-076b
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pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 270 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 271 pic24hj32gp202/204 and pic24hj16gp304 appendix a: revision history revision a (july 2007) initial release of this document. revision b (june 2008) this revision includes minor typographical and formatting changes throughout the data sheet text. the major changes are referenced by their respective section in the following table. table 25-1: major section updates section name update description ?high-performance, 16-bit microcontrollers? added extended interrupts column to remappable peripherals in the controller families table and note 2 (see table 1). added note 1 to all pin diagrams, which references rpn pin usage by remappable peripherals (see ?pin diagrams? ). section 1.0 ?device overview? changed porta pin name from ra15 to ra10 (see table 1-1). section 3.0 ?memory organization? updated reset values for the followin g sfrs: ipc1, ipc3-ipc5, ipc7, ipc16, and inttreg (see table 3-4). added the system control regi ster map (see table 3-20). section 5.0 ?resets? entire section was replaced to mainta in consistency with other pic24h data sheets. section 7.0 ?oscillator configuration? removed the first sentence of the third clock source item (external clock) in section 7.1.1.2 ?primary? . updated the default bit values for do ze and frcdiv in the clock divisor register (see register 7-2). added the center frequency in the osctun register for the frc tuning bits (tun<5:0>) value 011111 and updated the center frequency for bits value 011110 (see register 7-4). section 8.0 ?power-saving features? added the following two registers: ? pmd1: peripheral module disable control register 1 ? pmd2: peripheral module disable control register 2 section 9.0 ?i/o ports? added paragraph and table 9-1 to section 9.1.1 ?open-drain configuration? , which provides details on i/o pins and their functionality. removed the following sections, which are now available in the related section of the dspic33f/pic24h family reference manual: ? 9.4.2 ?available peripherals? ? 9.4.3.3 ?mapping? ? 9.4.5 ?considerations for peripheral pin selection? section 13.0 ?output compare? replaced sections 13.1, 13.2 and 13.3 and related figures and tables with entirely new content. section 14.0 ?serial peripheral interface (spi)? removed the following sections, which are now available in the related section of the dspic33f/pic24h family reference manual: ? 14.1 ?interrupts? ? 14.2 ?receive operations? ? 14.3 ?transmit operations? ? 14.4 ?spi setup? (retained figure 1 4-1: spi module block diagram)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 272 ? 2007-2011 microchip technology inc. section 15.0 ?inter-integrated circuit (i 2 c?)? removed the following sections, which are now available in the related section of the dspic33f/pic24h family reference manual: ? 15.3 ?i 2 c interrupts? ? 15.4 ?baud rate generator? (retained figure 15-1: i 2 c block diagram) ? 15.5 ?i 2 c module addresses? ? 15.6 ?slave address masking? ? 15.7 ?ipmi support? ? 15.8 ?general call address support? ? 15.9 ?automatic clock stretch? ? 15.10 ?software controlled clock stretching (stren = 1 )? ? 15.11 ?slope control? ? 15.12 ?clock arbitration? ? 15.13 ?multi-master communication, bus collision, and bus arbitration? ? 15.14 ?peripheral pin select limitations? section 16.0 ?universal asynchronous receiver transmitter (uart)? removed the following sections, which are now available in the related section of the dspic33f/pic24h family reference manual: ? 16.1 ?uart baud rate generator? ? 16.2 ?transmitting in 8-bit data mode? ? 16.3 ?transmitting in 9-bit data mode? ? 16.4 ?break and sync transmit sequence? ? 16.5 ?receiving in 8-bit or 9-bit data mode? ? 16.6 ?flow control using uxcts and uxrts pins? ? 16.7 ?infrared support? removed irda references and note 1, and updated the bit and bit value descriptions for utxinv (uxsta<14>) in the uartx status and control register (see register 16-2). section 17.0 ?10-bit/12-bit analog- to-digital converter (adc)? removed equation 17-1: adc conversion clock period and figure 17-2: adc transfer function (10-bit example). added adc1 module block diagram for pic24hfj16gp304 and PIC24HJ32GP204 devices (figure 17-1) and adc1 module block diagram for pic24hj32gp202 devices (figure 17-2). added note 2 to figure 17-3: adc conversion clock period block diagram. added device-specific information to no te 1 in the adc1 input scan select register low (see register 17-6), and updated the default bit value for bits 12-10 (css12-css10) from u-0 to r/w-0. added device-specific information to no te 1 in the adc1 port configuration register low (see register 17-7), and updated the default bit value for bits 12-10 (pcfg12-pcfg10) from u-0 to r/w-0. table 25-1: major section updates (continued) section name update description
? 2007-2011 microchip technology inc. ds70289j-page 273 pic24hj32gp202/204 and pic24hj16gp304 section 18.0 ?special features? added ficd register information fo r address 0xf8000e in the device configuration register map (see table 18-1). added ficd register content (bkbug, coe, jtagen, and ics<1:0> to the pic24hj32gp202/204 and pic24hj16gp304 configuration bits description (see table 18-2). added a note regarding the placement of low-esr capacitors, after the second paragraph of section 18.2 ?on-chip voltage regulator? and to figure 18-1. removed the words ?if enabled? from the second sentence in the fifth paragraph of section 18.3 ?bor: brown-out reset? . section 21.0 ?electrical characteristics? removed typ value for parameter dc12 (see table 21-4). updated mips conditions for para meters dc24c, dc44c, dc72a, dc72f and dc72g (see table 21-5, table 21-6 and table 21-8). added note 4 (reference to new table containing digital-only and analog pin information to i/o pin input sp ecifications (see table 21-9). updated min, typ, and max values and updated min values for program memory parameters d136, d137 and d138 (see table 21-12). updated max value for internal rc accuracy parameter f21 for -40c t a +125c condition and added note 2 (see table 21-19). removed all values for reset, watchdog timer, oscillator start-up timer, and power-up timer parameter sy20 and updated conditions, which now refers to section 18.4 ?watchdog timer (wdt)? and lprc parameter f21 (see table 21-21). updated min and typ values for parameters ad60, ad61, ad62 and ad63 and removed note 3 (see table 21-37). updated min and typ values for parameters ad60, ad61, ad62 and ad63 and removed note 3 (see table 21-38). table 25-1: major section updates (continued) section name update description
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 274 ? 2007-2011 microchip technology inc. revision c (december 2008) this revision includes minor typographical and formatting changes throughout the data sheet text. the major changes are referenced by their respective section in the following table. table 25-2: major section updates section name update description ?high-performance, 16-bit microcontrollers? updated all pin diagrams to denote the pin voltage tolerance (see ?pin diagrams? ). section 2.0 ?guidelines for getting started with 16-bit microcontrollers? added new section to the data sheet t hat provides guidelines on getting started with 16-bit microcontrollers. section 10.0 ?i/o ports? updated 5v tolerant status for i/o pin rb4 from yes to no (see table 10-1). section 22.0 ?electrical characteristics? removed the maximum value for para meter dc12 (ram data retention voltage) in table 22-4. updated typical values for operating current (i dd ) and added note 3 in table 22-5. updated typical and maximum values for idle current (i idle ): core off clock on base current and added note 3 in table 22-6. updated typical and maximum values for power down current (i pd ) and added note 5 in table 22-7. updated typical and maximum values for doze current (id oze ) and added note 2 in table 22-8. added note 3 to table 22-12. updated minimum value for internal voltage regulator specifications in table 22-13. added parameter os42 (g m ) and notes 4, 5, and 6 to table 22-16. added notes 2 and 3 to table 22-17. added note 2 to table 22-20. added note 2 to table 22-21. added note 2 to table 22-22. added note 1 to table 22-23. added note 1 to table 22-24. added note 3 to table 22-32. added note 2 to table 22-33. updated typical value for parameter ad08 (adc in operation) and added notes 2 and 3 in table 22-34. updated minimum, typical, and maximum values for parameters ad23a, ad24a, ad30a, ad32a, ad32a, and ad34a, and added notes 2 and 3 in table 22-35. updated minimum, typical, and maximum values for parameters ad23b, ad24b, ad30b, ad32b, ad32b, and ad34b, and added notes 2 and 3 in table 22-36.
? 2007-2011 microchip technology inc. ds70289j-page 275 pic24hj32gp202/204 and pic24hj16gp304 revision d (june 2009) this revision includes minor typographical and formatting changes throughout the data sheet text. global changes include: ? changed all instances of osci to osc1 and osco to osc2 ? changed all instances of pgcx/emucx and pgdx/emudx (where x = 1, 2, or 3) to pgecx and pgedx changed all instances of v ddcore and v ddcore /v cap to v cap /v ddcore all other major changes are referenced by their respective section in the following table. table 25-3: major section updates section name update description ?high-performance, 16-bit microcontrollers? added note 2 to the 28-pin qfn-s and 44-pin qfn pin diagrams, which references pin connections to v ss . section 8.0 ?oscillator configuration? updated the oscillator system diagram (see figure 8-1). added note 1 to the oscillator tuning (osctun) register (see register 8-4). section 10.0 ?i/o ports? removed table 10-1 and added reference to pin diagrams for i/o pin availability and functionality. section 15.0 ?serial peripheral interface (spi)? added note 2 to the spix control register 1 (see register 15-2). section 17.0 ?universal asynchronous receiver transm itter (uart)? updated the utxinv bit settings in the uxsta register and added note 1 (see register 17-2). section 22.0 ?electrical characteristics? updated the min value for parameter dc12 (ram retention voltage) and added note 4 to the dc temperature and voltage specifications (see table 22-4). updated the min value for parameter di35 (see table 22-20). updated ad08 and added reference to note 2 for parameters ad05a, ad06a, and ad08a (see table 22-34).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 276 ? 2007-2011 microchip technology inc. revision e (november 2009) the revision includes the following global update: ? added note 2 to the shaded table that appears at the beginning of each chapter. this new note provides information regarding the availability of registers and their associated bits this revision also includes minor typographical and formatting changes throughout the data sheet text. all other major changes are referenced by their respective section in the following table. revision f (november 2009) this revision includes minor typographical and formatting changes throughout the data sheet text. all other major changes are referenced by their respective section in the following table. table 25-4: major section updates section name update description ?high-performance, 16-bit microcontrollers? added information on high temperature operation (see ?operating range:? ). section 10.0 ?i/o ports? changed the reference to digital-only pins to 5v tolerant pins in the second paragraph of section 10.2 ?open-drain configuration? . section 17.0 ?universal asynchronous receiver transmitter (uart)? updated the two baud rate range features to: 10 mbps to 38 bps at 40 mips. section 18.0 ?10-bit/12-bit analog-to-digital converter (adc)? updated the adc1 block diagrams (see figure 18-1 and figure 18-2). section 19.0 ?special features? updated the second paragraph and removed the fourth paragraph in section 19.1 ?configuration bits? . updated the device configurati on register map (see table 19-1). section 22.0 ?electrical characteristics? updated the absolute maximum ratings for high temperature and added note 4. updated the spix module slave mode (cke = 1 ) timing characteristics (see figure 22-12). section 23.0 ?high temperature electrical characteristics? added new chapter with high temperature specifications. ?product identification system? added the ?h? definition for high temperature. table a-1: major section updates section name update description ?high-performance, 16-bit microcontrollers? updated mips rating from 16 to 20 for high temperature devices in ?operating range:? and in table 23-1: ?operating mips vs. voltage? .
? 2007-2011 microchip technology inc. ds70289j-page 277 pic24hj32gp202/204 and pic24hj16gp304 revision g (january 2011) this revision includes typographical and formatting changes throughout the data s heet text. in addition, all instances of v ddcore have been removed. all other major changes are referenced by their respective section in the following table. table a-2: major section updates section name update description high-performance, 16-bit microcontrollers added the ssop package information (see ?packaging:? , table 1, and ?pin diagrams? ). section 2.0 ?guidelines for getting started with 16-bit mi crocontrollers? the frequency limitation for device pll start-up conditions was updated in section 2.7 ?oscillator valu e conditions on device start-up? . the second paragraph in section 2.9 ?unused i/os? was updated. section 4.0 ?memory organization? updated the data memory reference in the third paragraph in section 4.2 ?data address space? . the all resets values for the following sfrs in the timer register map were changed (see table 4-5): ?tmr1 ?tmr2 ?tmr3 section 8.0 ?oscillator configuration? added note 3 to the osccon: osci llator control register (see register 8-1). added note 2 to the clkdiv: clock divisor register (see register 8-2). added note 1 to the pllfbd: pll feedback divisor register (see register 8-3). added note 2 to the osctun: frc oscillator tuning register (see register 8-4). section 18.0 ?10-bit/12-b it analog-to-digital converter (adc)? updated the v refl references in the adc1 module block diagrams (see figure 18-1 and figure 18-2). section 19.0 ?special features? added a new paragraph and removed the third paragraph in section 19.1 ?configuration bits? . added the column ?rtsp effects? to the configuration bits descriptions (see table 19-2).
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 278 ? 2007-2011 microchip technology inc. section 22.0 ?electrical characteristics? added 28-pin ssop thermal packaging characteristics (see table 22-3). removed note 4 from the dc temperature and voltage specifications (see table 22-4). updated the maximum value for parameter di19 and added parameters di28, di29, di60a, di60b , and di60c to the i/o pin input specifications (see table 22-9). updated note 3 in the pll clock timing specifications (see table 22-17). removed note 2 from the ac characteristics: internal rc accuracy (see table 22-18). updated the characteristic description for parameter di35 in the i/o timing requirements (see table 22-20). updated all spi specifications (see table 22-28 through table 22-35 and figure 22-10 through figure 22-16). added note 4 to the 12-bit ad c module specifications (see table 22-39). added note 4 to the 10-bit ad c module specifications (see table 22-40). section 23.0 ?high temperature electrical characteristics? updated all ambient temperatur e end range values to +150oc throughout the chapter. updated the storage temper ature end range to +160oc. updated the maximum junction tem perature from +145oc to +155oc. updated note 1 in the pll clock timing specifications (see table 23-10). added note 3 to the 12-bit mode adc module specifications (see table 23-17). added note 3 to the 10-bit mode adc module specifications (see table 23-18). section 24.0 ?packaging information? added the 28-lead ssop package information (see section 24.1 ?package marking information? and section 24.2 ?package details? ). ?product identification system? added the ?ss? definition for the ssop package. table a-2: major section updates (continued) section name update description
? 2007-2011 microchip technology inc. ds70289j-page 279 pic24hj32gp202/204 and pic24hj16gp304 revision h (july 2011) this revision includes typographical and formatting changes throughout the data sheet text. all other major changes are referenced by their respective section in the following table. revision j (july 2012) this revision includes typographical and formatting changes throughout the data sheet text. all other major changes are referenced by their respective section in the following table. table a-3: major section updates section name update description section 19.0 ?special features? added note 3 to the connections for the on-chip voltage regulator diagram (see figure 19-1). section 22.0 ?electrical characteristics? removed note 3 and parameter dc10 (v core ) from the dc temperature and voltage specifications (see table 22-4). updated the characteristics definition and conditions for parameter bo10 in the electrical characteristics: bor (see table 22-11). added note 1 to the internal volt age regulator specifications (see table 22-13 ). table a-4: major section updates section name update description section 22.0 ?electrical characteristics? added note 1 to the operat ing mips vs. voltage (see table 22-1 ). updated the notes in the following tables: ? operating current (i dd ) (see ta b l e 2 2 - 5 ) ? idle current (i idle ) (see table 22-6 ) ? power-down current (i pd ) (see ta b l e 2 2 - 7 ) ? doze current (i doze ) (see table 22-8 ) updated the conditions for program memory parameters d136b, d137b, and d138b (t a = +150oc) (see table 22-12 ). section 23.0 ?high temperature electrical characteristics? removed table 23-8: dc characteristics: program memory. section 24.0 ?dc and ac device characteristics graphs? added new chapter.
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 280 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 281 pic24hj32gp202/204 and pic24hj16gp304 index a a/d converter ................................................................... 165 initialization ............................................................... 165 key features............................................................. 165 ac characteristics .................................................... 211, 247 adc module.............................................................. 250 adc module (10-bit mode) ....................................... 251 adc module (12-bit mode) ....................................... 250 internal rc accuracy ................................................ 213 load conditions ................................................ 211, 247 adc module adc11 register map ...................................... 34, 36, 37 alternate interrupt vector table (aivt) .............................. 63 arithmetic logic unit (alu)................................................. 23 assembler mpasm assembler................................................... 196 b block diagrams 16-bit timer1 module ................................................ 127 a/d module ....................................................... 166, 167 connections for on-chip voltage regulator............. 183 device clock ......................................................... 89, 91 input capture ............................................................ 137 output compare ....................................................... 141 pic24h ....................................................................... 10 pic24h cpu core ...................................................... 18 pll.............................................................................. 91 reset system.............................................................. 53 shared port structure ............................................... 105 spi ............................................................................ 145 timer2 (16-bit) .......................................................... 132 timer2/3 (32-bit) ....................................................... 132 uart ........................................................................ 159 watchdog timer (wdt) ............................................ 184 c c compilers mplab c18 .............................................................. 196 clock switching................................................................... 98 enabling ...................................................................... 98 sequence.................................................................... 98 code examples erasing a program memory page............................... 51 initiating a programming sequence............................ 52 loading write buffers ................................................. 52 port write/read ........................................................ 106 pwrsav instruction syntax....................................... 99 code protection ........................................................ 179, 185 configuration bits.............................................................. 179 description (table).................................................... 180 configuration register map .............................................. 179 configuring analog port pins ............................................ 106 cpu control register .......................................................... 21 cpu clocking system......................................................... 90 options........................................................................ 90 selection ..................................................................... 90 customer change notification service ............................. 283 customer notification service........................................... 283 customer support ............................................................. 283 d data address space ........................................................... 27 alignment.................................................................... 27 memory map for pic24h devices with 8 kbs ram ... 28 near data space ........................................................ 27 software stack ........................................................... 40 width .......................................................................... 27 dc and ac characteristics graphs and tables ................................................... 253 dc characteristics............................................................ 200 doze current (i doze )................................................ 245 high temperature..................................................... 244 i/o pin input specifications ...................................... 206 i/o pin output specifications............................ 209, 246 idle current (i doze ) .................................................. 205 idle current (i idle ) .................................................... 203 operating current (i dd ) ............................................ 202 operating mips vs. voltage ..................................... 244 power-down current (i pd )........................................ 204 power-down current (i pd ) ........................................ 244 program memory...................................................... 210 temperature and voltage......................................... 244 temperature and voltage specifications.................. 201 thermal operating conditions.................................. 244 development support ....................................................... 195 e electrical characteristics .................................................. 199 ac..................................................................... 211, 247 equations device operating frequency...................................... 90 errata .................................................................................... 6 f flash program memory ...................................................... 47 control registers........................................................ 48 operations .................................................................. 48 programming algorithm.............................................. 51 rtsp operation ......................................................... 48 table instructions ....................................................... 47 flexible configuration ....................................................... 179 h high temperature el ectrical charac teristics .................... 243 i i/o ports ........................................................................... 105 parallel i/o (pio) ...................................................... 105 write/read timing.................................................... 106 i 2 c addresses................................................................. 153 operating modes ...................................................... 151 registers .................................................................. 153 i 2 c module i2c1 register map...................................................... 33 in-circuit debugger........................................................... 186 in-circuit emulation .......................................................... 179 in-circuit serial programming (icsp)....................... 179, 186 input capture registers .................................................................. 139 input change notification ................................................. 106 instruction addressing modes ............................................ 40 file register instructions ............................................ 40 fundamental modes supported ................................. 41 mcu instructions ........................................................ 40 move and accumulator instructions ........................... 41
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 282 ? 2007-2011 microchip technology inc. other instructions........................................................ 41 instruction set overview ................................................................... 189 summary................................................................... 187 instruction-based power-saving modes ............................. 99 idle ............................................................................ 100 sleep ........................................................................... 99 internal rc oscillator use with wdt ........................................................... 184 internet address................................................................ 283 interrupt control and status registers................................ 66 iecx ............................................................................ 66 ifsx............................................................................. 66 intcon1 .................................................................... 66 intcon2 .................................................................... 66 ipcx ............................................................................ 66 interrupt setup procedures ................................................. 88 initialization ................................................................. 88 interrupt disable.......................................................... 88 interrupt service routine ............................................ 88 trap service routine .................................................. 88 interrupt vector table (ivt) ................................................ 63 interrupts coincident with power save instructions.......... 100 j jtag boundary scan interface ........................................ 179 m memory organization.......................................................... 25 microchip internet web site .............................................. 283 mplab asm30 assembler, linker, librarian ................... 196 mplab integrated development environment software .. 195 mplab pm3 device programmer..................................... 198 mplab real ice in-circuit emulator system................. 197 mplink object linker/mplib object librarian ................ 196 multi-bit data shifter............................................................ 23 n nvm module register map............................................................... 39 o open-drain configuration ................................................. 106 output compare................................................................ 141 registers ................................................................... 144 p packaging ......................................................................... 257 details ....................................................................... 259 marking ............................................................. 257, 258 peripheral module disable (pmd)..................................... 100 pinout i/o descriptions (table) ............................................ 11 pmd module register map............................................................... 39 porta register map............................................................... 38 portb register map............................................................... 38 power-on reset (por) ....................................................... 59 power-saving features....................................................... 99 clock frequency and switching.................................. 99 program address space ..................................................... 25 construction ................................................................ 42 data access from program memory using program space visibility.................................................... 45 data access from program memory using table instruc- tions .................................................................... 44 data access from, address generation ..................... 43 memory map............................................................... 25 table read instructions tblrdh ............................................................. 44 tblrdl.............................................................. 44 visibility operation ...................................................... 45 program memory interrupt vector ........................................................... 26 organization ............................................................... 26 reset vector ............................................................... 26 r reader response............................................................. 284 registers ad1chs0 (adc1 input channel 0 select ................ 175 ad1chs123 (adc1 input channel 1, 2, 3 select)... 173 ad1con1 (adc1 control 1) .................................... 169 ad1con2 (adc1 control 2) .................................... 171 ad1con3 (adc1 control 3) .................................... 172 ad1cssl (adc1 input scan select low)................ 177 ad1pcfgl (adc1 port configuration low) ............ 177 clkdiv (clock divisor) .............................................. 95 corcon (core control) ...................................... 22, 68 i2cxcon (i2cx control) ........................................... 154 i2cxmsk (i2cx slave mode address mask) ............ 158 i2cxstat (i2cx status) ........................................... 156 icxcon (input capture x control)............................ 139 iec0 (interrupt enable control 0) ......................... 75, 78 iec1 (interrupt enable control 1) ............................... 77 ifs0 (interrupt flag status 0) ..................................... 71 ifs1 (interrupt flag status 1) ..................................... 73 ifs4 (interrupt flag status 4) ..................................... 74 intcon1 (interrupt control 1).................................... 69 intcon2 (interrupt control 2).................................... 70 inttreg interrupt control and status register ........ 87 ipc0 (interrupt priority control 0) ............................... 79 ipc1 (interrupt priority control 1) ............................... 80 ipc16 (interrupt priority control 16) ........................... 86 ipc2 (interrupt priority control 2) ............................... 81 ipc3 (interrupt priority control 3) ............................... 82 ipc4 (interrupt priority control 4) ............................... 83 ipc5 (interrupt priority control 5) ............................... 84 ipc7 (interrupt priority control 7) ............................... 85 nvmcom (flash memory control)....................... 49, 50 ocxcon (output compare x control) ..................... 144 osccon (oscillator control) ..................................... 93 osctun (frc oscillator tuning).............................. 97 pllfbd (pll feedback divisor)................................ 96 pmd1 (peripheral module disable control register 1) ........................................................ 102 pmd2 (peripheral module disable control register 2) ........................................................ 103 rcon (reset control)................................................ 55 spixcon1 (spix control 1)...................................... 148 spixcon2 (spix control 2)...................................... 150 spixstat (spix status and control) ....................... 147 sr (cpu status)................................................... 21, 67 t1con (timer1 control) .......................................... 129 txcon (t2con, t4con, t6con or t8con control)................................................ 134 tycon (t3con, t5con, t7con or t9con control)................................................ 135 uxmode (uartx mode).......................................... 161 uxsta (uartx status and control)......................... 163 reset
? 2007-2011 microchip technology inc. ds70289j-page 283 pic24hj32gp202/204 and pic24hj16gp304 illegal opcode ....................................................... 53, 61 trap conflict.......................................................... 60, 61 uninitialized w register........................................ 53, 61 reset sequence ................................................................. 63 resets ................................................................................. 53 s serial peripheral interface (spi) ....................................... 145 software reset instruction (swr) ...................................... 60 software simulator (mplab sim)..................................... 197 software stack pointer, frame pointer call stack frame...................................................... 40 special features of the cpu ............................................ 179 spi module spi1 register map...................................................... 33 symbols used in opcode descriptions............................. 188 system control register map............................................................... 39 t temperature and voltage specifications ac ..................................................................... 211, 247 timer1 ............................................................................... 127 timer2/3, timer4/5, timer6/7 and timer8/9 ..................... 131 timing characteristics clko and i/o ........................................................... 214 timing diagrams 10-bit a/d conversion............................................... 241 10-bit a/d conversion (chps<1:0> = 01, simsam = 0, asam = 0, ssrc<2:0> = 000) ......................... 241 12-bit a/d conversion (asam = 0, ssrc<2:0> = 000) ........................ 240 brown-out situations................................................... 60 external clock........................................................... 212 i2cx bus data (master mode) .................................. 233 i2cx bus data (slave mode) .................................... 235 i2cx bus start/stop bits (master mode) ................... 233 i2cx bus start/stop bits (slave mode) ..................... 235 input capture (capx)................................................ 219 oc/pwm................................................................... 220 output compare (ocx)............................................. 219 reset, watchdog timer, oscillator start-up timer and power-up timer ......................................... 215 timer1, 2, 3, 4, 5, 6, 7, 8, 9 external clock .............. 217 timing requirements adc conversion (10-bit mode) ................................ 252 adc conversion (12-bit mode) ................................ 252 clko and i/o ........................................................... 214 external clock .......................................................... 212 input capture............................................................ 219 spix master mode (cke = 0) ................................... 248 spix module master mode (cke = 1) ...................... 248 spix module slave mode (cke = 0) ........................ 249 spix module slave mode (cke = 1) ........................ 249 timing specifications 10-bit a/d conversion requirements ....................... 242 12-bit a/d conversion requirements ....................... 240 i2cx bus data requirements (master mode)........... 234 i2cx bus data requirements (slave mode)............. 236 output compare requirements................................ 219 pll clock ......................................................... 213, 247 reset, watchdog timer, oscillator start-up timer, power-up timer and brown-out reset requirements......................................... 216 simple oc/pwm mode requirements ..................... 220 timer1 external clock requirements....................... 217 timer2 external clock requirements....................... 218 timer3 external clock requirements....................... 218 u uart module uart1 register map ................................................. 33 using the rcon status bits............................................... 61 v voltage regulator (on-chip) ............................................ 183 w watchdog time-out reset (wdtr).................................... 60 watchdog timer (wdt)............................................ 179, 184 programming considerations ................................... 184 www address ................................................................. 283 www, on-line support ....................................................... 6
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 284 ? 2007-2011 microchip technology inc. notes:
? 2007-2011 microchip technology inc. ds70289j-page 285 pic24hj32gp202/204 and pic24hj16gp304 the microchip web site microchip provides online support via our www site at www.microchip.com . this web site is used as a means to make files and information easily available to customers. accessible by using your favorite internet browser, the web site contains the following information: ? product support ? data sheets and errata, application notes and sample programs, design resources, user?s guides and hardware support documents, latest software releases and archived software ? general technical support ? frequently asked questions (faqs), technical support requests, online discussion groups, microchip consultant program member listing ? business of microchip ? product selector and ordering guides, latest microchip press releases, listing of seminars and events, listings of microchip sales offices, distributors and factory representatives customer change notification service microchip?s customer notification service helps keep customers current on microchip products. subscribers will receive e-mail notification whenever there are changes, updates, revisions or errata related to a specified product family or de velopment tool of interest. to register, access the microchip web site at www.microchip.com . under ?support?, click on ?customer change notification? and follow the registration instructions. customer support users of microchip products can receive assistance through several channels: ? distributor or representative ? local sales office ? field application engineer (fae) ? technical support ? development systems information line customers should contact their distributor, representative or field application engineer (fae) for support. local sales offices are also available to help customers. a listing of sa les offices and locations is included in the back of this document. technical support is available through the web site at: http://microchip.com/support
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 286 ? 2007-2011 microchip technology inc. reader response it is our intention to provide you with the best document ation possible to ensure succe ssful use of your microchip product. if you wish to provide your comments on organiz ation, clarity, subject matter, and ways in which our documentation can better serve you, please fax your comments to the technical publications manager at (480) 792-4150. please list the following information, and use this outli ne to provide us with your comments about this document. to: technical publications manager re: reader response total pages sent ________ from: name company address city / state / zip / country telephone: (_______) _________ - _________ application (optional): would you like a reply? y n device: literature number: questions: fax: (______) _________ - _________ ds70289j pic24hj32gp202/204 and pic24hj16gp304 1. what are the best features of this document? 2. how does this document meet your hardware and software development needs? 3. do you find the organization of this document easy to follow? if not, why? 4. what additions to the document do you th ink would enhance the structure and subject? 5. what deletions from the document could be made without affecting the overall usefulness? 6. is there any incorrect or misleading information (what and where)? 7. how would you improve this document?
? 2007-2011 microchip technology inc. ds70289j-page 287 pic24hj32gp202/204 and pic24hj16gp304 product identification system to order or obtain information, e.g., on pricing or de livery, refer to the factory or the listed sales office . architecture: 24 = 16-bit microcontroller flash memory family: hj = flash program memory, 3.3v product group: gp2 = general purpose family gp3 = general purpose family pin count: 02 = 28-pin 03 = 44-pin temperature range: i = -40 c to +85 c (industrial) e=-40 c to +125 c (extended) h=-40 c to +150 c (high) package: sp = skinny plastic dual in-line - 300 mil body (spdip) so = plastic small outline - wide - 7.5 mm body (soic) ss = plastic shrink small outline - 5.3 mm body (ssop) mm = plastic quad, no lead package - 6x6 mm body (qfn-s) pt = plastic thin quad flatpack - 10x10x1 mm body (tqfp ml = plastic quad, no lead package - 8x8 mm body (qfn) examples: a) pic24hj32gp202-e/sp: general-purpose pic24h, 32 kb program memory, 28-pin, extended temp., spdip package. microchip trademark architecture flash memory family program memory size (kb) product group pin count temperature range package pattern pic 24 hj 32 gp2 02 t e / sp - xxx tape and reel flag (if applicable)
pic24hj32gp202/204 and pic24hj16gp304 ds70289j-page 288 ? 2007-2011 microchip technology inc. notes:
? 2007-2012 microchip technology inc. ds70289j-page 289 information contained in this publication regarding device applications and the like is prov ided only for your convenience and may be superseded by updates. it is your responsibility to ensure that your application me ets with your specifications. microchip makes no representations or warranties of any kind whether express or implied, written or oral, statutory or otherwise, related to the information, including but not limited to its condition, quality, performance, merchantability or fitness for purpose . microchip disclaims all liability arising from this information and its use. use of microchip devices in life support and/or safe ty applications is entirely at the buyer?s risk, and the buyer agrees to defend, indemnify and hold harmless microchip from any and all damages, claims, suits, or expenses resulting fr om such use. no licenses are conveyed, implicitly or ot herwise, under any microchip intellectual property rights. trademarks the microchip name and logo, th e microchip logo, dspic, k ee l oq , k ee l oq logo, mplab, pic, picmicro, picstart, pic 32 logo, rfpic and uni/o are registered trademarks of microchip technology incorporated in the u.s.a. and other countries. filterlab, hampshire, hi-tech c, linear active thermistor, mxdev, mxlab, seeval and the embedded control solutions company are register ed trademarks of microchip technology incorporated in the u.s.a. analog-for-the-digital age, application maestro, chipkit, chipkit logo, codeguard, dspicdem, dspicdem.net, dspicworks, dsspeak, ecan, economonitor, fansense, hi-tide, in-circuit serial programming, icsp, mindi, miwi, mpasm, mplab certified logo, mplib, mplink, mtouch, omniscient code generation, picc, picc-18, picdem, picdem.net, pickit, pictail, real ice, rflab, select mode, total endurance, tsharc, uniwindriver, wiperlock and zena are trademarks of microchip technology incorporated in the u.s.a. and other countries. sqtp is a service mark of mi crochip technology incorporated in the u.s.a. all other trademarks mentioned herein are property of their respective companies. ? 2007-2012, microchip technology incorporated, printed in the u.s.a., all rights reserved. printed on recycled paper. isbn: 978-1-62076-440-4 note the following details of the code protection feature on microchip devices: ? microchip products meet the specification cont ained in their particular microchip data sheet. ? microchip believes that its family of products is one of the mo st secure families of its kind on the market today, when used i n the intended manner and under normal conditions. ? there are dishonest and possibly illegal meth ods used to breach the code protection fe ature. all of these methods, to our knowledge, require using the microchip pr oducts in a manner outside the operating specif ications contained in microchip?s data sheets. most likely, the person doing so is engaged in theft of intellectual property. ? microchip is willing to work with the customer who is concerned about the integrity of their code. ? neither microchip nor any other semiconduc tor manufacturer can guarantee the security of their code. code protection does not mean that we are guaranteeing the product as ?unbreakable.? code protection is constantly evolving. we at microchip are committed to continuously improving the code protection features of our products. attempts to break microchip?s c ode protection feature may be a violation of the digital millennium copyright act. if such acts allow unauthorized access to your softwa re or other copyrighted work, you may have a right to sue for relief under that act. microchip received iso/ts-16949:2009 certification for its worldwide headquarters, design and wafer fabrication facilities in chandler and tempe, arizona; gresham, oregon and design centers in california and india. the company?s quality system processes and procedures are for its pic ? mcus and dspic ? dscs, k ee l oq ? code hopping devices, serial eeproms, microperi pherals, nonvolatile memory and analog products. in addition, microchip?s quality system for the design and manufacture of development systems is iso 9001:2000 certified. quality ? management ? ? ? ? by ? dnv ? == iso/ts ? 16949 ? == ?
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