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isp1581 universal serial bus 2.0 high-speed interface device rev. 02 23 october 2000 objective speci?cation c c 1. general description the isp1581 is a cost-optimized and feature-optimized universal serial bus (usb) interface device, which fully complies with the universal serial bus speci?cation rev. 2.0 . it provides high-speed usb communication capacity to systems based on a microcontroller or microprocessor. the isp1581 communicates with the systems microcontroller/processor through a high-speed general-purpose parallel interface. the isp1581 supports automatic detection of usb 2.0 system operation. the usb 1.1 fall-back mode allows the device to remain operational under full-speed conditions. it is designed as a generic usb interface device so that it can ?t into all existing device classes, such as: imaging class, mass storage devices, communication devices, printing devices and human interface devices. the internal generic dma block allows easy integration into data streaming applications. in addition, the various con?gurations of the dma block are tailored for mass storage applications. the modular approach to implementing a usb interface device allows the designer to select the optimum system microcontroller from the wide variety available. the ability to re-use existing architecture and ?rmware investments shortens the development time, eliminates risk and reduces costs. the result is fast and ef?cient development of the most cost-effective usb peripheral solution. the isp1581 is ideally suited for many types of peripherals, such as: printers; scanners; magneto-optical (mo), compact disc (cd), digital video disc (dvd) and zip ? /jaz ? drives; digital still cameras; usb-to-ethernet links; cable and dsl modems. the low power consumption during suspend mode allows easy design of equipment that is compliant to the acpi?, onnow? and usb power management requirements. the isp1581 also incorporates features such as softconnect?, a reduced frequency crystal oscillator and integrated termination resistors. these features allow signi?cant cost savings in system design and easy implementation of advanced usb functionality into pc peripherals.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 2 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 2. features n complies fully with universal serial bus speci?cation rev. 2.0 n complies with most device class speci?cations n high performance usb interface device with integrated serial interface engine (sie), fifo memory, data transceiver and 3.3 v voltage regulators n supports automatic usb 2.0 mode detection and usb 1.1 fall-back mode n high speed dma interface n fully autonomous and multi-con?guration dma operation n up to 14 programmable usb endpoints with 2 ?xed control in/out endpoints n integrated physical 8 kbyte of multi-con?guration fifo memory n endpoints with double buffering to increase throughput and ease real-time data transfer n bus independent interface with most microcontroller/microprocessors (16 mbytes/s or 16 mwords/s) n bus-powered capability with low power consumption and low suspend current n 12 mhz crystal oscillator with integrated pll for low emi n software controlled connection to the usb bus (softconnect?) n complies with the acpi?, onnow? and usb power management requirements n internal power-on and low-voltage reset circuit, also supporting a software reset n operation over the extended usb bus voltage range (4.0 to 5.5 v) with 5 v tolerant i/o pads n operating temperature range - 40 to + 85 c n 12 kv in-circuit esd protection on human accessible pins such as d + and d - n full-scan design with high fault coverage (>99%) n available in lqfp64 package. 3. applications n personal digital assistant (pda) n mass storage device, e.g., zip ? , jaz ? , mo, cd, dvd drive n digital camera n communication device, e.g. router, modem n printer n scanner. 4. ordering information table 1: ordering information type number package name description version ISP1581BD lqfp64 plastic low pro?le quad ?at package; 64 leads; body 10 x 10 x 1.4 mm sot314-2
philips semiconductors isp1581 usb 2.0 hs interface device 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. objective speci?cation rev. 02 23 october 2000 3 of 73 5. block diagram the direction of pins dreq, dack, dior and diow is determined by bit master (dma hardware register) and bit ata_mode (dma con?guration register). fig 1. block diagram. mgt234 16 4 1.5 k w 12.2 k w ( 0.1%) isp1581 usb 2.0 transceiver 10 8 7 3.3 v reset rref 4 3, 23 voltage regulators power-on reset memory management unit integrated ram (8 kbyte) micro controller interface dma interface micro- controller handler dma handler dma registers 12 mhz xtal2 xtal1 to/from usb 40 pll oscillator bit clock recovery system controller philips sie 2, 37, 43, 64 softconnect 18, 17, 19, 20, 21 12, 13, 14, 15 40, 41, 44 to 57 ready * 28 int internal reset analog supply 3.3 v data0 to data15 mode0 * , mode1 22 19 22 20, 9 16 bus_conf * 8 38, 39, 30 to 35 25, 29, 26, 27 ad0 to ad7 dreq, dack, dior, diow cs0, cs1, da0 * , da1 * , da2 v cc(5.0) digital supply 3.3 v 5 v 60 59 intrq iordy * * denotes shared pin usage rpu 5 d - 6 d + v reg(3.3) 24, 58 v cc(3.3) 63 suspend 62 wakeup agnd 2 5 4 2 2 1, 36, 42, 61 dgnd 4 4 cs, ale/a0, ( r/w)/rd, ds/wr 11 eot
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 4 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 6. pinning information 6.1 pinning fig 2. pin con?guration lqfp64. i dth ISP1581BD mbl248 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 data6 data5 data4 data3 data2 v cc(5.0) dgnd data1 data0 ad7 ad6 v cc(5.0) dgnd ad5 ad4 ad3 dgnd v cc(5.0) agnd v reg(3.3) d - d + rpu rref mode1 reset eot dreq dack dior diow intrq 33 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 v cc(5.0) suspend wakeup dgnd xtal1 xtal2 v cc(3.3) data15 data14 data13 data12 data11 data10 data9 data8 data7 cs1 cs0 bus_conf/da0 mode0/da1 da2 ready/iordy agnd v cc(3.3) cs (r/w)/rd ds/ wr int ale/a0 ad0 ad1 ad2 49
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 5 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 6.2 pin description table 2: pin description for lqfp64 symbol [1] pin type [2] description dgnd 1 - digital ground v cc(5.0) 2 - supply voltage (3.3 or 5.0 v) agnd 3 - analog ground v reg(3.3) 5 - regulated supply voltage (3.3 v 10%) from internal regulator; supplies internal analog circuits; used to connect decoupling capacitor and 1.5 k w pull-up resistor on d + line remark: cannot be used to supply external devices. d - 5 ai/o usb d - connection (analog) d + 6 ai/o usb d + connection (analog) rpu 7 ai connection for external pull-up resistor for usb d + line; must be connected to v reg(3.3) via a 1.5 k w resistor rref 8 ai connection for external bias resistor; must be connected to ground via a 12.2 k w ( 0.1%) resistor mode1 9 i selects function of pin ale/a0 (in split bus mode only): 0 ale function (address latch enable) 1 a0 function (address/data indicator). remark: connect to v cc(5.0) in generic processor mode. reset 10 i reset input (schmitt trigger); a low level produces an asynchronous reset; connect to v cc for power-on reset (internal por circuit) eot 11 i end of transfer input (programmable polarity, see ta b l e 3 7 ); used in dma slave mode only dreq 12 i/o dma request (programmable polarity); direction depends on the bit master in the dma hardware register (dma master: input, dma slave: output); see ta b l e 3 7 dack 13 i/o dma acknowledge (programmable polarity); direction of depends on bit master in the dma hardware register (dma slave: input, dma master: output); see ta b l e 3 7 dior 14 i/o dma read strobe (programmable polarity); direction depends on bit master in the dma hardware register (dma slave: input, dma master: output); see ta b l e 3 7 diow 15 i/o dma write strobe (programmable polarity); direction depends on bit master in the dma hardware register (dma slave: input, dma master: output); see ta b l e 3 7 intrq 16 i interrupt request input from ata/atapi peripheral cs1 17 o chip select output for atapi device cs0 18 o chip select output for atapi device bus_conf/ da0 19 i/o during power-up : input to select the bus con?guration 0 split bus mode; multiplexed 8-bit address/data bus on ad[7:0], separate 8/16-bit dma data bus on data[15:0] 1 generic processor mode; separate 8-bit address on ad[7:0], 16-bit dma data bus on data[15:0]. normal operation : address output to select the task ?le register of an atapi device
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 6 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. mode0/da1 20 i/o during power-up : input to select the read/write strobe functionality in generic processor mode 0 motorola style: pin 26 is r/ w and pin 27 is ds 1 8051 style: pin 26 is rd and pin 27 is wr normal operation : address output to select the task ?le register of an atapi device da2 21 o address output to select the task ?le register of an atapi device ready/ iordy 22 i/o generic processor mode : ready signal (ready; output) a low level signals that isp1581 is processing a previous command or data and is not ready for the next command or data transfer; a high level signals that isp1581 is ready for the next microprocessor read or write. split bus mode : dma ready signal (iordy; input); used for accessing atapi peripherals (pio and udma modes only). agnd 23 - analog ground v cc(3.3) 24 - supply voltage (3.3 v 10%); supplies internal digital circuits cs 25 i chip select input (r/ w)/ rd 26 i input; function is determined by input mode0 at power-up: mode0 = 0 pin functions as r/ w (motorola style) mode0 = 1 pin functions as rd (8051 style). ds/ wr 27 i input; function is determined by input mode0 at power-up: mode0 = 0 pin functions as ds (motorola style) mode0 = 1 pin functions as wr (8051 style). int 28 o interrupt output; programmable polarity (active high or low) and signaling (edge or level triggered) ale/a0 29 i input; function determined by input mode1 during power-up: mode1 = 0 address latch enable; a falling edge latches the address on the multiplexed address/data bus (ad[7:0]) mode1 = 1 address/data selection on ad[7:0]; a logic 1 indicates that an address will be written at the next wr pulse; a logic 0 indicates that data will be written at the next wr pulse; used in split bus mode only. ad0 30 i/o bit 0 of multiplexed address/data ad1 31 i/o bit 1 of multiplexed address/data ad2 32 i/o bit 2 of multiplexed address/data ad3 33 i/o bit 3 of multiplexed address/data ad4 34 i/o bit 4 of multiplexed address/data ad5 35 i/o bit 5 of multiplexed address/data dgnd 36 - digital ground v cc(5.0) 37 - supply voltage (3.3 or 5.0 v) ad6 38 i/o bit 6 of multiplexed address/data table 2: pin description for lqfp64 continued symbol [1] pin type [2] description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 7 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] symbol names with an overscore (e.g. name) represent active low signals. [2] all outputs and i/o pins can source 4 ma of current. 7. functional description the isp1581 is a high-speed usb device controller. it implements the usb 2.0/1.1 physical layer, the packet protocol layer and maintains up to 16 usb endpoints concurrently (2 control, 14 con?gurable). usb chapter 9 protocol handling is executed by means of external ?rmware. ad7 39 i/o bit 7 of multiplexed address/data data0 40 i/o bit 0 of bidirectional data data1 41 i/o bit 1 of bidirectional data dgnd 42 - digital ground v cc(5.0) 43 - supply voltage (3.3 or 5.0 v) data2 44 i/o bit 2 of bidirectional data data3 45 i/o bit 3 of bidirectional data data4 46 i/o bit 4 of bidirectional data data5 47 i/o bit 5 of bidirectional data data6 48 i/o bit 6 of bidirectional data data7 49 i/o bit 7 of bidirectional data data8 50 i/o bit 8 of bidirectional data data9 51 i/o bit 9 of bidirectional data data10 52 i/o bit 10 of bidirectional data data11 53 i/o bit 11 of bidirectional data data12 54 i/o bit 12 of bidirectional data data13 55 i/o bit 13 of bidirectional data data14 56 i/o bit 14 of bidirectional data data15 57 i/o bit 15 of bidirectional data v cc(3.3) 58 - supply voltage (3.3 v 10%); supplies internal digital circuits xtal2 59 o crystal oscillator output (12 mhz); connect a fundamental parallel-resonant crystal; leave this pin open when using an external clock source on pin xtal1 xtal1 60 i crystal oscillator input (12 mhz); connect a fundamental parallel-resonant crystal or an external clock source (leaving pin xtal2 unconnected) dgnd 61 - digital ground wakeup 62 i wake-up input (edge triggered); a low-to-high transition generates a remote wake-up from suspend state suspend 63 o suspend state indicator output (4 ma); used as a power switch control output (active low) for powered-off application or as a resume signal to the cpu (active high) for powered-on application v cc(5.0) 64 - supply voltage (3.3 or 5.0 v) table 2: pin description for lqfp64 continued symbol [1] pin type [2] description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 8 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. the isp1581 has a fast general-purpose interface for communication with most types of microcontrollers/processors. this microcontroller interface is con?gured by pins bus_conf, mode1 and mode0 to accommodate most interface types. two bus con?gurations are available, selected via input bus_conf during power-up: ? generic processor mode (bus_conf = 1): C ad[7:0]: 8-bit address bus (selects target register) C data[15:0]: 16-bit data bus (shared by processor and dma) C control signals: r/ w and ds or rd and wr (selected via pin mode0) C dma interface (generic slave mode only): uses lines data[15:0] as data bus, dior and diow as dedicated read and write strobes. ? split bus mode (bus_conf = 0): C ad[7:0]: 8-bit local microprocessor bus (multiplexed address/data) C data[15:0]: 16-bit dma data bus C control signals: cs, ale or a0 (selected via pin mode1), r/ w and ds or rd and wr (selected via pin mode0) C dma interface (master or slave mode): uses dior and diow as dedicated read and write strobes. for high-bandwidth data transfer, the integrated dma handler can be invoked to transfer data to/from external memory or devices. the dma interface can be con?gured by writing to the proper dma registers (see section 9.4 ). the isp1581 supports high-speed usb 2.0 and full-speed usb 1.1 signaling. detection of the usb signaling speed is done automatically. isp1581 has 8 kbytes of internal fifo memory, which is shared among the enabled usb endpoints. there are 14 con?gurable data endpoints and 2 control endpoints. any of the 14 data endpoints can be separately enabled or disabled. the endpoint type (interrupt, isochronous or bulk) and packet size of these endpoints can be individually con?gured depending on the requirements of the application. optional double buffering increases the data throughput of the data endpoints. the isp1581 requires a single supply of 3.0 v or 5.0 v, depending on the i/o voltage. it has 5.0 v tolerant i/o pads and has an internal 3.3 v regulator for powering the analog transceiver. it supports bus-powered operation with a suspend current below 500 m a. the isp1581 operates on a 12 mhz crystal oscillator. an integrated 40 pll clock multiplier generates the internal sampling clock of 480 mhz. 7.1 usb 2.0 transceiver the analog transceiver interfaces directly to the usb cable via integrated termination resistors. the high-speed transceiver requires an external resistor (12.2 k w 0.1%) between pin rref and ground to ensure an accurate current mirror. a full-speed transceiver is integrated as well. this makes the isp1581 compliant with usb 2.0
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 9 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. and usb 1.1, supporting both the high-speed and full-speed physical layer. after automatic speed detection, the philips serial interface engine sets the transceiver to use either high-speed or full-speed signaling. 7.2 philips serial interface engine (sie) the philips sie implements the full usb protocol layer. it is completely hardwired for speed and needs no ?rmware intervention. the functions of this block include: synchronization pattern recognition, parallel/serial conversion, bit (de-)stuf?ng, crc checking/generation, packet identi?er (pid) veri?cation/generation, address recognition, handshake evaluation/generation. 7.3 voltage regulators two 5 v to 3.3 v voltage regulators are integrated on-chip to separately supply the analog transceiver and the internal logic. the analog supply voltage is available at pin v reg(3.3) to supply an external 1.5 k w pull-up resistor on the d + line. remark: pin v reg(3.3) cannot be used to supply external devices. 7.4 memory management unit (mmu) and integrated ram the mmu and the integrated ram provide the conversion between the usb speed (full speed: 12 mbit/s, high speed: 480 mbit/s) and the microcontroller handler or the dma handler. the data from the usb bus is stored in the integrated ram, which is cleared only when the microcontroller clears the endpoint buffer or when the dma handler has read/written all data from/to the endpoint buffer. a total of 8 kbytes ram is available for buffering. 7.5 softconnect the connection to the usb is established by pulling the d + line (for high-speed devices) high through a 1.5 k w pull-up resistor. in the isp1581 an external 1.5 k w pull-up resistor must be connected between pins rpu and v reg(3.3) . the rpu pin connects the pull-up resistor to the d + line, when bit softct in the mode register is set (see ta b l e 7 ). after a hardware reset the pull-up resistor is disconnected by default (softct = 0). bit softct remains unchanged by a usb bus reset. 7.6 bit clock recovery the bit clock recovery circuit recovers the clock from the incoming usb data stream using 4 over-sampling principle. it is able to track the jitter and the frequency drift as speci?ed by the usb speci?cation. 7.7 multiplying pll oscillator a 12 mhz to 480 mhz clock multiplier phase-locked loop (pll) is integrated on-chip. this allows the use of a low-cost 12 mhz crystal, which also minimizes emi. no external components are needed for the operation of the pll.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 10 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 7.8 microcontroller interface and microcontroller handler the microcontroller interface allows direct interfacing to most microcontrollers. the interface is con?gured at power-up via inputs bus_conf, mode1 and mode0. when bus_conf is set to logic 1, the microcontroller interface switches to the generic processor mode in which ad[7:0] is the 8-bit address bus and data[15:0] is the separate 16-bit data bus. if bus_conf is made logic 0, the interface is in the split bus mode , where ad[7:0] is the local microprocessor bus (multiplexed address/data) and data[15:0] is used as the dma bus. if pin mode0 is set to logic 1, pins rd and wr are the read and write strobes (8051 style). if pin mode0 is logic 0, pins r/ w and ds pins represent the direction and data strobe (motorola style). when pin mode1 is made logic 0, ale is used to latch the multiplexed address on pins ad[7:0]. if pin mode1 is set to logic 1, a0 is used to indicate address or data. pin mode1 is only used in split bus mode: in generic processor mode it must be tied to v cc(5.0) (logic 1). the microcontroller handler allows the external microcontroller to access the register set in the philips sie as well as the dma handler. the initialization of the dma con?guration is done via the microcontroller handler. 7.9 dma interface and dma handler the dma block can be subdivided into two blocks: the dma handler and the dma interface. the ?rmware writes to the dma command register to start a dma transfer (see ta b l e 3 0 ). the command opcode determines whether a generic dma, pio, mdma or udma transfer will start. the handler interfaces to the same fifo (internal ram) as used by the usb core. upon receiving the dma command, the dma handler directs the data from the internal ram to the external dma device and vice versa. the dma interface con?gures the timings and how the dma data is accessed. data can be transferred either using dior and diow strobes or by the dack and dreq handshakes. the different dma con?gurations are set up by writing to the dma con?guration register (see ta b l e 3 5 ). for an ide-based storage interface, the applicable dma modes are pio (parallel i/o), mdma (multiword dma; ata), and udma (ultra dma; ata). for a generic dma interface, the dma modes that can be used are generic dma (slave) and mdma (master). 7.10 system controller the system controller implements the usb power-down capabilities of the isp1581. two modes are supported during suspend state: powered-on and powered-off . these modes are selected via bit pwroff in the mode register (see ta b l e 7 ). registers are protected against data corruption during wake-up following a resume.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 11 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 8. modes of operation the isp1581 has two bus con?guration modes, selected via pin bus_conf/da0 at power-up: ? split bus mode (bus_conf = 0): 8-bit multiplexed address/data bus and separate 8-bit/16-bit dma bus ? generic processor mode (bus_conf = 1) ; separate 8-bit address and 16-bit data bus details of the bus con?gurations for each mode are given in ta b l e 3 . typical interface circuits for each mode are given in section 13 application information . 9. register descriptions table 3: bus con?guration modes bus_conf pio width dma width description dmawd = 0 dmawd = 1 0 ad[7:0] d[7:0] d[15:0] split bus mode: multiplexed address/data on pins ad[7:0]; separate 8/16-bit dma bus on pins data[15:0] 1 a[7:0] d[15:0] d[7:0] d[15:0] generic processor mode: separate 8-bit address on pins ad[7:0]; 16-bit data (pio and dma) on pins data[15:0] table 4: register summary name destination address (hex) description size (bytes) initialization registers address device 00 usb device address + enable 1 mode device 0c power-down options, global interrupt enable, softconnect 1 interrupt con?guration device 10 interrupt sources, trigger mode, output polarity 1 interrupt enable device 14 interrupt source enabling 4 dma con?guration dma controller 38 see dma registers 2 dma hardware dma controller 3c see dma registers 1 data ?ow registers endpoint index endpoints 2c endpoint selection, data ?ow direction 1 control function endpoint 28 endpoint buffer management 1 data port endpoint 20 data access to endpoint fifo 2 buffer length endpoint 1c packet size counter 2 endpoint maxpacketsize endpoint 04 maximum packet size 2 endpoint type endpoint 08 selects endpoint type: control, isochronous, bulk or interrupt 2 short packet endpoint 24 short packet received on out endpoint 2
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 12 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. dma registers dma command dma controller 30 controls all dma transfers 1 dma transfer counter dma controller 34 sets byte count for dma transfer 4 dma con?guration dma controller 38 (byte 0) sets gdma con?guration (counter enable, burst length, data strobing, bus width) 1 39 (byte 1) sets ata con?guration (iordy enable, mode selection: ata/udma/mdma/pio) 1 dma hardware dma controller 3c endian type, master/slave selection, signal polarity for dack, dreq, diow, dior 1 1f0 task file atapi peripheral 40 single address word register: byte 0 (lower byte) is accessed ?rst 2 1f1task file atapi peripheral 48 ide device access 1 1f2 task file atapi peripheral 49 ide device access 1 1f3 task file atapi peripheral 4a ide device access 1 1f4 task file atapi peripheral 4b ide device access 1 1f5 task file atapi peripheral 4c ide device access 1 1f6 task file atapi peripheral 4d ide device access 1 1f7 task file atapi peripheral 44 ide device access (write only; reading returns 00h) 1 3f6 task file atapi peripheral 4e ide device access 1 3f7 task file atapi peripheral 4f ide device access 1 dma interrupt reason dma controller 50 (byte 0) shows reason (source) for dma interrupt 1 51 (byte 1) 1 dma interrupt enable dma controller 54 (byte 0) enables dma interrupt sources 1 55 (byte 1) 1 dma endpoint dma controller 58 selects endpoint fifo, data ?ow direction 1 dma strobe timing dma controller 60 strobe duration in udma/mdma mode 1 general registers interrupt device 18 shows interrupt sources 4 chip id device 70 product id code and hardware version 3 frame number device 74 last successfully received start of frame: lower byte (byte 0) is accessed ?rst 2 scratch device 78 allows save/restore of ?rmware status during suspend 2 unlock device device 7c re-enables register access after suspend 2 test mode phy 84 direct setting of d + , d - states, loopback mode, internal transceiver test (phy) 1 table 4: register summary continued name destination address (hex) description size (bytes)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 13 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.1 register access register access depends on the bus width used: ? 8-bit bus: multi-byte registers are accessed lower byte (lsb) ?rst. ? 16-bit bus: for single-byte registers the upper byte (msb) must be ignored. endpoint speci?c registers are indexed via the endpoint index register. the target endpoint must be selected ?rst, before accessing the following registers: ? buffer length ? control function ? data port ? endpoint maxpacketsize ? endpoint type ? short packet. 9.2 initialization registers 9.2.1 address register (address: 00h) this register is used to set the usb assigned address and enable the usb device. ta b l e 5 shows the address register bit allocation. the deven and devaddr bits will be cleared whenever a bus reset, a power-on reset or a soft reset occurs. in response to the standard usb request set_address, the ?rmware must write the (enabled) device address to the address register, followed by sending an empty packet to the host. the new device address is activated when the host acknowledges the empty packet. table 5: address register: bit allocation bit 7 6 5 4 3 2 1 0 symbol deven devaddr[6:0] reset 0 00h bus reset 0 00h access r/w r/w table 6: endpoint con?guration register: bit description bit symbol description 7 deven a logic 1 enables the device. 6 to 0 devaddr[6:0] this ?eld speci?es the usb device address.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 14 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.2.2 mode register (address: 0ch) this register consists of 1 byte (bit allocation: see ta b l e 7 ). in 16-bit bus mode the upper byte is ignored. the mode register controls the resume, suspend and wake-up behaviour, interrupt activity, soft reset, clock signals and softconnect operation. this register also controls the power off mode during suspend state. table 7: mode register: bit allocation bit 7 6 5 4 3 2 1 0 symbol clkaon sndrsu gosusp sfreset glintena wkupcs pwroff softct reset 00000000 bus reset 0 0 0 0 unchanged 0 unchanged unchanged access r/w r/w r/w r/w r/w r/w r/w r/w table 8: mode register: bit description bit symbol description 7 clkaon clock always on: a logic 1 indicates that the internal clocks are always running even during suspend state. a logic 0 switches off the internal oscillator and pll, when they are not needed. during suspend state, this bit must be set to logic 0 to meet the suspend current requirements. the clock is stopped after a delay of approximately 2 ms, following the setting of bit gosusp. 6 sndrsu send resume: writing a logic 1 followed by a logic 0 will generate an upstream resume signal of 10 ms duration, after a 5 ms delay. 5 gosusp go suspend: writing a logic 1 followed by a logic 0 will activate suspend mode. 4 sfreset soft reset: writing a logic 1 followed by a logic 0 will enable a software-initiated reset to isp1581. a soft reset is similar to a hardware-initiated reset (via the reset pin). 3 glintena global interrupt enable: a logic 1 enables all interrupts. individual interrupts can be masked off by clearing the corresponding bits in the interrupt enable register. bus reset value: unchanged. 2 wkupcs wake-up on chip select: a logic 1 enables remote wake-up via a low level on input cs. 1 pwroff power off mode: a logic 1 enables powering-off during suspend state. output suspend is con?gured as a power switch control signal for external devices (high during suspend). bus reset value: unchanged. 0 softct softconnect: a logic 1 enables the connection of the 1.5 k w pull-up resistor on pin rpu to the d + line. bus reset value: unchanged.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 15 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.2.3 interrupt con?guration register (address: 10h) this 1-byte register determines the behaviour and polarity of the int output. the bit allocation is shown in ta b l e 9 . when the usb sie receives or generates a ack, nak or stall, it will generate interrupts depending on three debug mode bit ?elds: ? cdbgmod[1:0]: interrupts for the control endpoint 0 ? ddbgmodin[1:0]: interrupts for the data in endpoints 1 to 7 ? ddbgmodout[1:0]: interrupts for the data out endpoints 1 to 7. the debug mode settings for cdbgmod, ddbgmodin and ddbgmodout allow the user to individually con?gure when the isp1581 will send an interrupt to the external microprocessor. ta b l e 1 1 lists the available combinations. bit intpol controls the signal polarity of the int output (active high or low, rising or falling edge). for level-triggering bit intlvl must be made logic 0. by setting intlvl to logic 1 an interrupt will generate a pulse of 60 ns (edge-triggering). [1] first nak: the ?rst nak on an in or out token after a previous ack response. table 9: interrupt con?guration register: bit allocation bit 7 6 5 4 3 2 1 0 symbol cdbgmod[1:0] ddbgmodin[1:0] ddbgmodout[1:0] intlvl intpol reset 03h 03h 03h 0 0 bus reset 03h 03h 03h unchanged unchanged access r/w r/w r/w r/w r/w table 10: interrupt con?guration register: bit description bit symbol description 7 to 6 cdbgmod[1:0] control 0 debug mode: values see ta bl e 1 1 5 to 4 ddbgmodin[1:0] data debug mode in: values see ta b l e 1 1 3 to 2 ddbgmodout[1:0] data debug mode out: values see ta b l e 1 1 1 intlvl interrupt level : selects the signaling mode on output int (0 = level, 1 = pulsed). in pulsed mode an interrupt produces a 60 ns pulse. bus reset value: unchanged. 0 intpol interrupt polarity: selects signal polarity on output int (0 = active low, 1 = active high). bus reset value: unchanged. table 11: debug mode settings value cdbgmod ddbgmodin ddbgmodout 00h interrupt on all ack, stall and nak interrupt on all ack and nak interrupt on all ack, stall, nyet and nak 01h interrupt on all ack and stall interrupt on ack interrupt on ack, stall and nyet 1xh interrupt on all ack, stall and ?rst nak [1] interrupt on all ack and ?rst nak [1] interrupt on all ack, stall, nyet and ?rst nak [1]
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 16 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.2.4 interrupt enable register (address: 14h) this register enables/disables individual interrupt sources. the interrupt for each endpoint can be individually controlled via the associated iepnrx or iepntx bits (n representing the endpoint number). all interrupts can be globally disabled via bit glintena in the mode register (see ta b l e 7 ). an interrupt is generated when the usb sie receives or generates an ack, nak or stall on the usb bus. the interrupt generation depends on the debug mode settings of bit ?elds cdbgmod, ddbgmodin and ddbgmodout. all data in transactions use the transmit buffers (tx), which are handled by the ddbgmodin bits. all data out transactions go via the receive buffers (rx), which are handled by the ddbgmodout bits. transactions on control endpoint 0 (in, out and setup) are handled by the cdbgmod bits. interrupts caused by events on the usb bus (sof, pseudo sof, suspend, resume, bus reset, setup and high speed status) can also be controlled individually. a bus reset disables all enabled interrupts except bit iebrst (bus reset), which remains unchanged. the interrupt enable register consists of 4 bytes. the bit allocation is given in ta b l e 1 2 . table 12: interrupt enable register: bit allocation bit 31 30 29 28 27 26 25 24 symbol reserved reserved reserved reserved reserved reserved iep7tx iep7rx reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 23 22 21 20 19 18 17 16 symbol iep6tx iep6rx iep5tx iep5rx iep4tx iep4rx iep3tx iep3rx reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 15 14 13 12 11 10 9 8 symbol iep2tx iep2rx iep1tx iep1rx iep0tx iep0rx reserved iep0setup reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol reserved iedma iehs_sta ieresm iesusp iepsof iesof iebrst reset 00000000 bus reset 0000000 unchanged access r/w r/w r/w r/w r/w r/w r/w r/w
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 17 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.2.5 dma con?guration register (address: 38h) see section 9.4.3 . 9.2.6 dma hardware register (address: 3ch) see section 9.4.4 . table 13: interrupt enable register: bit description bit symbol description 31 to 26 - reserved; must write logic 0 25 to 12 iep7tx to iep1rx a logic 1 enables interrupt from the indicated endpoint. 11 iep0tx a logic 1 enables interrupt from the control in endpoint 0. 10 iep0rx a logic 1 enables interrupt from the control out endpoint 0. 9 - reserved 8 iep0setup a logic 1 enables the interrupt for the setup data received on endpoint 0. 7 - reserved 6 iedma a logic 1 enables interrupt upon dma status change detection. 5 iehs_sta a logic 1 enables interrupt upon detection of a high speed status change. 4 ieresm a logic 1 enables interrupt upon detection of a resume state. 3 iesusp a logic 1 enables interrupt upon detection of a suspend state. 2 iepsof a logic 1 enables interrupt upon detection of a pseudo sof. 1 iesof a logic 1 enables interrupt upon detection of an sof. 0 iebrst a logic 1 enables interrupt upon detection of a bus reset.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 18 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.3 data ?ow registers 9.3.1 endpoint index register (address: 2ch) the endpoint index register selects a target endpoint for register access by the microcontroller. the register consists of 1 byte and the bit allocation is shown in ta b l e 1 4 . the following registers are indexed: ? endpoint maxpacketsize ? endpoint type ? buffer length ? data port ? short packet ? control function. for example, to access the out data buffer of endpoint 1 via the data port register, the endpoint index register has to be written ?rst with 02h. table 14: endpoint index register: bit allocation bit 7 6 5 4 3 2 1 0 symbol reserved reserved ep0setup endpidx[3:0] dir reset 0 0 0 00h 0 bus reset 0 0 0 00h 0 access r/w r/w r/w r/w r/w table 15: endpoint index register: bit description bit symbol description 7 to 6 - reserved 5 ep0setup selects the setup buffer for endpoint 0: 0 ep0 data buffer 1 setup buffer. must be logic 0 for access to other endpoints than endpoint 0. 4 to 1 endpidx[3:0] endpoint index: selects the target endpoint for register access of buffer length, control function, data port, endpoint type, maxpacketsize and short packet. 0 dir direction bit: sets the target endpoint as in or out endpoint: 0 target endpoint refers to out (rx) fifo 1 target endpoint refers to in (tx) fifo. table 16: addressing of endpoint 0 buffers buffer name ep0setup endpidx dir setup 1 00h 0 data out 0 00h 0 data in 0 00h 1
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 19 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.3.2 control function register (address: 28h) the control function register is used to perform the buffer management on the endpoints. it consists of 1 byte and the bit con?guration is given in ta b l e 1 7 .the register bits can stall, clear or validate any enabled data endpoint. before accessing this register, the endpoint index register must be written ?rst to specify the target endpoint. [1] only applicable for endpoint 0. 9.3.3 data port register (address: 20h) this 2-byte register provides direct access for a microcontroller to the fifo of the indexed endpoint. in case of an 8-bit bus the upper byte is not used. the bit allocation is shown in ta b l e 1 9 . device to host (in endpoint): after each write action an internal counter is auto-incremented (by 2 for a 16-bit access, by 1 for an 8-bit access) to the next location in the tx fifo. when all bytes have been written, the buffer can be validated via the control function register (bit vendp). the data packet will then be sent on the next in token. table 17: control function register: bit allocation bit 7 6 5 4 3 2 1 0 symbol reserved reserved reserved clbuf vendp reserved status [1] stall reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 18: control function register: bit description bit symbol description 7 to 5 - reserved. 4 clbuf clear buffer: a logic 1 clears the rx buffer of the indexed endpoint; the tx buffer is not affected. before new data can be received, old data in the buffer must be cleared ?rst. 3 vendp validate endpoint: a logic 1 validates the data in the tx fifo of an in endpoint for sending on the next in token. the fifo byte count is below or equal to the endpoint maxpacketsize. 2 - reserved 1 status status acknowledge: this bit controls the generation of ack or nak during the status stage of a setup packet. it is automatically cleared upon completion of the status stage and upon receiving a setup token. 0 sends nak 1 sends empty packet following in token (host-to-device) or ack following out token (device-to-host). 0 stall stall endpoint : a logic 1 stalls the indexed endpoint. this bit is not applicable for isochronous transfers.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 20 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. host to device (out endpoint) : after each read action an internal counter is auto-decremented (by 2 for a 16-bit access, by 1 for an 8-bit access) to the next location in the rx fifo. when all bytes have been read, the buffer contents can be cleared via the control function register (bit clbuf). a new data packet can then be received on the next out token. remark: the buffer can be validated or cleared automatically by using the buffer length register (see ta b l e 2 1 ). 9.3.4 buffer length register (address: 1ch) this 2-byte register determines the current packet size (datacount) of the indexed endpoint fifo. the bit allocation is given in ta b l e 2 1 . the buffer length register is automatically loaded with the fifo size, when the endpoint maxpacketsize register is written (see ta b l e 2 2 ). a smaller value can be written when required. after a bus reset the buffer length register is made zero. in endpoint: when writing bytes into the tx fifo, the buffer is automatically validated when datacount exceeds maxpacketsize. during the subsequent packet transmission datacount is decremented with the number of bytes sent. this process is repeated until the number of remaining bytes is less than maxpacketsize (case i) or zero (case ii). in case i, the remaining bytes are automatically validated and a short packet is sent. in case ii, a ?nal empty packet will be appended if bit noempkt in the endpoint type register is cleared (see ta b l e 2 4 ). otherwise (if bit noempkt is set), data transfer is considered ?nished when the buffer is empty. out endpoint: the datacount value is automatically initialized to the number of data bytes sent by the host on each ack. after reading datacount bytes from the rx buffer, the buffer is automatically cleared to allow the next packet to be received from the host. remark: for a 16-bit bus, the last byte of an odd-sized packet is output as the lower byte (lsb). table 19: data port register: bit allocation bit 15 14 13 12 11 10 9 8 symbol dataport[15:8] reset 00h bus reset 00h access r/w bit 7 6 5 4 3 2 1 0 symbol dataport[7:0] reset 00h bus reset 00h access r/w table 20: data port register: bit description bit symbol description 15 to 8 dataport[15:8] data (upper byte); not used in 8-bit bus mode 7 to 0 dataport[7:0] data (lower byte)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 21 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.3.5 endpoint maxpacketsize register (address: 04h) this register determines the maximum packet size for all endpoints except control 0. the register contains 2 bytes and the bit allocation is given in ta b l e 2 2 . each time the register is written, the buffer length registers of all endpoints are re-initialized to the ffosz ?eld value. the ntrans bits control the number of transactions allowed in a single micro-frame (for high-speed operation only). table 21: buffer length register: bit allocation bit 15 14 13 12 11 10 9 8 symbol datacount[15:8] reset 00h bus reset 00h access r/w bit 7 6 5 4 3 2 1 0 symbol datacount[7:0] reset 00h bus reset 00h access r/w table 22: endpoint maxpacketsize register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved reserved reserved ntrans[1:0] ffosz[10:8] reset 0 0 0 00h 00h bus reset 0 0 0 00h 00h access r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol ffosz[7:0] reset 00h bus reset 00h access r/w table 23: endpoint maxpacketsize register: bit description bit symbol description 15 to 13 reserved reserved 12 to 11 ntrans[1:0] number of transactions (hs mode only): 0 1 packet per microframe 1 2 packets per microframe 2 3 packets per microframe 3 reserved. 10 to 0 ffosz[10:0] fifo size : sets the fifo size in bytes for the indexed endpoint. applies to both hs and fs operation. remark: a fifo size of zero will disable the endpoint.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 22 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.3.6 endpoint type register (address: 08c) this register sets the endpoint type of the indexed endpoint: control, isochronous, bulk or interrupt. it also serves to enable the endpoint and con?gure it for double buffering. automatic generation of an empty packet for a zero length tx buffer can be disabled via bit noempkt. the register contains 2 bytes and the bit allocation is shown in ta b l e 2 4 . 9.3.7 short packet register (address: 24h) this read-only register is applicable only for out endpoints. it contains 2 bytes and the bit allocation is shown in ta b l e 2 6 . if the number of bytes of a received packet is less than the value speci?ed in the endpoint maxpacketsize register (see ta b l e 2 2 ), the corresponding short packet status bit (outnsh) is set. the short packet register is updated on every successfully received new packet. table 24: endpoint type register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved reset 00h bus reset 00h access r/w bit 7 6 5 4 3 2 1 0 symbol reserved reserved reserved noempkt enable dblbuf endptyp[1:0] reset 000000 00h bus reset 000000 00h access r/w r/w r/w r/w r/w r/w r/w table 25: endpoint type register: bit description bit symbol description 15 to 5 reserved reserved. 4 noempkt no empty packet: a logic 0 causes an empty packet to be appended to the next in token of the usb data, if the buffer length register or the endpoint maxpacketsize register is zero. a logic 1 disables this function. 3 enable endpoint enable : a logic 1 enables the fifo of the indexed endpoint. the memory size is allocated as speci?ed in the endpoint maxpacketsize register. a logic 0 disables the fifo. 2 dblbuf double buffering: a logic 1 enables double buffering for the indexed endpoint. a logic 0 disables double buffering. 1 to 0 endptyp[1:0] endpoint type: these bits select the endpoint type as follows: 00h control 01h isochronous 02h bulk 03h interrupt.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 23 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. table 26: short packet register: bit allocation bit 15 14 13 12 11 10 9 8 symbol out7sh out6sh out5sh out4sh out3sh out2sh out1sh out0sh reset 00000000 bus reset 00000000 access rrrrrrrr bit 7 6 5 4 3 2 1 0 symbol reserved reserved reserved reserved reserved reserved reserved reserved reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 27: short packet register: bit description bit symbol description 15 out7sh a logic 1 indicates that a short packet was received on out endpoint 7. a logic 0 indicates that the buffer is full. 14 out6sh a logic 1 indicates that a short packet was received on out endpoint 6. a logic 0 indicates that the buffer is full. 13 out5sh a logic 1 indicates that a short packet was received on out endpoint 5. a logic 0 indicates that the buffer is full. 12 out4sh a logic 1 indicates that a short packet was received on out endpoint 4. a logic 0 indicates that the buffer is full. 11 out3sh a logic 1 indicates that a short packet was received on out endpoint 3. a logic 0 indicates that the buffer is full. 10 out2sh a logic 1 indicates that a short packet was received on out endpoint 2. a logic 0 indicates that the buffer is full. 9 out1sh a logic 1 indicates that a short packet was received on out endpoint 1. a logic 0 indicates that the buffer is full. 8 out0sh a logic 1 indicates that a short packet was received on out endpoint 0. a logic 0 indicates that the buffer is full. 7 to 0 - reserved
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 24 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4 dma registers two types of generic dma transfer and three types of ide-speci?ed transfer can be done by writing the proper opcode in the dma command register. the control bits are given in ta b l e 2 8 (generic dma transfers) and ta b l e 2 9 (ide-speci?ed transfers). gdma read/write (opcode = 00h/01h) generic dma slave mode; the dior and diow strobe signals are driven by the external dma controller. mdma (master) read/write (opcode = 06h/07h) generic dma master mode; the dior and diow strobe signals are driven by the isp1581. pio read/write (opcode = 04h/05h) pio mode for ide transfers; the speci?cation of this mode can be obtained from the ata speci?cation rev. 4 . dior and diow are used as data strobes, iordy can be used by the device to extend the pio cycle. mdma read/write (opcode = 06h/07h) multiword dma mode for ide transfers; the speci?cation of this mode can be obtained from the ata speci?cation rev. 4 . dior and diow are used as data strobes, while dreq and dack serve as handshake signals. udma read/write (opcode = 02h/03h) ultra dma mode for ide transfers; the speci?cation of this mode can be obtained from the ata speci?cation rev. 4 . pins da0 to da2, cs0 and cs1 are used to select a device register for access. control signals are mapped as follows: dreq (= dmarq), dack (= dmack), diow (= stop), dior (= hdmardy or hstrobe), iordy (= dstrobe or ddmardy). table 28: control bits for generic dma transfers control bits description gdma read/write (opcode = 00h/01h) dma con?guration register (see ta bl e 3 5 ) burst[2:0] determines the number of dma cycles during which pin dreq is kept asserted mode[1:0] determines the active data strobe(s) width0 selects the dma bus width: 8 or 16 bits dis_xfer_cnt disables the use of the dma transfer counter ata_mode set to logic 0 (non-ata transfer) dma hardware register (see ta bl e 3 7 ) eot_pol selects the polarity of the eot signal ack_pol, dreq_pol, write_pol, read_pol select the polarity of the dma handshake signals master set to logic 0 (slave)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 25 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. mdma (master) read/write (opcode = 06h/07h) dma con?guration register (see ta bl e 3 5 ) udma_mode[1:0] determines the mdma timings for the dior and diow strobes (value 03h is used for udma only) mode[1:0] determines the active data strobe(s). width selects the dma bus width: 8 or 16 bits dis_xfer_cnt disables the use of the dma transfer counter ata_mode set to logic 1 (ata transfer) dma hardware register (see ta bl e 3 7 ) eot_pol input eot is not used ack_pol, dreq_pol, write_pol, read_pol select the polarity of the dma handshake signals master set to logic 1 (master) table 29: control bits for ide-speci?ed dma transfers control bits description pio read/write (opcode = 04h/05h) dma con?guration register (see ta bl e 3 5 ) pio_mode[2:0] selects the pio mode; timings are ata(pi) compatible ata_mode set to logic 1 (ata transfer) dma hardware register (see ta bl e 3 7 ) master set to logic 0 mdma read/write (opcode = 06h/07h) dma con?guration register (see ta bl e 3 5 ) mdma_mode[1:0] selects the mdma mode; timings are ata(pi) compatible ata_mode set to logic 1 (ata transfer) dma hardware register (see ta bl e 3 7 ) master set to logic 0 udma read/write (opcode = 02h/03h) dma con?guration register (see ta bl e 3 5 ) udma_mode[1:0] selects the udma mode; timings are ata(pi) compatible ignore_iordy used to ignore the iordy pin during transfer ata_mode set to logic 1 (ata transfer) dma hardware register (see ta bl e 3 7 ) master set to logic 0 table 28: control bits for generic dma transfers continued control bits description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 26 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4.1 dma command register (address: 30h) the dma command register is a 1-byte register that initiates all dma transfer activity on the dma controller. the register is write-only: reading it will return ffh. table 30: dma command register: bit allocation bit 7 6 5 4 3 2 1 0 symbol dma_cmd[7:0] reset ffh bus reset ffh access w table 31: dma command register: bit description bit symbol description 7:0 dma_cmd[7:0] dma command code, see ta b l e 3 2 . table 32: dma commands code (hex) name description 00 gdma read generic dma in token transfer (slave mode only): data is transferred from the external dma bus to the internal buffer. strobe: diow by external dma controller. 01 gdma write generic dma out token transfer (slave mode only): data is transferred from the internal buffer to the external dma bus. strobe: dior by external dma controller. 02 udma read udma read command: data is transferred from the external dma to the internal dma bus. 03 udma write udma write command: data is transferred in udma mode from the internal buffer to the external dma bus. 04 pio read pio read command for atapi device: data is transferred in pio mode from the external dma bus to the internal buffer. data transfer starts when iordy is asserted. inputs dreq and dack are ignored. 05 pio write pio write command for atapi device: data is transferred in pio mode from the internal buffer to the external dma bus. data transfer starts when iordy is asserted. inputs dreq and dack are ignored. 06 mdma read multiword dma read: data is transferred from the external dma bus to the internal buffer. 07 mdma write multiword dma write: data is transferred from the internal buffer to the external dma bus. 0a read 1f0 read at address 01f0h: initiates a pio read cycle from task file 1f0. before issuing this command the task ?le byte count should be programmed at address 1f4h (lsb) and 1f5h (msb). 0b poll bsy poll bsy status bit for atapi device: starts repeated pio read commands to poll the bsy status bit of the atapi device. when bsy = 0, polling is terminated and an interrupt is generated.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 27 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4.2 dma transfer counter register (address: 34h) this 4-byte register is used to set up the total byte count of a dma transfer (dmacr). it indicates the remaining number of bytes left for transfer. the bit allocation is given in ta b l e 3 3 . the transfer counter is used in dma modes: pio (commands: 04h, 05h), udma (commands: 02h, 03h), mdma (commands: 06h, 07h) and gdma (commands: 00h, 01h). a new value is written into the register starting with the lower byte (dmacr1) or the lower word (msb: dmacr2, lsb: dmacr1). internally, the transfer counter is initialized only after the last byte (dmacr4) has been written. in the gdma slave mode only, the transfer counter can be disabled via bit dis_xfer_cnt in the dma con?guration register (see ta b l e 3 5 ). in this case, input eot can be used to terminate the dma transfer when data is transferred from the external device to the host via in tokens. the last packet in the fifo is validated when pin eot is asserted. when the host sends data to an external device via out tokens, the eot condition is ignored. 0c read task files read task files: reads all task ?le registers except 1f0h and 1f7h. when reading has been completed, an interrupt is generated. 0d - reserved 0e validate buffer validate buffer (for debugging only): request from the microcontroller to validate the endpoint buffer following an ata to usb data transfer. 0f clear buffer clear buffer: request from the microcontroller to clear the endpoint buffer after a usb to ata data transfer. 10 restart restart: request from the microcontroller to move the buffer pointers to the beginning of the endpoint fifo. 11 reset dma reset dma: initializes the dma core to its power-on reset state. 12 to ff - reserved table 32: dma commands continued code (hex) name description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 28 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4.3 dma con?guration register (address: 38h) this register de?nes the dma con?guration for the generic dma (gdma) and the ultra-dma (udma) modes. the dma con?guration register consists of 2 bytes. the bit allocation is given in ta b l e 3 5 . table 33: dma transfer counter register: bit allocation bit 31 30 29 28 27 26 25 24 symbol dmacr4 = dmacr[31:24] reset 00h bus reset 00h access r/w bit 23 22 21 20 19 18 17 16 symbol dmacr3 = dmacr[23:16] reset 00h bus reset 00h access r/w bit 15 14 13 12 11 10 9 8 symbol dmacr2 = dmacr[15:8] reset 00h bus reset 00h access r/w bit 7 6 5 4 3 2 1 0 symbol dmacr1 = dmacr[7:0] reset 00h bus reset 00h access r/w table 34: dma transfer counter register: bit description bit symbol description 31 to 24 dmacr4, dmacr[31:24] dma transfer counter byte 4 (msb) 23 to 16 dmacr3, dmacr[23:16] dma transfer counter byte 3 15 to 8 dmacr2, dmacr[15:8] dma transfer counter byte 2 7 to 0 dmacr1, dmacr[7:0] dma transfer counter byte 1 (lsb)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 29 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. table 35: dma con?guration register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved ignore_ iordy ata _ mode dma_mode[1:0] pio_mode[2:0] reset 0 0 0 00h 00h bus reset 0 0 0 00h 00h access r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol dis_ xfer_ cnt burst[2:0] mode[1:0] reserved width reset 0 00h 00h 0 1 bus reset 0 00h 00h 0 1 access r/w r/w r/w r/w r/w table 36: dma con?guration register: bit description bit symbol description 15 - reserved 14 ignore_iordy a logic 1 ignores the iordy input signal (udma mode only). 13 ata_mode a logic 1 con?gures the dma core for ata or mdma mode. used when issuing dma commands 02h to 07h, 0ah and 0ch; also used when directly accessing task ?le registers. a logic 0 con?gures the dma core for non-ata mode. used when issuing dma commands 00h and 01h. 12 to 11 udma_mode[1:0] these bits affect the timing for udma and mdma mode: 00h udma/mdma mode 0: ata(pi) compatible timings 01h udma/mdma mode 1: ata(pi) compatible timings 02h udma/mdma mode 2: ata(pi) compatible timings 03h udma mode 3: enables the dma strobe timing register (see ta b l e 3 9 ) for non-standard strobe durations; only used in udma mode. 10 to 8 pio_mode[2:0] these bits affect the pio timing (see ta bl e 8 4 ): 00h to 04h pio mode 0 to 4: ata(pi) compatible timings 05h to 07h reserved. 7 dis_xfer_cnt a logic 1 disables the dma transfer counter (see ta b l e 3 3 ). the transfer counter can only be disabled in gdma slave mode; in master mode the counter is always enabled.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 30 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] dreq is asserted only if space (writing) or data (reading) is available in the fifo. [2] this process is stopped when the transfer fifo becomes empty. 9.4.4 dma hardware register (address: 3ch) the dma hardware register consists of 1 byte. the bit allocation is shown in ta b l e 3 7 . this register determines the polarity of the bus control signals (eot, dack, dreq, dior, diow) and the dma mode (master or slave). it also controls whether the upper and lower parts of the data bus are swapped (bits endian[1:0]), for modes gdma (slave) and mdma (master) only. 6 to 4 burst[2:0] these bits select the dma burst length and the dreq timing (gdma slave mode only): 00h dreq is asserted until the last byte/word is transferred or until the fifo becomes full or empty 01h dreq is asserted and negated for each byte/word transferred [1] [2] 02h dreq is asserted and negated for every 2 bytes/words transferred [1] [2] 03h dreq is asserted and negated for every 4 bytes/words transferred [1] [2] 04h dreq is asserted and negated for every 8 bytes/words transferred [1] [2] 05h dreq is asserted and negated for every 12 bytes/words transferred [1] [2] 06h dreq is asserted and negated for every 16 bytes/words transferred [1] [2] 07h dreq is asserted and negated for every 32 bytes/words transferred [1] [2] . 3 to 2 mode[1:0] these bits only affect the gdma (slave) and mdma (master) handshake signals: 00h dior (master) or diow (slave): strobes data from the dma bus into the isp1581; diow (master) or dior (slave): puts data from the isp1581 on the dma bus 01h dior (master) or dack (slave) strobes the data from the dma bus into the isp1581; dack (master) or dior (slave) puts the data from the isp1581 on the dma bus 02h dack (master and slave) strobes the data from the dma bus into the isp1581 and also puts the data from the isp1581 on the dma bus 03h reserved. 1 - reserved 0 width this bit selects the dma bus width for gdma (slave) and mdma (master): 0 8-bit data bus 1 16-bit data bus. table 36: dma con?guration register: bit description continued bit symbol description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 31 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] nibble = 4 bits. msn: most signi?cant nibble, lsn: least signi?cant nibble. 9.4.5 dma strobe timing register (address: 60h) this 1-byte register controls the strobe timings for udma and mdma mode, when the udma_mode bits in the dma con?guration register have been set to 03h. the bit allocation is given in ta b l e 3 9 . table 37: dma hardware register: bit allocation (modes gdma, mdma (master) and mdma (ata) only) bit 7 6 5 4 3 2 1 0 symbol endian[1:0] eot_ pol master ack_ pol dreq_ pol write_ pol read_ pol reset 00h 000100 bus reset 00h 000100 access r/w r/w r/w r/w r/w r/w r/w table 38: dma hardware register: bit description bit symbol description 7 to 6 endian[1:0] these bits determine whether the data bus is swapped between internal ram and the dma bus: nibbles [1] (8-bit bus) or bytes (16-bit bus). this only applies for modes gdma (slave) and mdma (master). 00h normal data representation 8-bit bus: msn on data[7:4], lsn on data[3:0]; 16-bit bus: msb on data[15:8], lsb on data[7:0] 01h swapped data representation 8-bit bus: msn on data[3:0], lsn on data[7:4]; 16-bit bus: msb on data[7:0], lsb on data[15:8] 02h, 03h reserved. 5 eot_pol selects the polarity of the end of transfer input (used in gdma slave mode only): 0 eot is active low 1 eot is active high. 4 master selects the dma master/slave mode: 0 gdma slave mode. 1 mdma master mode. 3 ack_pol selects the dma acknowledgement polarity: 0 dack is active low 1 dack is active high. 2 dreq_pol selects the dma request polarity: 0 dreq is active low 1 dreq is active high. 1 write_pol selects the diow strobe polarity. 0 diow is active low 1 diow is active high. 0 read_pol selects the dior strobe polarity. 0 dior is active low 1 dior is active high.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 32 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] the cycle duration for udma mode 3 is the same as for udma mode 2 (see ta b l e 8 7 ). 9.4.6 task file registers (addresses: 40h to 4fh) these registers allow direct access to the internal registers of an atapi peripheral using pio mode. the supported task file registers and their functions are shown in ta b l e 4 1 . the correct peripheral register is automatically addressed via pins cs1, cs0, da2, da1 and da0 (see ta b l e 4 2 ). table 39: dma strobe timing register: bit allocation bit 7 6 5 4 3 2 1 0 symbol reserved reserved reserved dma_strobe_cnt[4:0] reset 000 1fh bus reset 000 1fh access r/w r/w r/w r/w table 40: dma strobe timing register: bit description bit symbol description 7 to 5 - reserved. 4 to 0 dma_ strobe_ cnt[4:0] these bits select the strobe duration for udma_mode = 03h (see ta b l e 3 5 ). the strobe duration is (n+1) cycles [1] , with n representing the value of dma_.strobe_cnt. table 41: task file register functions address (hex) ata function atapi function 1f0 data (16-bits) data (16-bits) 1f1 error/feature error/feature 1f2 sector count interrupt reason 1f3 sector number/lba[7:0] reserved 1f4 cylinder low/lba[15:8] cylinder low 1f5 cylinder high/lba[23:16] cylinder high 1f6 drive/head/lba[27:24] drive select 1f7 command status/command 3f6 alternate status/command alternate status/command 3f7 drive address reserved table 42: atapi peripheral register addressing task ?le cs1 cs0 da2 da1 da0 1f0 hllll 1f1 hlllh 1f2 h l l h l 1f3 h l l h h 1f4 hl hl l 1f5 hl hl h 1f6 hl hhl
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 33 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. in 8-bit bus mode, the 16-bit task file register 1f0 requires 2 consecutive write/read accesses before the proper pio write/read is generated on the ide interface. the ?rst byte is always the lower byte (lsb). other task ?le registers can be accessed directly. writing to task file registers can be done in any order except for task file register 1f7, which must be written last. 1f7 hl hhh 3f6 l hhhl 3f7 l hhhh table 42: atapi peripheral register addressing continued task ?le cs1 cs0 da2 da1 da0 table 43: task file register 1f0 (address: 40h): bit allocation cs1 = h, cs0 = l, da2 = l, da1 = l, da0 = l. bit 7 6 5 4 3 2 1 0 symbol data (ata or atapi) reset 00h bus reset 00h access r/w table 44: task file register 1f1 (address: 48h): bit allocation cs1 = h, cs0 = l, da2 = l, da1 = l, da0 = h. bit 7 6 5 4 3 2 1 0 symbol error/feature (ata or atapi) reset 00h bus reset 00h access r/w table 45: task file register 1f2 (address: 49h): bit allocation cs1 = h, cs0 = l, da2 = l, da1 = h, da0 = l. bit 7 6 5 4 3 2 1 0 symbol sector count (ata) or interrupt reason (atapi) reset 00h bus reset 00h access r/w table 46: task file register 1f3 (address: 4ah): bit allocation cs1 = h, cs0 = l, da2 = l, da1 = h, da0 = h. bit 7 6 5 4 3 2 1 0 symbol sector number/lba[7:0] (ata), reserved (atapi) reset 00h bus reset 00h access r/w
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 34 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] task file register 1f7 is a write-only register; a read will return 00h. table 47: task file register 1f4 (address: 4bh): bit allocation cs1 = h, cs0 = l, da2 = h, da1 = l, da0 = l. bit 7 6 5 4 3 2 1 0 symbol cylinder low/lba[15:8] (ata) or cylinder low (atapi) reset 00h bus reset 00h access r/w table 48: task file register 1f5 (address: 4ch): bit allocation cs1 = h, cs0 = l, da2 = h, da1 = l, da0 = h. bit 7 6 5 4 3 2 1 0 symbol cylinder high/lba[23:16] (ata) or cylinder high (atapi) reset 00h bus reset 00h access r/w table 49: task file register 1f6 (address: 4dh): bit allocation cs1 = h, cs0 = l, da2 = h, da1 = h, da0 = l. bit 7 6 5 4 3 2 1 0 symbol drive/head/lba[27:24] (ata) or drive (atapi) reset 00h bus reset 00h access r/w table 50: task file register 1f7 (address: 44h): bit allocation cs1 = h, cs0 = l, da2 = h, da1 = h, da0 = h. bit 7 6 5 4 3 2 1 0 symbol command (ata) or status [1] /command (atapi) reset 00h bus reset 00h access w table 51: task file register 3f6 (address: 4eh): bit allocation cs1 = l, cs0 = h, da2 = h, da1 = h, da0 = l. bit 7 6 5 4 3 2 1 0 symbol alternate status/command (ata or atapi) reset 00h bus reset 00h access r/w
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 35 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4.7 dma interrupt reason register (address: 50h) this 2-byte register shows the source(s) of a dma interrupt. each bit is refreshed after a dma command has been executed. an interrupt source is cleared by writing a logic 1 to the corresponding bit. the bit allocation is given in ta b l e 5 3 . table 52: task file register 3f7 (address: 4fh): bit allocation cs1 = l, cs0 = h, da2 = h, da1 = h, da0 = h. bit 7 6 5 4 3 2 1 0 symbol drive address (ata) or reserved (atapi) reset 00h bus reset 00h access r/w table 53: dma interrupt reason register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved reserved reserved reserved reserved reserved intrq_ pending dma_ xfer_ok reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol 1f0_wf_e 1f0_wf_f 1f0_rf_e read_1f0 bsy_ done tf_rd_ done cmd_ intrq_ok reserved reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 54: dma interrupt reason register: bit description bit symbol description 15 to 10 - reserved 9 intrq_pending a logic 1 indicates that a pending interrupt was detected on pin intrq. 8 dma_xfer_ok a logic 1 indicates that the dma transfer has been completed (dma transfer counter has become zero). this bit is only used in gdma (slave) mode and mdma (master) mode. 7 1f0_wf_e a logic 1 indicates that the 1f0 write fifo is empty and the microcontroller can start writing data. 6 1f0_wf_f a logic 1 indicates that the 1f0 write fifo is full and the microcontroller must stop writing data. 5 1f0_rf_e a logic 1 indicates that 1f0 read fifo is empty and the microcontroller must stop reading data. 4 read_1f0 a logic 1 indicates that 1f0 fifo contains unread data and the microcontroller can start reading data. 3 bsy_done a logic 1 indicates that the bsy status bit has become zero and polling has been stopped.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 36 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.4.8 dma interrupt enable register (address: 54h) this 2-byte register controls the interrupt generation of the source bits in the dma interrupt reason register (see ta b l e 5 3 ). the bit allocation is given in ta b l e 5 5 . a logic 1 enables interrupt generation. the value after a (bus) reset is logic 0 (disabled). 9.4.9 dma endpoint register (address: 58h) this 1-byte register selects a usb endpoint fifo as a source or destination for dma transfers. the bit allocation is given in ta b l e 5 6 . 2 tf_rd_done a logic 1 indicates that the read task files command has been completed. 1 cmd_intrq_ok a logic 1 indicates that all bytes from the fifo have been transferred (dma transfer count zero) and an interrupt on pin intrq was detected. 0 - reserved table 54: dma interrupt reason register: bit description continued bit symbol description table 55: dma interrupt enable register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved reserved reserved reserved reserved reserved ie_intrq_ pending ie_dma_ xfer_ok reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol ie_1f0_ wf_e ie_1f0_ wf_f ie_1f0_ rf_e ie_ read_1f0 ie_bsy_ done ie_tf_ rd_done ie_cmd_ intrq_ok reserved reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 56: dma endpoint register: bit allocation bit 7 6 5 4 3 2 1 0 symbol reserved reserved reserved reserved epidx[2:0] dmadir power reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 57: dma endpoint register: bit description bit symbol description 7 to 4 - reserved 3 to 1 epidx[2:0] selects the indicated endpoint for dma access 0 dmadir 0 selects the rx/out fifo for dma read transfers 1 selects the tx/in fifo for dma write transfers.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 37 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.5 general registers 9.5.1 interrupt register (address: 18h) the interrupt register consists of 4 bytes. the bit allocation is given in ta b l e 5 8 . when a bit is set in the interrupt register, this indicates that the hardware condition for an interrupt has occurred. when the interrupt register content is non-zero, the int output will be asserted. upon detecting the interrupt, the external microprocessor must read the interrupt register to determine the source of the interrupt. each endpoint buffer has a dedicated interrupt bit (epntx, epnrx). in addition, various bus states can generate an interrupt: resume, suspend, pseudo-sof, sof and bus reset. the dma controller only has one interrupt bit: the source for a dma interrupt is shown in the dma interrupt reason register (see ta b l e 5 3 ). each interrupt bit (except bit dma) can be individually cleared by writing a logic 1. the dma interrupt bit can be cleared by writing a logic 1 to the related interrupt source bit in the dma interrupt reason register. table 58: interrupt register: bit allocation bit 31 30 29 28 27 26 25 24 symbol reserved reserved reserved reserved reserved reserved ep7tx ep7rx reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 23 22 21 20 19 18 17 16 symbol ep6tx ep6rx ep5tx ep5rx ep4tx ep4rx ep3tx ep3rx reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 15 14 13 12 11 10 9 8 symbol ep2tx ep2rx ep1tx ep1rx ep0tx ep0rx reserved ep0setup reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w bit 7 6 5 4 3 2 1 0 symbol reserved dma hs_stat resume susp psof sof breset reset 00000000 bus reset 0000000 unchanged access r/w r/w r/w r/w r/w r/w r/w r/w table 59: interrupt register: bit description bit symbol description 31 to 26 reserved reserved; must write logic 0 25 ep7tx a logic 1 indicates the endpoint 7 tx buffer as interrupt source. 24 ep7rx a logic 1 indicates the endpoint 7 rx buffer as interrupt source. 23 ep6tx a logic 1 indicates the endpoint 6 tx buffer as interrupt source.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 38 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.5.2 chip id register (address: 70h) this read-only register contains the chip identi?cation and the hardware version numbers. the ?rmware should check this information to determine the functions and features supported. the register contains 3 bytes and the bit allocation is shown in ta b l e 6 0 . 22 ep6rx a logic 1 indicates the endpoint 6 rx buffer as interrupt source. 21 ep5tx a logic 1 indicates the endpoint 5 tx buffer as interrupt source. 20 ep5rx a logic 1 indicates the endpoint 5 rx buffer as interrupt source. 19 ep4tx a logic 1 indicates the endpoint 4 tx buffer as interrupt source. 18 ep4rx a logic 1 indicates the endpoint 4 rx buffer as interrupt source. 17 ep3tx a logic 1 indicates the endpoint 3 tx buffer as interrupt source. 16 ep3rx a logic 1 indicates the endpoint 3 rx buffer as interrupt source. 15 ep2tx a logic 1 indicates the endpoint 2 tx buffer as interrupt source. 14 ep2rx a logic 1 indicates the endpoint 2 rx buffer as interrupt source. 13 ep1tx a logic 1 indicates the endpoint 1 tx buffer as interrupt source. 12 ep1rx a logic 1 indicates the endpoint 1 rx buffer as interrupt source. 11 ep0tx a logic 1 indicates the endpoint 0 data tx buffer as interrupt source. 10 ep0rx a logic 1 indicates the endpoint 0 data rx buffer as interrupt source. 9 reserved reserved. 8 ep0setup a logic 1 indicates that a setup token was received on endpoint 0. 7 reserved reserved. 6 dma dma status: a logic 1 indicates a change in the dma status register. 5 hs_stat high speed status: .a logic 1 indicates a change from fs to hs mode (hs connection). this bit is not set, when the system goes into a fs suspend. 4 resume resume status: a logic 1 indicates that a status change from suspend to resume (active) was detected. 3 susp suspend status: a logic 1 indicates that a status change from active to suspend was detected on the bus. 2 psof pseudo sof interrupt: a logic 1 indicates that a pseudo sof or m sof was received. pseudo sof is an internally generated clock signal (fs: 1 ms period, hs: 125 m s period) synchronized to the usb bus sof/ m sof. 1 sof sof interrupt: a logic 1 indicates that a sof/ m sof was received. 0 breset bus reset : a logic 1 indicates that a usb bus reset was detected. table 59: interrupt register: bit description continued bit symbol description
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 39 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.5.3 frame number register (address: 74h) this read-only register contains the frame number of the last successfully received start of frame (sof). the register contains 2 bytes and the bit allocation is given in ta b l e 6 2 . in case of 8-bit access the register content is returned lower byte ?rst. table 60: chip id register: bit allocation bit 23 22 21 20 19 18 17 16 symbol version[7:0] reset 01h bus reset 01h access r bit 15 14 13 12 11 10 9 8 symbol chipid[15:8] reset 15h bus reset 15h access r bit 7 6 5 4 3 2 1 0 symbol chipid[7:0] reset 81h bus reset 81h access r table 61: chip id register: bit description bit symbol description 23 to 16 version version number (01h). the version number will be incremented in case of a silicon revision with improved performance and functionality. 15 to 8 chipid[15:8] chip id: upper byte (15h) 7 to 0 chipid[7:0] chip id: lower byte (81h) table 62: frame number register: bit allocation bit 15 14 13 12 11 10 9 8 symbol reserved reserved microsof[2:0] sofr[10:8] power reset 0 0 00h 00h bus reset 0 0 00h 00h access rr r r bit 7 6 5 4 3 2 1 0 symbol sofr[7:0] power reset 00h bus reset 00h access r
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 40 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.5.4 scratch register (address: 78h) this 16-bit register can be used by the ?rmware to save and restore information, e.g. the device status before it enters power-off mode during suspend. the content of this register will not be altered by a bus reset. the bit allocation is given in ta b l e 6 4 . 9.5.5 unlock device register (address: 7ch) in suspend state all the internal registers are write-protected to prevent data corruption by external devices during a resume. register access for reading is not blocked. to re-enable the isp1581 registers from the write-protected mode, the ?rmware must write a 2-byte unlock code (aa37h) into this register. the bit allocation of the unlock device register is given in ta b l e 6 6 . table 63: frame number register: bit description bit symbol description 13 to 11 microsof[2:0] microframe number 10 to 0 sofr[10:0] frame number table 64: scratch register: bit allocation bit 15 14 13 12 11 10 9 8 symbol sfirh[7:0] reset 00h bus reset unchanged access r/w bit 7 6 5 4 3 2 1 0 symbol sfirl[7:0] reset 00h bus reset unchanged access r/w table 65: scratch information register: bit description bit symbol description 15 to 8 sfirh[7:0] scratch ?rmware information register (high byte) 7 to 0 sfirl[7:0] scratch ?rmware information register (low byte)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 41 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 9.5.6 test mode register (address: 84h) this 1-byte register allows the ?rmware to set the (d + , d -) lines to predetermined states for testing purposes. the bit allocation is given in ta b l e 6 8 . remark: only one bit can be set at a time. table 66: unlock device register: bit allocation bit 15 14 13 12 11 10 9 8 symbol ulcode[15:8] = aah reset not applicable bus reset not applicable access w bit 7 6 5 4 3 2 1 0 symbol ulcode[7:0] = 37h reset not applicable bus reset not applicable access w table 67: unlock device register: bit description bit symbol description 15 to 0 ulcode[15:0] writing data aa37h unlocks the internal registers and fifos for writing, following a resume. table 68: test mode register: bit allocation bit 7 6 5 4 3 2 1 0 symbol forcehs phytest lpbk forcefs prbs kstate jstate se0_nak reset 00000000 bus reset 00000000 access r/w r/w r/w r/w r/w r/w r/w r/w table 69: test mode register: bit description bit symbol description 7 forcehs a logic 1 forces the hardware to high-speed mode only and disables the chirp detection logic. 6 phytest a logic 1 initiates an internal hardware test of the transceiver. after successful completion the phytest bit reverts to logic 0. 5 lpbk a logic 1 selects loop-back mode. all data written to tx/in fifo of endpoint 1 is copied into rx/out of endpoint 1. 4 forcefs a logic 1 forces the physical layer to full-speed mode only and disables the chirp detection logic. 3 prbs a logic 1 sets the (d +, d - ) lines to toggle in a pre-determined random pattern. 2 kstate writing a logic 1 sets the (d +, d - ) lines to the k state. 1 jstate writing a logic 1 sets the (d +, d - ) lines to the j state. 0 se0_nak writing a logic 1 sets the (d +, d - ) lines to a hs quiescent state. the device only responds to a valid hs in token with a nak.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 42 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 10. limiting values 11. static characteristics [1] in suspend mode the minimum voltage is 3.0 v. table 70: absolute maximum ratings in accordance with the absolute maximum rating system (iec 60134). symbol parameter conditions min. max unit v cc supply voltage - 0.5 + 6.0 v v i input voltage - 0.5 v cc + 0.5 v i latchup latchup current v i < 0 or v i >v cc - 200 ma v esd electrostatic discharge voltage i li <15 m a - v t stg storage temperature - 60 + 150 c p tot total power dissipation - mw table 71: recommended operating conditions symbol parameter conditions min. max unit v cc supply voltage with voltage converter 4.0 5.5 v without voltage converter 3.0 3.6 v v i input voltage range 0 5.5 v v i(ai/o) input voltage on analog i/o pins (d + , d - ) 0 3.6 v v o(od) open-drain output pull-up voltage 0 v cc v t amb operating ambient temperature - 40 + 85 c table 72: static characteristics; supply pins v cc = 4.0 to 5.5 v; v gnd =0v; t amb = - 40 to + 85 c; unless otherwise speci?ed. symbol parameter conditions min. typ max unit v reg(3.3) regulated supply voltage with voltage converter 3.0 [1] 3.3 3.6 v i cc operating supply current - - ma i cc(susp ) suspend supply current 1.5 k w pull-up on pin d + - - m a no pull-up on pin d + - - m a table 73: static characteristics: digital pins v cc = 4.0 to 5.5 v; v gnd =0v; t amb = - 40 to + 85 c; unless otherwise speci?ed. symbol parameter conditions min. typ max unit input levels v il low-level input voltage - - 0.8 v v ih high-level input voltage 2.0 - - v
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 43 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] d + is the usb positive data pin; d - is the usb negative data pin. [2] includes external resistors of 22 w 1% on both d + and d - . schmitt trigger inputs v th(lh) positive-going threshold voltage 1.4 - 1.9 v v th(hl) negative-going threshold voltage 0.9 - 1.5 v v hys hysteresis voltage 0.4 - 0.7 v output levels v ol low-level output voltage (open drain outputs) i ol = rated drive - - 0.4 v i ol =20 m a - - 0.1 v v oh high-level output voltage (open drain outputs) i oh = rated drive 2.4 - - v i oh =20 m av cc -0.1 - - v leakage current i li input leakage current - - 5 m a open-drain outputs i oz off-state output current - - 5 m a table 73: static characteristics: digital pins continued v cc = 4.0 to 5.5 v; v gnd =0v; t amb = - 40 to + 85 c; unless otherwise speci?ed. symbol parameter conditions min. typ max unit table 74: static characteristics: analog i/o pins (d + , d - ) [1] v cc = 4.0 to 5.5 v; v gnd =0v; t amb = - 40 to + 85 c; unless otherwise speci?ed. symbol parameter conditions min. typ max unit input levels v di differential input sensitivity | v i(d + ) - v i(d - ) | 0.2 - - v v cm differential common mode voltage includes v di range 0.8 - 2.5 v v se single ended receiver threshold 0.8 2.0 v v il low-level input voltage - - 0.8 v v ih high-level input voltage 2.0 - - v output levels v ol low-level output voltage r l = 1.5 k w to + 3.6v - - 0.3 v v oh high-level output voltage r l =15k w to gnd 2.8 - 3.6 v leakage current i lz off-state leakage current 0 < v i < 3.3 v - - 10 m a capacitance c in transceiver capacitance pin to gnd - - 20 pf resistance r pu pull-up resistance on d + softconnect = on 1.1 - 1.9 k w z drv [2] driver output impedance steady-state drive 29 - 44 w z inp input impedance 10 - - m w
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 44 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12. dynamic characteristics [1] dependent on the crystal oscillator start-up time. table 75: dynamic characteristics v cc = 4.0 to 5.5 v; v gnd =0v; t amb = - 40 to + 85 c; unless otherwise speci?ed. symbol parameter conditions min. typ max unit reset t w( reset) pulse width on input reset crystal oscillator running - - m s crystal oscillator stopped - [1] -ms crystal oscillator f xtal crystal frequency - 12 - mhz table 76: dynamic characteristics: analog i/o pins (d + , d - ) [1] v cc = 4.0 to 5.5 v; v gnd =0v;t amb = - 40 to + 85 c; c l = 50 pf; r pu = 1.5 k w on d + to v term .; unless otherwise speci?ed. symbol parameter conditions min. typ max unit driver characteristics full-speed mode t fr rise time c l =50pf; 10 to 90% of | v oh - v ol | 4 - 20 ns t ff fall time c l =50pf; 90 to 10% of | v oh - v ol | 4 - 20 ns frfm differential rise/fall time matching (t fr /t ff ) [2] 90 - 111.11 % v crs output signal crossover voltage [2] [3] 1.3 - 2.0 v high-speed mode t hsr high-speed differential rise time with captive cable 500 - - ps t hsf high-speed differential fall time with captive cable 500 - - ps data source timing high-speed mode (template 1, universal serial bus speci?cation rev. 2.0 ) - driver waveform requirements eye patterns of template 1 and template 2; see figure 7 and figure 8 [3] see ta b l e 7 7 full-speed mode t feopt source eop width see figure 3 [3] 160 - 175 ns t fdeop source differential data-to-eop transition skew see figure 3 [3] - 2- + 5ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 45 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] test circuit: see figure 31 . [2] excluding the ?rst transition from idle state. [3] characterized only, not tested. limits guaranteed by design. receiver timing high-speed mode (template 4, universal serial bus speci?cation rev. 2.0 ) - data source jitter and receiver jitter tolerance eye patterns of template 3 and template 4; see figure 9 and figure 10 [3] see ta b l e 8 0 full-speed mode t jr1 receiver data jitter tolerance to next transition see figure 4 [3] - 18.5 - + 18.5 ns t jr2 receiver data jitter tolerance for paired transitions see figure 4 [3] - 9- + 9ns t feopr receiver se0 width accepted as eop; see figure 3 [3] 82--ns t fst width of se0 during differential transition rejected as eop; see figure 5 [3] --14ns table 76: dynamic characteristics: analog i/o pins (d + , d - ) [1] continued v cc = 4.0 to 5.5 v; v gnd =0v;t amb = - 40 to + 85 c; c l = 50 pf; r pu = 1.5 k w on d + to v term .; unless otherwise speci?ed. symbol parameter conditions min. typ max unit t period is the bit duration corresponding with the usb data rate. full-speed timing symbols have a subscript pre?x f, low-speed timings a pre?x l. fig 3. source differential data-to-eop transition skew and eop width. mgr776 t period differential data lines crossover point differential data to se0/eop skew n t period + t deop source eop width: t eopt receiver eop width: t eopr crossover point extended + 3.3 v 0 v
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 46 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.1 high-speed signals high-speed usb signals are characterized using eye patterns. for measuring the eye patterns 4 test points have been de?ned (see figure 6 ). the universal serial bus speci?cation rev. 2.0 de?nes the eye patterns in several templates. for isp1581 templates 1, 2, 3 and 4 are relevant. t period is the bit duration corresponding with the usb data rate. fig 4. receiver differential data jitter. mgr871 t period t jr differential data lines consecutive transitions n t period + t jr1 paired transitions n t period + t jr2 + 3.3 v 0 v t jr1 t jr2 fig 5. receiver se0 width tolerance. mgr872 differential data lines + 3.3 v 0 v t fst v ih(min) fig 6. eye pattern measurement planes. mbl205 transceiver hub circuit board a connector traces tp1 tp2 usb cable transceiver device circuit board b connector traces tp3 tp4
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 47 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.1.1 template 1 (transmit waveform; device without captive cable) the eye pattern in figure 7 de?nes the transmit waveform requirements for a hub (measured at tp2) or a device without a captive 1 cable (measured at tp3). the corresponding signal levels and timings are given in ta b l e 7 7 . timings are given as a percentage of the unit interval (ui), which represents the nominal bit duration t period for a 480 mbit/s transmission rate. [1] in the unit interval following a transition. [2] in all other cases. 1. captive cables have a vendor-speci?c connector to the peripheral (hardwired or detachable) and a usb a connector on the other side. for hot plugging, the vendor-speci?c connector must meet the same performance requirements as a usb b connector. fig 7. template 1 eye pattern (transmit waveform). table 77: template 1 eye pattern de?nition name differential voltage on dp, dm (mv) relative duration (% of unit interval) level 1 + 525 [1] + 475 [2] n.a. level 2 - 525 [1] - 475 [2] n.a. point 1 0 7.5 point 2 0 92.5 point 3 + 300 37.5 point 4 + 300 62.5 point 5 - 300 37.5 point 6 - 300 62.5 mbl206 level 1 level 2 point 3 point 4 point 2 point 1 point 5 0 100 relative duration (% of unit interval) - 400 mv + 400 mv 0 0 - 100 100 200 300 400 500 600 differential output voltage (mv) - 200 - 300 - 400 - 500 - 600 point 6
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 48 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.1.2 template 2 (transmit waveform; device with captive cable) the eye pattern in figure 8 de?nes the transmit waveform requirements for a device with a captive cable (measured at tp2). the corresponding signal levels and timings are given in ta b l e 7 8 . timings are given as a percentage of the unit interval (ui), which represents the nominal bit duration t period for a 480 mbit/s transmission rate. [1] in the unit interval following a transition. [2] in all other cases. fig 8. template 2 eye pattern (transmit waveform). table 78: template 2 eye pattern de?nition name differential voltage on dp, dm (mv) relative duration (% of unit interval) level 1 + 525 [1] + 475 [2] n.a. level 2 - 525 [1] - 475 [2] n.a. point 1 0 12.5 point 2 0 87.5 point 3 + 175 35 point 4 + 175 65 point 5 - 175 35 point 6 - 175 65 004aaa002 level 1 level 2 point 3 point 4 point 2 point 1 point 5 0 100 relative duration (% of unit interval) - 400 mv + 400 mv 0 0 - 100 100 200 300 400 500 600 differential output voltage (mv) - 200 - 300 - 400 - 500 - 600 point 6
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 49 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.1.3 template 3 (receive waveform; receiver sensitivity with captive cable) the eye pattern de?ned in figure 9 de?nes the receiver sensitivity requirements for a device with a captive cable (signal applied at test point tp2). the corresponding signal levels and timings are given in ta b l e 7 9 . timings are given as a percentage of the unit interval (ui), which represents the nominal bit duration t period for a 480 mbit/s transmission rate. fig 9. template 3 eye pattern (receive waveform). table 79: template 3 eye pattern de?nition name differential voltage on dp, dm (mv) relative duration (% of unit interval) level 1 + 575 n.a. level 2 - 575 n.a. point 1 0 10 point 2 0 90 point 3 + 275 40 point 4 + 275 60 point 5 - 275 40 point 6 - 275 60 004aaa003 level 1 level 2 0 100 relative duration (% of unit interval) - 400 mv + 400 mv 0 0 - 100 100 200 300 400 500 600 differential input voltage (mv) - 200 - 300 - 400 - 500 - 600 point 2 point 5 point 6 point 3 point 4 point 1
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 50 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.1.4 template 4 (receive waveform; receiver sensitivity without captive cable) the eye pattern de?ned in figure 10 de?nes the receiver sensitivity requirements for a hub (signal applied at test point tp2) or a device without a captive cable (signal applied at test point tp3). the corresponding signal levels and timings are given in ta b l e 8 0 . timings are given as a percentage of the unit interval (ui), which represents the nominal bit duration t period for a 480 mbit/s transmission rate. fig 10. template 4 eye pattern (receive waveform). table 80: template 4 eye pattern de?nition name differential voltage on dp, dm (mv) relative duration (% of unit interval) level 1 + 575 n.a. level 2 - 575 n.a. point 1 0 15 point 2 0 85 point 3 + 150 35 point 4 + 150 65 point 5 - 150 35 point 6 - 150 65 mbl207 level 1 level 2 0 100 relative duration (% of unit interval) - 400 mv + 400 mv 0 0 - 100 100 200 300 400 500 600 differential input voltage (mv) - 200 - 300 - 400 - 500 - 600 point 2 point 5 point 6 point 3 point 4 point 1
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 51 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.2 timing symbols table 81: legend for timing characteristics symbol description time symbols t time t cycle time (periodic signal) signal names a address; dma acknowledge (dack) c clock; command d data input; data e chip enable g output enable i instruction (program memory content); input (general) l address latch enable (ale) p program store enable ( psen, active low); propagation delay q data output r read signal ( rd, active low); read (action); dma request (dreq) s chip select w write signal ( wr, active low); write (action); pulse width u unde?ned y output (general) logic levels h logic high l logic low p stop, not active (off) s start, active (on) v valid logic level x invalid logic level z high-impedance (?oating, three-state)
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 52 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.3 parallel i/o timing 12.3.1 generic processor mode (bus_conf = 1) fig 11. parallel i/o timing: separate address and data buses. (write) data [ 15:0 ] write (read) data [ 15:0 ] read mgt497 ad [ 7:0 ] t whsh t avwl t dvwh t i1vi2l t rhdz t avrl t i2hi1x t cy(rw) t whax t rhax t rldv t whdz r/w (i1) ds/wr (i2) cs rd t rhsh table 82: parallel i/o timing parameters: separate address and data buses symbol parameter min max unit reading t avrl address set-up time before rd low 0 - ns t rhax address hold time after rd high 0 - ns t rldv rd low to data valid delay - 35 ns t rhdz rd high to data outputs three-state delay 0 20 ns t rhsh rd high to cs high delay 0 - ns writing t avwl address set-up time before wr low 0 - ns t whax address hold time after wr high 0 - ns t dvwh data set-up time before wr high 25 - ns t whdz data hold time after wr high 0 - ns t whsh wr high to cs high delay 0 - ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 53 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.3.2 split bus mode (bus_conf = 0) general t cy(rw) read/write cycle time 60 - ns t i1vi2l r/ w set-up time before ds low 5 - ns t i2hi1x r/ w hold time after ds high 5 - ns table 82: parallel i/o timing parameters: separate address and data buses continued symbol parameter min max unit fig 12. parallel interface timing: multiplexed address/data bus. address address data data (write) ad [ 7:0 ] ale (read) ad [ 7:0 ] t whsh t rhsh t rhdz t rldv t llwl t lli2l t dvwh t llrl t whdz t i2hi1x t i1vll t avll mgt498 t cy(rw) r/w (i1) ds/ wr (i2) cs rd table 83: parallel i/o timing parameters: multiplexed address/data bus symbol parameter min max unit reading t rldv rd low to data valid delay - 35 ns t rhdz rd high to data outputs three-state delay 0 20 ns t rhsh rd high to cs high delay 0 - ns t llrl ale low set-up time before rd low 0 - ns writing t dvwh data set-up time before wr high 25 - ns t llwl ale low to wr low delay 5 - ns t whdz data hold time after wr high 0 - ns t whsh wr high to cs high delay 0 - ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 54 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.4 dma timing 12.4.1 pio mode general t cy(rw) read/write cycle time 60 - ns t avll address set-up time before ale low 3 - ns t i1vll r/ w set-up time before ale low 3 - ns t lli2l ale low to ds low delay 5 - ns t i2hi1x r/ w hold time after ds high 5 - ns table 83: parallel i/o timing parameters: multiplexed address/data bus continued symbol parameter min max unit (1) the device address consists of signals cs1, cs0, da2, da1 and da0. (2) the data bus width depends on the pio access command used. task file register access uses 8 bits (data[7:0]), except for task file register 1f0 which uses 16 bits (data[15:0]). dma commands 04h and 05h also use a 16-bit data bus. (3) the device can negate iordy to extend the pio cycle with wait states. the host determines whether or not to extend the current cycle after t su4 following the assertion of dior or diow. the following three cases are distinguished: a) device keeps iordy released (high-impedance): no wait state is generated. b) device negates iordy during t su4 , but re-asserts iordy before t su4 expires: no wait state is generated. c) device negates iordy during t su4 and keeps iordy negated for at least 5 ns after t su4 expires: a wait state is generated. the cycle is completed as soon as iordy is re-asserted. for extended read cycles (dior asserted), the read data on lines datan must be valid at t d1 before iordy is asserted. (4) dior and diow have a programmable polarity: shown here as active low signals. fig 13. pio mode timing. high (write) data [ 7:0 ] (2) (read) data [ 7:0 ] (2) device (1) address valid dior, diow (4) iordy (3a) iordy (3b) iordy (3c) t w1 t w2 t h1 t su1 t su2 t su5 t su4 t su4 t w3 t h2 t su3 t d2 t h3 (min) t cy1 mgt499
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 55 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] t cy1 is the total cycle time, consisting of the command active time t w1 and is the command recovery (= inactive) time t w2 :t cy1 =t w1 +t w2 . the minimum timing requirements for t cy1 , t w1 and t w2 must all be met. since t cy1(min) is greater than the sum of t w1(min) and t w2(min) , a host implementation must lengthen t w1 and/or t w2 to ensure that t cy1 is equal to or greater than the value reported in the identify device data. a device implementation shall support any legal host implementation. [2] t d2 speci?es the time after dior is negated, when the data bus is no longer driven by the device (three-state). [3] if iordy is low at t su4 , the host waits until iordy is made high before the pio cycle is completed. in that case, t su5 must be met for reading (t su3 does not apply). when iordy is high at t su4 , t su3 must be met for reading (t su5 does not apply). table 84: pio mode timing parameters symbol parameter mode 0 mode 1 mode 2 mode 3 mode 4 unit t cy1(min) read/write cycle time (minimum) [1] 600 383 240 180 120 ns t su1(min) address to dior/diow on set-up time (minimum) 70 50 30 30 25 ns t w1(min) dior/diow pulse width (minimum) [1] 165 125 100 80 70 ns t w2(min) dior/diow recovery time (minimum) [1] ---7025ns t su2(min) data set-up time before diow off (minimum) 60 45 30 30 20 ns t h2(min) data hold time after diow off (minimum) 30 20 15 10 10 ns t su3(min) data set-up time before dior on (minimum) 50 35 20 20 20 ns t h3(min.) data hold time after dior off (minimum) 55555ns t d2(max) data to three-state delay after dior off (minimum) [2] 30 30 30 30 30 ns t h1(min) address hold time after dior/diow off (minimum) 20 15 10 10 10 ns t su4(min) iordy after dior/diow on set-up time (minimum) [3] 35 35 35 35 35 ns t su5(min) read data to iordy high set-up time (minimum) [3] 00000ns t w3(max) iordy low pulse width (maximum) 1250 1250 1250 1250 1250 ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 56 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.4.2 gdma slave mode dreq is continuously asserted until the last transfer is done or the fifo is full. data strobes: dior (read), diow (write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 14. gdma slave mode timing (burst = 00h, mode = 00h). t h1 t w1 t su1 t d1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) mgt500 dreq is continuously asserted until the last transfer is done or the fifo is full. data strobe: dack (read/write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 15. gdma slave mode timing (burst = 00h, mode = 02h). t h1 t w1 t su1 t d1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) high dack (1) dior/diow (1) mgt501
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 57 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. dreq is asserted for every transfer. data strobes: dior (read), diow (write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 16. gdma slave mode timing (burst = 01h, mode = 00h). t d1 t w1 t su1 t h1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) mgt502 dreq is asserted for every transfer. data strobe: dack (read/write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 17. gdma slave mode timing (burst = 01h, mode = 02h). t d1 t w1 t su1 t h1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) mgt503 high
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 58 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. dreq is asserted once per n transfers (n is determined by the burst value). example shown here: n = 2. data strobes: dior (read), diow (write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 18. gdma slave mode timing (burst > 01h, mode = 00h). t d1 t w1 t su1 t h1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) mgt504 dreq is asserted once per n transfers (n is determined by the burst value). example shown here: n = 2. data strobe: dack (read/write). (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 19. gdma slave mode timing (burst > 01h, mode = 02h). t d1 t w1 t su1 t h1 t su2 t d2 t h2 t cy1 (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) mgt505 high
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 59 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 12.4.3 mdma mode table 85: gmda slave mode timing parameters symbol parameter min max unit t cy1 read/write cycle time 66.67 - ns t su1 dreq set-up time before ?rst dack on 0 - ns t d1 dreq on delay after last strobe off 33.33 - ns t h1 dreq hold time after last strobe on 0 33.33 ns t w1 dior/diow pulse width 33.33 - ns t d2 read data valid delay after strobe on - 10 ns t h2 read data hold time after strobe off 5 - ns t su2 write data set-up time before strobe off 10 - ns (1) programmable polarity: shown as active low. (2) programmable polarity: shown as active high. fig 20. mdma master mode timing. (write) data [ 15:0 ] (read) data [ 15:0 ] dreq (2) dack (1) dior/diow (1) t w1 t w2 t su1 t su2 t d2 t su2 t h1 t h2 t h3 t cy1 mgt506 t d1 t d3 table 86: mdma mode timing parameters symbol parameter mode 0 mode 1 mode 2 unit t cy1(min) read/write cycle time (minimum) [1] 480 150 120 ns t w1(min) dior/diow pulse width (minimum) [1] 215 80 70 ns t d1(max) data valid delay after dior on (maximum) 150 60 50 ns t h3(min) data hold time after dior off (minimum) 555ns t su2(min) data set-up time before dior/diow off (minimum) 100 30 20 ns t h2(min) data hold time after diow off (minimum) 20 15 10 ns t su1(min) dack set-up time before dior/diow on (minimum) 000ns t h1(min) dack hold time after dior/diow off (minimum) 2055ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 60 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] t cy1 is the total cycle time, consisting of the command active time t w1 and is the command recovery (= inactive) time t w2 : t cy1 =t w1 +t w2 . the minimum timing requirements for t cy1 , t w1 and t w2 must all be met. since t cy1(min) is greater than the sum of t w1(min) and t w2(min) , a host implementation must lengthen t w1 and/or t w2 to ensure that t cy1 is equal to or greater than the value reported in the identify device data. a device implementation shall support any legal host implementation. 12.4.4 udma mode t w2(min) dior recovery time (minimum) [1] 50 50 25 ns diow recovery time (minimum) [1] 215 50 25 ns t d2(max) dior on to dreq off delay (maximum) 120 40 35 ns diow on to dreq off delay (maximum) 40 40 35 ns t d3(max) dack off to data lines three-state delay (maximum) 20 25 25 ns table 86: mdma mode timing parameters continued symbol parameter mode 0 mode 1 mode 2 unit (1) data[15:0] and strobe signals at the receiver require some time to stabilize due to the settling time and propagation delay of the cable. fig 21. udma timing: sustained synchronous burst. data [ 15:0 ] (1) (sender) dior (1) (sender) data [ 15:0 ] (1) (receiver) iordy (1) (receiver) t su1 t su1 t h1 t h2 t h2 t h2 t su2 t su2 t h1 t h1 t cy1 t cy1 mgt507
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 61 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. (1) programmable polarity: shown as active low. fig 22. udma timing: drive initiating a burst for a read command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (drive) da [ 2:0 ] and cs [ 1:0 ] iordy (drive) mgt508 t su3 t d6 t su3 t su3 t su1 t d4 t h1 t d5 t d6 t d1 t d13 t d13 t d11 (1) programmable polarity: shown as active low. fig 23. udma timing: drive initiating a burst for a write command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (host) da [ 2:0 ] and cs [ 1:0 ] iordy (drive) t su3 t su3 t su3 t su1 t d6 t d1 t d1 t d11 t d2 t h1 mgt509
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 62 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. (1) programmable polarity: shown as active low. fig 24. udma timing: receiver pausing a burst. dreq (drive) dack (1) (host) dior diow (host) data [ 15:0 ] iordy low t d7 t d7 t d8 t d9 mgt510 (1) programmable polarity: shown as active low. fig 25. udma timing: drive terminating a burst during a read command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (drive) iordy (drive) da [ 2:0 ] and cs [ 1:0 ] t su1 t h1 crc t h3 t h3 t h3 t d5 t d2 t d2 t d2 t d12 t d4 t d10 t d3 mgt511
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 63 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. (1) programmable polarity: shown as active low. fig 26. udma timing: drive terminating a burst during a write command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (host) da [ 2:0 ] and cs [ 1:0 ] iordy (drive) t su1 crc t d10 t d7 t d9 t h1 t h3 t d3 t d3 t h3 t h3 t d2 t d2 mgt512 (1) programmable polarity: shown as active low. fig 27. udma timing: host terminating a burst during a read command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (drive) da [ 2:0 ] and cs [ 1:0 ] iordy (drive) t h3 t h3 t h3 t su1 t d4 t d5 t d2 t d2 t d3 t d3 t h1 crc mgt513 t d10 t d7 t d9
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 64 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. (1) programmable polarity: shown as active low. fig 28. udma timing: host terminating a burst during a write command. dreq (drive) dack (1) (host) dior (host) diow (host) data [ 15:0 ] (host) da [ 2:0 ] and cs [ 1:0 ] iordy (drive) t d2 t d2 t d3 t d2 t h3 t su1 t h1 crc t h3 t h3 t d10 mgt514 t d12 table 87: udma mode timing parameters symbol parameter mode 0 mode 1 mode 2 unit min max min max min max t cy1 read/write cycle time (from strobe edge to strobe edge) 114 - 75 - 55 - ns t su2 data set-up time at receiver 15 - 10 - 7 - ns t h2 data hold time at receiver 5-5-5-ns t su1 data set-up time at sender 70 - 48 - 34 - ns t h1 data hold time at sender 6-6-6-ns t d1 unlimited interlock time [1] 0-0-0-ns t d2 limited interlock time [1] 0 150 0 150 0 150 ns t d3 limited interlock time with minimum [1] 20 - 20 - 20 - ns t d4 data line drivers switch-off delay - 10 - 10 - 10 ns t d5 data line drivers switch-on delay (host) 20 - 20 - 20 - ns data line drivers switch-on delay (drive) 0-0-0-ns t su3 control signal set-up time before dack on 20 - 20 - 20 - ns t h3 control signal hold time after dack off 20 - 20 - 20 - ns t d6 dack on to control signal transition delay 20 70 20 70 20 70 ns t d7 ready to paused delay 160 - 125 - 100 - ns t d8 strobe to ready delay to ensure a synchronous pause -50-30-20ns t d9 ready to ?nal strobe edge delay - 75 - 60 - 50 ns
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 65 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. [1] interlock time is the time allowed between an action by one agent and the following action by the other agent. an agent can be a sender or a receiver. interlocking actions require a response signal from the other agent before processing can continue. 13. application information t d10 dack off to iordy high-z delay - 20 - 20 - 20 ns t d11 dack on to iordy high delay 0-0-0-ns t d12 ?nal strobe edge to dreq off or diow on delay 50 - 50 - 50 - ns t d13 ?rst strobe delay after control signal on 0 230 0 200 0 170 ns table 87: udma mode timing parameters continued symbol parameter mode 0 mode 1 mode 2 unit min max min max min max fig 29. typical interface connections for generic processor mode. fig 30. typical interface connections for split bus mode. mgt515 data read strobe 16 isp1581 cpu data15 to data0 (r/w)/rd address 8 ad7 to ad0 write strobe ds/wr chip select cs 8 mgt516 data [ 15:0 ] dreq isp1581 dma 8051 microcontroller ad7 to ad0 int ale/a0 p0.7/ad7 to p0.0/ad0 ale dack diow dior write strobe read strobe interrupt address latch enable address/data (r/w)/rd ds/wr rd intn wr
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 66 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 14. test information the dynamic characteristics of the analog i/o ports (d + , d -) as listed in ta b l e 7 6 , were determined using the circuit shown in figure 31 . in full-speed mode an internal 1.5 k w pull-up resistor is connected to pin d + . fig 31. load impedance for d + and d - pins (full-speed mode). test point c l 50 pf 22 w 15 k w d.u.t mgt495
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 67 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 15. package outline fig 32. lqfp64 package outline. unit a max. a 1 a 2 a 3 b p ce (1) eh e ll p z y w v q references outline version european projection issue date iec jedec eiaj mm 1.60 0.20 0.05 1.45 1.35 0.25 0.27 0.17 0.18 0.12 10.1 9.9 0.5 12.15 11.85 1.45 1.05 7 0 o o 0.12 0.1 1.0 0.2 dimensions (mm are the original dimensions) note 1. plastic or metal protrusions of 0.25 mm maximum per side are not included. 0.75 0.45 sot314-2 ms-026 136e10 99-12-27 00-01-19 d (1) (1) (1) 10.1 9.9 h d 12.15 11.85 e z 1.45 1.05 d b p e q e a 1 a l p detail x l (a ) 3 b 16 c d h b p e h a 2 v m b d z d a z e e v m a x 1 64 49 48 33 32 17 y pin 1 index w m w m 0 2.5 5 mm scale lqfp64: plastic low profile quad flat package; 64 leads; body 10 x 10 x 1.4 mm sot314-2
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 68 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 16. soldering 16.1 introduction to soldering surface mount packages this text gives a very brief insight to a complex technology. a more in-depth account of soldering ics can be found in our data handbook ic26; integrated circuit packages (document order number 9398 652 90011). there is no soldering method that is ideal for all surface mount ic packages. wave soldering can still be used for certain surface mount ics, but it is not suitable for ?ne pitch smds. in these situations re?ow soldering is recommended. 16.2 re?ow soldering re?ow soldering requires solder paste (a suspension of ?ne solder particles, ?ux and binding agent) to be applied to the printed-circuit board by screen printing, stencilling or pressure-syringe dispensing before package placement. several methods exist for re?owing; for example, convection or convection/infrared heating in a conveyor type oven. throughput times (preheating, soldering and cooling) vary between 100 and 200 seconds depending on heating method. typical re?ow peak temperatures range from 215 to 250 c. the top-surface temperature of the packages should preferable be kept below 220 c for thick/large packages, and below 235 c small/thin packages. 16.3 wave soldering conventional single wave soldering is not recommended for surface mount devices (smds) or printed-circuit boards with a high component density, as solder bridging and non-wetting can present major problems. to overcome these problems the double-wave soldering method was speci?cally developed. if wave soldering is used the following conditions must be observed for optimal results: ? use a double-wave soldering method comprising a turbulent wave with high upward pressure followed by a smooth laminar wave. ? for packages with leads on two sides and a pitch (e): C larger than or equal to 1.27 mm, the footprint longitudinal axis is preferred to be parallel to the transport direction of the printed-circuit board; C smaller than 1.27 mm, the footprint longitudinal axis must be parallel to the transport direction of the printed-circuit board. the footprint must incorporate solder thieves at the downstream end. ? for packages with leads on four sides, the footprint must be placed at a 45 angle to the transport direction of the printed-circuit board. the footprint must incorporate solder thieves downstream and at the side corners.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 69 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. during placement and before soldering, the package must be ?xed with a droplet of adhesive. the adhesive can be applied by screen printing, pin transfer or syringe dispensing. the package can be soldered after the adhesive is cured. typical dwell time is 4 seconds at 250 c. a mildly-activated ?ux will eliminate the need for removal of corrosive residues in most applications. 16.4 manual soldering fix the component by ?rst soldering two diagonally-opposite end leads. use a low voltage (24 v or less) soldering iron applied to the ?at part of the lead. contact time must be limited to 10 seconds at up to 300 c. when using a dedicated tool, all other leads can be soldered in one operation within 2 to 5 seconds between 270 and 320 c. 16.5 package related soldering information [1] all surface mount (smd) packages are moisture sensitive. depending upon the moisture content, the maximum temperature (with respect to time) and body size of the package, there is a risk that internal or external package cracks may occur due to vaporization of the moisture in them (the so called popcorn effect). for details, refer to the drypack information in the data handbook ic26; integrated circuit packages; section: packing methods . [2] these packages are not suitable for wave soldering as a solder joint between the printed-circuit board and heatsink (at bottom version) can not be achieved, and as solder may stick to the heatsink (on top version). [3] if wave soldering is considered, then the package must be placed at a 45 angle to the solder wave direction. the package footprint must incorporate solder thieves downstream and at the side corners. [4] wave soldering is only suitable for lqfp, qfp and tqfp packages with a pitch (e) equal to or larger than 0.8 mm; it is de?nitely not suitable for packages with a pitch (e) equal to or smaller than 0.65 mm. [5] wave soldering is only suitable for ssop and tssop packages with a pitch (e) equal to or larger than 0.65 mm; it is de?nitely not suitable for packages with a pitch (e) equal to or smaller than 0.5 mm. table 88: suitability of surface mount ic packages for wave and re?ow soldering methods package soldering method wave re?ow [1] bga, lfbga, sqfp, tfbga not suitable suitable hbcc, hlqfp, hsqfp, hsop, htqfp, htssop, sms not suitable [2] suitable plcc [3] , so, soj suitable suitable lqfp, qfp, tqfp not recommended [3] [4] suitable ssop, tssop, vso not recommended [5] suitable
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 70 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. 17. revision history table 89: revision history rev date cpcn description 02 20001023 objective speci?cation; second version. supersedes isp1581-01 of 4 october 2000 (9397 750 07487). package replaced by sot314-2. 01 20001004 objective speci?cation; initial version. not published.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 71 of 73 9397 750 07648 ? philips electronics n.v. 2000 all rights reserved. 18. data sheet status [1] please consult the most recently issued data sheet before initiating or completing a design. 19. de?nitions short-form speci?cation the data in a short-form speci?cation is extracted from a full data sheet with the same type number and title. for detailed information see the relevant data sheet or data handbook. limiting values de?nition limiting values given are in accordance with the absolute maximum rating system (iec 60134). stress above one or more of the limiting values may cause permanent damage to the device. these are stress ratings only and operation of the device at these or at any other conditions above those given in the characteristics sections of the speci?cation is not implied. exposure to limiting values for extended periods may affect device reliability. application information applications that are described herein for any of these products are for illustrative purposes only. philips semiconductors make no representation or warranty that such applications will be suitable for the speci?ed use without further testing or modi?cation. 20. disclaimers life support these products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. philips semiconductors customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify philips semiconductors for any damages resulting from such application. right to make changes philips semiconductors reserves the right to make changes, without notice, in the products, including circuits, standard cells, and/or software, described or contained herein in order to improve design and/or performance. philips semiconductors assumes no responsibility or liability for the use of any of these products, conveys no licence or title under any patent, copyright, or mask work right to these products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless otherwise speci?ed. 21. trademarks acpi is an open industry speci?cation for pc power management, co-developed by intel corp., microsoft corp. and toshiba jaz is a registered trademark of iomega corp. onnow is a trademark of microsoft corp. softconnect is a trademark of royal philips electronics zip is a registered trademark of iomega corp. datasheet status product status de?nition [1] objective speci?cation development this data sheet contains the design target or goal speci?cations for product development. spec i?cation may change in any manner without notice. preliminary speci?cation quali?cation this data sheet contains preliminary data, and supplementary data will be published at a la ter date. philips semiconductors reserves the right to make changes at any time without notice in order to improve design and supply the best possible product. product speci?cation production this data sheet contains ?nal speci?cations. philips semiconductors reserves the right to make ch anges at any time without notice in order to improve design and supply the best possible product.
philips semiconductors isp1581 usb 2.0 hs interface device objective speci?cation rev. 02 23 october 2000 72 of 73 9397 750 07648 ? philips electronics n.v. 2000. all rights reserved. philips semiconductors - a worldwide company argentina: see south america australia: tel. +61 2 9704 8141, fax. +61 2 9704 8139 austria: tel. +43 160 101, fax. +43 160 101 1210 belarus: tel. +375 17 220 0733, fax. +375 17 220 0773 belgium: see the netherlands brazil: see south america bulgaria: tel. +359 268 9211, fax. +359 268 9102 canada: tel. +1 800 234 7381 china/hong kong: tel. +852 2 319 7888, fax. +852 2 319 7700 colombia: see south america czech republic: see austria denmark: tel. +45 3 288 2636, fax. +45 3 157 0044 finland: tel. +358 961 5800, fax. +358 96 158 0920 france: tel. +33 14 099 6161, fax. +33 14 099 6427 germany: tel. +49 40 23 5360, fax. +49 402 353 6300 hungary: see austria india: tel. +91 22 493 8541, fax. +91 22 493 8722 indonesia: see singapore ireland: tel. +353 17 64 0000, fax. +353 17 64 0200 israel: tel. +972 36 45 0444, fax. +972 36 49 1007 italy: tel. +39 039 203 6838, fax +39 039 203 6800 japan: tel. +81 33 740 5130, fax. +81 3 3740 5057 korea: tel. +82 27 09 1412, fax. +82 27 09 1415 malaysia: tel. +60 37 50 5214, fax. +60 37 57 4880 mexico: tel. +9-5 800 234 7381 middle east: see italy netherlands: tel. +31 40 278 2785, fax. +31 40 278 8399 new zealand: tel. +64 98 49 4160, fax. +64 98 49 7811 norway: tel. +47 22 74 8000, fax. +47 22 74 8341 philippines: tel. +63 28 16 6380, fax. +63 28 17 3474 poland: tel. +48 22 5710 000, fax. +48 22 5710 001 portugal: see spain romania: see italy russia: tel. +7 095 755 6918, fax. +7 095 755 6919 singapore: tel. +65 350 2538, fax. +65 251 6500 slovakia: see austria slovenia: see italy south africa: tel. +27 11 471 5401, fax. +27 11 471 5398 south america: tel. +55 11 821 2333, fax. +55 11 829 1849 spain: tel. +34 33 01 6312, fax. +34 33 01 4107 sweden: tel. +46 86 32 2000, fax. +46 86 32 2745 switzerland: tel. +41 14 88 2686, fax. +41 14 81 7730 taiwan: tel. +886 22 134 2451, fax. +886 22 134 2874 thailand: tel. +66 23 61 7910, fax. +66 23 98 3447 turkey: tel. +90 216 522 1500, fax. +90 216 522 1813 ukraine: tel. +380 44 264 2776, fax. +380 44 268 0461 united kingdom: tel. +44 208 730 5000, fax. +44 208 754 8421 united states: tel. +1 800 234 7381 uruguay: see south america vietnam: see singapore yugoslavia: tel. +381 11 3341 299, fax. +381 11 3342 553 for all other countries apply to: philips semiconductors, marketing communications, building be, p.o. box 218, 5600 md eindhoven, the netherlands, fax. +31 40 272 4825 internet: http://www.semiconductors.philips.com (sca70)
? philips electronics n.v. 2000. printed in the netherlands all rights are reserved. reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. the information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. no liability will be accepted by the publisher for any consequence of its use. publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights. date of release: 23 october 2000 document order number: 9397 750 07648 contents philips semiconductors isp1581 usb 2.0 hs interface device 1 general description . . . . . . . . . . . . . . . . . . . . . . 1 2 features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 3 applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 4 ordering information . . . . . . . . . . . . . . . . . . . . . 2 5 block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 3 6 pinning information . . . . . . . . . . . . . . . . . . . . . . 4 6.1 pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 6.2 pin description . . . . . . . . . . . . . . . . . . . . . . . . . 5 7 functional description . . . . . . . . . . . . . . . . . . . 7 7.1 usb 2.0 transceiver . . . . . . . . . . . . . . . . . . . . . 8 7.2 philips serial interface engine (sie). . . . . . . . . 9 7.3 voltage regulators. . . . . . . . . . . . . . . . . . . . . . . 9 7.4 memory management unit (mmu) and integrated ram . . . . . . . . . . . . . . . . . . . . . . . . 9 7.5 softconnect . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 7.6 bit clock recovery . . . . . . . . . . . . . . . . . . . . . . . 9 7.7 multiplying pll oscillator . . . . . . . . . . . . . . . . . 9 7.8 microcontroller interface and microcontroller handler . . . . . . . . . . . . . . . . . 10 7.9 dma interface and dma handler . . . . . . . . . . 10 7.10 system controller . . . . . . . . . . . . . . . . . . . . . . 10 8 modes of operation . . . . . . . . . . . . . . . . . . . . . 11 9 register descriptions . . . . . . . . . . . . . . . . . . . 11 9.1 register access . . . . . . . . . . . . . . . . . . . . . . . 13 9.2 initialization registers . . . . . . . . . . . . . . . . . . . 13 9.2.1 address register (address: 00h). . . . . . . . . . . 13 9.2.2 mode register (address: 0ch) . . . . . . . . . . . . 14 9.2.3 interrupt configuration register (address: 10h) 15 9.2.4 interrupt enable register (address: 14h) . . . . 16 9.2.5 dma configuration register (address: 38h) . . 17 9.2.6 dma hardware register (address: 3ch). . . . . 17 9.3 data flow registers . . . . . . . . . . . . . . . . . . . . . 18 9.3.1 endpoint index register (address: 2ch) . . . . . 18 9.3.2 control function register (address: 28h) . . . . 19 9.3.3 data port register (address: 20h). . . . . . . . . . 19 9.3.4 buffer length register (address: 1ch) . . . . . . 20 9.3.5 endpoint maxpacketsize register (address: 04h) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 9.3.6 endpoint type register (address: 08c). . . . . . 22 9.3.7 short packet register (address: 24h) . . . . . . . 22 9.4 dma registers . . . . . . . . . . . . . . . . . . . . . . . . . 24 9.4.1 dma command register (address: 30h) . . . . 26 9.4.2 dma transfer counter register (address: 34h) 27 9.4.3 dma configuration register (address: 38h) . . 28 9.4.4 dma hardware register (address: 3ch). . . . . 30 9.4.5 dma strobe timing register (address: 60h). . 31 9.4.6 task file registers (addresses: 40h to 4fh) . 32 9.4.7 dma interrupt reason register (address: 50h) 35 9.4.8 dma interrupt enable register (address: 54h) 36 9.4.9 dma endpoint register (address: 58h) . . . . . . 36 9.5 general registers . . . . . . . . . . . . . . . . . . . . . . 37 9.5.1 interrupt register (address: 18h). . . . . . . . . . . 37 9.5.2 chip id register (address: 70h) . . . . . . . . . . . 38 9.5.3 frame number register (address: 74h) . . . . . 39 9.5.4 scratch register (address: 78h) . . . . . . . . . . . 40 9.5.5 unlock device register (address: 7ch). . . . . . 40 9.5.6 test mode register (address: 84h) . . . . . . . . . 41 10 limiting values . . . . . . . . . . . . . . . . . . . . . . . . . 42 11 static characteristics . . . . . . . . . . . . . . . . . . . . 42 12 dynamic characteristics . . . . . . . . . . . . . . . . . 44 12.1 high-speed signals . . . . . . . . . . . . . . . . . . . . . 46 12.1.1 template 1 (transmit waveform; device without captive cable) . . . . . . . . . . . . . . . . . . 47 12.1.2 template 2 (transmit waveform; device with captive cable) . . . . . . . . . . . . . . . . . . . . 48 12.1.3 template 3 (receive waveform; receiver sensitivity with captive cable). . . . . . . . . . . . . 49 12.1.4 template 4 (receive waveform; receiver sensitivity without captive cable) . . . . . . . . . . 50 12.2 timing symbols . . . . . . . . . . . . . . . . . . . . . . . . 51 12.3 parallel i/o timing . . . . . . . . . . . . . . . . . . . . . . 52 12.3.1 generic processor mode (bus_conf = 1) . . 52 12.3.2 split bus mode (bus_conf = 0). . . . . . . . . . 53 12.4 dma timing . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 12.4.1 pio mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 12.4.2 gdma slave mode . . . . . . . . . . . . . . . . . . . . . 56 12.4.3 mdma mode . . . . . . . . . . . . . . . . . . . . . . . . . . 59 12.4.4 udma mode . . . . . . . . . . . . . . . . . . . . . . . . . . 60 13 application information . . . . . . . . . . . . . . . . . . 65 14 test information . . . . . . . . . . . . . . . . . . . . . . . . 66 15 package outline . . . . . . . . . . . . . . . . . . . . . . . . 67 16 soldering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 16.1 introduction to soldering surface mount packages . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 16.2 reflow soldering . . . . . . . . . . . . . . . . . . . . . . . 68 16.3 wave soldering . . . . . . . . . . . . . . . . . . . . . . . . 68 16.4 manual soldering. . . . . . . . . . . . . . . . . . . . . . . 69 16.5 package related soldering information . . . . . . 69 17 revision history . . . . . . . . . . . . . . . . . . . . . . . . 70 18 data sheet status . . . . . . . . . . . . . . . . . . . . . . . 71 19 definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71 20 disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71 21 trademarks . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71

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