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| features applications description typical application TPS23841 slus745a ? november 2006 ? revised may 2007 high-power, wide voltage range, quad-port ethernet power sourcing equipment manager medical/industrial applications at 24 v quad-port power management with integrated switches and sense resistors high power ethernet enterprise switches soho hubs, ethernet hubs high power poe up to 25 w at pd input operating from a 53-v minimum input power ethernet high power mid-spans rail high power pse injectors wide range single supply: 21.5 v up to 57 v i cut = 615 ma, i lim = 650 ma nominal ieee 802.3af compatible the TPS23841 is a high-power, wide voltage range, quad-port sourcing equipment manager. the individual port 15-bit a/d converters TPS23841 can provide up to 570 ma per port over a auto, semi-auto and power management wide temperature range (-40 c to +125 c). each modes port may operate from 21.5 v up to 57 v. the integrated output eliminates two external controlled current ramp power-up/down for components per port (mosfet and sense resistor) emi reduction and survives 100-v transients. four individual 15-bit over-temperature protection a/d converters are used to measure signature dc disconnect detection, supports ac resistance, voltage, current and die temperature, disconnect resulting in a simple and robust pse solution. the TPS23841 comes with a comprehensive software high-speed 400-khz i 2 c interface solution to meet the most demanding applications supports legacy pd detection which can serve as a core for all poe system powerpad? package designs. comprehensive power management software available for mps430 microcontroller please be aware that an important notice concerning availability, standard warranty, and use in critical applications of texas instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. powerpad is a trademark of texas instruments. production data information is current as of publication date. copyright ? 2006?2007, texas instruments incorporated products conform to specifications per the terms of the texas instruments standard warranty. production processing does not necessarily include testing of all parameters. www.ti.com f1 d1 z z retx nx px TPS23841 class det vdd vss rtn tps2376-h optional msp430 micro dc/dc converter sda_o sda_i scl +55v v poe rtn high-current poe xfmr high-current poe xfmr 36 1 2 7 8 rj45 45 36 1 2 7 8 rj45 45 tx rx tx rx up to 100m of cat 5a fb1 fb2 c1 pse pd
description (continued) TPS23841 slus745a ? november 2006 ? revised may 2007 the TPS23841 has three internal supply buses (10 v, 6.3 v and 3.3 v) generated from the 48-v input supply. these supplies are used to bias all internal digital and analog circuitry. each supply has been brought out separately for proper bypassing to insure high performance. the digital supply (3.3 v) is available for powering external loads up to 2 ma. for more demanding loads it is highly recommended to use external buffers to prevent system degradation. when the TPS23841 is initially powered up an internal power-on-reset (por) circuit resets all registers and sets all ports to the off state to ensure that the device is powered up in a known safe operating state. the TPS23841 has three modes of operation; auto mode (am), semi-auto mode (sam) and power management mode (pmm). in auto mode the TPS23841 performs discovery, classification and delivery of power autonomously to a compliant pd without the need of a micro-controller. in semi-auto mode the TPS23841 operates in auto mode but users can access the contents of all read status registers and a/d registers through the i 2 c serial interface. all write control registers are active except for d0 through d3 of port control register 1 (address 0010) for limited port control. the semi-auto mode allows the TPS23841 to detect valid pd's without micro-controller intervention but adds a flexibility to perform power management activities. power management mode (with a micro-controller) allows users additional capabilities of discovering non-compliant (legacy) pds, performing ac disconnect and advanced power management system control that are based on real time port voltages and currents. all functions in this mode are programmed and controlled through read/write registers over the i 2 c interface. this allows users complete freedom in detecting and powering devices. a comprehensive software package is available that mates the power of the TPS23841 with the msp430 micro-controller. TPS23841 integrated output stage provides port power and low-side control. the internal low-side circuitry is designed with internal current sensing so there are no external resistors required. the output design ensures the power switches operate in the fully enhanced mode for low power dissipation. the i 2 c interface allows easy application of opto-coupler circuitry to maintain ethernet port isolation when a ground based micro-controller is required. the TPS23841 five address pins (a1?a5) allow the device to be addressed at one of 31 possible i 2 c addresses. per-port write registers separately control each port state (discovery, classification, legacy, power up, etc) while the read registers contain status information of the entire process along with parametric values of discovery, classification, and real-time port operating current, voltage and die temperature. the proprietary 15-bit integrating a/d converter is designed to meet the harsh environment where the psepm resides. the converter is set for maximum rejection of power line noise allowing it to make accurate measurements of line currents during discovery, classification and power delivery for reliable power management decisions. the TPS23841 is available in either 64-pin powerpad? down (pap) or 64-pin powerpad up (pjd) packages. ordering information temperature range packaged devices (1) t a = t j tqfp ? 64 (pap) (2) tqfp ? 64 (pjd) (2) ?40 c to 125 c TPS23841pap TPS23841pjd (1) the pap and pjd packages are available taped and reeled. add r suffix to device type (e.g.TPS23841papr) to order quantities of 1,000 devices per reel. (2) pap = powerpad down, pjd = powerpad up. 2 submit documentation feedback www.ti.com absolute maximum ratings dissipation ratings (1) recommended operating conditions electro static discharge (esd) protection TPS23841 slus745a ? november 2006 ? revised may 2007 over operating free-air temperature range (unless otherwise noted) (1) (2) parameter value unit v10 current sourced 100 m a v3.3 current sourced 5 ma applied voltage on cint#, ct, rbias ?0.5 to 10 applied voltage on scl, sda_i, sda_o, intb, a1, a2, a3, a4, a5, ms, porb, wd_dis, ?0.5 to 6 v alt_a/b, ac_lo, ac_hi applied voltage on v48, p#, n# ?0.5 to 80 t j junction operating temperature ?40 to 125 t stg storage temperature --55 to 150 ?55 to 150 c t sol lead temperature (soldering, 10 sec.) 260 (1) stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. these are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. (2) all voltages are with respect to gnd. currents are positive into, negative out of the specified terminal. consult packaging section of the data book for thermal limitations and considerations of packages. thermal resistance thermal resistance package junction to case q jc junction to ambient q ja pap 0.38 c/w 21.47 c/w pjd 0.38 c/w 21.47 c/w (1) thermal resistance measured using 2-oz copper trace and copper pad solder following layout recommendation in ti publication powerpad thermally enhanced package technical brief slma002 . over operating free-air temperature range (unless otherwise noted) parameter min nom max unit v in input voltage, v48 pin 21.5 48 57 v t j junction temperature -40 125 c max unit human body model 1.5 cdm 1 kv machine model 0.2 3 submit documentation feedback www.ti.com electrical characteristics TPS23841 slus745a ? november 2006 ? revised may 2007 v48 = 48 v, r t = 124 k w , c t = 220 pf, c int = 0.027 m f (low leakage), ?40 c to 125 c and t a = t j (unless otherwise noted) parameter test conditions min typ max unit power supply v48 quiescent current off mode (all ports) 4 9 12 ma v48 quiescent current powered mode (all ports) 10 14 v10, internal analog supply i load = 0 9.75 10.5 11.5 v v3.3, internal digital supply i load = 0 to 3 ma 3 3.3 3.7 v3.3 short circuit current v = 0 3 12 ma v6.3, internal supply i load = 0 5 6.3 7 v2.5, internal reference supply i load = 0 2.46 2.5 2.54 v uvlo_r , v48 uvlo input voltage rising 16.0 21.5 v v uvlo_f , v48 uvlo input voltage falling 14 21 v hysuv , uvlo hysteresis 0.2 1.0 2.0 internal por time out(i 2 c) after all supplies are good i 2 c activity is valid 8 clock internal por time out (port) after all supplies are good port active to i 2 c 66000 pulses commands port discovery port off #p to #n input resistance 400 600 k w discovery open circuit voltage 22 30 discovery 1 voltage loop control 70 m a < i port < 3 ma 2.8 4.4 v discovery 2 voltage loop control 70 m a < i port < 3 ma 8.8 10 discovery current limit p = n = 48 v 3 4 5 ma auto-mode discovery resistance 19 26.5 acceptance band auto-mode discovery resistance low 0 15 k w end rejection auto-mode discovery resistance high 33 end rejection discovery1,2 a/d conversion scale 100 m a < i port < 3 ma 5.30 6.10 6.75 count/ m a factor discovery1,2 a/d conversion time i port = 120 m a ms port classification classification voltage loop control 100 m a < i port < 50 ma 15 17.5 20 v classification current limit p = n = 48 v 50 60 100 class 0 to 1 detection threshold 5.5 6.5 7.5 class 1 to 2 detection threshold 13 14.5 16 ma class 2 to 3 detection threshold 21 23 25 class 3 to 4 detection threshold 31 33 35 class 4 to 0 detection threshold 45 48 51 classification a/d conversion scale 375 424 475 count/m factor a classification a/d conversion time i port = 50 ma 18 22 ms 4 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 electrical characteristics (continued) v48 = 48 v, r t = 124 k w , c t = 220 pf, c int = 0.027 m f (low leakage), ?40 c to 125 c and t a = t j (unless otherwise noted) parameter test conditions min typ max unit port legacy detection legacy current limit p = n = 48 v 2.6 3.5 4.3 ma legacy voltage a/d conversion scale 100 mv < v port < 17.5 v 1365 1400 1445 count/v factor legacy a/d conversion time 0 v < v port < 15 v 18 22 ms port powered mode port on resistance 20 ma < i port < 300 ma 1.3 1.8 w i cut over current threshold r bias = 124 k w , c t = 220 pf, 570 615 665 i lim output current limit 600 650 700 ma i lim - threshold delta 2 70 i cut disconnect timer current threshold r bias = 124 k w , c t = 220 pf 7.5 10 t mpdo disconnect detection time i load < current threshold, r bias = 124 k w , c t = 300 400 ms 220 pf port output uv 42.0 42.7 44.0 v port output ov 54 55 56 t ovld over current time out r bias = 124 k w , c t = 220 pf 50 75 t lim short circuit time out rbias = 124 k., ct = 220 pf 50 75 ms turn--off delay from uv/ov faults rbias = 124 k., ct = 220 pf, after port enabled 3 and ramped up port current a/d conversion scale 20 ma < i port < 56 v 31 36.41 40 count/m factor a port current a/d conversion time i port < 300 ma 18 22 ms port voltage a/d conversion scale 335 353 370 count/v factor 45 v < v port < 56 v port voltage a/d conversion time 18 22 ms port temperature a/d conversion (17500 - counts)/16 c port disable mode port n voltage p = 48 v 47 v ac lo and ac hi specification ac_lo, ac_hi ? low output voltage 0 0.5 ac_lo ? high output voltage 3.0 5.0 v ac_hi ? high output voltage 5.0 7.0 5 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 electrical characteristics (continued) v48 = 48 v, r t = 124 k w , c t = 220 pf, c int = 0.027 m f (low leakage), ?40 c to 125 c and t a = t j (unless otherwise noted) parameter test conditions min typ max unit digital i 2 c dc specifications scl, sda_i, a1?a5 ,wd_dis, alta/b, ms, porb logic input 1.5 v threshold scl, sda_i input hysteresis 250 mv ms, porb input hysteresis 150 wd_dis, alta/b, ms, porb input input voltage 0.5 to 3 v 50 k w pulldown resistance a1?a5 pull-down current 10 m a sda_o logic high leakage drain = 5 v 100 na sda_o logic low i sink = 10 ma 200 mv intb logic high leakage drain = 6 v 10 m a intb logic low i sink = 10 ma 200 mv digital i 2 c timing scl clock frequency 0 400 khz scl high 0.6 pulse duration scl low 1.3 rise time, scl to sda 0.300 fall time, scl to sda 0.300 setup time, sda to scl 0.250 m s hold time, scl to sda 0.300 0.900 bus free time between start and stop 1.3 setup time, scl to start condition 0.6 hold time, start condition to scl 0.6 setup time, scl to stop condition 0.6 6 submit documentation feedback www.ti.com TPS23841 single port block diagram TPS23841 slus745a ? november 2006 ? revised may 2007 7 submit documentation feedback www.ti.com two 8 bits status register uv/ov comparators two 8 bits status register auto seq logic a2d registers resistor voltage current & die temp analog control circurty diff amp (fix gain) loop cntri amp detect/class modes lca power mode thermal detector ovi thld ovi max i thld 600 k w TPS23841 slus745a ? november 2006 ? revised may 2007 terminal functions terminal no. i/o description name pap pjd power and ground 48-v input to the device. this supply can have a range of 22 v to 57 v. this pin should be decoupled v48 60 5 i with a 0.1- m f capacitor from v48 to ag1 placed as close to the device as possible. 10-v analog supply. the 10-v reference is generated internally and connects to the main internal v10 58 7 o analog power bus. a 0.1- m f de-coupling capacitor should terminate as close to this node and the ag1 pin as possible. do not use for an external supply. 6.3-v analog supply. a 0.1- m f de-coupling capacitor should terminate as close to this pin and the v6.3 59 6 o ag1 pin as possible. do not use for an external supply. 3.3-v logic supply. the 3.3-v supply is generated internally and connects to the internal logic power v3.3 24 41 o bus. a 0.1- m f de-coupling capacitor should terminate as close to this node and the dg pin as possible. this output can be used as a low current supply to external logic. 2.5-v reference supply. the v2.5 is generated internally and connects to the internal reference power v2.5 54 11 o bus. this pin should not be tied to any external supplies. a 0.1- m f de-coupling capacitor should terminate as close to this node and the rg pin as possible. do not use for an external supply. analog ground 1. this is the analog ground of the v6.3, v10 and v48 power systems. it should be ag1 57 8 gnd externally tied to the common copper 48-v return plane. this pin should carry the low side of three de-coupling capacitors tied to v48, v10 and v6.3. analog ground 2. this is the analog ground which ties to the substrate and esd structures of the ag2 61 4 gnd device. it should be externally tied to the common copper 48-v return plane. ag1 and ag2 must be tied together directly for the best noise immunity. digital ground. this pin connects to the internal logic ground bus. it should be externally tied to the dg 23 42 gnd common copper 48-v return plane. reference ground. this is a precision sense of the external ground plane. the integration capacitor (cint) and the biasing resistor (rbias pin) should be tied to this ground. this ground should also be rg 56 9 gnd used to form a printed wiring board ground guard ring around the active node of the integration capacitor (cint). it should tie to common copper 48-v return plane. port analog signal p1 7 58 i port positive. 48-v load sense pin. terminal voltage is monitored and controlled differentially with p2 10 55 i respect to each port n pin optionally, if the application warrants, this high side path can be protected p3 39 26 i with the use of a self resetting poly fuse. p4 42 23 i n1 6 59 i n2 11 54 i port negative. 48-v load return pin. the low side of the load is switched and protected by internal circuitry that will limit the current. n3 38 27 i n4 43 22 i ret1 5 60 i ret2 12 53 i 48 v return pin ret3 37 28 i ret4 44 21 i cint1 4 61 i integration capacitor. this capacitor is used for the ramp a/d converter signal integration. connect a cint2 13 52 i 0.027- m f capacitor from this pin to rg. to minimize errors use a polycarbonate, poly-polypropylene, polystyrene or teflon capacitor type to prevent leakage. other types of capacitors can be used with cint3 36 29 i increased conversion error. cint4 45 20 i 8 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 terminal functions (continued) terminal no. i/o description name pap pjd analog signals this is a dual-purpose pin. when tied to an external capacitor this pin sets the internal clock. when the ct pin is grounded the syn pin turns from a output to an input (see syn pin description) the timing capacitor and the resistor on the rbias pin sets the internal clock frequency of the ct 53 12 i device. this internal clock is used for the internal state machine, integrating a/d counters, por time out, faults and delay timers of each port. using a 220-pf capacitor for ct and a 124-k w resistor for rbias sets the internal clock to 245 khz and ensure ieee 802.3af compliance along with maximizing the rejection of 60-hz line frequency noise from a/d measurements. bias set resistor. this resistor sets all precision bias currents within the chip. this pin will regulate to 1.25v (v2.5/2) when a resistor is connected between rbias and rg. this voltage and rbias generate a current which is replicated and used throughout the chip. this resistor also works in rbias 55 10 i conjunction with the capacitors on ct and cint to set internal timing values. the rbias resistor should be connected rg. rbias is a high impedance input and care needs to be taken to avoid signal injection from the syn pin or i 2 c signals. this is a dual purpose pin. when the ct pin is connected to a timing capacitor this output pin is a 0v to 3.3v pulse of the internal clock which can be used to drive other TPS23841 syn pins for syn 52 13 i/o elimination of a timing capacitor. when the ct pin is grounded this pin becomes an input pin that can be driven from a master TPS23841 or any other clock generator signal. ac_lo 51 14 o totem-pole output pin for ac disconnect excitation. ac_hi 50 15 o totem-pole output pin for ac disconnect excitation. digital signals scl 25 40 i serial clock input pin for the i 2 c interface. serial data input pin for the i 2 c interface. when tied to the sda_o pin, this connection becomes the sda_i 26 39 i standard bi-directional serial data line (sda) serial data open drain output for the i 2 c interface. when tied to the sda_i pin, this connection sda_o 27 38 o becomes the standard bi-directional serial data line (sda). this is a open drain output that can directly drive opto-coupler. the wd_dis pin disables the watchdog timer function when connected to 3.3 v. the pin has internal wd_dis 22 43 i 50-k. resistor to digital ground. the watchdog timer monitors the i 2 c clock pin (scl) and the internal oscillator activity in power management mode and only the internal oscillator activity in auto mode. intb 20 45 o this is an open-drain output that goes low if a fault condition occurs on any of the 4 ports. when this input is set to logic low there is no back-off time after a discovery failure. when this pin set alta/b 21 44 i to a logic high there is a back-off time (approximately 2 seconds) before initiating another discovery cycle. this pin has an internal 50-k w resistor pull-down to digital ground. a1 28 37 i a2 29 36 i address 1 through 5 these are the i 2 c address select inputs. select the appropriate binary address a3 30 35 i on these pins by connecting to the chip ground for a logic low or tying to the v3.3 pin for a logic high. each address line has an internal current source pull-down to digital ground. a4 31 34 i a5 32 33 i the ms pin selects either the auto mode (ms low) or the power management mode, pmm, (ms high). this pin can be held low for controller-less standalone applications. when ms is low and the ms 63 2 i por timing cycle is complete the chip will sequentially discover, classify and power on each port. when ms is set high the ports are controlled by register setting via the i 2 c bus. the ms pin has an internal 50-k w resistor pull-down to analog ground. this pin can be used to override the internal por. when held low, the i 2 c interface, all the state machines, and registers are held in reset. when all internal and external supplies are within specification, and this pin is set to a logic high level, the por delay will begin. the i 2 c interface and porb 62 3 i registers will become active within 70 m s of this event and communications to read or preset registers can begin. the reset delay for the remainder of the chip then extinguishes in 1 second. this pin has an internal 50-k w resistor pull-down to analog ground. 9 submit documentation feedback www.ti.com connection diagram TPS23841 slus745a ? november 2006 ? revised may 2007 (1) nic = no internal connection. pins are floating. (2) nic pins can be tied to the ground plane for improved thermal characteristics and to prevent noise injection from unused pins. (3) nic pins next to cint pins should be tied to ground to prevent noise injection into a/d converter. 10 submit documentation feedback www.ti.com TPS23841 64 pin power pad tqfp_pap TPS23841 slus745a ? november 2006 ? revised may 2007 (1) nic = no internal connection. pins are floating. (2) nic pins can be tied to the ground plane for improved thermal characteristics and to prevent noise injection from unused pins. (3) nic pins next to cint pins should be tied to ground to prevent noise injection into a/d converter. 11 submit documentation feedback www.ti.com laser marker pin 1 identifier powerpad outline top view TPS23841 64 pin power pad up tqfp - pjd auto mode functional description auto mode TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode (am, ms = 0) operation is the basic approach for applying power to ieee compliant pd?s. when am has been selected the TPS23841 automatically performs the following functions: discovery of ieee 802.3af compliant powered devices (pd's) classification power delivery port over/under voltage detection, (if enabled, see over/under voltage fault section) port over current detection (570 ma < i port < 665 ma port maximum current limit (600 ma < i port < 700 ma) dc disconnect (5 ma < i port < 10 ma) thermal shutdown protection (tsd), (t j > 150 c) internal oscillator watchdog in am the contents of all read registers are available via the i 2 c interface. in addition all control registers except for the function bits can be written. this supports a semi-auto mode where the TPS23841 auto detects compliant pd's while a host can access the a/d registers and class information and then implement power management (including turning a port off, responding to faults, etc). the write registers that are still active in am are: all ports disable ? common control register 0001b over/under voltage faults ? common control register 0001b software reset ? common control register 0001b disconnect disable ? port control 1 register 0010b discovery fault disable ? port control 1 register 0010b port enable ? port control 2 register 0011b for alternative b, semi-auto mode implementations which will manipulate the all ports disable or port enable bits, please contact the factory for additional application information. 12 submit documentation feedback www.ti.com auto mode functional description TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) figure 1. the basic flow for auto mode 13 submit documentation feedback www.ti.com update class register portpwr update reg a2d v/i measurements 300 ms am classification TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) after a successful discovery of a valid pd the TPS23841 enters the classification function that identifies the power level based on the pd's current signature. the classification current level is measured at a reduced terminal voltage of 17.5v. during classification the power dissipation can be at its highest; therefore, to prevent over temperature shutdown in automode only one port classifies at a time. when multiple ports successfully discover and proceed to classification at the same time the auto sequencer processes each request separately allowing only one port to enter classification. figure 3 shows all 4 ports successfully detecting a valid pd at the same time and than the classification of each port occurring separately. figure 3. 15 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) upon completion of classification the port classification register is updated. in am mode this information is not used but for semi-auto mode the class information can be used for power management. figure 4 shows actual class currents and the class assignment which were stored in the register. these assignments are compliant with the ieee 802.3af standard figure 4. 16 submit documentation feedback 0 or 1 0 or 1 or 2 0 or 2 or 3 1 2 0 10 20 30 40 60 50 4 32 1 0 www.ti.com am power delivery am faults and intb output TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) after successfully discovery and classification of a valid pd the power is delivered by controlling the current to the pd until its current requirements are met or until the internal current limit is reached (approximately 650 ma). the power switch is fully enhanced after 500 m s. figure 5 show the voltage and the current that is being applied to the pd during power-up and reaching the pd load of 250ma. figure 5. after power has been applied to the pd the TPS23841 automatically enters the current and voltage sample mode. the sample mode performs 31 current measurements and 1 voltage measurement. each measurement takes approximately 18 ms to complete. the port remains powered and the current/voltage measurement cycle continues until a fault condition occurs. the current and voltage measurements are both stored in the a/d current and voltage registers and can be accessed through the i 2 c pins. this allows power management in the am if it is desired. am faults are: port under and over voltage faults, (if enabled, see over/under voltage fault section) over current faults under current (dc disconnect) fault thermal shutdown (tsd) fault watchdog timer faults (disabled via wd_dis pin) any one of the first four fault conditions listed above causes the port to shut down, and a 3-bit fault code to be latched into the affected port's status read 1 register (addr = 0100b). watchdog faults cause all four ports to shut down. faulted ports are temporarily disabled after a fault has been detected and latched. the intb pin is an open-drain, active-low output which is asserted if a fault condition occurs on any of the four ports. this indication is asserted for any of the port faults which result in a code displayed in the port status register (the faults listed in table 8 ). in automode, the fault latch, the status register fault bits, and consequently, intb assertion, are cleared by expiration of the 750-ms ted timer. 17 submit documentation feedback www.ti.com over/under voltage fault TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) for the TPS23841, port over and undervoltge detection is disabled by default after device por. this continuous voltage monitoring feature can subsequently be enabled by writing a logic 1 to bit d2 in the common control register, assuming usage under the direction of a higher level controller, (i.e., usage in semi-auto mode). over/under voltage faults are only processed after port power up has completed (voltage/power ramp to pd is done). the TPS23841 measures the voltage between the p and n pin and if this voltage drops below the under voltage threshold (typically 43 v) or increases above the over voltage threshold (typically 55 v) the voltage timer is turned on. when the voltage timer reaches its time-out limit that is set between 2 ms to 5 ms the corresponding port is turned off and the uv/ov fault code generated in the port status 1 register. if the over/under voltage condition is removed prior to the voltage timer reaching its limit the timer is reset and waits for the next event. figure 6 shows a voltage fault lasting for more then 2 ms that has caused the port to shutdown. figure 6. 18 submit documentation feedback www.ti.com over current or current limit faults TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) over current or current limit faults are conditions when the load current that is being sensed trips either the i cut comparator (570 ma to 665 ma) or the i lim comparator (600 ma to 700 ma) and turns on the current fault timer. when the over current timer reaches its time out limit that is set between 50 ms to 75 ms the corresponding port is turned off and the over current fault code generated in the port status 1 register. if the over current condition goes away prior to the over current timer reaching its limit the timer is reset and waits for the next event. figure 7 shows an over current fault lasting more than 50 ms that has caused the port to shut off. figure 7. 19 submit documentation feedback www.ti.com under current fault (dc modulated disconnect) TPS23841 slus745a ? november 2006 ? revised may 2007 auto mode functional description (continued) under current fault (dc modulated disconnect) is a condition when the load current that is being measured drops below 7.5ma and turns on the disconnect timer. if the disconnect timer reaches its time out limit that is set between 300ms to 400ms the corresponding port is turned off and the load disconnect fault code generated in the port status 1 register. if the under current condition goes away prior to the disconnect timer reaching its limit the timer is reset and the port remains powered. figure 8 shows dc disconnect event. in this setup the load current was set right above the 7.5ma threshold. the duty cycle of the load was then adjusted until the off period exceeded the disconnect time out, causing turn-off of the port. the time-out period was > 300 ms. figure 8. 20 submit documentation feedback www.ti.com power management mode functional description power management mode (pmm) 13 funcitons TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode (pmm) has been designed to work efficiently with simple low-cost microcontrollers such as those in the msp430 family. the power management mode uses 13 self-contained functions to completely control the device operation. you simply write/read through the i 2 c pins and wait for the function done bit to be set. if an a/d measurement was performed during the function the results can be accessed by going to the read mode and addressing the proper register. disable: disable the port and reset all functions. discovery 1: enable the discovery 1 condition which applies a 4.4 v across the pd and measure and store the resulting current. discovery 2: enable the discovery 2 condition which applies a 8.8 v across the pd and measure and store the resulting current. v sample: measure the voltage between the p and n pins and store the result in the a/d voltage register. legacy: enable the 3.5-ma current source formeasuring capacitance and measure the voltage across the p and n terminals and store the result in the a/d voltage register. classify: enable the classification condition which applies 17.7 v across the pd and measure and store the resulting current. rup pwr: turn on the output switch while controlling the current being delivered to the pd until the pd current needs are met or the max current is reached. c sample: continuous cycle of 31 current measurements and 1 voltage measurement. after each measurement the contents of the appropriate register are updated. rdwn: turn off the output switch while controlling current until output current reaches 0 ma. ac lo: turns on low side output fet and measures voltage between p and n pin and store result in a/d voltage registers. ac hi: turns on high side output fet and measures voltage between p and n pin and store result in a/d voltage registers. isample: measure the current and store the result in the a/d current register. tsample: measure the internal die temperature and store the result in the a/d temperature register. conversion times for a/d measurements performed as part of the functions listed above are generally as shown in the typical values in the electrical characteristics table. however, conversion time is somewhat dependant on the magnitude of the input signal being measured. power management mode applications should take precautions to test the a/d done bit (msb of the high byte) of the pertinent results register before accepting or using the returned value. a logic 1 at this bit location indicates the conversion is complete. also, once an a/d conversion is in process on a given port, subsequent function calls to that port should wait until the currently executing conversion is complete. commands written prior to completion may cause the results of the initial conversion to be written to the register of the subsequent function. 21 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) figure 9. 22 submit documentation feedback decoder disable 0000 discover 1 0001 discover 2 0010 v sample 0011 legacy 0100 classify 0101 rup/pwr 0110 c sample 0111 ac lo 1001 ac hi 1010 rdwn 1000 i sample 1011 t sample 1100 power down measure chnl i (18ms) measure chnl v (18 ms) apply 2.5ma (vmax 18) to chnl apply ac lovoltage measure chnl i (18ms) measure die temperature (18ms) reset all functions apply 4.4v (imax5ma) to chnl measure chnl i (18ms) apply 8.8v (imax5ma) to chnl measure chnl v (18ms) apply 18v (imax 100ma) to chnl measure chnl i (18ms) ramppwr 1.4a/msec enable ovr i , ovr v & und v comparators measure chnl i (31 samples) store value i reg ramp down measure chnl v (18ms) apply ac hi voltage measure chnl v (18ms) control register i2c store value discovery i reg set done bit store value discovery i reg store value v reg store value v reg store value i reg 4msdelay start a2d 4 ms delay start a2d set done bit pwr off set done bit store value v reg store value v reg set done bit store value temp reg enable control enable control enable diff amp av 0.107 enable control enable control latch state power on wait for next function call set done bit set done bit set done bit set done bit set done bit wait for next function call set done bit clear on read wait for next function call set done bit set done bit wait for next function call set done bit notes: 1. each function state remains set until a new function is called. example function 1 - port voltage remains at 4.4 v and resistor register value is held. 2. times shown are typical and set by r bias , and c t . 3. poll for and verify a/d done indication prior to sending next function call. wait for next function call wait for next function call wait for next function call if 0111 repeat wait for next function call wait for next function call wait for next function call wait for next function call wait for next function call wait for next function call measure chnl v (1 sample) store value v reg www.ti.com pmm discovery 1 TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) pmm discovery 1 function waveforms for the n and cint pins are shown in figure 10 . the measurement is being performed using 25 k w impedance between the p and n pin. the discovery 1 voltage is allowed to settle for approximately 5ms before the a/d begins integrating. the voltage on the cint pin shows the a/d cycle. there are four distinct regions to any a/d cycle: pre-charge (to a known starting voltage), charge, coarse discharge, and fine discharge. cint pin is very high impedance therefore extreme care must be taken to avoid any noise or leakage affecting this pin. for the measurements where cint voltage is shown a buffer was used to prevent performance degradation. the a/d measurement time is approximately 18ms. the entire discovery 1 function takes approximately 22 ms to complete. at the end of the a/d cycle the discovery 1 current is stored in the discovery current register and the function done bit is set. the applied discovery 1 voltage level remains until a new function is called. the data for this measurement will remain stored in the discovery current register until another discovery 1 or 2 function is called. figure 10. 23 submit documentation feedback www.ti.com pmm discovery 2 pmm classification TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) pmm discovery 2 function waveforms for the n and cint pins are shown in figure 11 . again the measurement is being performed using 25 k w impedance between the p and n pin. the discovery 2 function was called after a discovery 1 function so the voltage ramps from 4.4 v to 8.8 v below the p pin. the discovery 2 voltage is given 5 ms to settle before the a/d begins to integrate. at the end of the a/d cycle the discovery 2 current is stored in the port discovery current register and the function done bit is set. the applied discovery 2 voltage level will remain until a new function is called. the data for this measurement will remain stored in the discovery current register until another discovery 1 or 2 function is called. figure 11. pmm classification function looks similar to discovery 1 and 2 except that the voltage between the p and n pins regulates to approximately 17.5 v. at the end of the a/d cycle the classification current is stored in the port current register and the done bit is set. the applied classification level will remain until a new function is called. the data for this measurement remains stored in the port current register until either the classify or isample function is called. as indicated in the flow diagram of figure 1 , the TPS23841 in am only performs classification at one port at a time. similarly, pmm applications should take care to ensure that only one port per device is put into the classification mode at any one time to limit power dissipation in the package. 24 submit documentation feedback www.ti.com pmm legacy TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) pmm legacy function is used to detect pds that are non compliant. legacy detection uses a current source (typically 3.5 ma) as a test current while the a/d measures the average voltage for approximately 18 ms. the waveform shown in figure 12 is the legacy function charging a 10- m f capacitor. the capacitance charges to a value that is no greater than 20v below the p port voltage. as the capacitor is charging the a/d is accumulating counts in the voltage a/d register. figure 13 shows the relationship between port capacitance and the number of counts. a user can characterize non-compliant pd's signatures and use the legacy function to recognize these devices. figure 12. figure 13. 25 submit documentation feedback www.ti.com pmm rup pwr pmm r dwn TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) pmm rup pwr function turns on the port power by ramping up the current that is being delivered to the load in a controlled fashion. the output current ramps from 0 ma to i lim (typically 650 ma) in approximately 500 m s. figure 14 shows the output voltage and current turning on for a 250-ma load. figure 14. pmm r dwn function turns off the port power by ramping down the current in a controlled fashion. the output current ramps from i lim (typically 650 ma) to 0ma in approximately 300 m s. figure 15 shows the output voltage and current shutting down for a 250-ma load. figure 15. 26 submit documentation feedback www.ti.com t - time - s/div m miscellaneous functional description pmm faults watchdog timer TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) pmm faults are the same as those shown in the am faults and intb output section. in pm mode, the port under- and over voltage and under-current faults can be enabled or disabled by writing to the control bits in the appropriate register. for the TPS23841, port under- and overvoltage detection is disabled by default after device por or other reset operation. under current detection, (dc disconnect), is enabled by default. the enable state of these features can be toggled by writing to the corresponding control bit as defined in table 5 andtable 6 . the pmm faults are: port under- and over-voltage faults (enable/disable via common control register 0001b, bit d2) overcurrent fault (cannot be disabled) under-current (dc disconnect) fault (enable/disable via port control register 0010b, bit d4) thermal shutdown (tsd) fault (cannot be disabled) watchdog fault (disable via wd_dis pin) any one of these faults causes the port to shutdown. once a fault has occurred the port can not be repowered until a disable function is sent. the disable function clears the fault latch and the fault register. intb pin operation is essentially the same in pmm as in am, with the following exceptions: for load under-current to generate a fault shutdown and status indication, the condition of load current less than the threshold must be detected by the continuous sample (c_sample) function (0111b). in pmm only, a watchdog timer fault also asserts intb. TPS23841 has two watchdog timers. one monitors the i 2 c clock and the other monitors the internal clock. when automode is selected and the watchdog timer has not been disabled only the internal clock is monitored. when in power management mode and the watchdog timer has not been disabled then both the i 2 c and internal clocks are monitored. if there is no i 2 c clock activity for approximately two seconds then all ports are disabled. there are three means to enable ports after a i 2 c clock fault and they are: 1. hard power reset 2. porb pulse 3. writing a software reset to the common control register. in both auto mode and power management mode if the internal oscillator is lost for more than 20 ms all ports are disabled. loss of these signals is considered catastrophic since the system loses its ability to talk to each port. therefore the watchdog timers disabling all ports protects the system. this function can be easily over ridden by setting the wd_dis pin high. 27 submit documentation feedback www.ti.com i 2 c interface description TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) the serial interface used in the TPS23841 is a standard 2-wire i 2 c slave architecture. the standard sda line of the i 2 c architecture is broken out into independent input and output data paths. this feature simplifies earth grounded controller applications that require opto-isolators to keep the 48-v return of the ethernet power system floating. for applications where opto-isolation is not required, the bidirectional property of the sda line can be restored by connecting sda_i to sda_o. the scl line is a unidirectional input only line as the TPS23841 is always accessed as a slave device and it never masters the bus. data transfers that require a data-flow reversal on the sda line are 4-byte operations. this occurs during a TPS23841 port read cycle where a slave address byte is sent, followed by a port/register address byte write. a second slave address byte is sent followed by the data byte read using the port/register setup from the second byte in the sequence. the i 2 c interface and the port read write registers are held in active reset until all input voltages are within specifications (v10, v6.3, v3.3 and v2.5) and the internal por timer has timed out (see electrical specifications). the i 2 c read cycle consists of the following steps 1 through 14 and is shown in figure 16 : 1. start sequence (s) 2. device address field 3. write 4. acknowledge 5. register/port address 6. acknowledge 7. stop 8. start 9. device address field 10. read 11. acknowledge 12. data transfer 13. acknowledge 14. stop data write transfers to the TPS23841 do not require a data-flow reversal and as such only a 3-byte operation is required. the sequence in this case would be to send a slave device address byte, followed by a write of the port/register address followed by a write of the data byte for the addressed port. the i 2 c write cycle consists of the following steps 1 through 9 and is also shown in figure 16 : 1. start sequence (s) 2. device address field 3. write 4. acknowledge 5. register/port address 6. acknowledge 7. data for TPS23841 8. acknowledge 9. stop 28 submit documentation feedback www.ti.com start/stop chip address TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) the high-to-low transition of sda_i while scl is high defines the start condition. the low to high transition of sda_i while scl is high defines the stop condition. the master device initiates all start and stop conditions. the first serial packet is enclosed within start and stop bits, consists of a 7-bit address field, read/write bit, and the acknowledge bit. the acknowledge bit is always generated by the device receiving the address or data field. five of the seven address bits are used by the TPS23841. the value of the sixth and seventh bit is ignored and not used by the TPS23841. the address field of the TPS23841 is 8 bits long and contains 5 bits of device address select and a read/write bit as and two spare bits per table 1 . the leading two bits are not used and are reserved for future port expansion. the five device address select bits follow this plan. these bits are compared against the hard-wired state of the corresponding device address select pins (a1?a5). when the field contents are equivalent to the pin logic states, the device is addressed. these bits are followed by lsb bit, which is used to set the read or write condition (1 for read and 0 for write). following a start condition and an address field, the TPS23841 responds with an acknowledge by pulling the sda_o line low during the 9 th clock cycle if the address field is equivalent to the value programmed by the pins. the sda_o line remains a stable low while the 9 th clock pulse is high. figure 16. i 2 c read/write cycles 29 submit documentation feedback www.ti.com scl sda clock data 1 value clock data 1 value clock data 0 value clock data 1 value write cycle sda_i read cycle sda_o a7 a6 a5 a4 a3 a2 a1 a0 d7 r3 r2 r1 r0 d2 p1 p0 d7 d6 d5 d4 d3 d2 d1 d0 a7 a6 a5 a4 a3 a2 a1 a0 d7 r3 r2 r1 r0 d2 p1 p0 a7 a6 a5 a4 a3 a2 a1 a0 d7 d6 d5 d4 d3 d2 d1 d0 start bit deviceaddress r/w=0 r/w bit register/port address data from master to TPS23841 stop bit r/w bit start bit deviceaddress r/w=0 register/port address deviceaddress r/w=1 r/w bit data from TPS23841to master stop bit start bit ack bit ack bit ack bit ack bit ack bit ack bit ack bit start/stop sequence stop condition(p) start condition(s) sda_o sda_i chip addressing port/register cycle data write cycle TPS23841 slus745a ? november 2006 ? revised may 2007 power management mode functional description (continued) table 1 shows the bit assignments during the addressing cycle. table 1. address selection field bit function a7 future expansion (value not compared) a6 future expansion (value not compared) a5 device address. compared with pin a5 a4 device address. compared with pin a4 a3 device address. compared with pin a3 a2 device address. compared with pin a2 a1 device address lsb. compared with pin a1 a0 read/write after the chip address cycle, the TPS23841 accepts eight bits of port/register select data as defined in table 2 . the scl line high-to-low transition after the eighth data bit then latches the selection of the appropriate internal register for the follow-on data read or write operation. after latching the eight-bit data field, the TPS23841 pulls the sda_o line low for one clock cycle, for the acknowledge pulse. for a data write sequence, after the port/register address cycle, the TPS23841 accepts the eight bits of data as defined in the tables below. the data is latched into the previously selected write register, and the TPS23841 generates a data acknowledge pulse by pulling the sda_o line low for one clock cycle. common register functions act on all ports simultaneously. per port registers are specific to the target port only. to reset the interface, the host or master subsequently generates a stop bit by releasing the sda_i line during the clock-high portion of an scl pulse. 30 submit documentation feedback www.ti.com data read cycles TPS23841 slus745a ? november 2006 ? revised may 2007 for a data read sequence, after the register acknowledge bit, the master device generates a stop condition. this is followed by a second start condition, and re-transmitting the device address as described in chip address above. for this cycle, however, the r/w bit is set to a 1 to signal the read operation. the TPS23841 again responds with an acknowledge pulse. the address acknowledge is then followed by sequentially presenting each of the eight data bits on the sda_o line (msb first), to be read by the host device on the rising edges of scl. after eight bits are transmitted, the host acknowledges by pulling the sda_i line high for one clock pulse. the completed data transfer is terminated with the host generating a stop condition. table 2. register/port addressing map bit function state preset state d7 unused 0 0 d6 register select msb 0000 = common read - port fault status, chip id and rev. 0001 = common control write - software reset, ports disable and ac disc. d5 register select bit 2 0010 = port control write 1 - function calls; misc. fault disables d4 register select bit 1 0011 = port control write 2 - port enable; a/d control 0100 = port status read 1 - fault status; device class info. 0101 = port status read 2 - function and other status 0110 = discovery current - lower bits - a/d resistance results 0111 = discovery current - upper bits - a/d resistance results 0000 1000 = voltage-lower bits - a/d voltage reslts 1001 = voltage - upper bits - a/d voltage results d3 register select lsb 1010 = current - lower bits - a/d current results 1011 = current - upper bits - a/d current results 1100 = temperature - lower bits - a/d temperature results 1101 = temperature - upper bits - a/d temperature results 1110 = unused 1111 = common write - test mode selections - timer disables, discovery control, etc. d2 unused 0 0 d1 port address msb 00 = port 1 00 01 = port 2 d0 port address lsb 10 = port 3 11 = port 4 31 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 table 3. common read, register select = 0000 bit function state preset state port 4 general 0 = no fault d7 0 fault status 1 = port fault (1) (2) port 3 general 0 = no fault d6 0 fault status 1 = port fault (1) (2) port 2 general 0 = no fault d5 0 fault status 1 = port fault (1) (2) port 1 general 0 = no fault d4 0 fault status 1 = port fault (1) (2) d3 00 = rev ? 01 = rev 1 chip rev 00 10 = rev 2 d2 11 = rev 3 d1 00 = TPS23841 01= future use chip id 00 10 = tps2384 d0 11 = reserved (1) pmm faults cleared by disable function. (2) am faults cleared by ted timer. table 4. common write, register select = 1111 (test register) (1) bit function state preset state d7 unused 0 0 d6 thermal shutdown test 0 = normal operation 0 1 = force tsd condition (all ports off) d5 por disable 0 = normal por timing 0 1 = force por to a non-reset state d4 discovery timers 0 = normal (4-ms discovery 1 and discovery 2) 0 1 = timers disable d3 discovery 1 and 2 0 = normal operation 0 1 = all 4-port discovery 1 and discovery 2 ? halt d2 dc disconnect timer 0 = dc disconnect timer between 300 ms to 400 ms for loads less than 5 ma (ieee 0 standard) 1 = dc disconnect timer 0 ms for loads less than 5 ma d1 ted timer 0 = normal operation 0 1 = 750-ms ted timer disable d0 unused 0 0 (1) test mode select; not intended for end--application use. 32 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 table 5. common control write, register select = 0001 bit function state preset state d7 unused 0 0 d6 unused 0 0 d5 thermal shutdown fault (1) 0 = active 0 1 = disable d4 ac high 0 = off 0 1 = ac_hi driver on d3 ac low 0 = off 0 1 = ac_lo driver on d2 port over/under voltage faults 0 = disable 0 1 = active d1 all ports disable (2) 0 = normal operation 0 1 = all ports shut down (no ramp) d0 software reset 0 = normal operation 0 1 = reset all circuits and start a por timing cycle (1) register 0001, bit d5 operation inhibited after device probe. (2) consult factory for alternative b, semi-auto mode implementations which write to bit d1. table 6. port control write 1, register select = 0010 (one per port) bit function state preset state d7 unused 0 0 d6 unused 0 0 0 = normal operation d5 discovery fault disable 0 1 = disable internal discovery fault limits (19 k w to 29.5 k w ) 0 = dc disconnect active d4 dc disconnect disable 0 1 = dc disconnect disable (for ac disconnect) d3 function bit 3 0000 = disable function (power down and reset all functions) 0001 = discovery 1 function d2 function bit 2 0010 = discovery 2 function d1 function bit 1 0011 = port voltage sample function (v sample) 0100 = legacy detection function 0101 = classification function 0110 = ramp up/power function (rup pwr) 0111 = continuous sample function c sample) 0000 1000 = ramp power down function r dwn ) 1001 = ac low d0 function bit 0 1010 = ac high 1011 = port current sample function (i sample) 1100 = die temperature sample function (t sample) 1101 = spare 1110 = spare 1111 = spare 33 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 table 7. port control write 2, register select = 0011 (one per port) bit function state preset state d7 unused 0 0 d6 unused 0 0 d5 unused 0 0 d4 port enable (1) 0 = normal 0 1 = port disable d3 a/d start 0 = normal 0 1 = start a/d (self clearing) d2 a/d abort 0 = normal 0 1 = abort d1 unused 0 0 d0 unused 0 0 (1) consult factory for alternative b, semi-auto mode implementations which write to bit d4. table 8. port status read 1, register select = 0100 (one per port) bit function state preset state 0 = normal d7 discovery status 0 1 = discovery fail 0 = normal d6 function done bit 0 1 = function complete (self clearing by a new function write) d5 port class 000 = class 0 001 = class 1 d4 port class 010 = class 2 000 011 = class 3 d3 port class 100 = class 4 d2 fault status (msb) 000 = no faults 001 = uv/ov fault d1 fault status 010 = thermal shutdown fault (tsd) 011 = overload current > 50-ms fault 000 100 = load disconnect d0 fault status (lsb) 101 = reserved for future 110 = reserved for future 111 = reserved for future 34 submit documentation feedback www.ti.com a/d results registers (discovery current, voltage, current and temperature) TPS23841 slus745a ? november 2006 ? revised may 2007 table 9. port status read 2, register select = 0101 (one per port) bit function state preset state d7 unused 0 0 d6 unused 0 0 d5 unused 0 0 d4 0 = not active watch dog timer 0 1 = active d3 0 = not active a/d status 0 1 = active (conversion in process) d2 function status (msb) 000 = disabled 001 = searching d1 function status 010 = power delivery d0 011 = fault 000 100 = test function status (lsb) 101 = other fault 110 = undefined 111 = undefined table 10. discovery current ? lower bits, register select = 0110 (one per port) bit function state preset state d7 a/d bit 7 a/d lower bits 0 d6 a/d bit 6 d5 a/d bit 5 d4 a/d bit 4 d3 a/d bit 3 d2 a/d bit 2 d1 a/d bit 1 d0 a/d bit 0 table 11. discovery current ? upper bits, register select = 0111 (one per port) bit function state preset state d7 resistor measurement 0 = measurement active (bit set low at the start of discovery 1 or discovery 2) 0 complete 1 = measurement complete (bit set high after a/d is completed during discovery 1 or discovery 2) d6 a/d bit 14 a/d upper bits 0 d5 a/d bit 13 d4 a/d bit 12 d3 a/d bit 11 d2 a/d bit 10 d1 a/d bit 9 d0 a/d bit 8 35 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 table 12. voltage ? lower bits, register select = 1000 (one per port) bit function state preset state d7 a/d bit 7 a/d lower bits 0 d6 a/d bit 6 d5 a/d bit 5 d4 a/d bit 4 d3 a/d bit 3 d2 a/d bit 2 d1 a/d bit 1 d0 a/d bit 0 table 13. voltage ? upper bits, register select = 1001 (one per port) bit function state preset state d7 voltage measurement 0 = measurement active (bit set low when a/d begins a voltage measurement) 0 complete 1 = measurement complete (bit set high after a/d has completed a voltage measurement) d6 a/d bit 14 a/d upper bits 0 d5 a/d bit 13 d4 a/d bit 12 d3 a/d bit 11 d2 a/d bit 10 d1 a/d bit 9 d0 a/d bit 8 table 14. current ? lower bits, register select = 1010 (one per port) bit function state preset state d7 a/d bit 7 a/d lower bits 0 d6 a/d bit 6 d5 a/d bit 5 d4 a/d bit 4 d3 a/d bit 3 d2 a/d bit 2 d1 a/d bit 1 d0 a/d bit 0 36 submit documentation feedback www.ti.com TPS23841 slus745a ? november 2006 ? revised may 2007 table 15. current ? upper bits, register select = 1011 (one per port) bit function state preset state d7 current measurement 0 = measurement active (bit set low when a/d begins a current measurement) 0 complete 1 = measurement complete (bit set high after a/d has completed a current measurement) d6 a/d bit 14 a/d upper bits 0 d5 a/d bit 13 d4 a/d bit 12 d3 a/d bit 11 d2 a/d bit 10 d1 a/d bit 9 d0 a/d bit 8 table 16. temperature ? lower bits, register select = 1100 (one per port) bit function state preset state d7 a/d bit 7 a/d lower bits 0 d6 a/d bit 6 d5 a/d bit 5 d4 a/d bit 4 d3 a/d bit 3 d2 a/d bit 2 d1 a/d bit 1 d0 a/d bit 0 table 17. temperature ? upper bits, register select = 1101 (one per port) bit function state preset state d7 temperature 0 = measurement active (bit set low when a/d begins a temperature measurement) 0 measurement complete 1 = measurement complete (bit set high after a/d has completed a temperature measurement) d6 a/d bit 14 a/d upper bits 0 d5 a/d bit 13 d4 a/d bit 12 d3 a/d bit 11 d2 a/d bit 10 d1 a/d bit 9 d0 a/d bit 8 37 submit documentation feedback www.ti.com TPS23841 ac drive application schematic TPS23841 slus745a ? november 2006 ? revised may 2007 figure 17. ac_hi and ac_lo with external fet configuration 38 submit documentation feedback www.ti.com TPS23841 system block diagram TPS23841 slus745a ? november 2006 ? revised may 2007 note: a fuse may be required to provide additional protection if isolation is lost or the low-side current sense fails. figure 18. 39 submit documentation feedback www.ti.com 36 12 45 7 8 rj-45 w/grn grn w/org org blue w/blue w/brn brn 568a 36 12 45 7 8 rj-45 w/grn grn w/org org blue w/blue w/brn brn 568a tx rx rx tx switch/hub powered dte pd signature pd dc-dc supply 48v supply up to 350ft category 5 cable msp430 controller + - pptc fuse TPS23841 pse (1port) p v48 gnd n opticallycoupled i2c serial bus ct choke ct choke ct choke ct choke ret TPS23841 basic 4-port (pmm) isolated configuration with ac disconnect TPS23841 slus745a ? november 2006 ? revised may 2007 TPS23841 basic 4-port isolated configuration with ac disconnect (pap pinout shown). figure 19. 40 submit documentation feedback www.ti.com 64 62 12 3 4 5 6 7 8 9 10 11 12 17 18 19 20 13 14 15 16 21 22 23 24 25 26 27 28 29 30 31 32 61 48 34 33 porb v10 ag2 v2.5 rg rbias ct syn ag1 v48 p1 n1 ret1 cint1 p2 n2 ret2 cint 2 p4 n4 cint4 p3 n3 ret3 cint3 ms ret4 v3 dg scl sda_i sda_o a2 a3 a4 a5 a1 v6.3 alta/b wd_dis TPS23841 quad psecontroller int ac_lo ac_hi 63 60 58 57 59 56 54 53 55 52 50 49 51 47 46 45 44 43 42 41 40 39 38 37 35 36 rj45-5 xformer 0.1uf 0.1uf 0.1uf 124k 220pf 0.027uf 0.027uf 220nf 0.1uf 48v bus pos neg rj45-5 xformer 220nf rj45-5 xformer rj45-5 xformer 7.5k 7.5k 7.5k 7.5k 68uf 0.027uf 0.027uf 220nf 270 270 v dd cpu gnd cpu sda_in por 9.1k 270 sda_ou t int scl 3.9k 3.9k 3.9k 9.1k 3.9k 3.9k 0.1uf + - 0.5w 0.5w open drain open drain open drain 220nf auto function tape and reel information *all dimensions are nominal device package type package drawing pins spq reel diameter (mm) reel width w1 (mm) a0 (mm) b0 (mm) k0 (mm) p1 (mm) w (mm) pin1 quadrant TPS23841papr htqfp pap 64 1000 330.0 24.4 13.0 13.0 1.5 16.0 24.0 q2 package materials information www.ti.com 18-aug-2014 pack materials-page 1 *all dimensions are nominal device package type package drawing pins spq length (mm) width (mm) height (mm) TPS23841papr htqfp pap 64 1000 367.0 367.0 45.0 package materials information www.ti.com 18-aug-2014 pack materials-page 2 www.ti.com important notice texas instruments incorporated and its subsidiaries (ti) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per jesd46, latest issue, and to discontinue any product or service per jesd48, latest issue. buyers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. all semiconductor products (also referred to herein as ? 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