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F71869A super i/o + hardware monitor release date:october, 2011 version: v0.19p
oct., 2011 v0.19p 2 F71869A F71869A datasheet revision history version date page revision history 0.10p 2010/04 preliminary version 0.11p 2010/05 45, 46 47-136 1. update cir/cpt function description 2. update register 0.12p 2010/06 19 47, 48 65, 66 142-144 10-20 70 90, 91 60, 61 10 140 13, 21 56 74 129, 130 132 133 148 1. modify pin54 description 2. add scan code and ovt function description 3. update rs485 enable register description ? index f0h 4. dc characteristics 5. update pin description 6. update ovt register ? index 02h 7. update fan3 control register ? index 9ah 8. add multi-function select register 5 ? index 2ch 9. correct pin type 10. add intel dsw delay select register ? index fch 11. update strap_protect description 12. update configuration port select register ? index 27h 13. add voltage protection power good select register ? index 3fh 14. add cir registers (cr08) 15. update erp psout deb-register ? index e5h; erp s5 delay register ? index e7h 16. update erp wdt timer ? index eeh 17. update application circuit ? s5# (s4#) , sus_ack# (3va) 0.13p 2010/07 147 1. update application circuit ? correct vin5 pin name 0.14p 2010/08 50 13, 21 8, 12, 47 52 56 58~62 59 60 61, 62 122~126 135 1. update global control registers 2. modify description for strap_protect 3. update gpio for scan code function 4. update gpio device configuration registers (ldn cr06) 5. update uart irq sharing register ? index 26h bit 3 6. update multi-function select register 1 ~ 5 ? index 28h ~ 2ch 7. add wdt clock divisor high byte ? index 29h 8. add wdt clock divisor low byte ? index 2ah 9. add wdt clock fine tune count ? index 2bh, 2ch 10. update gpio 35 ~ 37 scan code function registers 11. update erp wdt control register ? index edh 0.15p 2010/08 update for lab version 0.16p 2010/09 12-13 12-21 131 77 140 19 121 112 139-140 150 1. correct fdc/gpio pwr type 2. correct pwr type vcc to 3vcc 3. add wdt enable register 30h and base address high/low register 60h and 61h 4. add 2d ? 2fh in voltage reading and limit register 5. remove pcirstin_n in vddok delay register ? index f5h bit 2 6. correct rstcon# pin description 7. update gpio4 drive enable register -index b3h bit 5~7 8. add auto swap register - index feh (powered by vbat) bit 3 9. correct vddok delay register - index f5h pwrok unit 10. update reference circuit ? add c58 0.17p 2011/03 64 77 60 127 1. made clarification & modification 2. update wakeup control register - index 2dh bit5 description 3. add voltage reading and limit - index 30h, 31h 4. modify multi-function select register 3 ? index 2ah bit 1:0 5. modify gpio5 kbc emulation control register 2 ? index afh bit7
oct., 2011 v0.19p 3 F71869A 63 18, 19 112 description 6. correct multi-function select re gister 5 ( index 2ch bit3:1 default velue 7. modify scl & sda types and de scription (pin 57/58/59/60) 8. modify auto swap register ( index feh, bit 7 0.18p 2011/06 150, 154 17, 18 148 58 149 1. made clarification & modification 2. update application circuits 3. update fanctl1~3 pin description 4. add top marking specification 5. update multi-function select register 1 ? index 28h bit7 description 6. update package dimension 0.19p 2011/10 - 1.made clarification & modification 2.gpio pin status register ? index f2h, bit 5 & 4 3.update index no.(gpio7 output data register ? index 81h) 4.update index no.(gpio7 pin status register ? index 82h) 5.update index no.(gpio7 drive enable register ? index 83h) 6.update index no.(user wakeup code register ? index ffh) 7.smb protocol select ? index efh, bit3-0 8.update top marking specification description please note that all data and specifications are subjec t to change without notice. all the trade marks of products and companies mentioned in this data sheet belong to their respective owners. life support applicat 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. customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify fintek for any damages resulting from such improper use or sales.
oct., 2011 v0.19p 4 F71869A table of content 1. general descrip tion......................................................................................................... ......6 2. featur e li st ................................................................................................................ ...........7 3. pin conf iguration........................................................................................................... ......10 4. pin de scription ............................................................................................................. ....... 11 4.1 power pins ................................................................................................................1 2 4.2 lpc inte rface ............................................................................................................12 4.3 fdc ........................................................................................................................ ...12 4.4 uart and sir...........................................................................................................14 4.5 parall el port.............................................................................................................. .16 4.6 hardware monitor ......................................................................................................17 4.7 acpi func tion pins ...................................................................................................18 4.8 power saving and others ..........................................................................................20 4.9 kbc func tion ............................................................................................................21 5. function descrip tion........................................................................................................ ....22 5.1 power on strappi ng option........................................................................................22 5.2 hardware monitor ......................................................................................................22 5.3 acpi f unction ...........................................................................................................36 5.4 power timing cont rol sequenc e ...............................................................................38 5.5 s3_gate#, s3p5_gate# and s0p5_gate# timing....................................................39 5.6 amd tsi and intel pec i 3.0 func tions ..................................................................... 41 5.7 erp power savi ng functi on.......................................................................................42 5.8 cir f unction .............................................................................................................46 5.9 intel cougar poin t timing (c pt)................................................................................47 5.10 scan code f unction ..................................................................................................48 5.11 over voltage protecti on.............................................................................................48 6. register descrip tion ........................................................................................................ ....49 6.1 global control register s ...........................................................................................54 6.2 fdc register s (cr00) ..............................................................................................64 6.3 uart1 regist ers (cr 01) ..........................................................................................67 6.4 uart2 regist ers (cr 02) ..........................................................................................68 6.5 parallel port r egister ( cr03) .................................................................................... 69 6.6 hardware monitor registers ( cr04) ......................................................................... 70 6.7 kbc register s (cr05) ............................................................................................ 110 6.8 gpio register s (cr06) ........................................................................................... 111 6.9 watch dog timer r egisters ( cr07) ........................................................................ 130
oct., 2011 v0.19p 5 F71869A 6.10 cir register s (cr08) ..............................................................................................132 6.11 pme, acpi, and erp power saving register s (cr0a) ..........................................133 7. electrical c haracteri stics .................................................................................................. .144 7.1 absolute maxi mum rati ngs..................................................................................... 144 7.2 dc characte ristics ..................................................................................................144 8. ordering informa tion ........................................................................................................ .147 9. top marking s pecification..................................................................................................1 47 10.package dimensions (128-lqfp ) ...................................................................................148 11.applicati on circu it ......................................................................................................... ...149
oct., 2011 v0.19p 6 F71869A 1. general description the F71869A which is the featured io chip for pc system is equipped with one ieee 1284 parallel port, two uart ports, one 80 port (multi with com2), hardware keyboard controller, sir, cir with rc6 and smk qp protocols and one fdc. the F71869A integrates with hardware monitor, 9 sets of voltage sensor, 3 sets of creative auto-controlling fans and 3 temperature sensor pins for the accurate dual current type temperature measurement for cpu thermal diode or external transistors 2n3906. others, the F71869A supports newest amd tsi and intel peci 3.0 interfaces and intel ibex peak smbus for temperature sensing and provides the power sequence controller function for amd platform. the F71869A provides flexible features for multi-directional application. for instance, the F71869A provides 58 gpio pins (multi-pin), ir q sharing function also designed in uart feature for particular usage and accurate current mode h/w monitor will be worth in measurement of temperature, provides 3 m odes fan speed control mechanism included manual mode/stage auto mode/linear auto mode for users? selection. a power saving function which is in order to save the current consumption when the system is in the soft off state is also integrated a power saving function. the power saving function supports that system boot-on not only by pressing the power bu tton but also by the wake-up event. when the system enters the s4/s5 state, F71869A can cu t off the vsb power rail which supplies power source to the devices like the lan chip, the chipset, the sio, the audio codec, dram, and etc. the pc system can be simulated to g3-like state when system enters the s4/s5 states. at the g3-like state, the F71869A consumes the 5vsb power rail only. the integrated two control pins are utilized to turn on or off vsb power rail in the g3-like status. the turned on vsb rail is supplied to a wake up device to fulfill a low power consumption system which supports a wake up function. these features as above description will help you more and improve product value. finally, the F71869A is powered by 3.3v voltage, with the lpc interface in the green package of 128-lqfp (14*14).
oct., 2011 v0.19p 7 F71869A 2. feature list ? general functions ? comply with lpc spec. 1.0 ? support dpm (device power management), acpi ? support amd power sequence controller ? provides one fdc, two uarts, hardware kbc and parallel port ? h/w monitor functions ? support amd tsi interface, intel peci 3.0 interface, intel block read/write smbus interface ? support cir with rc6 and smk qp protocols ? support intel cougar point timing ? 58 gpio pins for flexible application ? 24/48 mhz clock input ? packaged in 128-lqfp and powered by 3.3vcc ? fdc ? compatible with ibm pc at disk drive systems ? variable write pre-compensation with track selectable capability ? support vertical recording format ? dma enable logic ? 16-byte data fifos ? support floppy disk drives and tape drives ? detects all overrun and under run conditions ? built-in address mark detection circuit to simplify the read electronics ? completely compatible with industry standard 82077 ? 360k/720k/1.2m/1.44m/2.88m format; 250k, 300k, 500k, 1m, 2m bps data transfer rate ? uart ? two high-speed 16c550 compatible uart with 16-byte fifos ? fully programmable serial-interface characteristics ? baud rate up to 115.2k ? support irq sharing ? support ring-in wakeup ? infrared ? support irda version 1.0 sir protocol with maximum baud rate up to 115.2k bps
oct., 2011 v0.19p 8 F71869A ? parallel port ? one ps/2 compatible bi-directional parallel port ? support enhanced parallel port (epp) ? compatible with ieee 1284 specification ? support extended capabilities port (ecp) ? compatible with ieee 1284 specification ? enhanced printer port back-drive current protection ? keyboard controller ? lpc interface support serial interrupt channel 1, 12. ? two 16bit programmable address fully decoder, default 0x60 and 0x64. ? support two ps/2 interface, one for ps/2 mouse and the other for keyboard. ? keyboard?s scan code support set1, set2. ? programmable compatibility with the 8042. ? support both interrupt and polling modes. ? fast gate a20 and hardware keyboard reset. ? hardware monitor functions ? 3 dual current type ( 3 ) thermal inputs for cpu thermal diode and 2n3906 transistors ? temperature range -40 ~127 ? 9 sets voltage monitoring (6 external and 3 internal powers) ? voltage monitor supports over voltage protection (ovp) ? high limit signal (pme#) for vcore level ? 3 fan speed monitoring inputs ? 3 fan speed pwm/dc control outputs(support 3 wire and 4 wire fans) ? the fan pwm output frequency can be programmed to 23.5k or 220hz for lcd backlight adjustment ? stage auto mode ( 2-limit and 3-stage)/linear auto mode/manual mode ? issue pme# and ovt# hardware signals output ? case intrusion detection circuit ? watchdog comparison of all monitored values ? power saving controller ? acpi timing and power control ? wake-up supported ? integrate amd tsi interface ? integrate intel peci 3.0 spec.
oct., 2011 v0.19p 9 F71869A ? integrate intel cougar point timing ? support amd power sequence controller ? intel block read/write smbus interface ? system volume control ? gpio 35~37, gpio 50~54 can control the system volume up/down/mute by lpc interface. ? windows osd can detect the system volume control input without any driver installation. ? 80-port interface ? monitor 0x80 port and output the value via signals defined for 7-segment display. ? high nibble and low nibble are outputted interleaved at 1khz frequency. ? 80-port output by lpt or com2 interface. ? package ? 128-pin lqfp (14*14) green package
oct., 2011 v0.19p 10 F71869A 3. pin configuration figure1. F71869A pin configuration (14 *14)
oct., 2011 v0.19p 11 F71869A 4. pin description i/o 12st,5v i/o 16t,u47k - ttl level bi-directional pin with schmitt trigger, output with 12 ma sink capability, 5v tolerance. - ttl level bi-directional pin with 16 ma source-sink cap ability. with internal 47k pull-up. i/od 12st,5v i/od 14st,5v i/od 16st,5v i lv /od 12st,5v - ttl level bi-directional pin with schmitt trigger, open-drain output with 12 ma sink capability, 5v tolerance. - ttl level bi-directional pin and schmitt trigger, open-drain output with 14 ma sink capability, 5v tolerance. - ttl level bi-directional pin with schmitt trigger, open-drain output with 16 ma sink capability, 5v tolerance. - low level bi-directional pin with schmitt trigger, open-drain output with 12 ma sink capability, 5v tolerance. i/ood 12t i/ood 12t,5v i/ood 8st,5v i/ood 12st,5v i/ood 24st,5v - ttl level bi-directional pin, can be sele cted to od or out by register, with 12 ma source-sink capability. - ttl level bi-directional pin, can select to od or out by register, with 12 ma source-sink capability, 5v tolerance. - ttl level bi-directional pin and schmitt trigger, open-drain output with 8 ma sink capability, 5v tolerance. - ttl level bi-directional pin and schmitt trigger, open-drain output with 12 ma sink capability, 5v tolerance. - ttl level bi-directional pin with schmitt trigger, can be selected to od or out by register, with 24 ma sink capability, 5v tolerance. i lv /o d8,s1 - low level bi-directional pin (vih ? 0.9v, vil ? 0.6v.). output with 8ma drive and 1ma sink capability. ood 12,5v ood 16,5v - od or out selected by register with 12 ma sink capability, 5v tolerance. - od or out selected by register with 16 ma sink capability, 5v tolerance. o 12 o 16 o 18 o 20 o 30 o 12,5v o 8t5v,u47k - output pin with 12 ma source-sink capability. - output pin with 16 ma source-sink capability. - output pin with 18 ma source-sink capability. - output pin with 20 ma source-sink capability. - output pin with 30 ma source-sink capability. - output pin with 12 ma source-s ink capability, 5v tolerance. - output pin with 8 ma source-sink cap ability, pull-up 47k ohms, 5v tolerance. od 12 od 14,5v od 12,5v od 24,5v od 12,5v,u10k od 16,5v,u10k - open-drain output pin with 12 ma sink capability. - open-drain output pin with 14 ma sink capability, 5v tolerance. - open-drain output pin with 12 ma sink capability, 5v tolerance. - open-drain output pin with 24 ma sink capability, 5v tolerance. - open-drain output pin with 12 ma sink capability, pull-up 10k ohms, 5v tolerance. - open-drain output pin with 16 ma sink capability, pull-up 10k ohms, 5v tolerance. in t5v in st,u47k in st in st,lv in st,5v - ttl level input pin,5v tolerance. - ttl level input pin and schmitt trigger. with internal pull-up 47k resistor. - ttl level input pin and schmitt trigger - ttl low level input pin (vih ? 0.9v, vil ? 0.6v.) - ttl level input pin and schmitt trigger, 5v tolerance. ain aout - input pin(analog). - output pin(analog). p - power.
oct., 2011 v0.19p 12 F71869A 4.1 power pins pin no. pin name type description 4,37 3vcc p power supply voltage input with 3.3v (support ovp) 45 5vsb(5va) p 5v stand by power input. nomally the 5v stand by power source is from atx power directly. 68 i_vsb3v p 3.3v internal standby power regulates from 5vsb, couple this pin with capacitor (0.1u) to ground for inter capacitance compensation. besides, this pin can be an output pin to provide little current for battery application when system enter s erp (g3? like) state. (detail pleaser refer application circuit) 86 vbat p battery voltage input 88 agnd(d-) p analog gnd 99 3vsb p analog stand-by power supply voltage input 3.3v 20, 48, 73, 117 gnd p digital gnd 4.2 lpc interface pin no. pin name type pwr description 29 lreset# in st,5v 3vcc reset signal. it can connect to pcirst# signal on the host. 30 ldrq# o 16 3vcc encoded dma request signal. 31 serirq i/o 16t-u47k 3vcc serial irq input/output. 32 lfram# in st-u47k 3vcc indicates start of a new cycle or termination of a broken cycle. 33-36 lad[0:3] i/o 16t-u47k 3vcc these signal lines communicat e address, control, and data information over the lpc bus between a host and a peripheral. 38 pciclk in st 3vcc 33mhz pci clock input. 39 clkin in st 3vcc system clock input. according to the input frequency 24/48mhz. 4.3 fdc pin no. pin name type pwr description gpio30 i/od 14st,5v default general purpose io. 7 densel# od 14,5v 3vcc drive density select. set to 1 - high data rate.(500kbps, 1mbps) set to 0 ? low data rate. (250kbps, 300kbps) fdc function is selected by register setting. gpio31 i/od 14st,5v default general purpose io. 8 moa# od 14,5v 3vcc motor a on. when set to 0, this pin enables disk drive 0. this is an open drain output. fdc function is selected by register setting. gpio32 i/od 14st,5v default general purpose io. 9 drva# od 14,5v 3vcc drive select a. when set to 0, this pin enables disk drive a.
oct., 2011 v0.19p 13 F71869A this is an open drain output. fdc function is selected by register setting. gpio33 i/od 14st,5v default general purpose io. 10 wdata# od 14,5v 3vcc write data. this logic low open drain writes pre-compensation serial data to the selected fdd. an open drain output. fdc function is selected by register setting. gpio34 i/od 14st,5v default general purpose io. 11 dir# od 14,5v 3vcc direction of the head step motor. an open drain output. logic 1 = outward motion logic 0 = inward motion fdc function is selected by register setting. gpio35 i/od 14st,5v default general purpose io. (suppot scan / make code setting). 12 step# od 14,5v 3vcc step output pulses. this active low open drain output produce s a pulse to move the head to another track. fdc function is selected by register setting. gpio36 i/od 14st,5v default general purpose io. (suppot scan code setting). 13 hdsel# od 14,5v 3vcc head select. this open drain output determines which disk drive head is active. logic 1 = side 0 logic 0 = side 1 fdc function is selected by register setting. gpio37 i/od 14st,5v default general purpose io. (suppot scan code setting). 14 wgate# od 14,5v 3vcc write enable. an open drain output. fdc function is selected by register setting. gpio50 i/ood 12st,5v default general purpose io. support volume up control from lpc (suppot scan code setting). 15 rdata# in st,5v 3vcc the read data input signal from the fdd. fdc function is selected by register setting. gpio51 i/ood 12st,5v default general purpose io. support volume down contro l from lpc (suppot scan code setting). 16 trk0# in st,5v 3vcc track 0. this schmitt-triggered input from the disk drive is active low when the head is positioned over the outermost track. fdc function is selected by register setting. gpio52 i/ood 12st,5v default general purpose io. support mute control from lp c (suppot scan code setting). 17 index# in st,5v 3vcc this schmitt-triggered input from the disk drive is active low when the head is positioned over the beginning of a track marked by an index hole. fdc function is selected by register setting. gpio53 i/ood 12st,5v default general purpose io. support pwm up for fanctl3 (suppot scan code setting). 18 wpt# in st,5v 3vcc write protected. this active lo w schmitt input from the disk drive indicates that the disk ette is write-protected. fdc function is selected by register setting. 19 gpio54 i/ood 12st,5v 3vcc default general purpose io. support pwm down for
oct., 2011 v0.19p 14 F71869A fanctl3 (suppot scan code setting). dskchg# in st,5v diskette change. this signal is active low at power on and whenever the diskette is removed. fdc function is selected by register setting. 4.4 uart and sir pin no. pin name type pwr description gpio42 i/ood 12t,5v default general purpose io. 27 irtx o 12 3vcc infrared transmitter output. t he function is selected by register setting. gpio43 i/ood 12t,5v default general purpose io. 28 irrx in st,5v 3vcc infrared receiver input. the function is selected by register setting. 118 dcd1# in st,5v 3vcc data carrier detect. an active low signal indicates th e modem or data set has detected a data carrier. 119 ri1# in st,5v i_vsb3v ring indicator. an active low signal indicates that a ring signal is being received from the modem or data set. 120 cts1# in st,5v 3vcc clear to send is the modem control input. dtr1# o 8t5v,u47k uart 1 data terminal ready. an active low signal inform s the modem or data set that controller is ready t o communicate. internal 47k ohms pulled high and disabl e after power on strapping. 121 fan40_100 in t,5v 3vcc power on strapping pin: 1(default): (internal pull high) power on fan speed default duty is 40%.(pwm) 0: (external pull down) power on fan speed default duty is 100%.(pwm) rts1# o 8t5v-u47k uart 1 request to send. an active low signal informs th e modem or data set that the controller is ready to send data. 122 strap_prot ect in t,5v 3vcc power on strapping pin for over voltage protection function. 1: default is alarm mode (disabled). voltage protection function is enabled via setting the related register. 0: force mode which is always enabled after power on. 123 dsr1# in st,5v 3vcc data set ready. an active low signal indicates the mode m or data set is ready to establish a communication link an d transfer data to the uart. sout1 o 8t5v,u47k uart 1 serial output. used to transmit serial data out t o the communication link. internal 47k ohms pulled high an d disable after power on strapping. 124 strap4e_2e in t,5v 3vcc power on strapping: 1(default): configuration register 4e 0: configuration register 2e 125 sin1 in st,5v 3vcc serial input. used to receive serial data through th e communication link. 126 dcd2# in st,5v 3vcc data carrier detect. an acti ve low signal indicates the modem or data set has detected a data carrier.
oct., 2011 v0.19p 15 F71869A the function is selected by register setting. segg o 18 segg for 7-segment display. (select by pin 5 power o n strapping) gpio20 i/ood 8st,5v default general purpose io. ri2# in st,5v ring indicator. an active low signal indicates that a ring signal is being received from the modem or data set. the function is selected by register setting. segf o 18 segf for 7-segment display. (select by pin 5 power o n strapping) 127 gpio21 i/ood 8st,5v i_vsb3v default general purpose io. cts2# in st,5v clear to send is the modem control input. the function is selected by register setting. sega o 18 sega for 7-segment display. (select by pin 5 power o n strapping) 128 gpio22 i/ood 8st,5v 3vcc default general purpose io. gpio23 i/ood 8st,5v default general purpose io. dtr2# o 8t5v,u47k u a rt 2 data terminal ready. an active low signal inform s the modem or data set that controller is ready t o communicate. the function is selected by register setting. 1 segd o 18 3vcc segd for 7-segment display. (select by pin 5 power o n strapping) gpio24 i/ood 8st,5v default general purpose io. rts2# o 8t5v,u47k uart 2 request to send. an active low signal informs th e modem or data set that the controller is ready to send data. the function is selected by register setting. 2 segc o 18 3vcc segc for 7-segment display. (select by pin 5 power o n strapping) gpio25 i/ood 8st,5v default general purpose io. dsr2# in st,5v data set ready. an active low signal indicates the mode m or data set is ready to establish a communication link an d transfer data to the uart. the function is selected b y register setting. 3 l# o 30 3vcc l# for 7-segment display. (select by pin 5 power o n strapping) gpio26 i/ood 8st,5v default general purpose io. sout2 o 8t,5v,u47k uart 2 serial output. used to transmit serial data out t o the communication link. the function is selected by registe r setting. segb o 18 segb for 7-segment display. (select by pin 5 power o n strapping) 5 strap_dport in t,5v 3vcc strap for 80 port. default internal pull high for 80 por t enable. gpio27 i/ood 8st,5v default general purpose io. 6 sin2 in st,5v 3vcc serial input. used to receive serial data through th e communication link. the function is selected by registe r
oct., 2011 v0.19p 16 F71869A setting. sege o 18 sege for 7-segment display. (select by pin 5 power o n strapping) 4.5 parallel port pin no. pin name type pwr description slct in st,5v an active high input on this pin indicates that the printer is selected. refer to the description of the parallel port for definition of this pin in ecp and epp mode. 100 gpio60 i/ood 12t,5v 3vcc default general purpose io. pe in st,5v an active high input on this pin indicates that the printer has detected the end of the paper. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 101 gpio61 i/ood 12t,5v 3vcc default general purpose io. busy in st,5v an active high input indicates that the printer is not ready to receive data. refer to the description of the parallel port for definition of this pin in ecp and epp mode. 102 gpio62 i/ood 12t,5v 3vcc default general purpose io. ack# in st,5v an active low input on this pin indicates that the printer has received data and is ready to accept more data. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 103 gpio63 i/ood 12t,5v 3vcc default general purpose io. 104 slin# i/ood 12st,5v 3vcc output line for detection of printer selection. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. init# i/ood 12st,5v output line for the printer initialization. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 105 gpio64 i/ood 12t,5v 3vcc default general purpose io. err# in st,5v an active low input on this pin indicates that the printer has encountered an error condition. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 106 gpio65 i/ood 12t,5v 3vcc default general purpose io. afd# i/ood 12st,5v an active low output from this pin causes the printer to auto feed a line after a line is printed. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 107 gpio66 i/ood 12t,5v 3vcc default general purpose io. 108 stb# i/ood 12st,5v 3vcc an active low output is used to latch the parallel data into the printer. refer to the description of the parallel port for the
oct., 2011 v0.19p 17 F71869A definition of this pin in ecp and epp mode. gpio67 i/ood 12t,5v default general purpose io. pd0 i/o 12st,5v parallel port data bus bit 0. refer to the description of the parallel port for the definition of this pin in ecp and epp mode. 109 gpio70 i/ood 12t,5v 3vcc default general purpose io. pd1 i/o 12st,5v parallel port data bus bit 1. 110 gpio71 i/ood 12t,5v 3vcc default general purpose io. pd2 i/o 12st,5v parallel port data bus bit 2. 111 gpio72 i/ood 12t,5v 3vcc default general purpose io. pd3 i/o 12st,5v parallel port data bus bit 3. 112 gpio73 i/ood 12t,5v 3vcc default general purpose io. pd4 i/o 12st,5v parallel port data bus bit 4. 113 gpio74 i/ood 12t,5v 3vcc default general purpose io. pd5 i/o 12st,5v parallel port data bus bit 5. 114 gpio75 i/ood 12t,5v 3vcc default general purpose io. pd6 i/o 12st,5v parallel port data bus bit 6. 115 gpio76 i/ood 12t,5v 3vcc default general purpose io. pd7 i/o 12st,5v parallel port data bus bit 7. 116 gpio77 i/ood 12t,5v 3vcc default general purpose io. 4.6 hardware monitor pin no. pin name type pwr description 93 vin6 ain i_vsb3v voltage input 6. this pin support ovp function, and default is disable. 94 vin5 ain i_vsb3v voltage input 5. this pin support ovp function, and default is disable. 95 vin4 (vdimm) ain i_vsb3v voltage input 4 or vdimm input used in amd platform. the input voltage level for timing control usage must be over 1v after voltage divider. 96 vin3 (vdda) ain i_vsb3v voltage input 3 or vdda input used in amd platform. the input voltage level for timing control usage must be over 1v after voltage divider. 97 vin2 (vldt) ain i_vsb3v voltage input 2 or vldt input used in amd platform. the input voltage level for timing control usage must be over 1v after voltage divider. 98 vin1 (vcore) ain i_vsb3v voltage input for vcore. the input voltage level for timing control usage must be over 0.7v. 21 fanin1 in st,5v 3vcc fan 1 tachometer input. 22 fanctl1 ood 12,5v aout 3vcc fan 1 control output. it is also a trap pin to select a pwm or a dac output, except being an output pin. it defaults to be a voltage output by pulling down 100k internally. it is set as a pwm output as connected a 4.7k resistor and pulled high to 3.3v. 23 fanin2 in st,5v 3vcc fan 2 tachometer input.
oct., 2011 v0.19p 18 F71869A 24 fanctl2 ood 12,5v aout 3vcc fan 2 control output. it is also a trap pin to select a pwm or a dac output, except being an output pin. it defaults to be a voltage output by pulling down 100k internally. it is set as a pwm output as connected a 4.7k resistor and pulled high to 3.3v. gpio40 i/ood 12st,5v default general purpose io. 25 fanin3 in st,5v 3vcc fan 3 speed input. this function is selected by register setting. gpio41 i/ood 12st,5v default general purpose io. this pin default function is gpio function. please take care of the application if user wants to implement fanctl function. 26 fanctl3 ood 12,5v aout 3vcc fan 3 control output. it is also a trap pin to select a pwm or a dac output, except being an output pin. it defaults to be a voltage output by pulling down 100k internally. it is set as a pwm output as connected a 4.7k resistor and pulled high to 3.3v. the pwm output frequency can be programmed to 220hz for lcd backlight control. cir_led# od 12,5v led for cir to indicate receiver is receiving data. 57 scl i lv /od 12st,5v i_vsb3v smbus interface clock pin. clock output for amd tsi & intel pch (ibx peak). peci i lv /o d8,s1 intel peci hardware monitor interface. when timing_gpio pin is set in gpio function (intel mode). peci function can be set by the register. 58 sda i lv /od 12st,5v i_vsb3v smbus interface data pin. amd tsi & intel pch (ibx peak) data pin. wdtrst# od 12,5v watch dog timer signal output. 63 gpio14 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by register setting 67 ovt# od 12,5v i_vsb3v over temperature signal output. 79 pme# od 12,5v i_vsb3v generated pme event. it supports the pci pme# interface. this signal allows the peripheral to request the system to wake up from the s3 state. 89 d3+ ain i_vsb3v thermal diode/transistor temperature sensor input for system use. 90 d2+ ain i_vsb3v thermal diode/transistor temperature sensor input. 91 d1+(cpu) ain i_vsb3v cpu thermal diode/transistor temperature sensor input. this pin is for cpu use. 92 vref aout i_vsb3v voltage sensor output. 4.7 acpi function pins pin no. pin name type pwr description gpio10 i/ood 12st,5v default general purpose io. gpio function is selected by register setting 59 pci_rst4# o 12,5v i_vsb3v it is an output buffer of lreset#. this function is selected by register setting.
oct., 2011 v0.19p 19 F71869A scl i lv /od 12st,5v smbus interface clock pin. clock output for amd tsi & intel pch (ibx peak). gpio11 i/ood 12st,5v default general purpose io. pci_rst5# o 12,5v it is an output buffer of lreset#. this function is selected by register setting. 60 sda i lv /od 12st,5v i_vsb3v smbus interface data pin. amd tsi & intel pch (ibx peak) data pin. gpio12 i/ood 12st,5v default general purpose io. 61 rstcon# in st,5v i_vsb3v reset button input. this function is selected by register setting. gpio15 i/ood 12st,5v default general purpose io. led_vsb od 12,5v power led for vsb. this functi on is selected by register setting. 64 alert# od 12,5v i_vsb3v alert a signal when temperature over limit setting. this function is selected by register setting. gpio16 i/ood 12st,5v default general purpose io. 65 led_vcc od 12,5v i_vsb3v power led for vcc. this functi on is selected by register setting. cpu_pwgd od 12,5v cpu power good signal output (detected by vin1~vin4 level good) 66 gpio17 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by registe r setting 74 pcirst1# od 12,5v i_vsb3v it is an output buffer of lreset#. 75 pcirst2# o 12,5v i_vsb3v it is an output buffer of lreset#. 76 pcirst3# o 12,5v i_vsb3v it is an output buffer of lreset#. 77 s5# in st,5v i_vsb3v s5# signal input. atxpg_in in st,5v atx power good input. 78 gpio44 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by register setting. psin# in ts,5v main power switch button input. 80 gpio45 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by register setting. psout# od 12,5v panel switch output. this pin is low active and pulse output. it is power on request output#. 81 gpio46 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by register setting. 82 s3# in st,5v i_vsb3v s3# input is main power on-off switch input. ps_on# od 12,5v power supply on-off control output. connect to atx power supply ps_on# signal. 83 gpio47 i/ood 12st,5v i_vsb3v general purpose io. gpio function is selected by register setting. 84 pwok od 12,5v vbat pwok function, it is power good signal of vcc, which is delayed 400ms (default) as vcc arrives at 2.8v. 85 rsmrst# od 12,5v,u10k vbat resume reset# function, it is power good signal of vsb, which rises delayed 66ms as vsb arrives at 2.8v and falls
oct., 2011 v0.19p 20 F71869A as vsb drops to 2.6v. there is an option to set rsmrst# rises at 3.05v and falls at 2.95v. 87 copen# in st,5v vbat case open detection #. this pin is connected to a specially designed low power cmos flip-flop backed by the battery for case open state preservation during power loss. 4.8 power saving and others pin no. pin name type pwr description 42 event_in0# in ts,5v i_vsb3v wake-up event input. the signal input wakes the system up from the sleep state. 43 erp_ctrl0# od 12 i_vsb3v standby power rail control pin 0. this pin controls an external pmos to turn on or off the standby power rail. in the s5 state, the default is set to 1 to cut off the standby power rail. 44 erp_ctrl1# od 12 i_vsb3v standby power rail control pin 1. this pin controls an external pmos to turn on or off the standby power rail. in the s5 state, the default is set to 1 to cut off the standby power rail. dpwrok od 12,5v resume reset# function, it is power good signal of vsb, which is delayed 66ms as vsb arrives at 4.4v. couple this pin to pch when system supports intel dsw state function. 46 timing_3 od 12,5v i_vsb3v active high. timing sequence 3 of power on/off sequence pins. the external pull high resistor is required. (detected by vin3 level good) slp_sus# in st,lv for intel cpt dsw function. connect to pch slp_sus pin. 47 timing_4 od 12,5v i_vsb3v active high. timing sequence 4 of power on/off sequence pins. the external pull high resistor is required. (detected by vin1 level good) cirwb# in st,5v cir wide-band receiver input. (for learning use) 49 gpio01 i/ood 12t i_vsb3v general purpose io. gpio function is selected by register setting cirtx# o 20 cir transmitter to transmit data. 50 gpio02 i/ood 12t i_vsb3v general purpose io. gpio function is selected by register setting cirrx# in st.5v cir long-range receiver input 51 gpio03 i/ood 12t i_vsb3v general purpose io. gpio function is selected by register setting 52 strap_timing in st,5v i_vsb3v strap pin for amd and intel cougar point timing. internal pull high with amd timing (default). sus_ack# ood 16,5v this pin must wait sus_warn# signal for entering dsw power state. 53 timing_2 od 12,5v i_vsb3v active high. timing sequence 2 of power on/off sequence pins. the external pull high resistor is required. (detected by vin4 level good)
oct., 2011 v0.19p 21 F71869A sus_warn# in st,5v this pin asserts low when the pch is planning to enter the dsw power state. it can detect 5vdual level with delay setting supported. 54 timing_1 od 12,5v i_vsb3v active high. timing sequence 1 of power on/off sequence pins. the external pull high resistor is required. (output detected by vccok(vddok) level good, ref figure 15 ) s 3p5 _gate# od 12 status pin2 for s0#/s3#/s5# st ates application. (default function) in s0# ? s 3p5 _gate# pin status is tri-state. in s3# ( s 3p5 _gate # pin status is low level. in s5# ( s 3p5 _gate # pin status is tri-state, and can be programmed low level. slotocc# in st,5v cpu slotocc# input. 55 gpio04 od 12,5v i_vsb3v general purpose io. gpio function is selected by register setting s 3 _gate# od 12 status pin1 for s0#/s3#/s5# st ates application. (default function) in s0# ( s 3 _gate# pin status is tri-state. in s3# ( s 3 _gate# pin status is low level. in s5# ( s 3 _gate# pin status is tri-state. gpio05 i/ood 12st,5v general purpose io. gpio function is selected by register setting 56 wdtrst# od 12,5v i_vsb3v watch dog timer signal output. s 0p5 _gate# od 24,5v s 0p5 _gate# for s0#/s3#/s5# states application. in s0# (s 0p5 _gate# pin status is low-state. in s3# (s 0p5 _gate# pin status is tri-state. in s5# ? s 0p5 _gate# pin status is tri-state, and can be programmed low-state. gpio13 i/ood 24st,5v general purpose io. gpio function is selected by register setting 62 beep od 24,5v i_vsb3v beep pin. 4.9 kbc function pin no. pin name type pwr description 40 kbrst# od 16,5v,u10k 3vcc keyboard reset. this pin is high after system reset. internal pull high 3.3v with 10k ohms. (kbc p20) 41 ga20 od 16,5v,u10k 3vcc gate a20 output. this pin is high after system reset. internal pull high 3.3v with 10k ohms. (kbc p21) 69 kdata i/od 16st,5v i_vsb3v keyboard data. 70 kclk i/od 16st,5v i_vsb3v keyboard clock. 71 mdata i/od 16st,5v i_vsb3v ps2 mouse data. 72 mclk i/od 16st,5v i_vsb3v ps2 mouse clock.
oct., 2011 v0.19p 22 F71869A 5. function description 5.1 power on strapping option the F71869A provides eight pins for power on hardware strapping to select functions. there is a form to describe how to set the functions you want. table1. power on trap configuration pin no. symbol value description 1 amd timing (default) 52 strap_timing 0 intel cougar point timing 1 power on fan speed default duty is 40% (pwm) (default) 121 fan40_100 0 power on fan speed default duty is 100%(pwm) 1 configuration register i/o port is 4e/4f. (default) 124 strap4e_2e 0 configuration register i/o port is 2e/2f. 1 fanctrl1 is pwm mode. connect a 4.7k resistor and pull high to 3.3v. 22 fanctl1 0 fanctlr1 is dac mode. (default) 1 fanctrl2 is pwm mode. connect a 4.7k resistor and pull high to 3.3v. 24 fanctl2 0 fanctlr2 is dac mode. (default) 1 fanctrl3 is pwm mode. connect a 4.7k resistor and pull high to 3.3v. 26 fanctl3 0 fanctlr3 is dac mode. (default) 1 enable 80 port (default) 5 strap_dport 0 disable 80 port 1 default is alarm mode (disabled). voltage protection function is enabled via setting the related register. 122 strap_protect 0 force mode which is always enabled after power on. 5.2 hardware monitor for the 8-bit adc has the 8mv lsb, the maxi mum input voltage of the analog pin is 2.048v. therefore the voltage under 2.048v (ex: 1.5v) can be directly connected to these analog inputs. the voltage higher than 2.048v should be reduced by a factor with external resistors so as to obtain the input range. only 3vcc/vsb/vbat is an exception for it is main power of the F71869A. therefore 3vcc/vsb/vbat can directly connect to this chip?s power pin and need no external resistors. there are two functions in this pin with 3.3v. the first function is to supply internal analog power of the F71869A and the second function is that voltage with 3.3v is connected to internal serial resistors to monitor the +3.3v voltage. the internal serial resistors are two 150k ohm, so that the internal reduced voltage is half of +3.3v.
oct., 2011 v0.19p 23 F71869A there are four voltage inputs in the F71869A and the voltage divided formula is shown as follows: 2 1 2 v 12 r r r v vin + = + where v +12v is the analog input voltage, for example. if we choose r1=27k, r2=5.1k, the exact input voltage for v+12v will be 1.907v, which is within the tolerance. as for application circuit, it can be refer to the figure shown as follows. vin (lower than 2.048v) 8-bit adc with 8 mv lsb voltage inputs r1 r2 vin1(max2.048v) vin(higher than 2.048v) (directly connect to the chip) 3vcc/vsb (directly connect to the chip) vin3.3 150k 150k typical thermister connection r thm 10k, 25 c r vref 10k, 1% 2n3906 typical bjt connection d+ d- figure 2. hardware monitor configuration the F71869A monitors three remote temperature sensors. these sensors can be measured from -40c to 127c. more detail please refer register description. table 2. remote-sensor transistor manufacturers manufacturer model number panasonic 2sb0709 2n3906 philips pmbt3906 5.2.1. table range: table 3. display range is from -40c to 127c in 2?s complement format. temperature digital output -40c 1101 1000 -1c 1111 1111 1c 0000 0001 90c 0101 1010
oct., 2011 v0.19p 24 F71869A 127c 1111 1111 open 1000 0000 5.2.2. monitor temperature from ?thermistor? the F71869A can connect three thermistors to measure environment temperature or remote temperature. the specification of thermistor should be considered to (1) ? value is 3435k (2) resistor value is 10k ohm at 25 o c. in the figure 2, the thermistor is connected by a serial resistor with 10k ohm, then being connected to vref. 5.2.3. monitor temperatur e from ?thermal diode? also, if the cpu, gpu or external circuits provide thermal diode for temperature measurement, the F71869A is capable to these situations. the build-in reference table is for pnp 2n3906 transistor. in the figure 2, the transistor is directly connected into temperature pins. 5.2.4. adc noise filtering the adc is integrating type with inherently good noise rejection. micro-power operation places constraints on high-frequency noise rejection; therefore, careful pcb board layout and suitable external filtering are required for high-accuracy remote measurement in electronically noisy environment. high frequency emi is best filtered at d+ and d- with an external 2200pf capacitor. too high capacitance may introduce errors due to the rise time of the switched current source. nearly all noise sources tested cause the adc measurement to be higher than the actual temperature, depending on the frequency and amplitude. 5.2.5. monitor temperature from ?smbus device? F71869A provides smbus block read/write compatible platform control hub (pch) ec smbus protocol, and provides byte read/write protocol to read cpu and chipset thermal temperature information. for byte read /write protocol, F71869A supports 4-suit device address to read or write from device information. for block read/write, F71869A support 1 suits device address and maximum 17 byte count for read protocol to read from device information, and 4 byte count for write protocol to write information to device. 5.2.6. monitor temperature from ?peci? F71869A support intel peci1.1/peci3.0/peci_request/peci_available interfaces to read temperature from peci device.
oct., 2011 v0.19p 25 F71869A 5.2.7. temperature ovt# signal there is a mode of temperature (t1 to t4) ovt function, and refer t1 to t4 temperature in the below figure. over temperature event will trigger ovt# that shown as figure 3. in hysteresis mode, when monitored temperature exceeds the high temperature threshold value, ovt# will be asserted until the temperature goes below the hysteresis temperature. t hyst t ovt# ovt t1 t2 t3 t4 figure 3 5.2.8. temperature pme# pme# interrupt for temperature is shown as figure 4. temperature exceeding high limit (low limit) or going below high hysteresis (low hysteresis) will cause an interrupt if the previous interrupt has been reset by writing ?1? all the interrupt status register.
oct., 2011 v0.19p 26 F71869A *interrupt reset when interrupt status registers are written 1 pme# (pulse mode) * * t ovt t hhys * * t high t hhys figure 4 hysteresis mode illustration 5.2.9. fan speed count inputs are provided by the signals from fans equipped with tachometer outputs. the level of these signals should be set to ttl level, and maximum input voltage cannot be over 5v. if the input signals from the tachometer outputs are ov er the 5v, the external trimming circuit should be added to reduce the voltage to obtain the input specification. determine the fan counter according to: rpm 10 5 . 1 count 6 = in other words, the fan speed counter has been read from register, the fan speed can be evaluated by the following equation. as for fan, it would be best to use 2 pulses tachometer output per round. count 10 5 . 1 rpm 6 = as the register description of datasheet, the parameter ?count? register provides 12-bit resolution for rpm counting. in fintek design, the value of parameter ?count? is from 4096 ~ 64 (5 bit filter). therefore the rpm measure capability is from 366 ~ 23438 rpm. above example is for 2 pulses tachometer (normal 4 phases fan) output per round. if you use 8 phases fan, means output 4 pulses per round. the rpm measure capability is from 183 ~ 11719 rpm. 5.2.10. fan speed control the F71869A provides 2 fan speed control methods: one is dac fan control and the other is pwm duty cycle. 1. dac fan control
oct., 2011 v0.19p 27 F71869A the range of dc output is 0~3.3v, controlled by 8-bit register. 1 lsb is about 0.013v. the output dc voltage is amplified by external op circuit, thus to reach maximum fan operation voltage, 12v. the output voltage will be given as followed: 255 value register 8bit programmed 3 . 3 (v) tage output_vol = and the suggested application circuit for dac fan control would be: fanin monitor dc output voltage +12v r10k 1 2 3 jp1 con3 r 10k r 3.6k d1 1n4148 3 2 1 8 4 + - u1a lm358 r27k r 4.7k c 47u q1 pmos c 0.1u r 4.7k figure 5 dac fan control application circuit 2. pwm duty fan control the duty cycle of pwm can be programmed by a 8-bit register. the default duty cycle is set to 100%, that is, the default 8-bit registers is set to ffh. the expression of duty can be represented as follows. % 100 255 value register 8bit programmed (%) duty_cycle = +12v fan r1 r2 nmos pnp transisto r c + - d s g figure 6 +12/5v pwm fan control application circuit
oct., 2011 v0.19p 28 F71869A 5.2.11. fan speed control mechanism there are some modes to control fan speed and they are 1.manual mode, 2.stage auto mode 3. linear auto mode. more detail, please refer the description of registers. each fan can be controlled by up to 8 kinds of temperature inputs: (1) d1+ temperature (2) d2+ temperature (3) d3+ temperature (4) peci temperature (5) 4 suits smbus master temperature. each fan would make the maximum temperature comparison form those inputs with the expected speed, and decide the suitable fan speed. please refer below figure 7. figure 7 relative temperature fan control manual mode for manual mode, it generally acts as software fan speed control. auto mode in auto mode, the F71869A provides automatic fan speed control related to temperature variation of cpu/gpu or the system. the F71869A can provide four temperature boundaries and five intervals, and each interval has its related fan speed count. all these values should be set by bios first. take fan1 for example, the 4 temperature b oundaries could be set from register 0xa6 to 0xa9 and the five intervals for fan speed control coul d be set from register 0xaa to 0xae. and the expected speed1 expected speed 2 fan1 fan2 d2+ t (t2) d1+ t (t1) peci (t0) d3+ t (t3) ibx byte1 ibx byte3:2 ibx byte4 ibx byte5 expeted speed 3 fan3
oct., 2011 v0.19p 29 F71869A hysteresis setting (0 ~ 15c) could also be found in register 0x98. the manual mode and auto mode could be selected by register 0x96h. there are two kinds of auto mode: stag e auto mode and linear auto mode. the ?fan1_ interpolation_en? in register 0xafh is used for linear auto mode enable. the following examples explain the differences fo r stage auto mode and linear auto mode. stage auto mode in this mode, the fan keeps in a same speed fo r each temperature interval. and there are two types of fan speed setting: pwm duty and rpm %. a. stage auto mode (pwm duty) set the temperature limits as 70c, 60c, 50c, 40 c and the duty as 100%, 90%, 80%, 70%, 60% figure 8 stage mode fan control illustration-2 a. once the temperature is under 40c, the lowest fan speed keeps in the 60% pwm duty. b. once the temperature is over 40c, 50cand 60 c, the fan speed will vary from 70%, 80% to 90% pwm duty and increasing with the temperature level. c. for the temperature higher than 70c, the fan speed keeps in 100% pwm duty. d. if set the hysteresis is 3c (default 4c), onc e the temperature becomes lower than 67c, the fan speed would reduce to 90% pwm duty. b. stage auto mode (rpm%) set the temperature as 70c, 60c, 50c, 40 c and the corresponding fan speed is 6,000 rpm,
oct., 2011 v0.19p 30 F71869A 5,400 rpm, 4,800 rpm, 4,200 rpm, and 3,600 rpm (assume the max fan speed is 6,000 rpm). figure 9 stage mode fan control illustration-3 a. once the temperature is lower than 40c, the lowest fan speed keeps in 3,600 rpm (60% of full speed). b. once the temperature is higher than 40c, 50c and 60c, the fan speed will vary from 4,200 rpm to 5,400 rpm and increasing with the temperature level. c. for the temperature higher than 70c, the fan speed keeps in the full speed 6,000 rpm. d. if the hysteresis is set as 3c (default 4c) , once temperature gets lower than 67c, the fan speed would reduce to 5,400 rpm. linear auto mode F71869A also supports linear auto mode. the fan speed would increase or decrease linearly with the temperature. there are also pwm duty and rpm% modes for it. a. linear auto mode (pwm duty) set the temperature as 70c, 60c, 50c and 40c and the duty is 100%, 80%, 70%, 60% and 50%.
oct., 2011 v0.19p 31 F71869A figure 10 linear mode fa n control illustration-1 a. once the temperature is lower than 40c, the lowest fan speed keeps in the 50% pwm duty b. once the temperature becomes higher than 40c , 50c and 60c, the fan speed will vary from 50% to 80% pwm duty linearly with the tempreat ure variation. the temp.-fan speed monitoring flash interval is 1sec. c. once the temperature goes over 70c, the fan speed will directly increase to 100% pwm duty (full speed). d. if set the hysteresis is 5c (default is 4c) , once the temperature becomes lower than 65c (instead of 70c), the fan speed will reduce from 100% pwm duty and decrease linearly with the temperature. b. linear auto mode (rpm%) set the temperature as 70c, 60c, 50c, 40 c and the corresponding fan speed is 6,000 rpm, 4,800 rpm, 4,200 rpm, 3,600 rpm and 3,000 rpm (assume the max fan speed is 6,000 rpm).
oct., 2011 v0.19p 32 F71869A figure 11 linear mode fa n control illustration-2 a. once the temperature is lower than 40c, the lowest fan speed keeps in 3,000 rpm (50% of full speed). b. once the temperature is over 40c,50c and 60 c, the fan speed will vary from 3,000 to 4,800 rpm almost linearly with the temperature variation because the temp.-fan speed monitoring flash interval is 1sec. c. once the temperature goes over 70c, the f an speed will directly increase to full speed 6,000 rpm. d. if the hysteresis is 5c (default is 4c), onc e the temperature becomes lower than 65c (instead of 70c), the fan speed wull reduce from full s peed and decrease linearly with the temperature.
oct., 2011 v0.19p 33 F71869A fan speed control with multi-temperature. F71869A supports multi-temperature for one fan control. this function works with linear auto mode can extend two linear slopes for one fan control. as the graph below, this machine can support more silence fan control in low temperature environment and faster fan speed in high temperature segment. more detail setting please refers to the registers.
oct., 2011 v0.19p 34 F71869A in the figure below, tfan1 is the scaled temperature for fan1. t1 is the real temperature for the fan1 sensor. ta is another temperature data which can be used for linearly scale up or scale down the fan1 speed curve. tb would be the point which starts the temperature scaling. the slope for the temperature curve over and under tb would be ctup and ctdn. in application, we can set the ta as the 2 nd sensor temperature and tb as the temperature which starts the scaling. so if the 2 nd sensor temperature ta is higher or lower than tb, the fan1 speed would be changed with it.
oct., 2011 v0.19p 35 F71869A ex: ta = t1, tb = 60, ctu = 1, ctd = 1/4 5.2.12. fan_fault# fan_fault# will be asserted when the fan speed doesn?t meet the expected fan speed within a programmable period (default is 11 seconds) or when fan stops with respect to pwm duty-cycle which should be able to turn on the fan. there are two conditions may cause the fan_fault# event. (1). when pwm_duty reaches 0xff, the fan speed count can?t reach the fan expected count in time. fan_fault# expected fan count 11 sec ( default ) current fan count duty-cycle 100% figure 12 fan_fault# event
oct., 2011 v0.19p 36 F71869A (2). after the period of detecting fan full speed, pwm_duty > min. duty, fan count is still in 0xfff. 5.3 acpi function the advanced configuration and power interface (acpi) is a system for controlling the use of power in a computer. it lets computer manufacturer and user to determine the computer?s power usage dynamically. there are three acpi states that are of primar y concern to the system designer and they are designated s0, s3 and s5. s0 is a full-power state; the computer is being actively used in this state. the other two are called sleep states and reflect different power consumption when power-down. s3 is a state that the processor is powered down but the last procedural state is being stored in memory which is still active. s5 is a state that memory is off and the last procedural state of the processor has been stored to the hard disk. take s3 and s5 as comparison, since memory is fast, the computer can quickly come back to full-power state, the disk is slower than the memory and the computer takes longer time to come back to full-power state. however, since the memory is off, s5 draws the minimal power comparing to s0 and s3. it is anticipated that only the following state transitions may happen: s0 s3, s0 s5, s5 s0, s3 s0 and s3 s5. among them, s3 s5 is illegal transition and won?t be allowed by state machine. it is necessary to enter s0 first in order to get to s5 from s3. as for transition s5 s3 will occur only as an immediate state during state transition from s5 s0. it isn?t allowed in the normal state transition. the below diagram described the timing, the always on and always off, keep last state could be set in control register. in keep last state mode, one register will keep the status of before power loss. if it is power on before power loss, it will remain power on when power is resumed, otherwise, if it is power off before power loss, it will remain power off when power is resumed.
oct., 2011 v0.19p 37 F71869A vbat vsb rsmrst# s3# ps_on# psin# psout# vcc3v figure 13 default timing: always off vbat vsb rsmrst# s3# ps_on# psin# psout# vcc3v figure 14 optional timing: always on
oct., 2011 v0.19p 38 F71869A pci reset and pwok signals the F71869A supports 5 output buffers for 5 reset signals. so far as the pwok issue is as the figure above. pwok is delayed 400ms (default) as vcc arrives 2.8v, and the delay timing can be programm ed by register. an additional delay could be added to pwok (0ms, 100ms, 200ms and 400ms). if rstcion# and pcirst4#/pcirst5# are enabled, rstcon# could be programmed to be asserted via pwrok or pcirst4#/pcirst5#. 5.4 power timing control sequence the F71869A offers 4 timing pins which are designed for amd platform power sequence control including vdimm, vdda, vcore, and vldt (default) or other timing application purposes. all the timings on/off are relative to s3#/s5# and can be programmed by the register 0x0af7. as shown in the below figure, the default timings of timing_1~4 are displayed in blue lines, and all the timings are enabled in the s0 state except timing_1. however, timing_2~4 can be programmed to enable in the s3 state, and timing_1 can also be programmed to disable in the s3 state, like the dotted blue line shown in the figure below. vddok_d400 is the pwok delay timing from vdd3vok. the default setting is that delay 400ms, there are 100ms, 200ms, and 300ms for opti on. it can be set in the register 0x0af5. delay +3.3v atxpg lreset# pcirst1~5# pwok buffer
oct., 2011 v0.19p 39 F71869A figure 15 timing on/off sequence 5.5 s 3 _gate#, s 3p5 _gate# and s 0p5 _gate# timing the F71869A provides three additional timing switching pins which are named as s 3 _gate#, s 3p5 _gate# and s 0p5 _gate#. they can be applied in the cert ain applications about power switch which depends on the acpi states. the detail timing can be referred in the following diagrams. the default timing of s 0p5 _gate# in the s5 state is low, but it can be programmed high by the register 0x0af6. s5 s3 s0 s5 s5# s3# pson# atxpwgd timing_1 timing_2 timing_3 timing_4 cpu_pwgd vddok_d400 s0 s3
oct., 2011 v0.19p 40 F71869A s5# s3# pson# vdd3v vddok vddok_d400 atxpg pwrok s0p5_gate# 400ms could be programmed low s5 s3_gate# could be programmed low s3p5_gate# 10us 10us s0 s3 figure 16 timing chart of s5->s0->s3
oct., 2011 v0.19p 41 F71869A s5# s3# pson# vdd3v vddok vddok_d400 atxpg pwrok s0p5_gate# 400ms s3 s3_gate# s3p5_gate# 10us 10us s0 s5 could be programmed low figure 17 timing chart of s3->s0->s5 5.6 amd tsi and intel peci 3.0 functions the F71869A provides intel peci/amd tsi interfaces for new generational cpu temperature sensing. in amdsi interface, there are sic and sid signals for temperature information reading from amd cpu. the sic signal is for clocking use, the other is for data transferring. more detail, please refer register description. scl vddio F71869A amd cpu sic sid 300 300 sda figure 18 amd tsi typical application in intel peci interface, the F71869A can connect to cpu directly. the F71869A can read the temperature data from cpu, than the fan control machine of F71869A can implement the fan to cool down cpu temperature. the application circuit is as below.
oct., 2011 v0.19p 42 F71869A peci F71869A cpu peci intel 100k avoid pre-bios floating figure 19 intel peci typical application in intel peci 3.0 spec., it?s including below commands. the F71869A integrated most of those commands for future advantage application. more detail, please refer the register descriptions. F71869A support peci 3.0 command name peci 1.0 command name status v ping( ) ping( ) v gettemp( ) gettemp( ) v getdib( ) v rdiamsr( ) - wriamsr( ) - rdpciconfiglocal( ) not available in mobile/dt - wrpciconfiglocal( ) not available in mobile/dt - rdpciconfig( ) not available in mobile/dt - wrpciconfig( ) not available in mobile/dt v rdpkgconfig( ) v wrpkgconfig( ) 5.7 erp power saving function the two pins, erp_ctrl0# and erp_ctrl1#, which control the standby power rail on/off to fulfill the purpose which decreases the power consumption when the system in the sleep state or the soft-off state. these two pins connected to the external pmoss and the defaults are high in the sleep state in order to cut off all the standby power rails to save the power consumption. if the system needs to support wake-up function, the two pins can be programmable to set which power rail is turned on. the programmable register is powered by battery. so, the setting is kept even the ac power is lost when the register is set. at the power saving state (fintek calls it g3-like state), the F71869A consumes 5vsb power rail only to rea lize a low power consumption system. below is erp function?s timing graphs.
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oct., 2011 v0.19p 46 F71869A 5.8 cir function the F71869A is compatible with microsoft windows vista and windows 7 ir receiver or transceiver emulation device which supports rc6 & qp protocol. it supports 1 ir transceiver functions for blaster application and 1 ir receiver with long range frequency and another with wide band application. in power function, the F71869A supports vista and windows 7 wakeup programming function when the pc is in the s3 state. the F71869A decode ir protocol via the same vista and windows 7 wakeup programming key. the F71869A is asserted pme or psout to wakeup pc system. where wake up programming function is reference from microsoft vista and windows 7 remote controller specification. the F71869A supports 1 ir transceiver function for blaster application and two ir receivers for long range frequency and wideband application. the wide-band receiver is necessary to support ir learning, ir-blasting and set-top box control. the long-range receiver is a receiver which has the following characteristics: 1. works at a distance of 10 meters. 2. demodulates the signal inside the receiver part 3. has a bpf which works with carriers from 32-60 khz. the wide-band receiver is a receiver part which has the following characters: 1. works at a distance of approximately 5 centimeters. 2. does not demodulate the signal inside the receiver part 3. works with carriers from 32-60 khz. (probably doesn?t have a bpf, but still has the same (or wider) range. about ir information, reference microsoft wi ndows vista / 7 ir receiver or transceiver emulation device spec.
oct., 2011 v0.19p 47 F71869A 5.9 intel cougar point timing (cpt) the F71869A supports intel cougar point chipset timing for sandy bridge. there are 4 pins for cpt control: sus_warn#, sus_ack#, slp_sus# and dpwrok. for entering intel deep sleep well (dsw) state, the pch will assert sus_warn# and turn off 5vdual. after the level of 5vdual is lower than 1.05v, F71869A will assert sus_ack# to inform pch it is ready for entering dsw. finally, pch will ramp down the internal vccsus and assert slp_sus# to F71869A. F71869A will turn off the 5vsb and 3vsb by erp_ctrl0# and enter the dsw state. to exit dsw state, pch will de-assert slp_sus#, turn on the sus rail fets and ramp up internal 1.05v vccsus. after the sus rails voltages are up, rsmrst# will be desserted and the pch will release sus_warn# so that the 5vdual will ramp up. because the dsw function is controlled by F71869A instead of controlled by pch directly, there will be more wakeup events such as lan, kb/mouse, sio ri# wake up rather than the 3 wakeup events (rtc, power button and gpio27) for intel dsw. in order to achieve lower power consumption, F71869A provides the erp_ctrl1# to turn off the v3a so that the system can enter the fintek g3? state. the block diagram below shows how the connection and control method for F71869A and pch.
oct., 2011 v0.19p 48 F71869A 5.10 scan code function F71869A has 8 gpio pins (gpio 35~37, gpio 50~54) support scan code. these pins can not only be set to volume up/down, mute and pwm up/down but also any function keys on keyboard. because the protocol for these 5 pins is scan code, so we don?t need a driver to connect this function to os. if the button for the gpio has been pressed continuesly over nearly 1 second (delay time), the gpio will repeatedly sending this function in an interval of 50 ms (repeat time). the delay time could be set from 0.5 to 1.5 sec. the repeat time could be set from 50, 100, 250 to 500 ms. 5.11 over voltage protection F71869A over voltage protection function could protect the damage from voltage spikes via over voltage protection (ovp) function. voltage protection function is enabled via setting the related register. when force mode occurs, the system would shut down and then can not boot at all. only re-plugging the power code (cut off vsb) could re-activate or re-boot the system at the force mode. please see below table for detail information:
oct., 2011 v0.19p 49 F71869A 6. register description the configuration register is used to control the behavior of the corresponding devices. to configure the register, using the index port to select the index and then writing data port to alter the parameters. the default index port and data port are 0x4e and 0x4f respectively. pull down the sout1 pin to change the default value to 0x2e/0x2f. to enable configuration, the entry key 0x87 must be written to the index port. to disable configuration, write exit key 0xaa to the index port. following is a example to enable configurat ion and disable configuration by using debug. -o 4e 87 -o 4e 87 (enable configuration) -o 4e aa (disable configuration) the following is a register map (total devices) grouped in hexadecimal address order, which shows a summary of all registers and their default value. please refer each device chapter if you want more detail information. global control registers ?-? reserved or tri-state global control registers register 0x[hex] register name default value msb lsb 02 software reset register - - - - - - - 0 07 logic device number register (ldn) 0 0 0 0 0 0 0 0 20 chip id register 1 0 0 0 1 0 0 0 0 21 chip id register 2 0 0 0 0 0 1 1 1 23 vendor id register 1 0 0 0 1 1 0 0 1 24 vendor id register 2 0 0 1 1 0 1 0 0 25 software power down register - - - - 0 0 0 0
oct., 2011 v0.19p 50 F71869A 26 uart irq sharing register 0 - 0 - 0 0 0 0 27 configuration port select r egister 1/0 0 1/0 1/0 - - - 1/0 28 multi-function select register1 0 0 1 1 1 0 0 0 29 multi-function select register2 0 1 1 0 1 1 1 1 29 wdt clock divisor high byte - - - - 0 0 1 1 2a multi-function select register3 0 0 0 0 1 1 1 1 2a wdt clock divisor low byte 1 1 1 0 0 1 1 1 2b multi-function select register4 0 0 0 0 1 1 1 1 2b wdt clock fine tune count high byte - - - - - - - - 2c multi-function select register 5 0 0 0 0 0 0 0 0 2c wdt clock fine tune count low byte - - - - - - - - 2d wakeup control register 0 0 1 0 1 0 0 0 device configuration registers ?-? reserved or tri-state fdc device configuration registers (ldn cr00) register 0x[hex] register name default value msb lsb 30 fdc device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 1 1 61 base address low register 1 1 1 1 0 0 0 0 70 irq channel select register - - - - 0 1 1 0 74 dma channel select register - - - - - 0 1 0 f0 fdd mode register 0 - - 0 1 1 1 0 f2 fdd drive type register - - - - - - 1 1 f4 fdd selection register - - - 0 0 - 0 0 uart1 device configuration registers (ldn cr01) register 0x[hex] register name default value msb lsb 30 uart1 device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 1 1 61 base address low register 1 1 1 1 1 0 0 0 70 irq channel select register - - - - 0 1 0 0 f0 rs485 enable register - - 0 0 - - - - uart2 device configuration registers (ldn cr02) register register name default value
oct., 2011 v0.19p 51 F71869A 0x[hex] msb lsb 30 uart2 device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 1 0 61 base address low register 1 1 1 1 1 0 0 0 70 irq channel select register - - - - 0 0 1 1 f0 rs485 enable register - - - 0 0 0 - - f1 sir mode control register - - 0 0 0 1 0 0 parallel port device configuration registers (ldn cr03) register 0x[hex] register name default value msb lsb 30 parallel port device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 1 1 61 base address low register 0 1 1 1 1 0 0 0 70 irq channel select register - - - - 0 1 1 1 74 dma channel select register - - - 0 - 0 1 1 f0 prt mode select register 0 1 0 0 0 0 1 0 hardware monitor device configuration registers (ldn cr04) register 0x[hex] register name default value msb lsb 30 h/w monitor device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 1 0 61 base address low register 1 0 0 1 0 1 0 1 70 irq channel select register - - - - 0 0 0 0 kbc device configuration registers (ldn cr05) register 0x[hex] register name default value msb lsb 30 kbc device enable register - - - - - - - 1 60 base address high register 0 0 0 0 0 0 0 0 61 base address low register 0 1 1 0 0 0 0 0 70 kb irq channel select register - - - - 0 0 0 1 72 mouse irq channel select register - - - - 1 1 0 0 f0 clock select register 1 0 - - - - 1 1 fe swap register 1 - - 0 0 0 0 1 ff user wakeup code register 0 0 1 0 1 0 0 1 gpio device configuration registers (ldn cr06) register 0x[hex] register name default value msb lsb
oct., 2011 v0.19p 52 F71869A 30 gpio device enable register - - - - - - - 0 60 base address high register 0 0 0 0 0 0 0 0 61 base address low register 0 0 0 0 0 0 0 0 70 gpirq channel select register - - - - 0 0 0 0 f0 gpio output enable register - - 0 0 0 0 0 0 f1 gpio output data register - - 1 1 1 1 1 1 f2 gpio pin status register - - - - - - - - f3 gpio drive enable register - - 0 0 0 0 0 0 e0 gpio1 output enable register 0 0 0 0 0 0 0 0 e1 gpio1 output data register 1 1 1 1 1 1 1 1 e2 gpio1 pin status register - - - - - - - - e3 gpio1 drive enable register 0 0 0 0 0 0 0 0 e4 gpio1 pme enable register 0 0 0 0 0 0 0 0 e5 gpio1 detect edge select register 0 0 0 0 0 0 0 0 e6 gpio1 pme status register 0 0 0 0 0 0 0 0 d0 gpio2 output enable register 0 0 0 0 0 0 0 0 d1 gpio2 output data register 1 1 1 1 1 1 1 1 d2 gpio2 pin status register - - - - - - - - d3 gpio2 drive enable register 0 0 0 0 0 0 0 0 c0 gpio3 output enable register 0 0 0 0 0 0 0 0 c1 gpio3 output data register 1 1 1 1 1 1 1 1 c2 gpio3 pin status register - - - - - - - - b0 gpio4 output enable register - - - - 0 0 0 0 b1 gpio4 output data register - - - - 1 1 1 1 b2 gpio4 pin status register - - - - - - - - b3 gpio4 drive enable register - - - - 0 0 0 0 b4 gpio4 pme enable register - - - - 0 0 0 0 b5 gpio4 detect edge select register - - - - 0 0 0 0 b6 gpio4 pme status register - - - - 0 0 0 0 a0 gpio5 output enable register - - - 0 0 0 0 0 a1 gpio5 output data register - - - 1 1 1 1 1 a2 gpio5 pin status register - - - - - - - - a4 gpio5 pme enable register 0 0 0 0 0 0 0 0 a5 gpio5 detect edge select register 0 0 0 0 0 0 0 0 a6 gpio5 pme status register 0 0 0 0 0 0 0 0 a9 gpio5 kbc emulation control register 1 0 0 0 0 0 0 0 0 ab gpio5 kbc emulation make code register 0 0 0 0 0 0 0 0
oct., 2011 v0.19p 53 F71869A ac gpio5 kbc emulation prefix code register 1 1 1 0 0 0 0 0 ad gpio5 kbc emulation status register 1 0 0 0 0 0 0 0 0 ae gpio5 kbc emulation status register 2 0 0 0 0 0 0 0 0 af gpio5 kbc emulation control register 2 0 1 0 0 0 0 0 0 90 gpio6 output enable register 0 0 0 0 0 0 0 0 91 gpio6 output data register 1 1 1 1 1 1 1 1 92 gpio6 pin status register - - - - - - - - 80 gpio7 output enable register 0 0 0 0 0 0 0 0 81 gpio7 output data register 1 1 1 1 1 1 1 1 82 gpio7 pin status register - - - - - - - - 83 gpio7 drive enable register 0 0 0 0 0 0 0 0 wdt device configuration registers (ldn cr07) register 0x[hex] register name default value msb lsb f0 watchdog timer enable register - - - - - - - 1 f2 bus manual register 0 0 0 0 0 0 0 0 f3 key data register 0 0 0 0 0 0 0 0 f4 busin status register - - - - - - - - f5 wdt unit select register - 0 - 0 0 0 0 0 f6 wdt count register 0 0 0 0 1 0 1 0 f7 watchdog timer pme register 0 0 0 - - - - 0 cir configuration register (ldn cr08) register 0x[hex] register name default value msb lsb 30 cir device enable register - - - - - - - 0 60 base address high register 0 0 0 0 0 0 0 0 61 base address low register 0 0 0 0 0 0 0 0 70 cir irq channel select register - - - - 0 0 0 0 f0 reserved - - - - - - - - f1 reserved - - - - - - - - f8 reserved 0 0 0 0 0 0 0 0 f9 reserved 0 0 0 0 0 0 0 0 fa reserved 1 0 0 0 0 0 0 0 fb reserved 0 0 1 1 1 0 1 1 fc reserved 0 0 0 0 0 0 0 0 fd reserved 0 0 0 0 0 0 0 0 fe reserved 0 0 0 0 0 0 0 0 pme, acpi, and erp power saving device configuration registers (ldn cr0a)
oct., 2011 v0.19p 54 F71869A register 0x[hex] register name default value msb lsb 30 pme device enable register - - - - - - - 0 e0 erp enable register 0 - - - - - 0 0 e1 erp control register 1 1 0 0 1 1 0 0 e2 erp control register - 0 1 1 1 1 0 - e3 erp psin deb-register 0 0 0 1 0 0 1 1 e4 erp rsmrst deb-register 0 0 0 0 1 0 0 1 e5 erp psout deb-register 1 1 0 0 0 1 1 1 e6 erp pson deb-register 0 0 0 0 1 0 0 1 e7 erp s5 delay register 0 1 1 0 0 0 1 1 e8 wakeup enable register 0 - 0 0 1 0 0 0 e9 erp s3 delay register 0 0 0 0 1 1 1 1 ec erp mode select register 0 0 0 - - - - - ed erp wdt control register - - - - - - 0 0 ee erp wdt timer - - - - - - - 0 f0 pme event enable register 1 0 0 0 0 0 0 0 0 f1 pme event status register 1 - - - - - - - - f2 pme event enable register 2 - - - 0 - 0 0 0 f3 pme event status register 2 - - - - - - - - f4 keep last state select register 0 0 0 0 0 1 1 0 f5 vddok delay select register 0 0 0 1 1 1 0 0 f6 pcirst control register 0 0 0 1 1 1 1 1 f7 power sequence control register 1 0 0 0 0 1 1 0 f8 led vcc control register 0 0 0 0 0 0 0 0 f9 led vsb control register - 0 0 0 0 0 0 0 fa led vsb additional control register - 0 0 0 - 0 0 0 fc intel dsw delay register - - - - 0 1 1 1 fe ri de-bounce select register 0 0 - 0 - - 0 0 6.1 global control registers 6.1.1 software reset register ? index 02h bit name r/w default description 7-1 reserved - - reserved 0 soft_rst r/w 0 write 1 to reset the regi ster and device powered by vdd ( 3vcc ).
oct., 2011 v0.19p 55 F71869A 6.1.2 logic device number register (ldn) ? index 07h bit name r/w default description 7-0 ldn r/w 00h 00h: select fdc device co nfiguration registers. 01h: select uart 1 device configuration registers. 02h: select uart 2 device configuration registers. 03h: select parallel port devic e configuration registers. 04h: select hardware monitor dev ice configuration registers. 05h: select kbc device co nfiguration registers. 06h: select gpio device c onfiguration registers. 07h: select wdt device c onfiguration registers. 0ah: select pme & acpi device configuration registers. 6.1.3 chip id register 1 ? index 20h bit name r/w default description 7-0 chip_id1 r 10h chip id1 6.1.4 chip id register 2 ? index 21h bit name r/w default description 7-0 chip_id2 r 07h chip id2 6.1.5 vendor id register 1 ? index 23h bit name r/w default description 7-0 vendor_id1 r 19h vendor id1 6.1.6 vendor id register 2 ? index 24h bit name r/w default description 7-0 vendor_id2 r 34h vendor id2 6.1.7 software power down register ? index 25h bit name r/w default description 7-4 reserved - - reserved. 3 softpd_prt r/w 0 set ?1? to power do wn parallel port. the clock will stop.
oct., 2011 v0.19p 56 F71869A 2 softpd_ur2 r/w 0 set ?1? to power down uart 2. the clock will stop. 1 softpd_ur1 r/w 0 set ?1? to power down uart 1. the clock will stop. 0 softpd_fdc r/w 0 set ?1? to powe r down fdc. the clock will stop. 6.1.8 uart irq sharing register ? index 26h bit name r/w default description 7 clk24m_sel r/w 0 0: clkin is 48mhz 1: clkin is 24mhz 6 reserved - - reserved. 5 dport_dec_sel r/w 0 0: the debug port address is 0x80. 1: the debug port address is uart2 base address. 4 reserved - - reserved. 3 clk_tune_en r/w 0 set ?1? to switch index 0x29 ~ 0x2c to wdt clock fine tune registers. 2 tx_del_1bit r/w 0 0: uart transmits data immediately after writing thr. 1: uart transmits data delay one bit time after writing thr. 1 irq_mode r/w 0 0: pci irq sharing mode (low level). 1: isa irq sharing mode (low pulse). 0 irq_shar r/w 0 0: disable irq sharing of two uart devices. 1: enable irq sharing of two uart devices. 6.1.9 configuration port select register ? index 27h bit name r/w default description 7 ovp_mode r/w - 1: alarm mode. voltage protection is default disabled. 0: force mode. voltage protection is default enabled. this bit is power on strapped by rts1#/strap_protect. pull down to select force mode. 6 temp_out_en r/w 0 debug port output select. 0: 80 port data. 1: temperature fetched by hardware mmonitor.
oct., 2011 v0.19p 57 F71869A 5 dport_en r/w - 0: disable debug port. 1: enable debug port. this bit is power on strapped by gpio26/sout2/segb/strap_dport. pull down to disable. 4 port_4e_en r/w - 0: the configuration register port is 2e/2f. 1: the configuration register port is 4e/4f. this register is power on trapped by sout1/ config4e_2e. pull down to select port 2e/2f. 3-1 reserved - - reserved. 0 timing_en r - this bit is the pin status of timing_gpio pin. 0: disable power sequence control. 1: enable power sequence control. 6.1.10 multi-function select register 1 ? index 28h (powered by vsb3v) bit name r/w default description 7 fdc_gp_rst_sel r/w 0 select gpio5/gpio3 reset signal. 0: reset by internal vsb3v power good. 1: reset by lreset#. 6 reserved r/w 0 reserved 5 pwr_ s 3 _gate#_en r/w 1 0: s 3 _gate# / gpio05/wdtrst# functions as gpio05/wdtrst# determined by gpio05_en. 1: s 3 _gate#/gpio05/wdtrst# functions as s 3 _gate#. 4 pwr_ s 3p5 _gate#_en r/w 1 0: s 3p5 _gate#/slotocc#/gpio04 functions as slotocc#/gpio04 determined by gpio04_en. 1: s 3p5 _gate#/slotocc#/gpio04 functions as s 3p5 _gate#. 3 gpio05_en r/w 1 0: s 3 _gate#/gpio05/wdtrst# functions as wdtrst if pwr_ s 3 _gate#_en is not set. 1: s 3 _gate#/gpio05/wdtrst# functions as gpio05 is pwr_ s 3 _gate#_en is not set. 2 gpio04_en r/w 0 0: s 3p5 _gate# / slotocc#/gpio04 functions as slotocc# i f pwr_ s 3p5 _gate#_en is not set. 1: s 3p5 _gate#/slotocc#/gpio04 functions as gpio04 if pwr_ s 3p5 _gate#_en is not set.
oct., 2011 v0.19p 58 F71869A 1 pin60_lvl_sel r/w 0 0: pin 60 input level is ttl level. 1: pin 60 input level is low level (0.6v/0.9v). 0 pin59_lvl_sel r/w 0 0: pin 59 input level is ttl level. 1: pin 59 input level is low level (0.6v/0.9v). 6.1.11 multi-function select register 2 ? index 29h (powered by vbat clk_tune_en = 0) bit name r/w default description 7 gpio17_en r/w 0 cpu_pwgd/gpio17 function select. 0: the pin function is cpu_pwgd. 1: the pin function is gpio17. 6 gpio16_en* r/w 1 gpio16/led_vcc function select. 0: the pin function is led_vcc. 1: the pin function is gpio16. this bit is powered by vbat. 5 gpio15_en r/w 1 gpio15/led_vsb/alert# function select. {led_vsb_en, gpio15_en} 1x: the pin function is led_vsb. 01: the pin function is gpio15. 00: the pin function is alert#. 4 gpio14_en r/w 0 wdtrst#/gpio14 function select. 0: the pin function is wdtrst#. 1: the pin function is gpio14. 3 gpio13_en r/w 1 s 0 p 5 _gate#/gpio13/beep function select. if s 0 p 5 _gate#_en is set , the ping function is s 0 p 5 _gate#, the pin function is determined by { s 0 p 5 _gate#_en, gpio13_en} 1x: the pin function is s 0 p 5 _gate#. 01: the pin function is gpio13. 00: the pin function is beep. 2 gpio12_en r/w 1 gpio12/ rstcon#/fanctl1 function select. 0: the pin function is fanctl1. 1: the pin function is gpio12.
oct., 2011 v0.19p 59 F71869A 1 gpio11_en r/w 1 gpio11/pcirst5#/sda function select. if ibx_alt_en is set , the ping f unction is sda, otherwise the pin function is determined by this bit: 0: the pin function is pcirst5#. 1: the pin function is gpio11. 0 gpio10_en r/w 1 gpio10/pcirst4#/scl function select. if ibx_alt_en is set , the ping fu nction is scl, otherwise the pin function is determined by this bit: 0: the pin function is pcirst4#. 1: the pin function is gpio10. 6.1.12 wdt clock divisor high byte ? index 29h (powered by vbat, clk_tune_en = 1) bit name r/w default description 7 wdt_tune_star t w - write ?1? to this bit to start coun t internal 500khz period (10 times). 6-4 reserved - - reserved. 3-0 wdt_clk_div[11: 8] r/w 3h this is the high nibble of 12-bit divisor for wdt clock. the clock used for wdt is 10hz which is divided by internal 10khz clock. program this divisor to fine tune clock. 6.1.13 multi-function select register 3 ? index 2ah (powered by vbat, clk_tune_en = 0) bit name r/w default description 7 lpt_gp_en r/w 0 parallel port/gpio function select. 0: pin 100 ~ 116 functions as parallel port. 1: pin 100 ~ 116 functions as gpio6 and gpio7. 6 ibx_alt_en r/w 0 alternative ibx pin enable. 0: disable ibx alternative pins. 1: enable ibx alternative pins. see gpio11_en and gpio10_en for detail.
oct., 2011 v0.19p 60 F71869A 5 led_vsb_en r/w 0 gpio15/led_vsb/alert# function select. {led_vsb_en, gpio15_en} 1x: the pin function is led_vsb. 01: the pin function is gpio15. 00: the pin function is alert#. 4 rstcon_pin_en r/w 0 rstcon# enable register: 0: the pin function of gpio12/ rstcon#/fanctl1 is gpio12/ fanctl1 1: the pin function of gpio12/rstcon#/fanctl1 is rstcon#. 3 s 0p5 _gate# _en r/w 1 s 0p5 _gate#/gpio13/beep function select. if s 0 p 5 _gate#_en is set , the ping function is s 0p5 _gate#, the pin function is determined by { s 0p5 _gate#_en, gpio13_en} 1x: the pin function is s 0p5 _gate#. 01: the pin function is gpio13. 00: the pin function is beep. 2 fdc_gp_en r/w 1 set ?1? will disable fdc and change the fdc pins to gpios. 1 ur2_gp_en2 r/w 1 = 0 set pin5, 6 to be sout2 and sin2 = 1 will change pin5, 6 (sout2 and sin2) to gpios. set ur2_gp_en1 and ur2_gp_en2 will also disable uart2 i/o port. 0 ur2_gp_en1 r/w 1 = 0 will change pin 1, 2, 3, 126, 127 and 128 to be dtr2#, rts2#, dsr2#, dcd2#, ri2# and cts2#. = 1 will change pin 1, 2, 3, 126, 127 and 128 to be gpio. set ur2_gp_en1 and ur2_gp_en2 will also disable uart2 i/o port. 6.1.14 wdt clock divisor low byte ? index 2ah (powered by vbat, clk_tune_en = 1) bit name r/w default description 7-0 wdt_clk_div[7:0] r/w e7h this is the high nibble of 12-bit divisor for wdt clock. the clock used for wdt is 10hz which is divided by internal 10khz clock. program this divisor to fine tune clock.
oct., 2011 v0.19p 61 F71869A 6.1.15 multi-function select register 4 ? index 2bh (powered by vsb3v, clk_tune_en = 0) bit name r/w default description 7 gpio47_en r/w 0 pson#/gpio47 function select. 0: the pin function is pson#. 1: the pin function is gpio47. 6 gpio46_en r/w 0 psout#/gpio46 function select. 0: the pin function is psout#. 1: the pin function is gpio46. 5 gpio45_en r/w 0 psin#/gpio45 function select. 0: the pin function is psin#. 1: the pin function is gpio45. 4 gpio44_en r/w 0 atxpg_in/gpio44 function select. 0: the pin function is atxpg_in. 1: the pin function is gpio44. 3 gpio43_en r/w 1 gpio43/irrx function select. 0: the pin function is irrx. 1: the pin function is gpio43. 2 gpio42_en r/w 1 gpio42/irtx function select. 0: the pin function is irtx. 1: the pin function is gpio42. 1 gpio41_en r/w 1 fanctrl3/gpio41 function select. 0: the pin function is fanctrl3. 1: the pin function is gpio41. 0 gpio40_en r/w 1 fanin3/gpio40 function select. 0: the pin function is fanin3. 1: the pin function is gpio40. 6.1.16 wdt clock fine tune count ? index 2bh (powered by vsb3v, clk_tune_en = 1) bit name r/w default description 7 wdt_tune_st w - this bit will be one if the counting action is in process. 6-4 reserved - - reserved.
oct., 2011 v0.19p 62 F71869A 3-0 clk_tune_cnt[1 1:8] r/w - this is the high nibble of 12-bit count for wdt clock fine tune. hardware use 48mhz clock to count the internal 500khz clock 10 times. the ideal value will be 960. the error is used to calculate the divisor for wdt clock. 6.1.17 multi-function select register 5 ? index 2ch (powered by i_vsb3v, clk_tune_en = 0) bit name r/w default description 7 tsi_pin60_en r/w 0 enable pin 60 sda function. 0: the pin function is gpio11/pci_rst5#. 1: the pin function is sda. 6 tsi_pin59_en r/w 0 enable pin 59 scl function. 0: the pin function is gpio10/pci_rst4#. 1: the pin function is scl. 5 tsi_pin58_en r/w 0 enable pin 58 sda function. 0: the pin function is peci. 1: the pin function is sda. 4 tsi_pin57_en r/w 0 enable pin 57 scl function. 0: the pin function is cir_led#. 1: the pin function is scl. 3 gpio03_en r/w 0 cirrx#/gpio03 function select. 0: the pin function is cirrx#. 1: the pin function is gpio03. 2 gpio02_en r/w 0 cirtx#/gpio02function select. 0: the pin function is cirtx#. 1: the pin function is gpio02. 1 gpio01_en r/w 0 cirwb#/gpio01 function select. 0: the pin function is cirwb#. 1: the pin function is gpio01. 0 reserved r/w 0 reserved 6.1.18 wdt clock fine tune count ? index 2ch (powered by vsb3v, clk_tune_en = 1) bit name r/w default description
oct., 2011 v0.19p 63 F71869A 7-0 clk_tune_cnt[7 :0] r/w - this is the high nibble of 12-bit count for wdt clock fine tune. hardware use 48mhz clock to count the internal 500khz clock 10 times. the ideal value will be 960. the error is used to calculate the divisor for wdt clock. 6.1.19 wakeup control register ? index 2dh (powered by vbat) bit name r/w default description 7 slot_pwr_sel r/w 0 0: slotocc# is pull-up to vsb3v. 1: slotocc# is pull-up to vbat. 6 vsbok_hys_dis r/w 0 set ?1? to disable vsbok hysteresis. 5 vsbok_level _sel r/w 1 0: vsb3v power good level is 3. 05v and not good level is 2.95v. 1: vsb3v power good level is 2.8v and not good level is 2.5v. by vsbok_hys_dis and vsbok_lvl_sel, rsmrst# falling edge could be determined: 00: when vsb3v is lower than 2.95v. 01: when vsb3v is lower than 2.5v. 10: when vsb3v is lower than 3.05v. 11: when vsb3v is lower than 2.8v. 4 key_sel_add r/w 0 this bit is added to add more wakeup key function. 3 wakeup_en r/w 1 0: disable keyboard/mouse wake up. 1: enable keyboard/mouse wake up.
oct., 2011 v0.19p 64 F71869A 2-1 key_sel r/w 00 this registers select the keyboar d wake up key. accompanying with key_sel_add, there are eight wakeup keys: key_sel_add key_sel wakeup key 0 00 ctrl + esc 0 01 ctrl + f1 0 10 ctrl + space 0 11 any key 1 00 windows wakeup 1 01 windows power 1 10 ctrl + alt + space 1 11 space 0 mo_sel r/w 0 this register selects the mouse wake up key. 0: wake up by click. 1: wake up by click and movement. 6.2 fdc registers (cr00) 6.2.1 fdc device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 fdc_en r/w 1 0: disable fdc. 1: enable fdc. 6.2.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 03h the m sb of fdc base address. 6.2.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w f0h the lsb of fdc base address.
oct., 2011 v0.19p 65 F71869A 6.2.4 irq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selfdcirq r/w 06h select the irq channel for fdc. 6.2.5 dma channel select register ? index 74h bit name r/w default description 7-3 reserved - - reserved. 2-0 selfdcdma r/w 010 select the dma channel for fdc. 6.2.6 fdd mode register ? index f0h bit name r/w default description 7 fdc_sw_pd r/w 0 write ?1? to software power down fdc. 6-5 reserved - - reserved. 4 fdc_sw_wp r/w 0 write ?1? to this bit will force fd c to write protect. otherwise, write protect is controlled by hardware pin wp#. 3-2 if_mode r/w 11 00: model 30 mode. 01: ps/2 mode. 10: reserved. 11: at mode (default). 1 fdmamode r/w 1 0: enable burst mode. 1: non-busrt mode (default). 0 en3mode r/w 0 0: normal floppy mode (default). 1: enhanced 3-mode fdd. 6.2.7 fdd drive type register ? index f2h bit name r/w default description 7-2 reserved - - reserved. 1-0 fdd_type r/w 11 fdd drive type. 6.2.8 fdd selection register ? index f4h bit name r/w default description 7-5 reserved - - reserved.
oct., 2011 v0.19p 66 F71869A 4-3 fdd_drt r/w 00 data rate table select, refer to table a. 00: select regular drives and 2.88 format. 01: 3-mode drive. 10: 2 mega tape. 11: reserved. 2 reserved - - reserved. 1-0 fdd_dt r/w 00 drive type select, refer to table b. table a data rate table select data rate selected data rate densel fdd_drt[1] fdd_drt[0] datarate1 datarate0 mfm fm 0 0 500k 250k 1 0 1 300k 150k 0 1 0 250k 125k 0 0 0 1 1 1meg --- 1 0 0 500k 250k 1 0 1 500k 250k 0 1 0 250k 125k 0 0 1 1 1 1meg --- 1 0 0 500k 250k 1 0 1 2meg --- 0 1 0 250k 125k 0 1 0 1 1 1meg --- 1 table b drive type fdd_dt1 fdd_dt0 drvden0 remark 0 0 densel 4/2/1 mb 3.5? 2/1 mb 5.25? 1/1.6/1 mb 3.5? ( 0 1 datarate1 1 0 densel# 1 1 datarate0
oct., 2011 v0.19p 67 F71869A 6.3 uart1 registers (cr01) 6.3.1 uart 1 device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 ur1_en r/w 1 0: disable uart 1. 1: enable uart 1. 6.3.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 03h the msb of uart 1 base address. 6.3.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w f8h the lsb of uart 1 base address. 6.3.4 irq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selur1irq r/w 4h select t he irq channel for uart 1. 6.3.5 rs485 enable register ? index f0h bit name r/w default description 7-6 reserved - - reserved. 5 rs485_inv - - write ?1? will invert the rts# if rs485_en is set. 4 rs485_en r/w 0 0: rs232 driver. 1: rs485 driver. rts# drive high when transmitting data, otherwise is kept low. 3-0 reserved - - reserved.
oct., 2011 v0.19p 68 F71869A 6.4 uart2 registers (cr02) 6.4.1 uart 2 device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 ur2_en r/w 1 0: disable uart 2. 1: enable uart 2. 6.4.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 02h the msb of uart 2 base address. 6.4.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w f8h the lsb of uart 2 base address. 6.4.4 irq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selur2irq r/w 3h select t he irq channel for uart 2. 6.4.5 rs485 enable register ? index f0h bit name r/w default description 7-6 reserved - - reserved. 5 rs485_inv - - write ?1? will invert the rts# if rs485_en is set. 4 rs485_en r/w 0 0: rs232 driver. 1: rs485 driver. rts# drive high when transmitting data, otherwise is kept low. 3 rxw4c_ir r/w 0 0: no reception delay when sir is changed form tx to rx. 1: reception delays 4 characters time when sir is changed form tx to rx. 2 txw4c_ir r/w 0 0: no transmission delay when sir is changed form rx to tx. 1: transmission delays 4 characters time when sir is changed form rx to tx. 1-0 reserved - - reserved.
oct., 2011 v0.19p 69 F71869A 6.4.6 sir mode control register ? index f1h bit name r/w default description 7 reserved - - reserved. 6 reserved - - reserved. 5 reserved - - reserved. 4-3 irmode r/w 00 00: disable ir function. 01: disable ir function. 10: irda function, active pulse is 1.6us. 11: irda function, active pulse is 3/16 bit time. 2 hduplx r/w 1 0: sir is in full duplex mode for loopback test. txw4c_ir and rxw4c_ir are of no use. 1: sir is in half duplex mode. 1 txinv_ir r/w 0 0: irtx is in normal condition. 1: inverse the irtx. 0 rxinv_ir r/w 0 0: irrx is in normal condition. 1: inverse the irrx. 6.5 parallel port register (cr03) 6.5.1 parallel port device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 prt_en r/w 1 0: disable parallel port. 1: enable parallel port. 6.5.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 03h the msb of parallel port base address. 6.5.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w 78h the lsb of parallel port base address. 6.5.4 irq channel select register ? index 70h bit name r/w default description 7-5 reserved - - reserved. 3-0 selprtirq r/w 7h select the irq channel for parallel port.
oct., 2011 v0.19p 70 F71869A 6.5.5 dma channel select register ? index 74h bit name r/w default description 7-5 reserved - - reserved. 4 ecp_dma_mode r/w 0 0: non-burst mode dma. 1: enable burst mode dma. 3 reserved - - reserved. 2-0 selprtdma r/w 011 select the dma channel for parallel port. 6.5.6 prt mode select register ? index f0h bit name r/w default description 7 spp_irq_mode r/w 0 interrupt mode in non-ecp mode. 0: level mode. 1: pulse mode. 6-3 ecp_fifo_thr r/w 1000 ecp fifo threshold. 2-0 prt_mode r/w 010 000: standard and bi-direction (spp) mode. 001: epp 1.9 and spp mode. 010: ecp mode (default). 011: ecp and epp 1.9 mode. 100: printer mode. 101: epp 1.7 and spp mode. 110: reserved. 111: ecp and epp1.7 mode. 6.6 hardware monitor registers (cr04) 6.6.1 hardware monitor configuration registers ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 hm_en r/w 1 0: disable hardware monitor. 1: enable hardware monitor. 6.6.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 02h the msb of ha rdware monitor base address.
oct., 2011 v0.19p 71 F71869A 6.6.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w 95h the lsb of hardware monitor base address. 6.6.4 irq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selhmirq r/w 0000 select the irq channel for hardware monitor. before the device registers, the following is a register map order which shows a summary of all registers. please refer each one register if you want more detail information. register cr01 ~ cr03 ? configuration registers register cr0a ~ cr0f ? peci/tsi control register register cr10 ~ cr37 ? voltage setting register register cr40 ~ cr4f ? peci 3.0 command and register register cr60 ~ cr8e ? temperature setting register register cr90 ~ crdf ? fan control setting register ? fan1 detail setting cra0 ~ craf ? fan2 detail setting crb0 ~ crbf ? fan3 detail setting crc0 ~ crcf 6.6.5 configuration register ? index 01h bit name r/w default description 7-3 reserved - 0 reserved 2 power_down r/w 0 hardware monitor function power down. 1 fan_start r/w 1 set one to enable startup of fan monitoring operations; a zero puts the part in standby mode. 0 v_t_start r/w 1 set one to enable startup of temperature and voltage monitoring operations; a zero puts the part in standby mode. 6.6.6 configuration register ? index 02h bit name r/w default description 7 reserved r/w 0 dummy register. 6 case_beep_en r/w 0 0: disable case open event output via beep. 1: enable case open event output via beep.
oct., 2011 v0.19p 72 F71869A 5-4 ovt_mode r/w 0 00: the ovt# will be low active level mode. 01: the ovt# will be low pulse mode. 10: the ovt# will indicate by 1hz led function. 11: the ovt# will indicate by (400/800hz) beep output. 3 reserved r/w 0 dummy register. 2 case_smi_en r / w 0 0: disable case open event output via pme. 1: enable case open event output via pme. 1-0 alert_mode r/w 0 00: the alert# will be low active level mode. 01: the alert# will be high active level mode. 10: the alert# will indicate by 1hz led function. 11: the alert# will indicate by (400/800hz) beep output. 6.6.7 configuration register ? index 03h bit name r/w default description 7-1 reserved r/w 0 reserved 0 case_sts r/w 1 case open event status. write 1 to clear if case open event cleared. (this bit is powered by vbat.) 6.6.8 new tsi mode enable register ? index 07h bit name r/w default description 7-1 reserved - 0 reserved 0 new_tsi_mode r/w 0 set this bit to enable tsi new mode. please check cr0a for more detail. 6.6.9 configuration register ? index 08h bit name r/w default description 7-1 smbus_addr r/w 7?h26 when amd tsi or intel pch smbus is enabled, this byte is used as smbus_addr. smbus_addr[7:1] is the slave address sent by the embedded master to fetch the temperature. 0 reserved - - reserved 6.6.10 configuration register ? index 09h bit name r/w default description 7 - 1 i2c_addr r /w 0 i2c_addr[7:1] is the slave addres s sent by the embedded master when using a block write command 0 reserved r/w 0 reserved
oct., 2011 v0.19p 73 F71869A 6.6.11 configuration register ? index 0ah bit name r/w default description 7 beta_en r/w 0 0: disable the t1 beta compensation. 1: enable the t1 beta compensation. 6 intel_model r/w 1 0: amd model. 1: intel model. 5 reserved - 0 reserved. 4 mxm_mode r/w 0 reserved 3-2 vtt_sel r/w 0 peci (vtt) voltage select. 00: vtt is 1.23v 01: vtt is 1.13v 10: vtt is 1.00v 11: vtt is 1.00v 1 tsi_en r/w 0 0: disable the tsi function via peci / cir_led / pci_rst4# / pci_rst5# pins. 1: enable the tsi function via peci / cir_led / pci_rst4# / pci_rst5# pins. this bit accompanies with in tel_model, ibx_alt_en, peci_en, and it determines the availability of amd tsi, intel pch smbus, or peci. setting (cr07[0]-- new_tsi_mode = 0) intel _mod el (cr0 a, bit6) tsi_ en (cr0 a, bit1) peci_ en (cr0a, bit0) ibx_alt_ en (cr2a, bit6 in global configurati on register) pe ci amd tsi intel pch smbus 0 0 x x n n n 0 1 x x n y n 1 0 1 x y n n 1 1 1 1 y n y 1 1 0 x n n y setting (cr07[0]-- new_tsi_mode = 1) intel _mod el (cr0 a, bit6) tsi_ en (cr0 a, bit1) peci_ en (cr0a, bit0) ibx_alt_ en (cr2a, bit6 in global configurati on register) pe ci amd tsi intel pch smbus 0 0 x x n n n 0 1 x x n n y 1 0 1 x y n n 1 1 1 1 y y n 1 1 0 x n y n 0 peci_en r/w 0 0: disable peci function via peci pin 1: enable peci function via peci pin
oct., 2011 v0.19p 74 F71869A 6.6.12 configuration register ? index 0bh bit name r/w default description 7-4 cpu_sel r/w 0 select the intel cpu socket number. 0000: no cpu presented. peci host will use ping() command to find cpu address. 0001: cpu is in socket 0, i.e. peci address is 0x30. 0010: cpu is in socket 0, i.e. peci address is 0x31. 0100: cpu is in socket 0, i.e. peci address is 0x32. 1000: cpu is in socket 0, i.e. peci address is 0x33. others are reserved. 3-1 reserved - 0 reserved. 0 domain1_en r/w 0 if the cpu is selected as dual core. set this register 1 to read the temperature of domain1. 6.6.13 configuration register ? index 0ch bit name r/w default description 7-0 tcc_temp r/w 8?h55 tcc activation temperature. when peci is enabled, the absolute value of cpu temperature is calculated by the equation: cpu_temp = tcc_temp + peci reading. the range of this register is -128 ~ 127. 6.6.14 configuration register ? index 0dh bit name r/w default description 7-0 tsi_offset r/w 8?h00 tsi temperature offset for cpu when amd tsi or intel pch smbus is enabled, this byte is used as the offset to be added to the temperature reading of cpu. 6.6.15 configuration register ? index 0fh bit name r/w default description 7-6 reserved - 0 reserved. 5 reserved r/w 1 dummy register 4-2 reserved - 0 reserved. 1-0 dig_rate_sel r/w 0 digital temperatures monitoring rate for peci, amd tsi, or intel pch smbus. the rate is calculated by 20hz/(dig_rate_sel + 1).
oct., 2011 v0.19p 75 F71869A 6.6.16 voltage-protect shut down enable register ? index 10h bit name r/w default description 7 reserved - 0 reserved. 6 v6_vp_en r/w 0 voltage-protect shut down enable for vin6 5 v5_vp_en r/w 0 voltage-protect enable for vin5 4-1 reserved - 0 reserved 0 v0_vp_en r/w 0 voltage-protect shut down enable for 3vcc 6.6.17 voltage-protect status register (powered by vbat) ? index 11h bit name r/w default description 7-6 reserved - 0 reserved. 0 v_exc_vp r/w c 0 this bit is voltage-protect status. on ce one of the monitored voltages (3vcc, vin5, vin6) over its rela ted over-voltage limits or under its related under-voltage limits and if the related voltage-protect shut down enable bit is set, this bit will be se t to 1. write a 1 to this bit will clear it to 0. (this bit is powered by vbat) 6.6.18 voltage-protect configuration register (powered by vbat) ? index 12h bit name r/w default description 7-4 reserved - - reserved. 3-2 pu_time r/w 2?h1 pson# de-active time select in alarm mode of voltage protection. 00: pson# tri-state 0.5 sec and then inverted of s3# when over voltage or under voltage occurs. 01: pson# tri-state 1 sec and then inverted of s3# when over voltage or under voltage occurs. 10: pson# tri-state 2 sec and then inverted of s3# when over voltage or under voltage occurs. 11: pson# tri-state 4 sec and then inverted of s3# when over voltage or under voltage occurs. 1-0 vp_en_delay r/w 2?h2 vp_en_delay could set the delay time to start voltage protecting after vdd power is ok when ovp_mode is 1. (ovp_mode is strapped by rts1# pin) 00: bypass 01: 50ms 10: 100ms 11: 200ms
oct., 2011 v0.19p 76 F71869A 6.6.19 v oltage protection power good select register ? index 3fh bit name r/w default description 7-1 reserved -- 0 reserved 0 ovp_rst_sel r/w 0 0: ovp/uvp power good signal is vdd3vok (vcc3v > 2.8v) 1: ovp/uvp power good signal is pwrok. ovp/uvp function wont? star t detecting until power good. 6.6.20 voltage reading and limit ? index 20h- 37h address attribute default value description 20h r -- 3vcc reading. the unit of reading is 8mv. 21h r -- vin1 (vcore) reading. the unit of reading is 8mv. 22h r -- vin2 reading. the unit of reading is 8mv. 23h r -- vin3 reading. the unit of reading is 8mv. 24h r -- vin4 reading. the unit of reading is 8mv. 25h r -- vin5 reading. the unit of reading is 8mv. 26h r -- vin6 reading. the unit of reading is 8mv. 27h r -- vsb3v reading. the unit of reading is 8mv. 28h r -- vbat reading. the unit of reading is 8mv. 29h r ff reserved 2dh ro -- fan1 present fan duty reading 2eh ro -- fan2 present fan duty reading 2fh ro -- fan3 present fan duty reading 30h r/w 7a 3vcc under-voltage limit (v0_uvv_limit). the unit is 9mv (this byte is powered by vbat) 31h r/w d7 3vcc over-voltage limit (v0_ovv_limit) . the unit is 9mv. (this byte is powered by vbat.) 32~35h r ff reserved 36h r/w c9 vin5 over-voltage limit (v5_ovv_limi t). the unit is 9mv. (this byte is powered by vbat.) 37h r/w c8 vin6 over-voltage limit (v6_ovv_limi t). the unit is 9mv. (this byte is powered by vbat.) 38h r/w 75 vin5 under-voltage limit (v5_uvv_limi t). the unit is 9mv (this byte is powered by vbat) 39h r/w 85 vin6 under-voltage limit (v6_uvv_limi t). the unit is 9mv (this byte is powered by vbat) 3fh w 00 write bit 0 to ?1? to select ovp start monitor after pwrok ready.
oct., 2011 v0.19p 77 F71869A peci 3.0 command and register 6.6.21 peci configuration register ? index 40h bit name r/w default description 7 r diamsr_cmd_e n r/w 0 when peci temperature monitoring is enabled, set this bit 1 will generate a rdiamsr() command before a gettemp() command. 6 c3_update_en r/w 0 if rdiamsr_cmd_en is not set to 1, the temperature data is not allowed to be updated when the co mpletion code of rdiamsr() is 0x82. 5-4 reserved r - reserved 3 c3_ptemp_en r/w 0 set this bit 1 to enable updateing positive value of temperature if the completion code of rdiamsr() is 0x82. 2 c0_ptemp_en r/w 0 set this bit 1 to enable updating positive value of temperature if the completion code of rdiamsr() is not 0x82 and the bit 8 of completion code is not 1 either. 1 c3_all0_en r/w 0 set this bit 1 to enable updating temperature value 0x0000 if the completion code of rdiamsr() is 0x82. 0 c0_all0_en r/w 0 set this bit 1 to enable updating temperature value 0x0000 if the completion code of rdiamsr() is not 0x82 and the bit 8 of completion code is not 1 either. 6.6.22 peci master control register ? index 41h bit name r/w default description 7 peci_cmd_star t w - write 1 to this bit to start a peci command when using as a peci master. (peci_pending must be set to 1) 6-5 reserved r - reserved 4 peci_pending r/w 0 set this bit 1 to stop monitoring peci temperature. 3 reserved r - reserved 2-0 peci_cmd r/w 3?h0 peci command to be used by peci master. 000: ping() 001: getdib() 010: gettemp() 011: rdiamsr() 100: rdpkgconfig() 101: wrpkgconfig() others: reserved 6.6.23 peci master status register ? index 42h bit name r/w default description 7-3 reserved r - reserved 2 abort_fcs r/w c - this bit is the abort fcs status of peci master commands. write this bit 1 or read this byte will clear this bit to 0. 1 peci_fcs_err r/w c - this bit is the fcs error status of peci master commands. write this bit 1 or read this byte will clear this bit to 0. 0 peci_finish r/w c - this bit is the command finish status of peci master commands. write this bit 1 or read this by te will clear this bit to 0.
oct., 2011 v0.19p 78 F71869A 6.6.24 peci master data0 register ? index 43h bit name r/w default description 7-0 peci_data0 r/w 0 for rdiamsr(), rdpkgconfig() and wrpkgconfig() command, this byte represents ?host id[7:1] & retry[0]?. please refer to peci interface specification for more detail. 6.6.25 peci master data1 register ? index 44h bit name r/w default description 7-0 peci_data1 r/w 0 for rdiamsr() , this byte represents ?processor id?. for rdpkgconfig() and wrpkgconfig() , this byte represents ?index?. please refer to peci interface specification for more detail. 6.6.26 peci master data2 register ? index 45h bit name r/w default description 7-0 peci_data2 r/w 0 for rdiamsr(), this byte is the least significant byte of ?msr address?. for rdpkgconfig() and wrpkgconfig(), this byte is the least significant byte of ?parameter?. please refer to peci interface specification for more detail. 6.6.27 peci master data3 register ? index 46h bit name r/w default description 7-0 peci_data3 r/w 0 for rdiamsr(), this byte is the most significant byte of ?msr address?. for rdpkgconfig() and wrpkgconfig(), this byte is the most significant byte of ?parameter?. please refer to peci interface specification for more detail. 6.6.28 peci master data4 register ? index 47h bit name r/w default description 7-0 peci_data4 r/w 0 for getdib() , this byte represents ?device info? for gettemp(), this byte represent s the least significant byte of temperature. for rdiamsr() and rdpkgconfig() , th is byte is ?completion code?. for wrpkgconfig(), this byte represents ?data[7:0]? 6.6.29 peci master data5 register ? index 48h bit name r/w default description 7-0 peci_data5 r/w 0 for getdib() , this byte represents ?revision number? for gettemp(), this byte represent s the most significant byte of temperature. for rdiamsr() and rdpkgconfig() , this byte represents ?data[7:0]? for wrpkgconfig(), this byte represents ?data[15:8]?
oct., 2011 v0.19p 79 F71869A 6.6.30 peci master data6 register ? index 49h bit name r/w default description 7-0 peci_data6 r/w 0 for rdiamsr() and rdpkgconfig() , this byte represents ?data[15:8]?. for wrpkgconfig(), this byte represents ?data[23:16]? 6.6.31 peci master data7 register ? index 4ah bit name r/w default description 7-0 peci_data7 r/w 0 for rdiamsr() and rdpkgconfig() , this byte represents ?data[23:16]?. for wrpkgconfig(), this byte represents ?data[31:24]? 6.6.32 peci master data8 register ? index 4bh bit name r/w default description 7-0 peci_data8 r/w 0 for rdiamsr() and rdpkgconfig() , this byte represents ?data[31:24]?. for wrpkgconfig(), this byte represents ?aw fcs? 6.6.33 peci master data9 register ? index 4ch bit name r/w default description 7-0 peci_data9 r/w 0 for rdiamsr(), this byte represents ?data[39:32]?. for wrpkgconfig(), this byte represents ?completion code? 6.6.34 peci master data10 register ? index 4dh bit name r/w default description 7-0 peci_data10 r/w 0 for rdiamsr(), th is byte represents ?data[47:40]?. 6.6.35 peci master data11 register ? index 4eh bit name r/w default description 7-0 peci_data11 r/w 0 for rdiamsr(), th is byte represents ?data[55:48]?. 6.6.36 peci master data12 register ? index 4fh bit name r/w default description 7-0 peci_data12 r/w 0 for rdiamsr(), th is byte represents ?data[63:56]?. temperature setting 6.6.37 temperature pme# enable register ? index 60h bit name r/w default description 7 en_ t3_ovt_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp3 exceeds ovt limit setting. 6 en_ t2_ovt_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp2 exceeds ovt setting.
oct., 2011 v0.19p 80 F71869A 5 en_ t1_ovt_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp1 exceeds ovt setting. 4 reserved r/w 0 reserved 3 en_ t3_exc_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp3 exceeds high limit setting. 2 en_ t2_exc_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp2 exceeds high limit setting. 1 en_ t1_exc_pme r/w 0 if set this bit to 1, pme# signal will be issued when temp1 exceeds high limit setting. 0 reserved r/w 0 reserved 6.6.38 temperature interrupt status register ? index 61h bit name r/w default description 7 t3_ovt_sts r/w 0 this bit gets 1 to indicate temp3 temperature sensor has exceeded ovt limit or below the ?ovt limit ?hysteresis?. write 1 to clear this bit, and write 0 to ignore. 6 t2_ovt _sts r/w 0 this bit gets 1 to indicate temp2 temperature sensor has exceeded ovt limit or below the ?ovt limit ?hysteresis?. write 1 to clear this bit, write 0 to ignore. 5 t1_ovt _sts r/w 0 this bit gets 1 to indicate temp1 temperature sensor has exceeded ovt limit or below the ?ovt limit ?hysteresis?. write 1 to clear this bit, write 0 to ignore. 4 reserved r/w 0 reserved 3 t3_exc _sts r/w 0 this bit gets 1 to indicate temp3 temperature sensor has exceeded high limit or below the ?high limit ?hysteresis?. write 1 to clear this bit, write 0 to ignore. 2 t2_exc _sts r/w 0 this bit gets 1 to indicate temp2 temperature sensor has exceeded high limit or below the ?high limit ?hysteresis? limit. write 1 to clear this bit, write 0 to ignore. 1 t1_exc _sts r/w 0 this bit gets 1 to indicate temp1 temperature sensor has exceeded high limit or below the ?high limit ?hysteresis? limit. write 1 to clear this bit, write 0 to ignore. 0 reserved r/w 0 reserved
oct., 2011 v0.19p 81 F71869A 6.6.39 temperature real time status register ? index 62h bit name r/w default description 7 t3_ovt r/w 0 set when the temp3 exceeds the ovt limit. clear when the temp3 is below the ?ovt limit ?hysteresis? temperature. 6 t2_ovt r/w 0 set when the temp2 exceeds the ovt limit. clear when the temp2 is below the ?ovt limit ?hysteresis? temperature. 5 t1_ovt r/w 0 set when the temp1 exceeds the ovt limit. clear when the temp1 is below the ?ovt limit ?hysteresis? temperature. 4 reserved r/w 0 reserved 3 t3_exc r/w 0 set when the temp3 exceeds the high limit. clear when the temp3 is below the ?high limit ?hysteresis? temperature. 2 t2_exc r/w 0 set when the temp2 exceeds the high limit. clear when the temp2 is below the ?high limit ?hysteresis? temperature. 1 t1_exc r/w 0 set when the temp1 exceeds the high limit. clear when the temp1 is below the ?high limit ?hysteresis? temperature. 0 reserved r/w 0 reserved 6.6.40 temperature beep enable register ? index 63h bit name r/w default description 7 en_t3_ ovt_beep r/w 0 if set this bit to 1, beep signal will be issued when temp3 exceeds ovt limit setting. 6 en_ t2_ ovt_beep r/w 0 if set this bit to 1, beep signal will be issued when temp2 exceeds ovt limit setting. 5 en_ t1_ ovt_beep r/w 0 if set this bit to 1, beep signal will be issued when temp1 exceeds ovt limit setting. 4 reserved r/w 0 reserved 3 en_ t3_exc_beep r/w 0 if set this bit to 1, beep signal will be issued when temp3 exceeds high limit setting. 2 en_ t2_exc_beep r/w 0 if set this bit to 1, beep signal will be issued when temp2 exceeds high limit setting. 1 en_ t1_exc_beep r/w 0 if set this bit to 1, beep signal will be issued when temp1 exceeds high limit setting. 0 reserved r/w 0 reserved
oct., 2011 v0.19p 82 F71869A 6.6.41 t1 ovt and high limit temperature select register ? index 64h bit name r/w default description 7-6 reserved r/w 0 reserved 5-4 ovt_temp_sel r/w 0 select the source temperature for t1 ovt limit. 0: select t1 to be compared to temperature 1 ovt limit. 1: select cpu temperature fr om peci to be compared to temperature 1 ovt limit. 2: select cpu temperature from amd tsi or intel pch smbus to be compared to temperature 1 ovt limit. 3: select the max temperature from intel pch smbus to be compared to temperature 1 ovt limit. 3-2 reserved r/w 0 reserved 1-0 high_ temp_sel r/w 0 select the source temperature for t1 high limit. 0: select t1 to be compared to temperature 1 high limit. 1: select cpu temperature fr om peci to be compared to temperature 1 high limit. 2: select cpu temperature from amd tsi or intel pch smbus to be compared to temperature 1 high limit. 3: select the max temperature from intel pch smbus to be compared to temperature 1 high limit. 6.6.42 ovt and alert output enable register 1 ? index 66h bit name r/w default description 7 en_t3_alert r 0 enable temperature 3 alert event (a sserted when temperature over high limit) 6 en_t2_alert r 0 enable temperature 2 alert event (a sserted when temperature over high limit) 5 en_t1_alert r 0 enable temperature 1 alert event (a sserted when temperature over high limit) 4 reserved r 0 reserved. 3 en_t3_ovt r/w 0 enable over temperat ure (ovt) mechanism of temperature3. 2 en_t2_ovt r/w 0 enable over temperat ure (ovt) mechanism of temperature2. 1 en_t1_ovt r/w 1 enable over temperat ure (ovt) mechanism of temperature1. 0 reserved r 0h reserved.
oct., 2011 v0.19p 83 F71869A 6.6.43 reserved ? index 67~69h bit name r/w default description 7-0 reserved - - reserved 6.6.44 temperature sensor type register ? index 6bh bit name r/w default description 7-4 reserved ro 0 reserved 3 t3_mode r/w 1 0: temp3 is connected to a thermistor 1: temp3 is connected to a bjt.(default) 2 t2_mode r/w 1 0: temp2 is connected to a thermistor. 1: temp2 is connected to a bjt. (default) 1 t1_mode r/w 1 0: temp1 is connected to a thermistor 1: temp1 is connected to a bjt.(default) 0 reserved r 0 reserved 6.6.45 temp1 limit hyst ersis select register ? index 6ch bit name r/w default description 7-4 temp1_hys r/w 4h limit hysteresis. (0~15 degree c) temperature and below the (boundary ? hysteresis ). 3-0 reserved r 0h reserved 6.6.46 temp2 and temp3 limit hystersis select register ? index 6dh bit name r/w default description 7-4 temp3_hys r/w 2h limit hysteresis. (0~15 degree c) temperature and below the ( boundary ? hysteresis ). 3-0 temp2_hys r/w 4h limit hysteresis. (0~15 degree c) temperature and below the ( boundary ? hysteresis ). 6.6.47 diode open status register ? index 6fh bit name r/w default description 7-6 reserved r - reserved 5 peci_open r - when peci interface is enabled, ?1? indicates an error code (0x0080 or 0x0081) is received from peci slave. 4 tsi_open r - when tsi interface is enabled, ?1? indicates the error of not receiving nack bit or a timeout occurred. 3 t3_diode_open r - ?1? indicates external diode 3 is open 2 t2_diode_open r - ?1? indicates external diode 2 is open or short
oct., 2011 v0.19p 84 F71869A 1 t1_diode_open r - ?1? indicates external diode 1 is open or short 0 reserved r - reserved 6.6.48 temperature ? index 70h- 8dh address attribute default value description 70h reserved ffh reserved 71h reserved ffh reserved 72h r -- temperature 1 reading. the unit of reading is 1oc.at the moment of reading this register. 73h r -- reserved 74h r -- temperature 2 reading. the unit of reading is 1oc.at the moment of reading this register. 75h r -- reserved 76h r -- temperature 3 reading. the unit of reading is 1oc.at the moment of reading this register. 77-79h r -- reserved 7ah r -- the data of cpu temperature from digital interface after iir filter. (available if intel ibx or amd tsi interface is enabled) 7bh r -- the raw data of pch temperature from digital interface. (only available if intel ibx interface is enabled) 7ch r -- the raw data of mch read from digita l interface. (only available if intel ibx interface is enabled) 7dh r -- the raw data of maximum temperature between cpu/pch/mch from digital interface. (only ava ilable if intel ibx interface is enabled) 7eh r -- the data of cpu temperature from digital interface after iir filter. (only available if peci interface is enabled) 7fh reserved ffh reserved 80h reserved ffh reserved 81h reserved ffh reserved 82h r/w 64h temperature sensor 1 ovt limit. the unit is 1oc. 83h r/w 55h temperature sensor 1 high limit. the unit is 1oc. 84h r/w 64h temperature sensor 2 ovt limit. the unit is 1oc. 85h r/w 55h temperature sensor 2 high limit. the unit is 1oc. 86h r/w 55h temperature sensor 3 ovt limit. the unit is 1oc.
oct., 2011 v0.19p 85 F71869A 87h r/w 46h temperature sensor 3 high limit. the unit is 1oc. 88-8bh r -- reserved 8c~8dh r ffh reserved 6.6.49 temperature filter select register ? index 8eh bit name r/w default description 7-6 iir-queur3 r/w 1h the queue time for second filter to quickly update values. 00: 8 times. 01: 12 times. 10: 16 times. (default) 11: 24 times. 5-4 iir-queur2 r/w 1h the queue time for second filter to quickly update values. 00: 8 times. 01: 12 times. 10: 16 times. (default) 11: 24 times. 3-2 iir-queur1 r/w 1h the queue time for second filter to quickly update values. 00: 8 timers. 01: 12 times. 10: 16 times. (default) 11: 24 times. 1-0 iir-queur_dig r/w 1h the queue time for second filter to quickly update values. (for cpu temperature from peci or tsi interface) 00: 8 timers. 01: 12 times. 10: 16 times. (default) 11: 24 times. fan control setting 6.6.50 fan pme# enable register ? index 90h bit name r/w default description 7-3 reserved r 0 reserved 2 en_fan3_pme r/w 0 a one enables the corresponding interrupt status bit for pme# interrupt set this bit 1 to enable pme# function for fan3.
oct., 2011 v0.19p 86 F71869A 1 en_fan2_pme r/w 0 a one enables the corresponding interrupt status bit for pme# interrupt. set this bit 1 to enable pme# function for fan2. 0 en_fan1_pme r/w 0 a one enables the corresponding interrupt status bit for pme# interrupt. set this bit 1 to enable pme# function for fan1. 6.6.51 fan interrupt status register ? index 91h bit name r/w default description 7-3 reserved r 0 reserved 2 fan3_sts r/w -- this bit is set when the fan3 count exceeds the count limit. write 1 to clear this bit, write 0 will be ignored. 1 fan2_sts r/w -- this bit is set when the fan2 count exceeds the count limit. write 1 to clear this bit, write 0 will be ignored. 0 fan1_sts r/w -- this bit is set when the fan1 count exceeds the count limit. write 1 to clear this bit, write 0 will be ignored. 6.6.52 fan real time status register ? index 92h bit name r/w default description 7-3 reserved -- 0 reserved 2 fan3_exc r -- this bit set to high mean that fan3 count can?t meet expect count over than smi time(cr9f) or when duty not zero but fan stop over then 3 sec. 1 fan2_exc r -- this bit set to high mean that fan2 count can?t meet expect count over than smi time(cr9f) or when duty not zero but fan stop over then 3 sec. 0 fan1_exc r -- this bit set to high mean that fan1 count can?t meet expect count over than smi time(cr9f) or when duty not zero but fan stop over then 3 sec. 6.6.53 fan beep# enable register ? index 93h bit name r/w default description 7 full_with_ t3_en r/w 0 set one will enable fan to force full speed when t3 over high limit. 6 full_with_ t2_en r/w 0 set one will enable fan to force full speed when t2 over high limit.
oct., 2011 v0.19p 87 F71869A 5 full_with_ t1_en r/w 0 set one will enable fan to force full speed when t1 over high limit. 4 reserved - - reserved 3 reserved - - reserved. 2 en_fan3_ beep r/w 0 a one enables the corr esponding interrupt status bit for beep. 1 en_fan2_ beep r/w 0 a one enables the corr esponding interrupt status bit for beep. 0 en_fan1_ beep r/w 0 a one enables the corr esponding interrupt status bit for beep. 6.6.54 fan type select register ? index 94h fan_prog_sel = 0 bit name r/w default description 7-6 reserved - - reserved. 5-4 fan3_type r/w 2?b 0s 00: output pwm mode (push pull) to control fans. 01: use linear fan application circui t to control fan speed by fan?s power terminal. 10: output pwm mode (open drain) to control intel 4-wire fans. 11: reserved. bit 0 is power on trap by fanctrl3 0: fanctrl3 is pull up by external resistor. 1: fanctrl3 is pull down by internal 100k resistor. 3-2 fan2_type r/w 2?b 0s 00: output pwm mode (push pull) to control fans. 01: use linear fan application circui t to control fan speed by fan?s power terminal. 10: output pwm mode (open drain) to control intel 4-wire fans. 11: reserved. bit 0 is power on trap by fanctrl2 0: fanctrl2 is pull up by external resistor. 1: fanctrl2 is pull down by internal 100k resistor. 1-0 fan1_type r/w 2?b 0s 00: output pwm mode (push pull) to control fans. 01: use linear fan application circui t to control fan speed by fan?s power terminal. 10: output pwm mode (open drain) to control intel 4-wire fans. 11: reserved. bit 0 is power on trap by fanctrl1 0: fanctrl1 is pull up by external resistor. 1: fanctrl1is pull down by internal 100k resistor.
oct., 2011 v0.19p 88 F71869A s : register default values are decided by trapping. fan_prog_sel = 1 bit name r/w default description 7-0 fan1_base _temp r/w 0 this register is used to set the base temperature for fan1 temperature adjustment. the fan1 temperature is calculated according to the equation: tfan1 = tnow + (ta ? tb)*ct where tnow is selected by fan1_temp_sel_dig and fan1_temp_sel. tb is this register, ta is selected by tfan1_adj_sel and ct is selected by tfan1_adj_up_rate/tfan1_adj_dn_rate. to access this register, fan_prog_ sel(cr9f[7]) must set to ?1?. 6.6.55 fan1 temperature adjust rate register ? index 95h (fan_prog_sel = 1) bit name r/w default description 7 reserved - - reserved 6-4 tfan1_adj_up _rate 3?h0 this selects the weighting of the difference between ta and tb if ta is higher than tb. 3?h1: 1 (ct = 1) 3?h2: 1/2 (ct= 1/2) 3?h3: 1/4 (ct = 1/4) 3?h4: 1/8 (ct = 1/8) otherwise: 0 to access this byte, fan_pr og_sel must set to ?1?. 3 reserved - - reserved
oct., 2011 v0.19p 89 F71869A 2-0 tfan1_adj_dn _rate r/w 3?h0 this selects the weighting of the difference between ta and tb if ta is lower than tb. 3?h1: 1 (ct = 1) 3?h2: 1/2 (ct= 1/2) 3?h3: 1/4 (ct = 1/4) 3?h4: 1/8 (ct = 1/8) otherwise: 0 to access this byte, fan_pr og_sel must set to ?1?. 6.6.56 fan mode select register ? index 96h fan_prog_sel = 0 bit name r/w default description 7-6 reserved - - reserved 5-4 fan3_mode r/w 01 00: auto fan speed control. fan spee d will follow different temperature by different rpm defined in 0xc6-0xce. 01: auto fan speed control. fan spee d will follow different temperature by different duty cycle defined in 0xc6-0xce. 10: manual mode fan control. user can write expected rpm count to 0xc2-0xc3, and F71869A will adjus t duty cycle (pwm fan type) or voltage (linear fan type) to control fan speed automatically. 11: manual mode fan control. user can write expected duty cycle (pwm fan type) or voltage (linear fan type) to 0xc3, and F71869A will output this desired duty or voltage to control fan speed. 3-2 fan2_mode r/w 01 00: auto fan speed control. fan spee d will follow different temperature by different rpm defined in 0xb6-0xbe. 01: auto fan speed control. fan spee d will follow different temperature by different duty cycle (voltage) defined in 0xb6-0xbe. 10: manual mode fan control. user can write expected rpm count to 0xb2-0xb3, and F71869A will adjust duty cycle (pwm fan type) or voltage (linear fan type) to control fan speed automatically. 11: manual mode fan control, user can write expected duty cycle (pwm fan type) or voltage (linear fan type) to 0xb3, and F71869A will output this desired duty or voltage to control fan speed.
oct., 2011 v0.19p 90 F71869A 1-0 fan1_mode r/w 01 00: auto fan speed control. fan spee d will follow different temperature by different rpm defined in 0xa6-0xae. 01: auto fan speed control. fan spee d will follow different temperature by different duty cycle defined in 0xa6-0xae. 10: manual mode fan control, user can write expected rpm count to 0xa2-0xa3, and F71869A will auto c ontrol duty cycle (pwm fan type) or voltage (linear fan type) to control fan speed automatically. 11: manual mode fan control, user can write expected duty cycle (pwm fan type) or voltage (linear fan type) to 0xa3, and F71869A will output this desired duty or voltage to control fan speed. fan_prog_sel = 1 bit name r/w default description 7-3 reserved - - reserved 2-0 tfan1_adj_sel r/w 0h this selects which temperature to be used as ta for fan1 temperature adjustment. 000: peci (cr7eh) 001: t1 (cr72h) 010: t2 (cr74h) 011: t3 (cr76h) 100: digital t1 (cr7ah) 101: digital t1 (cr7bh) 110: digital t2 (cr7ch) 111: digital t3 (cr7dh) otherwise: ta will be 0. to access this register fa n_prog_sel must set to ?1?. 6.6.57 auto fan1 and fan2 boundary hystersis select register ? index 98h bit name r/w default description 7-4 fan2_hys r/w 4h boundary hysteresis. (0~15 degree c) segment will change when the temperature over the boundary temperature and below the ( boundary ? hysteresis ). 3-0 fan1_hys r/w 4h boundary hysteresis. (0~15 degree c) segment will change when the temperature over the boundary temperature and below the ( boundary ? hysteresis ).
oct., 2011 v0.19p 91 F71869A 6.6.58 auto fan3 boundary hystersis select register ? index 99h bit name r/w default description 7-4 reserved - - reserved. 3-0 fan3_hys r/w 2h boundary hysteresis. (0~15 degree c) segment will change when the temperature over the boundary temperature and below the ( boundary ? hysteresis ). 6.6.59 fan3 control register ? index 9ah bit name r/w default description 7 reserved - - reserved. 6 freq_sel_add3 r/w 0 this bit and fan3_pwm_freq_sel are used to select fan3 pwm frequency. new_freq_sel3 = { freq_sel_add3, fan3_pwm_freq_sel} 00: 23.5 khz 01: 220 hz 10: 11.75 khz 11: 5.875 khz 5 freq_sel_add2 r/w 0 this bit and fan2_pwm_freq_sel are used to select fan2 pwm frequency. new_freq_sel2 = { freq_sel_add2, fan2_pwm_freq_sel} 00: 23.5 khz 01: 220 hz 10: 11.75 khz 11: 5.875 khz 4 freq_sel_add1 r/w 0 this bit and fan1_pwm_freq_sel are used to select fan1 pwm frequency. new_freq_sel1 = { freq_sel_add1, fan1_pwm_freq_sel} 00: 23.5 khz 01: 220 hz 10: 11.75 khz 11: 5.875 khz 3-2 reserved r/w 0 reserved (keep the value of these two bits ?0?) 1 reserved r/w 1 reserved (keep the value of this bit ?1?) 0 fan3_ext_en r/w 0 set this bit 1 to enable the function that fan3 output duty could be adjusted by gpio53/gpio54.
oct., 2011 v0.19p 92 F71869A 6.6.60 auto fan up speed update rate select register ? index 9bh fan_prog_sel = 0 bit name r/w default description 7-6 reserved - - reserved. 5-4 fan3_up_rate r/w 01 fan3 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz 3-2 fan2_up_rate r/w 01 fan2 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz 1-0 fan1_up_rate r/w 01 fan1 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz fan_prog_sel = 1 bit name r/w default description 7 up_dn_rate_en r/w 0 0: fan down rate disable 1: fan down rate enable 6 direct_load_en r/w 0 0: direct load disable 1: direct load enable for manual duty mode 5-4 fan3_dn_rate r/w 01 fan3 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz 3-2 fan2_dn_rate r/w 01 fan2 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz
oct., 2011 v0.19p 93 F71869A 1-0 fan1_dn_rate r/w 01 fan1 duty update rate: 00: 2hz 01: 5hz (default) 10: 10hz 11: 20hz 6.6.61 fan1 and fan2 start up duty-cycle/voltage ? index 9ch bit name r/w default description 7-4 fan2_stop _duty r/w 5h when fan start, the fan_ctrl2 will in crease duty-cycle from 0 to this (value x 8) directly. and if fan speed is down, the fan_ctrl 2 will decrease duty-cycle to 0 when the pwm duty cycle is less than this (value x 4). 3-0 fan1_stop _duty r/w 5h when fan start, the fan_ctrl 1 will increase duty-cycle from 0 to this (value x 8 directly. and if fan speed is down, the fan_ctrl 1 will decrease duty-cycle to 0 when the pwm duty cycle is less than this (value x 4). 6.6.62 fan3 start up duty-cycle/voltage ? index 9dh bit name r/w default description 7-4 reserved - - reserved. 3-0 fan3_stop_ duty r/w 5h when fan start, the fan_ctrl 3 will increase duty-cycle from 0 to this (value x 8 directly. and if fan speed is down, the fan_ctrl 3 will decrease duty-cycle to 0 when the pwm duty cycle is less than this (value x 4). 6.6.63 fan programmable duty-cycle/voltage loaded after power-on ? index 9eh bit name r/w default description 7-0 prog_duty_val r/w 66h this byte will be immediately loaded as fan duty value after vdd is powered on if it has been programmed before shut down. 6.6.64 fan fault time register ? index 9fh bit name r/w default description 7 fan_prog_sel r/w 0 set this bit to ?1? will enable accessing regi sters of other bank. 6 fan_mnt_sel r/w 0 set this bit to monitor a slower fan.
oct., 2011 v0.19p 94 F71869A 5 reserved - - reserved 4 full_duty_sel r/w - 0: the fan duty is 100% and will be loaded immediately after vdd is powered on if cr9e is not been programmed before shut down. (pull down by external resistor) 1: the fan duty is 40% and will be loaded immediately after vdd is powered on if cr9e is not been programmed before shut down. (pull up by internal 47k resistor). this register is power on trap by dtr1#. 3-0 f_fault_time r/w ah this register determines the time of fan fault. the condition to cause fan fault event is: when pwm_duty reaches ffh, if the fan speed count can?t reach the fan expect count in time. the unit of this register is 1 second. the default value is 11 seconds. (set to 0 , means 1 seconds. ; set to 1, means 2 seconds. set to 2, means 3 seconds. ?. ) another condition to cause fan f ault event is fan stop and the pwm duty is greater than the minimum duty programmed by the register index 9c-9dh. 6.6.65 fan1 index a0h~afh address attribute default value description a0h ro 8?h0f fan1 count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. a1h ro 8?hff fan1 count reading (lsb). a2h r/w 8?h00 rpm mode(cr96 bit0=0): fan1 expect speed count val ue (msb), in auto fan mode (cr96 bit1 ? 0) this register is auto updated by hardware. duty mode(cr96 bit0=1): this byte is reserved byte. a3h r/w 8?h01 rpm mode(cr96 bit0=0): fan1 expect speed count value (l sb) or expect pwm duty, in auto fan mode this register is auto updated by hardware and read only. duty mode(cr96 bit0=1): the value programming in this byte is duty value. in auto fan mode (cr96 bit1 ? 0) this register is updated by hardware.
oct., 2011 v0.19p 95 F71869A ex: 5 ? 5*100/255 % 255 ? 100% a4h r/w 8?h03 fan1 full speed count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. a5h r/w 8?hff fan1 full speed count reading (lsb). 6.6.66 vt1 boundary 1 temperature ? index a6h bit name r/w default description 7-0 bound1tmp1 r/w 3ch (60 o c) the first boundary temperature for vt1 in temperature mode. when vt1 temperature exceeds this boundary, expected fan1 value will be loaded from segment 1 register (index aah). when vt1 temperature is under this boundary ? hysteresis, expected fan1 value will be loaded from segment 2 register (index abh). this byte is a 2?s complement value ranged from -128?c ~ 127?c. 6.6.67 vt1 boundary 2 temperature ? index a7 bit name r/w defaul t description 7-0 bound2tmp1 r/w 32 (50 o c) the 2nd boundary temperature for vt1 in temperature mode. when vt1 temperature is exceed this boundary, fan1 expected value will load from segment 2 register (index abh). when vt1 temperature is below this boundary ? hysteresis, fan1 expected value will load from segment 3 register (index ach). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.68 vt1 boundary 3 temperature ? index a8h bit name r/w defaul t description 7-0 bound3tmp1 r/w 28h (40 o c) the 3rd boundary temperature for vt1 in temperature mode. when vt1 temperature is exceed this boundary, fan1 expected value will load from segment 3 register (index ach). when vt1 temperature is below this boundary ? hysteresis, fan1 expected value will load from segment 4 register (index adh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.69 vt1 boundary 4 temperature ? index a9 bit name r/w defaul t description
oct., 2011 v0.19p 96 F71869A 7-0 bound4tmp1 r/w 1eh (30 o c) the 4th boundary temperature for vt1 in temperature mode. when vt1 temperature is exceed this boundary, fan1 expected value will load from segment 4 register (index adh). when vt1 temperature is below this boundary ? hysteresis, fan1 expected value will load from segment 5 register (index aeh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.70 fan1 segment 1 speed count ? index aah bit name r/w default description 7 - 0 sec1speed1 r /w ffh (100%) the meaning of this register is depending on the fan1_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. ex: 100%:full speed: user must set this register to 0. 60% full speed: (100-60)*32/60, so user must program 21 to this reg. x% full speed: the value programming in this byte is ( (100-x)*32/x 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.71 fan1 segment 2 speed count ? index abh bit name r/w default description 7-0 sec2speed1 r/w d9h (85%) the meaning of this register is depending on the fan1_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.72 fan1 segment 3 speed count register ? index ach bit name r/w default description 7-0 sec3speed1 r/w b2h (70%) the meaning of this register is depending on the fan1_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.73 fan1 segment 4 speed count register ? index adh bit name r/w default description
oct., 2011 v0.19p 97 F71869A 7-0 sec4speed1 99h (60%) the meaning of this register is depending on the fan1_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.74 fan1 segment 5 speed count register ? index aeh bit name r/w default description 7-0 sec5peed1 r/w 80h (50%) the meaning of this register is depending on the fan1_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.75 fan1 temperature mapping select ? index afh bit name r/w default description 7 fan1_temp _sel_dig r/w 0 this bit companies with fan1_temp_sel select the temperature source for controlling fan1. 6 fan1_pwm _freq_sel r/w 0 set this bit to select fan2 pwm output frequency. 0: 23.5 khz 1: 220 hz 5 fan1_up_t_en r/w 0 set 1 to force fan1 to full speed if any temperature over its high limit. 4 fan1_ interpolation_ en r/w 1 set 1 will enable the interpolat ion of the fan expect table. 3 fan1_jump _high_en r/w 1 this register controls the fan1 dut y movement when temperature over highest boundary. 0: the fan1 duty will increases with the slope selected by fan1_rate_sel register. 1: the fan1 duty will directly jumps to the value of sec1speed1 register. this bit only activates in duty mode.
oct., 2011 v0.19p 98 F71869A 2 fan1_jump _low_en r/w 1 this register controls the fan1 duty movement when temperature under (highest boundary ? hysteresis). 0: the fan1 duty will decreases with the slope selected by fan1_rate_sel register. 1: the fan1 duty will directly jumps to the value of sec2speed1 register. this bit only activates in duty mode. 1 - 0 fan1_temp_sel r /w 01 this registers company with fan1_temp_sel_dig select the temperature source for controlling fan1. the following value is comprised by {fan1_temp_sel_dig, fan1_temp_sel} 000: fan1 follows peci temperature (cr7eh) 001: fan1 follows temperature 1 (cr72h). 010: fan1 follows temperature 2 (cr74h). 011: fan1 follows temperature 3 (cr76h). 100: fan1 follows ibx/tsi cpu temperature (cr7ah) 101: fan1 follows ibx pch temperature (cr7bh). 110: fan1 follows ibx m ch temperature (cr7ch). 111: fan1 follows ibx maximum temperature (cr7dh). others are reserved. 6.6.76 fan2 index b0h~bfh address attribute default value description b0h ro 8?h0f fan2 count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. b1h ro 8?hff fan2 count reading (lsb). b2h r/w 8?h00 rpm mode(cr96 bit2=0): fan2 expect speed count val ue (msb), in auto fan mode(cr96 bit3 ? 0) this register is auto updated by hardware. duty mode(cr96 bit2=1): this byte is reserved byte. b3h r/w 8?h01 rpm mode(cr96 bit2=0): fan2 expect speed count value (lsb) or expect pwm duty , in auto fan mode this register is auto updated by hardware and read only. duty mode(cr96 bit2=1): the value programming in this byte is duty value. in auto fan
oct., 2011 v0.19p 99 F71869A mode(cr96 bit3 ? 0) this register is updated by hardware. ex: 5 ? 5*100/255 % 255 ? 100% b4h r/w 8?h03 fan2 full speed count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. b5h r/w 8?hff fan2 full speed count reading (lsb). 6.6.77 vt2 boundary 1 temperature ? index b6h bit name r/w default description 7-0 bound1tmp2 r/w 3ch (60 o c) the first boundary temperature for vt2 in temperature mode. when vt2 temperature exceeds this boundary, fan2 expect value will load from segment 1 register (index bah). when vt2 temperature is under this boundary ? hysteresis, fan2 expect value will load from segment 2 register (index bah). this byte is a 2?s complement value ranging from -128?c ~ 127?c. 6.6.78 vt2 boundary 2 temperature ? index b7 bit name r/w default description 7-0 bound2tmp2 r/w 32 (50 o c) the 2nd boundary temperature for vt2 in temperature mode. when vt2 temperature is exceed this boundary, fan2 expected value will load from segment 2 register (index bbh). when vt2 temperature is below this boundary ? hysteresis, fan2 expected value will load from segment 3 register (index bch). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.79 vt2 boundary 3 temperature ? index b8h bit name r/w default description 7-0 bound3tmp2 r/w 28h (40 o c) the 3rd boundary temperature for vt2 in temperature mode. when vt2 temperature is exceed this boundary, fan2 expected value will load from segment 3 register (index bch). when vt2 temperature is below this boundary ? hysteresis, fan2 expected value will load from segment 4 register (index bdh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.80 vt2 boundary 4 temperature ? index b9 bit name r/w default description
oct., 2011 v0.19p 100 F71869A 7-0 bound4tmp2 r/w 1eh (30 o c) the 4th boundary temperature for vt2 in temperature mode. when vt2 temperature is exceed this boundary, fan2 expected value will load from segment 4 register (index bdh). when vt2 temperature is below this boundary ? hysteresis, fan2 expected value will load from segment 5 register (index beh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.81 fan2 segment 1 speed count ? index bah bit name r/w default description 7 - 0 sec1speed2 r /w ffh (100%) the meaning of this register is depending on the fan2_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. ex: 100%:full speed: user must set this register to 0. 60% full speed: (100-60)*32/60, so user must program 21 to this reg. x% full speed: the value programming in this byte is ? (100-x)*32/x 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.82 fan2 segment 2 speed count ? index bbh bit name r/w default description 7 - 0 sec2speed2 r /w d9h (85%) the meaning of this register is depending on the fan2_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.83 fan2 segment 3 speed count register ? index bch bit name r/w default description 7 - 0 sec3speed2 r /w b2h (70%) the meaning of this register is depending on the fan2_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.84 fan2 segment 4 speed count register ? index bdh bit name r/w default description
oct., 2011 v0.19p 101 F71869A 7 - 0 sec4speed2 r /w 99h (60%) the meaning of this register is depending on the fan2_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.85 fan2 segment 5 speed count register ? index beh bit name r/w default description 7 - 0 sec5peed2 r /w 80h (50%) the meaning of this register is depending on the fan2_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.86 fan2 temperature mapping select ? index bfh bit name r/w default description 7 fan2_temp_ sel_dig r/w 0 this bit companies with fan2_tem p_sel to select the temperature source for controlling fan2. 6 fan2_pwm_ freq_sel r/w 0 set this bit to select fan2 pwm output frequency. 0: 23.5 khz 1: 220 hz 5 fan2_up_t_en r /w 0 set 1 to force fan2 to full speed if any temperature over its high limit. 4 fan2_ interpolation_en r/w 1 set 1 will enable the interpolat ion of the fan expect table. 3 fan2_jump_ high_en r/w 1 this register controls the fan2 duty movement when temperature over highest boundary. 0: the fan2 duty will increases with the slope selected by fan2_rate_sel register. 1: the fan2 duty will directly jumps to the value of sec1speed2 register. this bit only activates in duty mode.
oct., 2011 v0.19p 102 F71869A 2 fan2_jump_ low_en r/w 1 this register controls the fan2 duty movement when temperature under (highest boundary ? hysteresis). 0: the fan2 duty will decreases with the slope selected by fan2_rate_sel register. 1: the fan2 duty will directly jumps to the value of sec2speed2 register. this bit only activates in duty mode. 1 - 0 fan2_temp_sel r /w 10 this registers companying with fan2_temp_sel_dig select the temperature source for controlling fan2. the following value is comprised by {fan2_temp_sel_dig, fan2_temp_sel} 000: fan2 follows peci temperature (cr7eh) 001: fan2 follows temperature 1 (cr72h). 010: fan2 follows temperature 2 (cr74h). 011: fan2 follows temperature 3 (cr76h). 100: fan2 follows ibex/tsi cpu temperature (cr7ah) 101: fan2 follows ibex pch temperature (cr7bh). 110: fan2 follows ibex m ch temperature (cr7ch). 111: fan2 follows ibex maxi mum temperature (cr7dh). otherwise: reserved. 6.6.87 fan3 index c0h- cfh address attribute default value description c0h ro 8?h0f fan3 count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. c1h ro 8?hff fan3 count reading (lsb). c2h r/w 8?h00 rpm mode(cr96 bit4=0): fan3 expect speed count val ue (msb), in auto fan mode(cr96 bit5 ? 0) this register is auto updated by hardware. duty mode(cr96 bit4=1): this byte is reserved byte. c3h r/w 8?h01 rpm mode(cr96 bit4=0): fan3 expect speed count value (lsb) or expect pwm duty , in auto fan mode this register is auto updated by hardware and read only. duty mode(cr96 bit4=1): the value programming in this byte is duty value. in auto fan
oct., 2011 v0.19p 103 F71869A mode(cr96 bit5 ? 0) this register is updated by hardware. ex: 5 ? 5*100/255 % 255 ? 100% c4h r/w 8?h03 fan3 full speed count reading (msb). at the moment of reading this register, the lsb will be latched. this will prevent from data updating when reading. to read the fan count correctly, read msb first and followed read the lsb. c5h r/w 8?hff fan3 full speed count reading (lsb). 6.6.88 vt3 boundary 1 temperature ? index c6h bit name r/w default description 7-0 bound1tmp3 r/w 3ch (60 o c) the first boundary temperature for vt3 in temperature mode. when vt3 temperature exceeds this boundary, fan3 expect value will load from segment 1 register (index ca)h. when vt3 temperature is under this boundary ? hysteresis, fan3 expect value will load from segment 2 register (index cah). this byte is a 2?s complement value ranging from -128?c ~ 127?c. 6.6.89 vt3 boundary 2 temperature ? index c7 bit name r/w default description 7-0 bound2tmp3 r/w 32 (50 o c) the 2nd boundary temperature for vt3 in temperature mode. when vt3 temperature is exceed this boundary, fan3 expected value will load from segment 2 register (index cbh). when vt3 temperature is below this boundary ? hysteresis, fan3 expected value will load from segm ent 3 register (index cch). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.90 vt3 boundary 3 temperature ? index c8h bit name r/w default description 7-0 bound3tmp3 r/w 28h (40 o c) the 3rd boundary temperature for vt3 in temperature mode. when vt3 temperature is exceed this boundary, fan3 expected value will load from segment 3 register (index cch). when vt3 temperature is below this boundary ? hysteresis, fan3 expected value will load from segm ent 4 register (index cdh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c. 6.6.91 vt3 boundary 4 temperature ? index c9 bit name r/w default description 7-0 bound4tmp3 r/w 1eh (30 o c) the 4th boundary temperature for vt3 in temperature mode. when vt3 temperature is exceed this boundary, fan3 expected value will load from segment 4 register (index cdh). when vt3 temperature is below this boundary ? hysteresis, fan3 expected value will load from segment 5 register (index ceh). this byte is a 2?s complement value ranging from -128 o c ~ 127 o c.
oct., 2011 v0.19p 104 F71869A 6.6.92 fan3 segment 1 speed count ? index cah bit name r/w default description 7 - 0 sec1speed3 r /w ffh (100%) the meaning of this register is depending on the fan3_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. ex: 100%:full speed: user must set this register to 0. 60% full speed: (100-60)*32/60, so user must program 21 to this reg. x% full speed: the value programming in this byte is ? (100-x)*32/x 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.93 fan3 segment 2 speed count ? index cbh bit name r/w default description 7 - 0 sec2speed3 r /w d9h (85%) the meaning of this register is depending on the fan3_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.94 fan3 segment 3 speed count ? index cch bit name r/w default description 7 - 0 sec3speed3 r /w b2h (70%) the meaning of this register is depending on the fan3_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.95 fan3 segment 4 speed count ? index cdh bit name r/w default description 7 - 0 sec4speed3 r /w 99h (60%) the meaning of this register is depending on the fan3_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.96 fan3 segment 5 speed count ? index ceh bit name r/w default description
oct., 2011 v0.19p 105 F71869A 7 - 0 sec5speed3 r /w 80h (50%) the meaning of this register is depending on the fan3_mode(cr96) 2?b00: the value that set in this byte is the relative expect fan speed % of the full speed in this temperature section. 2?b01: the value that set in this byte is mean the expect pwm duty-cycle in this temperature section. 6.6.97 fan3 temperature mapping select ? index cfh bit name r/w default description 7 fan3_temp_ sel_dig r/w 0 this bit companies with fan3_temp_sel select the temperature source for controlling fan3. 6 fan3_pwm_ freq_sel r/w 0 set this bit to select fan3 pwm output frequency. 0: 23.5 khz 1: 220 hz 5 fan3_up_t_en r /w 0 set 1 to force fan3 to full speed if any temperature over its high limit. 4 fan3_ interpolation_en r/w 1 set 1 will enable the interpolat ion of the fan expect table. 3 fan3_jump_ high_en r/w 1 this register controls the fan3 duty movement when temperature over highest boundary. 0: the fan3 duty will increases with the slope selected by fan3_rate_sel register. 1: the fan3 duty will directly jumps to the value of sec1speed3 register. this bit only activates in duty mode. 2 fan3_jump_ low_en r/w 1 this register controls the fan3 duty movement when temperature under (highest boundary ? hysteresis). 0: the fan3 duty will decreases with the slope selected by fan3_rate_sel register. 1: the fan3 duty will directly jumps to the value of sec2speed3 register. this bit only activates in duty mode.
oct., 2011 v0.19p 106 F71869A 1 - 0 fan3_temp_sel r /w 11 this registers companying with fan3_temp_sel_dig select the temperature source for controlling fan3. the following value is comprised by {fan3_temp_sel_dig, fan3_temp_sel} 000: fan3 follows peci temperature (cr7eh) 001: fan3 follows temperature 1 (cr72h). 010: fan3 follows temperature 2 (cr74h). 011: fan3 follows temperature 3 (cr76h). 100: fan3 follows ibex/tsi cpu temperature (cr7ah) 101: fan3 follows ibex pch temperature (cr7bh). 110: fan3 follows ibex m ch temperature (cr7ch). 111: fan3 follows ibex maxi mum temperature (cr7dh). otherwise: reserved. 6.6.98 tsi temperature 0 ? index e0h bit name r/w default description tsi_temp0 r /w - this is the amd tsi reading if amd tsi enable. and will be highest temperature am ong cpu, mch and pch if intel temperature interface enable. the ra nge is 0~255?c. to access this byte, mch_bank_sel must set to ?0?. 7-0 smb_data0 r /w 8?h00 this byte is used as multi-purpose: 1. the received data of receive protocol. 2. the first received byte of read word protocol. 3. the 10 th received byte of read block protocol. 4. the sent data for send byte protocol and write byte protocol. 5. the first send byte for write word protocol. 6. the first send byte for write block protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.99 tsi temperature 1 ? index e1h bit name r/w default description 7-0 tsi_temp1 r - this is the high byte of intel te mperature interfac e pch reading. the range is 0~255?c. to access this byte, mch_ban k_sel should be set to ?0?.
oct., 2011 v0.19p 107 F71869A smb_data1 r /w 8?h00 this byte is used as multi-purpose: 1. the second received byte of read word protocol. 2. the 11 th received byte of read block protocol. 3. the second send byte for write word protocol. 4. the second send byte fo r write block protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.100 tsi temperature 2 low byte ? index e2h bit name r/w default description tsi_temp2_lo r - this is the low byte of intel temperature interface cpu reading. the reading is the fraction part of cpu temperature. bit 0 indicates the error status. 0: no error. 1: error code. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data2 r /w 8?h00 this is the 12 th byte of the block read protocol. this byte is also used as the 3rd byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.101 tsi temperature 2 high byte ? index e3h bit name r/w default description tsi_temp2_hi r - this is the high byte of intel tem perature interface cpu reading. the reading is the decimal part of cpu temperature. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data3 r /w 8?h00 this is the 13 th byte of the block read protocol. this byte is also used as the 4t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.102 tsi temperature 3 ? index e4h bit name r/w default description tsi_temp3 r - this is the high byte of intel te mperature interfac e mch reading. the range is 0~255?c. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data4 r /w 8?h00 this is the 14 th byte of the block read protocol. this byte is also used as the 5t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?.
oct., 2011 v0.19p 108 F71869A 6.6.103 tsi temperature 4 ? index e5h bit name r/w default description tsi_temp4 r - this is the high byte of intel te mperature interface dimm0 reading. the range is 0~255?c. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data5 r /w 8?h00 this is the 15 th byte of the block read protocol. this byte is also used as the 6t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.104 tsi temperature 5 ? index e6h bit name r/w default description tsi_temp5 r - this is the high byte of intel te mperature interface dimm1 reading. the range is 0~255?c. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data6 r /w 8?h00 this is the 16 th byte of the block read protocol. this byte is also used as the 7t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.105 tsi temperature 6 ? index e7h bit name r/w default description tsi_temp6 r - this is the high byte of intel te mperature interface dimm2 reading. the range is 0~255?c. to access this byte, mch_ban k_sel should be set to ?0?. 7-0 smb_data7 r /w 8?h00 this is the 17 th byte of the block read protocol. this byte is also used as the 8t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.106 tsi temperature 7 ? index e8h bit name r/w default description tsi_temp7 r - this is the high byte of intel te mperature interface dimm3 reading. the range is 0~255?c. the above 9 bytes could also be used as the read data of block read protocol if the tsi is disable or pending. 7-0 smb_data8 r /w 8?h00 this is the 18 th byte of the block read protocol. this byte is also used as the 9t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.107 smb data buffer 9 ? index e9h bit name r/w default description
oct., 2011 v0.19p 109 F71869A 7-0 smb_data9 r/w ffh this is the 18 th byte of the block read protocol. this byte is also used as the 9t h byte of block write protocol. to access this byte, mch_ban k_sel should be set to ?1?. 6.6.108 block write count register ? index ech bit name r/w default description 7 mch_bank_sel r /w 0 this bit is used to select the register in index e0h to e9h. set ?0? to read the temperature bank and ?1? to access the data bank. 6 reserved - 0 reserved 5-0 block_wr_cnt r/w 0 use the register to specify the byte count of block write protocol. support up to 10 bytes. 6.6.109 smb command byte/tsi command byte ? index edh bit name r/w default description 7 - 0 smb_cmd/tsi_cmd r /w 0/1 there are actual two bytes for this index. tsi_cmd_prog select which byte to be programmed: 0: smb_cmd, which is the command code for write byte/word, read byte/word, block write/read and process call protocol. 1: tsi_cmd, which is the command code for intel temperature interface block read protocol and t he data byte for amd tsi send byte protocol. 6.6.110 smb status ? index eeh bit name r/w default description 7 tsi_pending r /w 0 set 1 to pending auto tsi accessing. (in amd model, auto accessing will issue a send-byte followed a re ceive-byte; in intel model, auto accessing will issue a block read). to use the scl/ sda as a smbus master, set this bit to ?1? first. 6 tsi_cmd_prog r /w 0 set 1 to program tsi_cmd. 5 proc_kill r /w 0 kill the current smbus tran sfer and return the stat e machine to idle. it will set an fail status if the cu rrent transfer is not completed. 4 fail_sts r 0 this is set when proc_ki ll kill an un-completed transfer. it will be auto cleared by next smbus transfer. 3 smb_abt_err r 0 this is the arbitration lost status if a smbus command is issued. auto cleared by next smbus command. 2 smb_to_err r 0 this is the timeout status if a smbus command is issued. auto cleared by next smbus command.
oct., 2011 v0.19p 110 F71869A 1 smb_nac_err r 0 this is the nack error status if a smbus command is issued. auto cleared by next smbus command. 0 smb_ready r 1 0: a smbus transfer is in process. 1: ready for next smbus command. 6.6.111 smb protocol select ? index efh bit name r/w default description 7 smb_start w 0 write ?1? to trigger a smbus transfer with the protocol specified by smb_protocol. 6-4 reserved - - reserved. 3 - 0 smb_protocol r /w 0 select what protocol if a smbus transfer is triggered. 0001b: send byte. 0010b: write byte. 0011b: write word. 0100b: reserved. 0101b: block write. 0111b: quick command (write). 1001b: receive byte. 1010b: read byte. 1011b: read word. 1101b: block read. 1111b: reserved otherwise: reserved. 6.7 kbc registers (cr05) 6.7.1 kbc device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 kbc_en r/w 1 0: disable kbc. 1: enable kbc. 6.7.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 00h the msb of kbc command port address. the address of data port is command port address + 4; 6.7.3 base address low register ? index 61h bit name r/w default description
oct., 2011 v0.19p 111 F71869A 7-0 base_addr_lo r/w 60h the lsb of kbc command port address. the address of data port is command port address + 4. 6.7.4 kbc irq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selkirq r/w 1h select the irq channel for keyboard interrupt. 6.7.5 mouse irq channel select register ? index 72h bit name r/w default description 7-4 reserved - - reserved. 3-0 selmirq r/w ch select the irq channel for ps/2 mouse interrupt. 6.7.6 auto swap register ? index feh (powered by vbat) bit name r/w default description 7-5 reserved - - reserved. 4 kb_mo_swap r/w 0 0: keyboard/mouse does not swap. 1: keyboard/mouse swap. users could also program this bit manually. 3 pseudo_8408_en r/w 0 set ?1? to enable auto response to kbc command. it will return 0xfa, 0xaa for 0xff command and 0xfa for other commands. this bit is used for gpio scan code function without ps/2 keyboard. 2-0 reserved - 1h reserved 6.7.7 user wakeup code register ? index ff h (powered by vbat) bit name r/w default description 9-0 user_wakeup_ code r/w 29h user defined wakeup code. 6.8 gpio registers (cr06) 6.8.1 gpio device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 gpio_en r/w 0 0: disable gpio i/o port. 1: enable gpio i/o port. 6.8.2 base address high register ? index 60h bit name r/w default description
oct., 2011 v0.19p 112 F71869A 7-0 base_addr_hi r/w 00h the msb of gpio index/data port address. the index port is base_addr[15:2] + 5 and the data port is base_addr[15:2] + 6. 6.8.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w 00h the lsb of gpio index/data port address. the index port is base_addr[15:2] + 5 and the data port is base_addr[15:2] + 6. 6.8.4 gpirq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selgpirq r/w 0h select the irq channel for gpio interrupt. 6.8.5 gpio0 output enable register ? index f0h bit name r/w default description 7-6 reserved - - reserved. 5 gpio05_oe r/w 0 0: gpio05 is in input mode. 1: gpio05 is in output mode. 4 gpio04_oe r/w 0 0: gpio04 is in input mode. 1: gpio04 is in output mode. 3 gpio03_oe r/w 0 0: gpio03 is in input mode. 1: gpio03 is in output mode. 2 gpio02_oe r/w 0 0: gpio02 is in input mode. 1: gpio02 is in output mode. 1 gpio01_oe r/w 0 0: gpio01 is in input mode. 1: gpio01 is in output mode. 0 reserved r/w 0 reserved 6.8.6 gpio0 output data register ? index f1h bit name r/w default description 7-6 reserved - - reserved. 5 gpio05_val r/w 1 0: gpio05 outputs 0 when in output mode. 1: gpio05 outputs 1 when in output mode. 4 gpio04_val r/w 1 0: gpio04 outputs 0 when in output mode. 1: gpio04 outputs 1 when in output mode. 3 gpio03_val r/w 1 0: gpio03 outputs 0 when in output mode. 1: gpio03 outputs 1 when in output mode. 2 gpio02_val r/w 1 0: gpio02 outputs 0 when in output mode. 1: gpio02 outputs 1 when in output mode.
oct., 2011 v0.19p 113 F71869A 1 gpio01_val r/w 1 0: gpio01 outputs 0 when in output mode. 1: gpio01 outputs 1 when in output mode. 0 reserved r/w 1 reserved 6.8.7 gpio pin status register ? index f2h bit name r/w default description 7-6 reserved - - reserved. 5 gpio05_in r - the pin status of s3_gate# /gpio05/ wdtrst# 4 gpio04_in r - the pin status of s3p5_gate# /slotocc#/gpio04 3 gpio03_in r - the pin status of cirrx#/gpio03 2 gpio02_in r - the pin status of cirtx#/gpio02 1 gpio01_in r - the pin status of cirwb#/gpio01 0 reserved r - reserved 6.8.8 gpio drive enable register ? index f3h bit name r/w default description 7 reserved - - reserved. 5 gpio05_drv_en r/w 0 0: gpio05 is open drain in output mode. 1: gpio05 is push pull in output mode. 4 gpio04_drv_en r/w 0 0: gpio04 is open drain in output mode. 1: gpio04 is push pull in output mode. 3 gpio03_drv_en r/w 0 0: gpio03 is open drain in output mode. 1: gpio03 is push pull in output mode. 2 gpio02_drv_en r/w 0 0: gpio02 is open drain in output mode. 1: gpio02 is push pull in output mode. 1 gpio01_drv_en r/w 0 0: gpio01 is open drain in output mode. 1: gpio01 is push pull in output mode. 0 reserved r/w 0 reserved 6.8.9 gpio1 output enable register ? index e0h bit name r/w default description 7 gpio17_oe r/w 0 0: gpio17 is in input mode. 1: gpio17 is in output mode. 6 gpio16_oe r/w 0 0: gpio16 is in input mode. 1: gpio16 is in output mode. 5 gpio15_oe r/w 0 0: gpio15 is in input mode. 1: gpio15 is in output mode. 4 gpio14_oe r/w 0 0: gpio14 is in input mode. 1: gpio14 is in output mode. 3 gpio13_oe r/w 0 0: gpio13 is in input mode. 1: gpio13 is in output mode. 2 gpio12_oe r/w 0 0: gpio12 is in input mode. 1: gpio12 is in output mode.
oct., 2011 v0.19p 114 F71869A 1 gpio11_oe r/w 0 0: gpio11 is in input mode. 1: gpio11 is in output mode. 0 gpio10_oe r/w 0 0: gpio10 is in input mode. 1: gpio10 is in output mode. 6.8.10 gpio1 output data register ? index e1h bit name r/w default description 7 gpio17_val r/w 1 0: gpio17 outputs 0 when in output mode. 1: gpio17 outputs1 when in output mode. 6 gpio16_val r/w 1 0: gpio16 outputs 0 when in output mode. 1: gpio16 outputs1 when in output mode. 5 gpio15_val r/w 1 0: gpio15 outputs 0 when in output mode. 1: gpio15 outputs 1 when in output mode. 4 gpio14_val r/w 1 0: gpio14 outputs 0 when in output mode. 1: gpio14 outputs 1 when in output mode. 3 gpio13_val r/w 1 0: gpio13 outputs 0 when in output mode. 1: gpio13 outputs 1 when in output mode. 2 gpio12_val r/w 1 0: gpio12 outputs 0 when in output mode. 1: gpio12 outputs 1 when in output mode. 1 gpio11_val r/w 1 0: gpio11 outputs 0 when in output mode. 1: gpio11 outputs 1 when in output mode. 0 gpio10_val r/w 1 0: gpio10 outputs 0 when in output mode. 1: gpio10 outputs 1 when in output mode. 6.8.11 gpio1 pin status register ? index e2h bit name r/w default description 7 gpio17_in r - the pin status of cpu_pwgd/gpio17. 6 gpio16_in r - the pin status of led_vcc/gpio16. 5 gpio15_in r - the pin status of led_vsb/alert#/gpio15. 4 gpio14_in r - the pin status of wdtrst#/gpio14. 3 gpio13_in r - the pin status of beep/gpio13. 2 gpio12_in r - the pin stat us of rstcon#/gpio12. 1 gpio11_in r - the pin status of pci_rst5#/gpio11. 0 gpio10_in r - the pin status of pci_rst4#/gpio10. 6.8.12 gpio1 drive enable register ? index e3h bit name r/w default description 7 gpio17_drv_en r/w 0 0: gpio17 is open drain in output mode. 1: gpio17 is push pull in output mode. 6 gpio16_drv_en r/w 0 0: gpio16 is open drain in output mode. 1: gpio16 is push pull in output mode. 5 gpio15_drv_en r/w 0 0: gpio15 is open drain in output mode. 1: gpio15 is push pull in output mode. 4 gpio14_drv_en r/w 0 0: gpio14 is open drain in output mode. 1: gpio14 is push pull in output mode.
oct., 2011 v0.19p 115 F71869A 3 gpio13_drv_en r/w 0 0: gpio13 is open drain in output mode. 1: gpio13 is push pull in output mode. 2 gpio12_drv_en r/w 0 0: gpio12 is open drain in output mode. 1: gpio12 is push pull in output mode. 1 gpio11_drv_en r/w 0 0: gpio11 is open drain in output mode. 1: gpio11 is push pull in output mode. 0 gpio10_drv_en r/w 0 0: gpio10 is open drain in output mode. 1: gpio10 is push pull in output mode. 6.8.13 gpio1 pme enable register ? index e4h bit name r/w default description 7 gpio17_pme_en r/w 0 when gpio17_event_sts is 1 and gpio17_pme_en is set to 1, a gpio pme event will be generated. 6 gpio16_pme_en r/w 0 when gpio16_event_sts is 1 and gpio16_pme_en is set to 1, a gpio pme event will be generated. 5 gpio15_pme_en r/w 0 when gpio15_event_sts is 1 and gpio15_pme_en is set to 1, a gpio pme event will be generated. 4 gpio14_pme_en r/w 0 when gpio14_event_sts is 1 and gpio14_pme_en is set to 1, a gpio pme event will be generated. 3 gpio13_pme_en r/w 0 when gpio13_event_sts is 1 and gpio13_pme_en is set to 1, a gpio pme event will be generated. 2 gpio12_pme_en r/w 0 when gpio12_event_sts is 1 and gpio12_pme_en is set to 1, a gpio pme event will be generated. 1 gpio11_pme_en r/w 0 when gpio11_event_sts is 1 and gp io11_pme_en is set to 1, a gpio pme event will be generated. 0 gpio10_pme_en r/w 0 when gpio10_event_sts is 1 and gpio10_pme_en is set to 1, a gpio pme event will be generated. 6.8.14 gpio1 input detection select register ? index e5h bit name r/w default description 7 gpio17_det_sel r/w 0 when gpio17 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 6 gpio16_det_sel r/w 0 when gpio16 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 5 gpio15_det_sel r/w 0 when gpio15 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 4 gpio14_det_sel r/w 0 when gpio14 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge
oct., 2011 v0.19p 116 F71869A 3 gpio13_det_sel r/w 0 when gpio13 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 2 gpio12_det_sel r/w 0 when gpio12 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 1 gpio11_det_sel r/w 0 when gpio11 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 0 gpio10_det_sel r/w 0 when gpio10 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 6.8.15 gpio1 event status register ? index e6h bit name r/w default description 7 gpio17_ event_sts r/w 0 when gpio17 is in input mode and a gpio17 input is detected according to cre5[7], this bit will be set to 1. write a 1 to this bit will clear it to 0. 6 gpio16_ event_sts r/w 0 when gpio16 is in input mode and a gpio16 input is detected according to cre5[6], this bit will be set to 1. write a 1 to this bit will clear it to 0. 5 gpio15_ event_sts r/w 0 when gpio15 is in input mode and a gpio15 input is detected according to cre5[5], this bit will be set to 1. write a 1 to this bit will clear it to 0. 4 gpio14_ event_sts r/w 0 when gpio14 is in input mode and a gpio14 input is detected according to cre5[4], this bit will be set to 1. write a 1 to this bit will clear it to 0. 3 gpio13_ event_sts r/w 0 when gpio13 is in input mode and a gpio13 input is detected according to cre5[3], this bit will be set to 1. write a 1 to this bit will clear it to 0. 2 gpio12_ event_sts r/w 0 when gpio12 is in input mode and a gpio12 input is detected according to cre5[2], this bit will be set to 1. write a 1 to this bit will clear it to 0. 1 gpio11_ event_sts r/w 0 when gpio11 is in input mode and a gpio11 input is detected according to cre5[1], this bit will be set to 1. write a 1 to this bit will clear it to 0. 0 gpio10_ event_sts r/w 0 when gpio10 is in input mode and a gpio10 input is detected according to cre5[0], this bit will be set to 1. write a 1 to this bit will clear it to 0. 6.8.16 gpio2 output enable register ? index d0h bit name r/w default description 7 gpio27_oe r/w 0 0: gpio27 is in input mode. 1: gpio27 is in output mode.
oct., 2011 v0.19p 117 F71869A 6 gpio26_oe r/w 0 0: gpio26 is in input mode. 1: gpio25 is in output mode. 5 gpio25_oe r/w 0 0: gpio25 is in input mode. 1: gpio25 is in output mode. 4 gpio24_oe r/w 0 0: gpio24 is in input mode. 1: gpio24 is in output mode. 3 gpio23_oe r/w 0 0: gpio23 is in input mode. 1: gpio23 is in output mode. 2 gpio22_oe r/w 0 0: gpio22 is in input mode. 1: gpio22 is in output mode. 1 gpio21_oe r/w 0 0: gpio21 is in input mode. 1: gpio21 is in output mode. 0 gpio20_oe r/w 0 0: gpio20 is in input mode. 1: gpio20 is in output mode. 6.8.17 gpio2 output data register ? index d1h bit name r/w default description 7 gpio27_val r/w 1 0: gpio27 outputs 0 when in output mode. 1: gpio27 outputs 1 when in output mode. 6 gpio26_val r/w 1 0: gpio26 outputs 0 when in output mode. 1: gpio26 outputs 1 when in output mode. 5 gpio25_val r/w 1 0: gpio25 outputs 0 when in output mode. 1: gpio25 outputs 1 when in output mode. 4 gpio24_val r/w 1 0: gpio24 outputs 0 when in output mode. 1: gpio24 outputs 1 when in output mode. 3 gpio23_val r/w 1 0: gpio23 outputs 0 when in output mode. 1: gpio23 outputs 1 when in output mode. 2 gpio22_val r/w 1 0: gpio22 outputs 0 when in output mode. 1: gpio22 outputs 1 when in output mode. 1 gpio21_val r/w 1 0: gpio21 outputs 0 when in output mode. 1: gpio21 outputs 1 when in output mode. 0 gpio20_val r/w 1 0: gpio20 outputs 0 when in output mode. 1: gpio20 outputs 1 when in output mode. 6.8.18 gpio2 pin status register ? index d2h bit name r/w default description 7 gpio27_in r - the pin status of sin2/gpio27. 6 gpio26_in r - the pin status of sout2/gpio26. 5 gpio25_in r - the pin status of dsr2#/gpio25. 4 gpio24_in r - the pin status of rts2#/gpio24. 3 gpio23_in r - the pin status of dtr2#/gpio23. 2 gpio22_in r - the pin status of cts2#/gpio22. 1 gpio21_in r - the pin status of ri2#/gpio21. 0 gpio20_in r - the pin status of dcd2#/gpio20.
oct., 2011 v0.19p 118 F71869A 6.8.19 gpio2 drive enable register ? index d3h bit name r/w default description 7 gpio27_drv_en r/w 0 0: gpio27 is open drain in output mode. 1: gpio27 is push pull in output mode. 6 gpio26_drv_en r/w 0 0: gpio26 is open drain in output mode. 1: gpio26 is push pull in output mode. 5 gpio25_drv_en r/w 0 0: gpio25 is open drain in output mode. 1: gpio25 is push pull in output mode. 4 gpio24_drv_en r/w 0 0: gpio24 is open drain in output mode. 1: gpio24 is push pull in output mode. 3 gpio23_drv_en r/w 0 0: gpio23 is open drain in output mode. 1: gpio23 is push pull in output mode. 2 gpio22_drv_en r/w 0 0: gpio22 is open drain in output mode. 1: gpio22 is push pull in output mode. 1 gpio21_drv_en r/w 0 0: gpio21 is open drain in output mode. 1: gpio21 is push pull in output mode. 0 gpio20_drv_en r/w 0 0: gpio20 is open drain in output mode. 1: gpio20 is push pull in output mode. 6.8.20 gpio3 output enable register ? index c0h bit name r/w default description 7 gpio37_oe r/w 0 0: gpio37 is in input mode. 1: gpio37 is in output mode. (open-drain). 6 gpio36_oe r/w 0 0: gpio36 is in input mode. 1: gpio35 is in output mode. (open-drain). 5 gpio35_oe r/w 0 0: gpio35 is in input mode. 1: gpio35 is in output mode. (open-drain). 4 gpio34_oe r/w 0 0: gpio34 is in input mode. 1: gpio34 is in output mode. (open-drain). 3 gpio33_oe r/w 0 0: gpio33 is in input mode. 1: gpio33 is in output mode. (open-drain). 2 gpio32_oe r/w 0 0: gpio32 is in input mode. 1: gpio32 is in output mode. (open-drain). 1 gpio31_oe r/w 0 0: gpio31 is in input mode. 1: gpio31 is in output mode. (open-drain). 0 gpio30_oe r/w 0 0: gpio30 is in input mode. 1: gpio30 is in output mode. (open-drain). 6.8.21 gpio3 output data register ? index c1h bit name r/w default description 7 gpio37_val r/w 1 0: gpio37 outputs 0 when in output mode. 1: gpio37 outputs 1 when in output mode. 6 gpio36_val r/w 1 0: gpio36 outputs 0 when in output mode. 1: gpio36 outputs 1 when in output mode.
oct., 2011 v0.19p 119 F71869A 5 gpio35_val r/w 1 0: gpio35 outputs 0 when in output mode. 1: gpio35 outputs 1 when in output mode. 4 gpio34_val r/w 1 0: gpio34 outputs 0 when in output mode. 1: gpio34 outputs 1 when in output mode. 3 gpio33_val r/w 1 0: gpio33 outputs 0 when in output mode. 1: gpio33 outputs 1 when in output mode. 2 gpio32_val r/w 1 0: gpio32 outputs 0 when in output mode. 1: gpio32 outputs 1 when in output mode. 1 gpio31_val r/w 1 0: gpio31 outputs 0 when in output mode. 1: gpio31 outputs 1 when in output mode. 0 gpio30_val r/w 1 0: gpio30 outputs 0 when in output mode. 1: gpio30 outputs 1 when in output mode. 6.8.22 gpio3 pin status register ? index c2h bit name r/w default description 7 gpio37_in r - the pin status of wgate#/gpio37. 6 gpio36_in r - the pin status of hdsel#/gpio36. 5 gpio35_in r - the pin status of step#/gpio35. 4 gpio34_in r - the pin status of dir#/gpio34. 3 gpio33_in r - the pin status of wdata#/gpio3. 2 gpio32_in r - the pin status of drva#/gpio32. 1 gpio31_in r - the pin status of moa#/gpio31. 0 gpio30_in r - the pin status of densel#/gpio30. 6.8.23 gpio4 output enable register ? index b0h bit name r/w default description 7 gpio47_oe r/w 0 0: gpio47 is in input mode. 1: gpio47 is in output mode. 6 gpio46_oe r/w 0 0: gpio46 is in input mode. 1: gpio46 is in output mode. 5 gpio45_oe r/w 0 0: gpio45 is in input mode. 1: gpio45 is in output mode. 4 gpio44_oe r/w 0 0: gpio44 is in input mode. 1: gpio44 is in output mode. 3 gpio43_oe r/w 0 0: gpio43 is in input mode. 1: gpio43 is in output mode. 2 gpio42_oe r/w 0 0: gpio42 is in input mode. 1: gpio42 is in output mode. 1 gpio41_oe r/w 0 0: gpio41 is in input mode. 1: gpio41 is in output mode. 0 gpio40_oe r/w 0 0: gpio40 is in input mode. 1: gpio40 is in output mode. 6.8.24 gpio4 output data register ? index b1h bit name r/w default description
oct., 2011 v0.19p 120 F71869A 7 gpio47_val r/w 1 0: gpio47 outputs 0 when in output mode. 1: gpio47 outputs 1 when in output mode. 6 gpio46_val r/w 1 0: gpio46 outputs 0 when in output mode. 1: gpio46 outputs 1 when in output mode. 5 gpio45_val r/w 1 0: gpio45 outputs 0 when in output mode. 1: gpio45 outputs 1 when in output mode. 4 gpio44_val r/w 1 0: gpio44 outputs 0 when in output mode. 1: gpio44 outputs 1 when in output mode. 3 gpio43_val r/w 1 0: gpio43 outputs 0 when in output mode. 1: gpio43 outputs 1 when in output mode. 2 gpio42_val r/w 1 0: gpio42 outputs 0 when in output mode. 1: gpio42 outputs 1 when in output mode. 1 gpio41_val r/w 1 0: gpio41 outputs 0 when in output mode. 1: gpio41 outputs 1 when in output mode. 0 gpio40_val r/w 1 0: gpio40 outputs 0 when in output mode. 1: gpio40 outputs 1 when in output mode. 6.8.25 gpio4 pin status register ? index b2h bit name r/w default description 7 gpio47_in r - the pin status of ps_on#/gpio47. 6 gpio46_in r - the pin status of psout#/gpio46 5 gpio45_in r - the pin status of psin#/gpio45 4 gpio44_in r - the pin status of atxpg_in/gpio44 3 gpio43_in r - the pin status of irrx/gpio43. 2 gpio42_in r - the pin status of irtx/gpio42. 1 gpio41_in r - the pin status of fanctl3/gpio41. 0 gpio40_in r - the pin status of fanin3/gpio40. 6.8.26 gpio4 drive enable register ? index b3h bit name r/w default description 7 gpio47_drv_en r/w 0 0: gpio47 is open drain in output mode. 1: gpio47 is push pull in output mode. 6 gpio46_drv_en r/w 0 0: gpio46 is open drain in output mode. 1: gpio46 is push pull in output mode. 5 gpio45_drv_en r/w 0 0: gpio45 is open drain in output mode. 1: gpio45 is push pull in output mode. 4 gpio44_drv_en r/w 0 0: gpio44 is open drain in output mode. 1: gpio44 is push pull in output mode. 3 gpio43_drv_en r/w 0 0: gpio43 is open drain in output mode. 1: gpio43 is push pull in output mode. 2 gpio42_drv_en r/w 0 0: gpio42 is open drain in output mode. 1: gpio42 is push pull in output mode. 1 gpio41_drv_en r/w 0 0: gpio41 is open drain in output mode. 1: gpio41 is push pull in output mode.
oct., 2011 v0.19p 121 F71869A 0 gpio40_drv_en r/w 0 0: gpio40 is open drain in output mode. 1: gpio40 is push pull in output mode. 6.8.27 gpio4 pme enable register ? index b4h bit name r/w default description 7-4 reserved - - reserved 3 gpio43_pme_en r/w 0 when gpio43_event_sts is 1 and gpio43_pme_en is set to 1, a gpio pme event will be generated. 2 gpio42_pme_en r/w 0 when gpio42_event_sts is 1 and gpio42_pme_en is set to 1, a gpio pme event will be generated. 1 gpio41_pme_en r/w 0 when gpio41_event_sts is 1 and gpio41_pme_en is set to 1, a gpio pme event will be generated. 0 gpio40_pme_en r/w 0 when gpio40_event_sts is 1 and gpio40_pme_en is set to 1, a gpio pme event will be generated. 6.8.28 gpio4 input detection select register ? index b5h bit name r/w default description 7-4 reserved - - reserved 3 gpio43_det_sel r/w 0 when gpio43 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 2 gpio42_det_sel r/w 0 when gpio42 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 1 gpio41_det_sel r/w 0 when gpio41 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 0 gpio40_det_sel r/w 0 when gpio40 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 6.8.29 gpio4 event status register ? index b6h bit name r/w default description 7-4 reserved - - reserved 3 gpio43_ event_sts r/w - when gpio43 is in input mode and a gpio43 input is detected according to crb5[3], this bit will be set to 1. write a 1 to this bit will clear it to 0. 2 gpio42_ event_sts r/w - when gpio42 is in input mode and a gpio42 input is detected according to crb5[2], this bit will be set to 1. write a 1 to this bit will clear it to 0.
oct., 2011 v0.19p 122 F71869A 1 gpio41_ event_sts r/w - when gpio41 is in input mode and a gpio41 input is detected according to crb5[1], this bit will be set to 1. write a 1 to this bit will clear it to 0. 0 gpio40_ event_sts r/w - when gpio40 is in input mode and a gpio40 input is detected according to crb5[0], this bit will be set to 1. write a 1 to this bit will clear it to 0. 6.8.30 gpio5 output enable register ? index a0h bit name r/w default description 7-5 reserved - - reserved. 4 gpio54_oe r/w 0 0: gpio54 is in input mode. 1: gpio54 is in output mode. 3 gpio53_oe r/w 0 0: gpio53 is in input mode. 1: gpio53 is in output mode. 2 gpio52_oe r/w 0 0: gpio52 is in input mode. 1: gpio52 is in output mode. 1 gpio51_oe r/w 0 0: gpio51 is in input mode. 1: gpio51 is in output mode. 0 gpio50_oe r/w 0 0: gpio50 is in input mode. 1: gpio50 is in output mode. 6.8.31 gpio5 output data register ? index a1h bit name r/w default description 7-5 reserved - - reserved. 4 gpio54_val r/w 1 0: gpio54 outputs 0 when in output mode. 1: gpio54 outputs 1 when in output mode. 3 gpio53_val r/w 1 0: gpio53 outputs 0 when in output mode. 1: gpio53 outputs 1 when in output mode. 2 gpio52_val r/w 1 0: gpio52 outputs 0 when in output mode. 1: gpio52 outputs 1 when in output mode. 1 gpio51_val r/w 1 0: gpio51 outputs 0 when in output mode. 1: gpio51 outputs 1 when in output mode. 0 gpio50_val r/w 1 0: gpio50 outputs 0 when in output mode. 1: gpio50 outputs 1 when in output mode. 6.8.32 gpio5 pin status register ? index a2h bit name r/w default description 7-5 reserved - - reserved. 4 gpio54_in r - the pin status of dskchg#/gpio54. 3 gpio53_in r - the pin status of wpt#/gpio53. 2 gpio52_in r - the pin status of index#/gpio52. 1 gpio51_in r - the pin status of trk0#/gpio51. 0 gpio50_in r - the pin status of rddata#/gpio50.
oct., 2011 v0.19p 123 F71869A 6.8.33 gpio5 pme enable register ? index a4h bit name r/w default description 7 gpio37_pme_en r/w 0 when gpio37_event_sts is 1 and gpio37 _ pme_en is set to 1, a gpio pme event will be generated. 6 gpio36_pme_en r/w 0 when gpio37_event_sts is 1 and gpio37 _ pme_en is set to 1, a gpio pme event will be generated. 5 gpio35_pme_en r/w 0 when gpio37_event_sts is 1 and gpio37 _ pme_en is set to 1, a gpio pme event will be generated. 4 gpio54_pme_en r/w 0 when gpio54_event_sts is 1 and gpio54_pme_en is set to 1, a gpio pme event will be generated. 3 gpio53_pme_en r/w 0 when gpio53_event_sts is 1 and gpio53_pme_en is set to 1, a gpio pme event will be generated. 2 gpio52_pme_en r/w 0 when gpio52_event_sts is 1 and gpio52_pme_en is set to 1, a gpio pme event will be generated. 1 gpio51_pme_en r/w 0 when gpio51_event_sts is 1 and gpio51_pme_en is set to 1, a gpio pme event will be generated. 0 gpio50_pme_en r/w 0 when gpio50_event_sts is 1 and gpio50_pme_en is set to 1, a gpio pme event will be generated. 6.8.34 gpio5 input detection select register ? index a5h bit name r/w default description 7 gpio37_det_sel r/w 0 when gpio37 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 6 gpio36_det_sel r/w 0 when gpio36 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 5 gpio35_det_sel r/w 0 when gpio35 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 4 gpio54_det_sel r/w 0 when gpio54 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 3 gpio53_det_sel r/w 0 when gpio53 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 2 gpio52_det_sel r/w 0 when gpio52 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge
oct., 2011 v0.19p 124 F71869A 1 gpio51_det_sel r/w 0 when gpio51 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 0 gpio50_det_sel r/w 0 when gpio50 is in input mode, set this bit to select which input event should be detected. 0: rising edge 1: falling edge 6.8.35 gpio5 event status register ? index a6h bit name r/w default description 7 gpio37_ event_sts r/w - when gpio37 is in input mode and a gpio37 input is detected according to cra5[7], this bit will be set to 1. write a 1 to this bit will clear it to 0. 6 gpio36_ event_sts r/w - when gpio36 is in input mode and a gpio36 input is detected according to cra5[6], this bit will be set to 1. write a 1 to this bit will clear it to 0. 5 gpio35_ event_sts r/w - when gpio35 is in input mode and a gpio35 input is detected according to cra5[5], this bit will be set to 1. write a 1 to this bit will clear it to 0. 4 gpio54_ event_sts r/w - when gpio54 is in input mode and a gpio54 input is detected according to cra5[4], this bit will be set to 1. write a 1 to this bit will clear it to 0. 3 gpio53_ event_sts r/w - when gpio53 is in input mode and a gpio53 input is detected according to cra5[3], this bit will be set to 1. write a 1 to this bit will clear it to 0. 2 gpio52_ event_sts r/w - when gpio52 is in input mode and a gpio52 input is detected according to crb5[2], this bit will be set to 1. write a 1 to this bit will clear it to 0. 1 gpio51_ event_sts r/w - when gpio51 is in input mode and a gpio51 input is detected according to crb5[1], this bit will be set to 1. write a 1 to this bit will clear it to 0. 0 gpio50_ event_sts r/w - when gpio50 is in input mode and a gpio50 input is detected according to crb5[0], this bit will be set to 1. write a 1 to this bit will clear it to 0. 6.8.36 gpio5 kbc emulation control register 1 ? index a9h bit name r/w default description 7-6 delay_time r/w 00 the delay time for repeat make code. 00: 500ms ~ 750ms. 01: 750ms ~ 1000ms. 10: 1000ms ~ 1250ms. 11: 1250ms ~ 1500ms. 5-4 rep_time r/w 00 the make code repeat time select. 00: 50ms. 01: 100ms. 10: 250ms. 11: 500ms.
oct., 2011 v0.19p 125 F71869A 3 event_en_sel r/w 0 0: index 0xaf is gpio5 event enable register. 1: index 0xaf is gpio3 event enable register. 2-0 make_code_se l r/w 000 make code select. select which make code to be accessed. 000: gpio50 make code. 001: gpio51 make code. 010: gpio52 make code. 011: gpio53 make code. 100: gpio54 make code. 101: gpio35 make code. 110: gpio36 make code. 111: gpio37 make code. this changes the content of gp_make_code register (crab). 6.8.37 gpio5 kbc make code register ? index abh bit name r/w default description 7-0 gp_make_code r/w 00h this byte is the make code for gpio5 kbc emulation. the break code will be gp_make_code + 0x80. 6.8.38 gpio5 kbc prefix code register ? index ach bit name r/w default description 7-0 gp_pre_code r/w e0h this byte is the prefix code for gpio5 kbc emulation if pre_code_en is set. 6.8.39 gpio5 kbc emulation status register 1 ? index adh bit name r/w default description 7 gp37_brk_sts r/w 0 break code status of gpio37. it will be set if gpio37 is released (rising edge). write ?1? to clear this bit. 6 gp36_brk_sts r/w 0 break code status of gpio36. it will be set if gpio36 is released (rising edge). write ?1? to clear this bit. 5 gp35_brk_sts r/w 0 break code status of gpio35. it will be set if gpio35 is released (rising edge). write ?1? to clear this bit. 4 gp54_brk_sts r/w 0 break code status of gpio54. it will be set if gpio54 is released (rising edge). write ?1? to clear this bit. 3 gp53_brk_sts r/w 0 break code status of gpio53. it will be set if gpio53 is released (rising edge). write ?1? to clear this bit. 2 gp52_brk_sts r/w 0 break code status of gpio52. it will be set if gpio52 is released (rising edge). write ?1? to clear this bit. 1 gp51_brk_sts r/w 0 break code status of gpio51. it will be set if gpio51 is released (rising edge). write ?1? to clear this bit. 0 gp50_brk_sts r/w 0 break code status of gpio50. it will be set if gpio50 is released (rising edge). write ?1? to clear this bit. 6.8.40 gpio5 kbc emulation status register 2 ? index aeh bit name r/w default description 7 gp37_make_sts r/w 0 make code status of gpio37. it will be set if gpio37 is pressed (falling edge). write ?1? to clear this bit.
oct., 2011 v0.19p 126 F71869A 6 gp36_make_sts r/w 0 make code status of gpio36. it will be set if gpio36 is pressed (falling edge). write ?1? to clear this bit. 5 gp35_make_sts r/w 0 make code status of gpio35. it will be set if gpio35 is pressed (falling edge). write ?1? to clear this bit. 4 gp54_make_sts r/w 0 make code status of gpio54. it will be set if gpio54 is pressed (falling edge). write ?1? to clear this bit. 3 gp53_make_sts r/w 0 make code status of gpio53. it will be set if gpio53 is pressed (falling edge). write ?1? to clear this bit. 2 gp52_make_sts r/w 0 make code status of gpio52. it will be set if gpio52 is pressed (falling edge). write ?1? to clear this bit. 1 gp51_make_sts r/w 0 make code status of gpio51. it will be set if gpio51 is pressed (falling edge). write ?1? to clear this bit. 0 gp50_make_sts r/w 0 make code status of gpio50. it will be set if gpio50 is pressed (falling edge). write ?1? to clear this bit. 6.8.41 gpio5 kbc emulation control register 2 ? index afh bit name r/w default description 7 gp_kbc_en r/w 0 0: disable kbc emulation function. 1: enable kbc emulation function. this bit is only available when event_en_sel is ?0? 6 pre_code_en r/w 0 0: one byte is sent when gpio5 event occurs. 1: two bytes are sent when gpio5 event occurs. the prefix code is defined by gp_pre_code. this bit is only available when event_en_sel is ?0? 5 reserved - - reserved. 4 gp54_event_en r/w 0 0: disable gpio54 event detection. 1: enable gpio54 event detection. this bit is only available when event_en_sel is ?0? 3 gp53_event_en r/w 0 0: disable gpio53 event detection. 1: enable gpio53 event detection. this bit is only available when event_en_sel is ?0? 2 gp52_event_en/ gp37_event_en r/w 0 when event_en_sel is ?1?, t he register is gp37_event_en. 0: disable gpio52/gpio37 event detection. 1: enable gpio52/gpio37 event detection. 1 gp51_event_en/ gp36_event_en r/w 0 when event_en_sel is ?1?, t he register is gp36_event_en. 0: disable gpio51/gpio36 event detection. 1: enable gpio51/gpio37 event detection. 0 gp50_event_en/ gp35_event_en r/w 0 when event_en_sel is ?1?, t he register is gp35_event_en. 0: disable gpio50/gpio35 event detection. 1: enable gpio50/gpio35 event detection. 6.8.42 gpio6 output enable register ? index 90h bit name r/w default description 7 gpio67_oe r/w 0 0: gpio67 is in input mode. 1: gpio67 is in output mode. 6 gpio66_oe r/w 0 0: gpio66 is in input mode. 1: gpio66 is in output mode.
oct., 2011 v0.19p 127 F71869A 5 gpio65_oe r/w 0 0: gpio65 is in input mode. 1: gpio65 is in output mode. 4 gpio64_oe r/w 0 0: gpio64 is in input mode. 1: gpio64 is in output mode. 3 gpio63_oe r/w 0 0: gpio63 is in input mode. 1: gpio63 is in output mode. 2 gpio62_oe r/w 0 0: gpio62 is in input mode. 1: gpio62 is in output mode. 1 gpio61_oe r/w 0 0: gpio61 is in input mode. 1: gpio61 is in output mode. 0 gpio60_oe r/w 0 0: gpio60 is in input mode. 1: gpio60 is in output mode. 6.8.43 gpio6 output data register ? index 91h bit name r/w default description 7 gpio67_val r/w 1 0: gpio67 outputs 0 when in output mode. 1: gpio67 outputs 1 when in output mode. 6 gpio66_val r/w 1 0: gpio66 outputs 0 when in output mode. 1: gpio66 outputs 1 when in output mode. 5 gpio65_val r/w 1 0: gpio65 outputs 0 when in output mode. 1: gpio65 outputs 1 when in output mode. 4 gpio64_val r/w 1 0: gpio64 outputs 0 when in output mode. 1: gpio64 outputs 1 when in output mode. 3 gpio63_val r/w 1 0: gpio63 outputs 0 when in output mode. 1: gpio63 outputs 1 when in output mode. 2 gpio62_val r/w 1 0: gpio62 outputs 0 when in output mode. 1: gpio62 outputs 1 when in output mode. 1 gpio61_val r/w 1 0: gpio61 outputs 0 when in output mode. 1: gpio61 outputs 1 when in output mode. 0 gpio60_val r/w 1 0: gpio60 outputs 0 when in output mode. 1: gpio60 outputs 1 when in output mode. 6.8.44 gpio6 pin status register ? index 92h bit name r/w default description 7 gpio67_in r - the pin status of stb#/gpio67. 6 gpio66_in r - the pin status of afd#/gpio66. 5 gpio65_in r - the pin status of err#/gpio65. 4 gpio64_in r - the pin status of init#/gpio64. 3 gpio63_in r - the pin status of ack#/gpio63. 2 gpio62_in r - the pin status of busy/gpio62. 1 gpio61_in r - the pin status of pe/gpio61. 0 gpio60_in r - the pin status of slct/gpio60.
oct., 2011 v0.19p 128 F71869A 6.8.45 gpio6 drive enable register ? index 93h bit name r/w default description 7 gpio67_drv_en r/w 0 0: gpio67 is open drain in output mode. 1: gpio67 is push pull in output mode. 6 gpio66_drv_en r/w 0 0: gpio66 is open drain in output mode. 1: gpio66 is push pull in output mode. 5 gpio65_drv_en r/w 0 0: gpio65 is open drain in output mode. 1: gpio65 is push pull in output mode. 4 gpio64_drv_en r/w 0 0: gpio64 is open drain in output mode. 1: gpio64 is push pull in output mode. 3 gpio63_drv_en r/w 0 0: gpio63 is open drain in output mode. 1: gpio63 is push pull in output mode. 2 gpio62_drv_en r/w 0 0: gpio62 is open drain in output mode. 1: gpio62 is push pull in output mode. 1 gpio61_drv_en r/w 0 0: gpio61 is open drain in output mode. 1: gpio61 is push pull in output mode. 0 gpio60_drv_en r/w 0 0: gpio60 is open drain in output mode. 1: gpio60 is push pull in output mode. 6.8.46 gpio7 output enable register ? index 80h bit name r/w default description 7 gpio77_oe r/w 0 0: gpio77 is in input mode. 1: gpio77 is in output mode. 6 gpio76_oe r/w 0 0: gpio76 is in input mode. 1: gpio76 is in output mode. 5 gpio75_oe r/w 0 0: gpio75 is in input mode. 1: gpio75 is in output mode. 4 gpio74_oe r/w 0 0: gpio74 is in input mode. 1: gpio74 is in output mode. 3 gpio73_oe r/w 0 0: gpio73 is in input mode. 1: gpio73 is in output mode. 2 gpio72_oe r/w 0 0: gpio72 is in input mode. 1: gpio72 is in output mode. 1 gpio71_oe r/w 0 0: gpio71 is in input mode. 1: gpio71 is in output mode. 0 gpio70_oe r/w 0 0: gpio70 is in input mode. 1: gpio70 is in output mode. 6.8.47 gpio7 output data register ? index 81h bit name r/w default description 7 gpio77_val r/w 1 0: gpio77 outputs 0 when in output mode. 1: gpio77 outputs 1 when in output mode. 6 gpio76_val r/w 1 0: gpio76 outputs 0 when in output mode. 1: gpio76 outputs 1 when in output mode.
oct., 2011 v0.19p 129 F71869A 5 gpio75_val r/w 1 0: gpio75 outputs 0 when in output mode. 1: gpio75 outputs 1 when in output mode. 4 gpio74_val r/w 1 0: gpio74 outputs 0 when in output mode. 1: gpio74 outputs 1 when in output mode. 3 gpio73_val r/w 1 0: gpio73 outputs 0 when in output mode. 1: gpio73 outputs 1 when in output mode. 2 gpio72_val r/w 1 0: gpio72 outputs 0 when in output mode. 1: gpio72 outputs 1 when in output mode. 1 gpio71_val r/w 1 0: gpio71 outputs 0 when in output mode. 1: gpio71 outputs 1 when in output mode. 0 gpio70_val r/w 1 0: gpio70 outputs 0 when in output mode. 1: gpio70 outputs 1 when in output mode. 6.8.48 gpio7 pin status register ? index 82h bit name r/w default description 7 gpio77_in r - the pin status of pd7/gpio77. 6 gpio76_in r - the pin status of pd6/gpio76. 5 gpio75_in r - the pin status of pd5/gpio75. 4 gpio74_in r - the pin status of pd4/gpio74. 3 gpio73_in r - the pin status of pd3/gpio73. 2 gpio72_in r - the pin status of pd2/gpio72. 1 gpio71_in r - the pin status of pd1/gpio71. 0 gpio70_in r - the pin status of pd0/gpio70. 6.8.49 gpio7 drive enable register ? index 83h bit name r/w default description 7 gpio77_drv_en r/w 0 0: gpio77 is open drain in output mode. 1: gpio77 is push pull in output mode. 6 gpio76_drv_en r/w 0 0: gpio76 is open drain in output mode. 1: gpio76 is push pull in output mode. 5 gpio75_drv_en r/w 0 0: gpio75 is open drain in output mode. 1: gpio75 is push pull in output mode. 4 gpio74_drv_en r/w 0 0: gpio74 is open drain in output mode. 1: gpio74 is push pull in output mode. 3 gpio73_drv_en r/w 0 0: gpio73 is open drain in output mode. 1: gpio73 is push pull in output mode. 2 gpio72_drv_en r/w 0 0: gpio72 is open drain in output mode. 1: gpio72 is push pull in output mode. 1 gpio71_drv_en r/w 0 0: gpio71 is open drain in output mode. 1: gpio71 is push pull in output mode. 0 gpio70_drv_en r/w 0 0: gpio70 is open drain in output mode. 1: gpio70 is push pull in output mode.
oct., 2011 v0.19p 130 F71869A 6.9 watch dog timer registers (cr07) 6.9.1 wdt enable register ? index 30h bit name r/w default description 7-1 reserved - 0 reserved 0 wdt_en r/w 0 0: disable watch dog timer 1: enable watch dog timer 6.9.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 00h the m sb of wdt base address. 6.9.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w 00h the l sb of wdt base address. 6.9.4 configuration register ? index f0h (offset 00h) (* cleared by slotocc# and watch dog timeout) bit name r/w default description 7 wdout_en r/w - this bit is decided by rts1# power-on trapping. if this bit is set to 1 and watchd og timeout event occurs, wdtrst# output is enabled. 6-1 reserved - - reserved 0 wd_rst_en r/w 1 0: disable wdt to reset the vid register marked with *. 1: enable wdt to reset the vi d register marked with *. 6.9.5 serial key data register 1 ? index f2h (offset 02h) bit name r/w default description 7 reserved - - reserved 6 key_ok r 1 this bit is 1 represents that t he serial key is entered correctly. 5-0 reserved - - reserved 6.9.6 serial key data register 2 ? index f3h (offset 03h) bit name r/w default description 7-0 key_data r/w f3h write serial data to this register co rrectly, the key_ok bit will be set to 1. hence, users are able to wr ite key protected registers. the sequence to enable key_ok is 0x 32, 0x5d, 0x42, 0xac. when key_ok is set, write this r egister 0x35 will clear key_ok.
oct., 2011 v0.19p 131 F71869A 6.9.7 reserved ? index f4h (offset 04h) bit name r/w default description 7-0 reserved - - reserved 6.9.8 watchdog timer configuration register 1 ? index f5h (offset 05h) bit name r/w default description 7 wdt_clk_sel r 0 select the wdt clock source. 0: the clock source is from clkin. (powered by vdd and is accurate)\ 1: the clock source is from in ternal 500khz (powered by vsb3v and 20% tolerance). 6 wdtmout_sts r/w 0 if watchdog timeout event occurs, this bit will be set to 1. write a 1 to this bit will clear it to 0. 5 wd_en r/w - this bit is decided by rts1# power-on trapping. if this bit is set to 1, the counting of watchdog time is enabled. 4 wd_pulse r/w 0 select output mode (0: level, 1: pulse) of rstout# by setting this bit. 3 wd_unit r/w 0 select time unit (0: 1sec, 1: 60 sec) of watchdog timer by setting this bit. 2 wd_hactive r/w 0 select output polarity of rstout# (1: high active, 0: low active) by setting this bit. 1:0 wd_pswidth r/w 0 select output pulse width of rstout# 0: 750 us 1: 18 ms 2: 93 ms 3: 3.75 sec 6.9.9 watchdog timer configuration register 2 ? index f6h (offset 06h) bit name r/w default description 7:0 wd_time r/w 0a time of watchdog timer 6.9.10 wdt pme register ? index f7h (offset 07h) bit name r/w default description 7 wdt_pme r 0 wdt pme real time status. 6 wdt_pme_en r/w 0 0: disable wdt pme. 1: enable wdt pme. 6 wdt_pme_st r/w 0 0: no wdt pme occurred. 1: wdt pme occurred. the wdt pme is occurred one unit before wdt timeout. 4-1 reserved r 0 reserved
oct., 2011 v0.19p 132 F71869A 0 cpu_change r/w c - this bit will be set at slotocc# rising edge. internal 1us de-bounce circuit is implemented. write ?1? to th is bit will clear the status.(this bit is powered by vbat.) 6.10 cir registers (cr08) configuration registers 6.10.1 cir enable register ? index 30h bit name r/w default description 7-1 reserved - 0 reserved 0 cir_en r/w 0 0: disable cir 1: enable cir 6.10.2 base address high register ? index 60h bit name r/w default description 7-0 base_addr_hi r/w 00h the m sb of cir base address. 6.10.3 base address low register ? index 61h bit name r/w default description 7-0 base_addr_lo r/w 00h the lsb of cir base address. 6.10.4 cirirq channel select register ? index 70h bit name r/w default description 7-4 reserved - - reserved. 3-0 selcirirq r/w 0h select the irq channel for cir interrupt. device registers 6.10.5 cir status register ? index 00h bit name r/w default description 7 cir_irq_en r/w 0 cir irq function enable 6-4 reserved r 0 reserved 3 tx_finish r/w 0 cir transmittion finish status. write 1 clear. 2 tx_underrun r/w 0 cir transmitttion underrun status. write 1 clear. 1 rx_timeout r/w 0 cir receiver timeout status. write 1 clear. 0 rx_receive r/w 0 cir receiver rece ives data status. write 1 clear. 6.10.6 cir rx data register ? index 01h bit name r/w default description
oct., 2011 v0.19p 133 F71869A 7-0 rx_data r - cir received data is read from here. 6.10.7 cir tx control register ? index 02h bit name r/w default description 7 tx_start r/w 0 set 1 to start cir tx transmittion and will be auto cleared if transmittion is finished. 6 tx_end r/w 0 set 1 to indicate that all tx data has been written to cir tx fifo. 5-0 reserved - - reserved 6.10.8 cir tx data register ? index 03h bit name r/w default description 7-0 tx_data r/w - the transmittion data should be written to tx_data. 6.10.9 cir control register ? index 04h bit name r/w default description 7-0 cir_cmd r/w 0 host writes command to cir. 6.11 pme, acpi, and erp power saving registers (cr0a) 6.11.1 device enable register ? index 30h bit name r/w default description 7-1 reserved - - reserved 0 pme_en r/w 0 0: disable pme. 1: enable pme. 6.11.2 erp enable register ? index e0h bit name r/w default description 7 eup_en r/w 0 0 : disable erp function 1: enable erp function 6 s3_back r/w 0 this bit will set ?1? when system is back from s3 state. 5-2 reserved - - reserved 1 ring_pme_en r/w 0 ring1 pme event enable. 0: disable ring1 pme event. 1: enable ring1 pme event, when ring1 falling edge detect 0 ring_psout_en r/w 0 ring1 psout event enable. 0: disable ring1 psout event. 1: enable ring1 psout event, when ring1 falling edge detect 6.11.3 erp control register ? index e1h bit name r/w default description
oct., 2011 v0.19p 134 F71869A 7-6 boot_mode r/w 11 write these two bits to select boot mode for always off/ always on/ keep last state. 00:always off 11:support always on and keep last state 10:reserved 01:reserved 5 s3_ erp_ctrl1#_dis r/w 0 if clear to ?0? erp_ctrl1# will output low when s3 state. else if set to ?1? erp_ctrl1# will output high when s3 state. 4 s3 _ erp_ctrl0#_dis r/w 0 if clear to ?0? erp_ctrl0# will output low when s3 state. else if set to ?1? erp_ctrl0# will output high when s3 state. 3 s5 _ erp_ctrl1#_dis r/w 1 if clear to ?0? erp_ctrl1# will output low when s5 state. else if set to ?1? erp_ctrl1# will output high when s5 state. 2 s5 _ erp_ctrl0#_dis r/w 1 if clear to ?0? erp_ctrl0# will output low when s5 state. else if set to ?1? erp_ctrl0# will output high when s5 state. 1 ac_ erp_ctrl1#_dis r/w 0 if clear to ?0? erp_ctrl1# will output low when after ac lost. else if set to ?1? erp_ctrl1# will output high when after ac lost. 0 ac_ erp_ctrl0#_dis r/w 0 if clear to ?0? erp_ctrl0# will output low when after ac lost. else if set to ?1? erp_ctrl0# will output high when after ac lost. 6.11.4 erp control register ? index e2h bit name r/w default description 7 ac_lost r - this bit is ac lost status and writes 1 to this bit will clear it. 6 reserved r/w 0 reserved 5 vsb_ctrl_en[1] r/w 1?b0 0: disable erp_ctrl1# assert rsmrst low 1: enable erp_ctrl1# assert rsmrst low 4 vsb_ctrl_en[0] r/w 1?b0 0: disable erp_ctrl0# assert rsmrst low 1: enable erp_ctrl0# assert rsmrst low 3-2 reserved r/w 0 reserved 1 rsmrst_det_5v _n r/w 0 device detects vsb5v power ok (4 .4v) and vsb3v_in become high, and after ~50ms de-bounce time rsmrst will become high. but when user set this bit to 1. rsmr st will not check vsb5v power ok. 0 reserved r - reserved 6.11.5 erp psin deb-register ? index e3h bit name r/w default description 7-0 ps_deb_time r/w 0x13 ps_in pin input de-bounce time default is ~20msec 6.11.6 erp rsmrst deb-register ? index e4h bit name r/w default description 7-0 rsmrst_deb_ti me r/w 0x09 rsmrst internal de-bounce time default is ~10msec 6.11.7 erp psout deb-register ? index e5h bit name r/w default description 7-0 ps_out_pulse_w r/w 0xc7 ps_out_out output pulse width default is ~200msec low pulse
oct., 2011 v0.19p 135 F71869A 6.11.8 erp pson deb-register ? index e6h bit name r/w default description 7-0 ps_on_deb_time r/w 0x09 pson_in pin i nput de-bounce time default is 10msec 6.11.9 erp s5 delay register ? index e7h bit name r/w default description 7-0 s5_del_time r/w 0x63 s5 to deep s5 state del ay time. the unit of this byte is 64 ms 6.11.10 wakeup enable register ? index e8h bit name r/w default description 7 ri2_wakeup_en r/w 0 set this bit to enable ri2# event to wakeup system. 6 cir_wakeup_en r/w 0 set this bit to enable cir event to wakeup system. 5 ri1_wakeup_en r/w 0 set this bit to enable ri1# event to wakeup system. 4 ring_wakeup_en r/w 1 set this bit to enable event_in0# event to wakeup system. 3 gp_wakeup_en r/w 0 set this bit to enable gpio event to wakeup system. 2 tmout_wakeup_en r/w 0 set this bit to enable timeout event to wakeup system. 1 mo_wakeup_en r/w 0 set this bit to enable mouse event to wakeup system. 0 kb_wakeup_en r/w 0 set this bit to enabl e keyboard event to wakeup system. 6.11.11 erp s3 delay register ? index e9h bit name r/w default description 7-0 s3_del_time r/w 0x0f s3 to deep s3 state delay time. the unit of this byte is 64ms. 6.11.12 erp mode select register ? index ech bit name r/w default description 7-6 erp_mode r/w 0 00: fintek g3? mode. 01: intel dsw + fintek g3` mode. 10: reserved. 11: intel dsw mode. 5 dpwrok_ctrl_ en r/w 0 set ?1? to enable dpwrok reset by erp_ctrl1#. 4-0 reserved r - reserved 6.11.13 erp wdt control register ? index edh bit name r/w default description 7-6 erp_wd_time[11 :10] r - time of erp watchdog timer. write index eeh will load watchdog time. 5 reserved r - reserved 4 erp_wdtmout r - time of erp watchdog timer. write index eeh will load watchdog time. 3-2 erp_wd_time[9: 8] r - reserved
oct., 2011 v0.19p 136 F71869A 1 wd_unit r/w 0 erp wdt unit. it is the time unit of erp_wd_time. 0: 1sec. 1: 60 sec. 0 wd_en r/w 0 set ?1? to enable erp wdt. auto clear if timeout occurs. 6.11.14 erp wdt timer ? index eeh bit name r/w default description 7-0 erp_wd_time r/w 0 time of erp watchdog timer. 6.11.15 pme event enable register 1 ? index f0h bit name r/w default description 7 wdt_pme_en r/w 0 wdt pme event enable. 0: disable wdt pme event. 1: enable wdt pme event. 6 mo_pme_en r/w 0 mouse pme event enable. 0: disable mouse pme event. 1: enable mouse pme event. 5 kb_pme_en r/w 0 keyboard pme event enable. 0: disable keyboard pme event. 1: enable keyboard pme event. 4 hm_pme_en r/w 0 hardware monitor pme event enable. 0: disable hardware monitor pme event. 1: enable hardware monitor pme event. 3 prt_pme_en r/w 0 parallel port pme event enable. 0: disable parallel port pme event. 1: enable parallel port pme event. 2 ur2_pme_en r/w 0 uart 2 pme event enable. 0: disable uart 2 pme event. 1: enable uart 2 pme event. 1 ur1_pme_en r/w 0 uart 1 pme event enable. 0: disable uart 1 pme event. 1: enable uart 1 pme event. 0 fdc_pme_en r/w 0 fdc pme event enable. 0: disable fdc pme event. 1: enable fdc pme event. 6.11.16 pme event status register ? index f1h bit name r/w default description 7 wdt_pme_st r/w - wdt pme event status. 0: wdt has no pme event. 1: wdt has a pme event to assert. write 1 to clear to be ready for next pme event. 6 mo_pme_st r/w - mouse pme event status. 0: mouse has no pme event. 1: mouse has a pme event to assert. write 1 to clear to be ready for next pme event.
oct., 2011 v0.19p 137 F71869A 5 kb_pme_st r/w - keyboard pme event status. 0: keyboard has no pme event. 1: keyboard has a pme event to assert. write 1 to clear to be ready for next pme event. 4 hm_pme_st r/w - hardware monitor pme event status. 0: hardware monitor has no pme event. 1: hardware monitor has a pme event to assert. write 1 to clear to be ready for next pme event. 3 prt_pme_st r/w - parallel port pme event status. 0: parallel port has no pme event. 1: parallel port has a pme event to assert. write 1 to clear to be ready for next pme event. 2 ur2_pme_st r/w - uart 2 pme event status. 0: uart 2 has no pme event. 1: uart 2 has a pme event to assert. write 1 to clear to be ready for next pme event. 1 ur1_pme_st r/w - uart 1 pme event status. 0: uart 1 has no pme event. 1: uart 1 has a pme event to assert. write 1 to clear to be ready for next pme event. 0 fdc_pme_st r/w - fdc pme event status. 0: fdc has no pme event. 1: fdc has a pme event to assert. write 1 to clear to be ready for next pme event. 6.11.17 pme event enable register 2 ? index f2h bit name r/w default description 7-5 reserved - - reserved 4 cir_pme_en r/w 0 cir pme event enable. 0: disable cir pme event. 1: enable cir pme event. 3 reserved - - reserved 2 ri2_pme_en r/w 0 ri2# pme event enable. 0: disable ri2# pme event. 1: enable ri2# pme event. 1 ri1_pme_en r/w 0 ri1# pme event enable. 0: disable ri1# pme event. 1: enable ri1# pme event. 0 gp_pme_en r/w 0 gpio pme event enable. 0: disable gpio pme event. 1: enable gpio pme event. 6.11.18 pme event status register ? index f3h bit name r/w default description 7-5 reserved - - reserved
oct., 2011 v0.19p 138 F71869A 4 cir_pme_st r/w - cir pme event status. 0: cir has no pme event. 1: cir has a pme event to assert. write 1 to clear to be ready for next pme event. 3 erp_pme_st r/w - erp pme event status. 0: erp has no pme event. 1: erp has a pme event to assert. write 1 to clear to be ready for next pme event. 2 ri2_pme_st r/w - ri2# pme event status. 0: ri2# has no pme event. 1: ri2# has a pme event to assert. write 1 to clear to be ready for next pme event. 1 ri1_pme_st r/w - ri1# pme event status. 0: ri1# has no pme event. 1: ri1# has a pme event to assert. write 1 to clear to be ready for next pme event. 0 gp_pme_st r/w - gpio pme event status. 0: gpio has no pme event. 1: gpio has a pme event to assert. write 1 to clear to be ready for next pme event. 6.11.19 keep last state select register ? index f4h bit name r/w default description 7 reserved - - - 6 en_cirwakeup r/w 0 set one to enable ci r wakeup event asserted via psout#. 5 en_gpwakeup r/w 0 set one to enable gpio wakeup event asserted via psout#. 4 en_kbwakeup r/w 0 set one to enable keyboard wakeup event asserted via psout#. 3 en_mowakeup r/w 0 set one to enable mouse wakeup event asserted via psout#. 2-1 pwrctrl r/w 11 the acpi control the pson_n to always on or always off or keep last state 00 : keep last state 10 : always on 01 : bypass mode. 11: always off 0 vsb_pwr_loss r/w 0 when vsb 3v comes, it will set to 1, and write 1 to clear it 6.11.20 vddok delay register ? index f5h (powered by vbat) bit name r/w default description 7-6 pwrok_delay r/w 0 the additional pwrok delay. the unit is 100 ms. 00: no delay 01: 1x 10: 2x 11: 4x 5 rstcon_en r/w 0 0: rstcon# will assert via pwrok. 1: rstcon# will assert via pcirst4# and pcirst5#.
oct., 2011 v0.19p 139 F71869A 4-3 vdd_delay r/w 11 the pwrok delay timing from vdd3vok by followed setting. the unit is 100 ms. 00 : 1x 01 : 2x 10 : 3x 11 : 4x 2 vindb_en r/w 1 enable the atxpwgd de-bounce. 1 pcirst_db_en r/w 0 enabl e the lreset_n de-bounce. 0 reserved r/w 0 reserved 6.11.21 pcirst control register ? index f6h bit name r/w default description 7 s3_sel r/w 0 select the kbc s3 state. 0: enter s3 state when internal vdd3vok signal de-asserted. 1: enter s3 state when s3# is low or the ts3 register is set to 1. 6 pson_del_en r/w 0 0: pson# is the inverted of s3# signal. 1: pson# will sink low only if the time after the last turn-off elapse at least 4 seconds. 5 reserved - - reserved 4 pcirst5_gate r/w 1 write ?0? to this bit will force pcirst5# to sink low. 3 pcirst4_gate r/w 1 write ?0? to this bit will force pcirst4# to sink low. 2 pcirst3_gate r/w 1 write ?0? to this bit will force pcirst3# to sink low. 1 pcirst2_gate r/w 1 write ?0? to this bit will force pcirst2# to sink low. 0 pcirst1_gate r/w 1 write ?0? to this bit will fo rce pcirst1# to sink low. 6.11.22 power sequence control register ? index f7h (powered by vbat) bit name r/w default description 7 vdimm_s3_on r/w 1 0: timing_1 will low during s3 state. 1: timing_1 will be tri-state during s3 state. 6 vdda_s3_on r/w 0 0: timing_2 will low during s3 state. 1: timing_2 will be tri-state during s3 state. 5 vcore_s3_on r/w 0 0: timing_3 will low during s3 state. 1: timing_3 will be tri-state during s3 state. 4 vldt_s3_on r/w 0 0: timing_4 will low during s3 state. 1: timing_4 will be tri-state during s3 state. 3 wdt_pwrok_en r/w 0 set ?1? to enable wdtrst# assert from pwrok pin. 2 s 0p5 _gate#_tri r/w 1 0: s 0p5 _gate# will sink low in s5 state. 1: s 0p5 _gate# will be tri-state in s5 state. 1 pwr_ s 3p5 _gate#_tri r/w 1 0: s 3p5 _gate# will sink low in s5 state. 1: s 3p5 _gate# will be tri-state in s5 state. 0 reserved r/w 0 reserved 6.11.23 led vcc mode select register ? index f8h bit name r/w default description
oct., 2011 v0.19p 140 F71869A 7 led_inv_dis r/w 0 0: default invert signal 1: invert disable 6 led_vcc_ds3 r/w 0 0: disable led_vcc deep s3 mode. 1: enable led_vcc deep s3 m ode. led_vcc will output 0.25hz clock with 75% duty when enter deep s3 state. 5-4 led_vcc_s5_mo de r/w 0 select led_vcc mode in s5 state. the mode is controlled by {led_vcc_s5_add, led_vcc_s5_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 3-2 led_vcc_s3_mo de r/w 0 select led_vcc mode in s3 state. the mode is controlled by {led_vcc_s3_add, led_vcc_s3_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 1-0 led_vcc_s0_mo de r/w 0 select led_vcc mode in s0 state. the mode is controlled by {led_vcc_s0_add, led_vcc_s0_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 6.11.24 led vsb mode select register ? index f9h bit name r/w default description 7 reserved - - reserved 6 led_vsb_ds3 r/w 0 0: disable led_vsb deep s3 mode. 1: enable led_vsb deep s3 mode. led_vsb will output 0.25hz clock with 25% duty when enter deep s3 state.
oct., 2011 v0.19p 141 F71869A 5-4 led_vsb_s5_mo de r/w 0 select led_vsb mode in s5 state. the mode is controlled by {led_vsb_s5_add, led_vsb_s5_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 25% duty. 111: 0.25hz clock with 25% duty. 3-2 led_vsb_s3_mo de r/w 0 select led_vsb mode in s3 state. the mode is controlled by {led_vsb_s3_add, led_vsb_s3_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 25% duty. 111: 0.25hz clock with 25% duty. 1-0 led_vsb_s0_mo de r/w 0 select led_vsb mode in s0 state. the mode is controlled by {led_vsb_s0_add, led_vsb_s0_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 25% duty. 111: 0.25hz clock with 25% duty. 6.11.25 led additional mode select register ? index fah bit name r/w default description 7 reserved - - reserved 6 led_vsb_s5_ad d r/w 0 select led_vsb mode in s5 state. the mode is controlled by {led_vsb_s5_add, led_vsb_s5_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty.
oct., 2011 v0.19p 142 F71869A 5 led_vsb_s3_ad d r/w 0 select led_vsb mode in s3 state. the mode is controlled by {led_vsb_s3_add, led_vsb_s3_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 4 led_vsb_s0_ad d r/w 0 select led_vsb mode in s0 state. the mode is controlled by {led_vsb_s0_add, led_vsb_s0_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 3 reserved - - reserved 2 led_vcc_s5_ad d r/w 0 select led_vcc mode in s5 state. the mode is controlled by {led_vcc_s5_add, led_vcc_s5_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 1 led_vcc_s3_ad d r/w 0 select led_vcc mode in s3 state. the mode is controlled by {led_vcc_s3_add, led_vcc_s3_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty.
oct., 2011 v0.19p 143 F71869A 0 led_vcc_s0_ad d r/w 0 select led_vcc mode in s0 state. the mode is controlled by {led_vcc_s0_add, led_vcc_s0_mode} 000: sink low. 001: tri-state. 010: 0.5hz clock. 011: 1hz clock. 100: 0.125hz clock with 50% duty. 101: 0.25hz clock with 50% duty. 110: 0.125hz clock with 75% duty. 111: 0.25hz clock with 75% duty. 6.11.26 intel dsw delay select register ? index fch bit name r/w default description 7-4 reserved r/w - reserved 3-0 dsw_delay r/w 7h this is the delay time for sus_ack# and sus_warn#. time unit is 0.5s. 6.11.27 ri de-bounce select register ? index feh bit name r/w default description 7 wr_trim_en r/w 0 after entry key is enabl ed, write ?1? to enable trim operation. 6 wr_key_en r/w 0 enable crfd for entry data. 5 reserved - - reserved 4 cir_vdd_s3 r/w 0 write ?1? to emulate a s3 state for cir. 3-2 reserved - - reserved 1-0 ri_db_sel r/w 0 select ri de-bounce time. 00: reserved. 01: 200us. 10: 2ms. 11: 20ms.
oct., 2011 v0.19p 144 F71869A 7. electrical characteristics 7.1 absolute maximum ratings parameter rating unit power supply voltage -0.5 to 5.5 v input voltage -0.5 to vdd+0.5 v operating temperature 0 to +70 c storage temperature -55 to 150 c note: exposure to conditions beyond those listed under absolute maximum ratings may dversely affect the life and reliability of the device. 7.2 dc characteristics (ta = 0 c to 70 c, 3vcc = 3.3v 10%, vss = 0v) parameter sym. min. typ. max. unit conditions operating voltage vdd 3.0 3.3 3.6 v battery voltage vbat 2.4 3.3 3.6 v operating current icc 10 ma 3vcc=3.3v vbat=3.3v idle state current isty 5 ua 3vcc=3.3v vbat=3.3v battery current ibat 4 ua 3vcc=3.3v vbat=3.3v parameter sym. min. typ. max. unit conditions i/o 12st,5v -ttl level bi-directional pin with schmitt trigger, output with12 ma sink capability, 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v output low current iol +12 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/o 16t,u47k -ttl level bi-directional pin with 16 ma sour ce-sink capability, internal pull-up 47k ohms input low voltage vil 0.8 v input high voltage vih 2.0 v output low current iol +16 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/ood 12t -ttl level bi-directional pin, output pin with 12ma source-sink capability, and can programming to open-drain function. input low threshold voltage vt- 0.8 v vdd = 3.3 v input high threshold voltage vt+ 2.0 v vdd = 3.3 v output low current iol -12 -9 ma vol = 0.4 v output high current ioh +9 +12 ma voh = 2.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/ood 12t,5v -ttl level bi-directional pin, output pin with 12ma source-sink capability, and can programming to open-drain function, 5v tolerance. input low threshold voltage vt- 0.8 v vdd = 3.3 v
oct., 2011 v0.19p 145 F71869A input high threshold voltage vt+ 2.0 v vdd = 3.3 v output low current iol -12 -9 ma vol = 0.4 v output high current ioh +9 +12 ma voh = 2.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/ood 8st,5v -ttl level bi-directional pin and schmitt triggrt, open-drain output with 8ma source-sink capability, 5v tolerance. input low threshold voltage vt- 0.8 v vdd = 3.3 v input high threshold voltage vt+ 2.0 v vdd = 3.3 v output low current iol -8 -9 ma vol = 0.4 v output high current ioh +9 +8 ma voh = 2.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/ood 12st,5v -ttl level bi-directional pin and schmitt triggrt, open-drain output with 12ma source-sink capability, 5v tolerance. input low threshold voltage vt- 0.8 v vdd = 3.3 v input high threshold voltage vt+ 2.0 v vdd = 3.3 v output low current iol -12 -9 ma vol = 0.4 v output high current ioh +9 +12 ma voh = 2.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/ood 24st,5v -ttl level bi-directional pin and schmitt triggrt, open-drain output with 24ma source-sink capability, 5v tolerance. input low threshold voltage vt- 0.8 v vdd = 3.3 v input high threshold voltage vt+ 2.0 v vdd = 3.3 v output low current iol -24 -9 ma vol = 0.4 v output high current ioh +9 +24 ma voh = 2.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v in st - ttl level input pin with schmitt trigger input low voltage vil 0.8 v input high voltage vih 2.0 v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v in t,5v - ttl level input pin with 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v in st,5v - ttl level input pin with schmitt trigger, 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v in st-u47k - ttl level input pin with schmitt trigger, internal pull-up 47k ohms input low voltage vil 0.8 v input high voltage vih 2.0 v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v in st,lv - ttl level input pin with schmitt trigger, low level. input low voltage vil 0.8 v input high voltage vih 2.0 v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v
oct., 2011 v0.19p 146 F71869A od 12 -open-drain output with12 ma sink capability. output low current iol -12 ma vol = 0.4v od 12,5v -open-drain output with12 ma sink capability, 5v tolerance. output low current iol -12 ma vol = 0.4v od 14,5v -open-drain output with14 ma sink capability, 5v tolerance. output low current iol -14 ma vol = 0.4v od 24,5v -open-drain output with24 ma sink capability, 5v tolerance. output low current iol -24 ma vol = 0.4v od 12,u10k,5v -open-drain output with 12 ma sink capability, pull-up 10k ohms, 5v tolerance. output low current iol -12 ma vol = 0.4v od 16,u10k,5v -open-drain output with 16 ma sink capability, pull-up 10k ohms, 5v tolerance. output low current iol -16 ma vol = 0.4v o 8t,u47,5v - ttl level output pin with 8 ma source-si nk capability, pull-up 47k ohms, 5v tolerance. output high current ioh +6 +8 ma voh = 2.4v o 12 - output pin with 12 ma source-sink capability. output high current ioh +9 +12 ma voh = 2.4v o 16 - output pin with 16 ma source-sink capability. output high current ioh +16 ma voh = 2.4v o 18 - output pin with 18 ma source-sink capability. output high current ioh +18 ma voh = 2.4v o 20 - output pin with 20 ma source-sink capability. output high current ioh +20 ma voh = 2.4v o 30 - output pin with 30 ma source-sink capability. output high current ioh +26 +30 ma voh = 2.4v o 12-5v - output pin with 12 ma source-sink capability, 5v tolerance. output high current ioh +9 +12 ma voh = 2.4v i lv /o d8-s1 - low level bi-directional pin (vih ? 0.9v, vil ? 0.6v.). output with 8ma drive and 1ma sink capability. input low voltage vil 0.6 v input high voltage vih 0.9 v output high current ioh +8 ma voh = 1.0v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0 v i/od 12st,5v -ttl level bi-directional pin with schmitt tri gger, open-drain output with12 ma sink capability, 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v output low current iol +12 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i lv /od 12st,5v -low level bi-directional pin with schmitt tr igger, open-drain output with12 ma sink capability, 5v tolerance. input low voltage vil 0.6 v input high voltage vih 0.9 v output low current iol +12 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v i/od 14st,5v -ttl level bi-directional pin with schmitt trigger, open-drain output with 16 ma sink capability, 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v output low current iol +14 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v
oct., 2011 v0.19p 147 F71869A i/od 16st,5v -ttl level bi-directional pin with schmitt trigger, open-drain output with 16 ma sink capability, 5v tolerance. input low voltage vil 0.8 v input high voltage vih 2.0 v output low current iol +16 ma vol = 0.4v input high leakage ilih +1 a vin = vdd input low leakage ilil -1 a vin = 0v 8. ordering information part number package type production flow F71869Ad 128-lqfp (green package) commercial, 0 c to +70 c 9. top marking specification F71869Ad xxxxxx x xxxxxx.x fintek logo 1 st line: device name ? F71869Ad, where d means the package type (128-lqfp) 2 nd line: assembly plant code (x) + assembled year code (x) + week code (xx) + fintek internal code (xx) + ic version (x) where a means version a, b means version b, ? 3 rd line: wafer fab code (xxxx?xx) fintek
oct., 2011 v0.19p 148 F71869A 10. package dimensions (128-lqfp) 128 lqfp (14*14) feature integration technology inc. headquarters taipei office 3f-7, no 36, tai yuan st., bldg. k4, 7f, no.700, chung cheng rd., chupei city, hsinchu, taiwan 302, r.o.c. chungho city, taipei, taiwan 235, r.o.c. tel : 886-3-5600168 tel : 866-2-8227-8027 fax : 886-3-5600166 fax : 866-2-8227-8037 www: http://www.fintek.com.tw please note that all datasheet and specifications are subject to change without notice. all the trade marks of products and companies mentioned in this datasheet belong to their respective owner
oct., 2011 v0.19p 149 F71869A 11. application circuit strap_protect densel# moa# index# drva# step# dir# wpt# rdata# wdata# wgate# trk0# 5 vcc3v dskchg# hdsel# pwok rsmrst# vsb3v r5 4.7k r1 4.7k rsmrst# and pwok pull-up ctrl0# lreset# sout2 disable uvp gpio23/dtr2#/segd 1 gpio24/rts2#/segc 2 gpio25/dsr2#/l# 3 3vcc 4 gpio26/sout2/segb/strap_dport 5 gpio27/sin2/sege 6 gpio30/densel# 7 gpio31/moa# 8 gpio32/drva# 9 gpio33/wdata# 10 gpio34/dir# 11 gpio35/step# 12 gpio36/hdsel# 13 gpio37/wgate# 14 gpio50/rdata# 15 gpio51/trk0# 16 gpio52/index# 17 gpio53/wpt# 18 gpio54/dskchg# 19 gnd 20 fanin1 21 fanctl1 22 fanin2 23 fanctl2 24 gpio40/fanin3 25 gpio41/fanctl3 26 gpio42/irtx 27 gpio43/irrx 28 lreset# 29 ldrq# 30 serirq 31 lfram# 32 lad0 33 lad1 34 lad2 35 lad3 36 3vcc 37 pciclk 38 clkin 39 kbrst# 40 ga20 41 event_in0# 42 erp_ctrl0# 43 erp_ctrl1# 44 5vsb 45 dpwrok/timing_3 46 slp_sus#/timing_4 47 gnd 48 cirwb#/gpio01 49 cirtx/gpio02 50 cirrx#/gpio03 51 strap_timing 52 sus_ack#/timing_2 53 sus_warn#/timing_1 54 s3p5_gate#/slotocc#/gpio04 55 s3_gate#/gpio05/wdtrst# 56 cir_led#/scl 57 peci/sda 58 gpio10/pci_rst4#/scl 59 gpio11/pci_rst5#/sda 60 gpio12/rstcon# 61 s0p5_gate#/gpio13/beep 62 wdtrst#/gpio14 63 gpio15/led_vsb/alert# 64 gpio16/led_vcc 65 cpu_pwgd/gpio17 66 ovt# 67 i_vsb3v 68 kdata 69 kclk 70 mdata 71 mclk 72 gnd 73 pcirst1# 74 pcirst2# 75 pcirst3# 76 s5# 77 atxpg_in/gpio44 78 pme# 79 psin#/gpio45 80 psout#/gpio46 81 s3# 82 ps_on#/gpio47 83 pwok 84 rsmrst# 85 vbat 86 copen# 87 agnd(d-) 88 d3+ 89 d2+ 90 d1+(cpu) 91 vref 92 vin6 93 vin5 94 vin4(vdimm) 95 vin3(vdda) 96 vin2(vldt) 97 vin1(vcore) 98 3vsb 99 slct/gpio60 100 pe/gpio61 101 busy /gpio62 102 ack#/gpio63 103 slin# 104 init#/gpio64 105 err#/gpio65 106 afd#/gpio66 107 stb#/gpio67 108 pd0/gpio70 109 pd1/gpio71 110 pd2/gpio72 111 pd3/gpio73 112 pd4/gpio74 113 pd5/gpio75 114 pd6/gpio76 115 pd7/gpio77 116 gnd 117 dcd1# 118 ri1# 119 cts1# 120 dtr1#/fan40_100 121 rts1#/strap_protect 122 dsr1# 123 sout1/strap4e_2e 124 sin1 125 dcd2#/segg/gpio20 126 ri2#/segf/gpio21 127 cts2#/sega/gpio22 128 F71869A f71869_10 tr k0# enable uvp dsr2# rts2# dtr2# sin2 sout2 s3_gate# & s3p5_gate# pull-up s3p5_gate# vsb3v r15 4.7k r16 4.7k s3_gate# 2 2 4 4 6 6 8 8 10 10 12 12 14 14 16 16 18 18 20 20 22 22 24 24 26 26 28 28 30 30 32 32 34 34 1 1 3 3 5 5 7 7 9 9 11 11 13 13 15 15 17 17 19 19 21 21 23 23 25 25 27 27 29 29 31 31 33 33 j1 header 17x2 strap_dport x_r128 1k 5va 1 2 c6 0.1u even_in# 80 port x_r129 1k com2 index# r115 10r fanctl2 2e 4e tit le size document number rev date: sheet of f71869ed&fdd 2.0 feature integration technology inc. b 18 thursday , february 10, 2011 fanctl3 kdat kclk md at mc lk pwok led_vcc cpu_pwgd ovt# psin# psout# s3# pson# pcirst3# s4# atxpg_in pme# pcirst1# pcirst2# sout2 strap_timing vcc3v vsb3v r10 1k config 4e/2e vcc3v function pin hi net name lo vbat wpt# s3 irrx irtx densel# sout1# dtr1# floppy conn. fanin1 r6 1k r4 1k r2 1k r3 1k r7 1k 26 vcc5v 22 wpt# rdata# tr k0# index# dskchg# 124 121 fan speed duty:40% fan speed duty:100% d12 diode 52 d13 diode fan40_100 fanctl1 drva# 1 2 c1 0.1u fanctl3 timing/gpio (place capacitor close to ic) vbat rts1# step# vcc3v 1 2 c3 0.1uf pciclk fanctl2 sout1# 24 vcc3v i_3vsb vsb3v 1 2 c4 0.1u fanctl1 1 2 c58 0.1u lad3 vbat 1 2 c2 0.1u vcc3v i_3vsb timing/gpio 1 2 c5 0.1u vbat (gnd close to ic) lad2 gpio timing dtr1# fanctl1 lad1 r9 1k moa# fanctl1 fanctl2 fanctl3 dskchg# d11 diode 3va r140 nc/0r hdsel# lad0 cts2# dtr1# cts1# ri1# dcd1# dir# sin1 sout1 dsr1# rts1# ri2# dcd2# linear fan linear fan pwm fan pwm fan pwm fan linear fan lframe# fanctl2 fanin2 pd7 ack# pd4 init# slin# pd5 pd6 pd0 stb# afd# err# pd3 pd2 pd1 atxpg_in serirq wgate# i_3vsb wdtrst# ldrq# r8 1k r12 1k peci ibx_clk led_vsb ibx_dat s3p5_gate# s3_gate# rstcon# cirled# cirtx sus_ack#/timing_2 cirrx# sus_warn#/timing_1 r11 1k strap_timing ctrl1# cirwb# strap_timing clk_24/48m kbrst# ga20 dpwrok/timing_3 slp_sus#/timing_4 power-on trip ga20 r14 1k s0p5_gate# clk_24/48m wdtrst# kbrst# fanin3 fanctl3 vdda(vin3) vcore(vin1) vldt(vin2) slct rsmrst# d3+ d- pe copen# vref d1+ d2+ busy vdimm(vin4) vin5 vin6 122 rdata# rts1# wdata#
oct., 2011 v0.19p 150 F71869A slct pe busy 1 2 3 4 5 6 7 8 rn5 33-8p4r 1 2 3 4 5 6 7 8 rn6 33-8p4r dtr2# rts2# dsr2# sout2 sin2 mc lk md at kclk kdat 1 2 3 4 5 6 7 8 rn2 2.7k-8p4r dcd1# ri1# cts1# dsr1# sin1 if you do not use the uart port 1, please pull-up these pin to vcc3v. r17 4.7k 1 2 3 4 5 6 7 8 rn4 2.7k-8p4r r18 4.7k r19 4.7k r20 4.7k r21 4.7k vcc3v 1 2 3 4 5 6 7 8 rn7 33-8p4r ring-in wake-up is supported by F71869A vcc5v/3v dcd2# ri2# cts2# dsr2# sin2 if you do not use the uart port 2, please pull-up these pin to vcc3v. r23 4.7k r24 4.7k r25 4.7k r26 4.7k vcc3v r27 4.7k 13 25 12 24 11 23 10 22 9 21 8 20 7 19 6 18 5 17 4 16 3 15 2 14 1 j2 db25 1 2 3 4 5 6 7 8 rn3 2.7k-8p4r 1 2 3 4 5 6 7 8 rn1 2.7k-8p4r cts2# dcd1# ri1# cts1# dtr1# rts1# dsr1# sout1 sin1 dcd2# ri2# vcc5v r28 4.7k c26 100p r22 2.7k r29 4.7k f1 fuse l1 fb c27 0.1u c25 100p l3 fb 1 2 3 4 5 6 js1 m-din_6-r r30 4.7k if you do not use the kbc, please pull-up these pin to vsb5v. l2 fb 1 2 3 4 5 6 js2 m-din_6-r c28 100p c30 0.1u l4 fb c29 100p f2 fuse r31 4.7k 1 2 3 j3 con3 vsb5v ps2 mouse interface ps2 keyboard interface rin2 dtrn2 -12v rtsn2 dsrn2 ctsn2 vcc 20 da1 16 da2 15 da3 13 ry1 19 ry2 18 ry3 17 ry4 14 ry5 12 gnd 11 +12v 1 dy1 5 dy2 6 dy3 8 ra1 2 ra2 3 ra3 4 ra4 7 ra9 9 -12v 10 u2 gnd sinn2 ctsn2 soutn2 vcc5v soutn2 dcdn2 dsrn2 sinn2 dcdn2 rtsn2 dtrn2 5 9 4 8 3 7 2 6 1 p2 uart db9 rin2 +12v vcc5v 1 2 d1 1n5819 pd4 ack# pd7 pd5 pd6 slin# init# err# afd# stb# pd0 pd1 pd2 pd3 tit le size document number rev date: sheet of printer &uart 2.0 feature integration technology inc. b 28 thursday , february 10, 2011 c15 180p parallel port interface c14 180p c16 180p for lekage to power c7 180p c17 180p (female) c8 180p dtrn1 c18 180p dsrn1 gnd ctsn1 sinn1 dcdn1 rtsn1 ctsn1 soutn1 c9 180p vcc 20 da1 16 da2 15 da3 13 ry1 19 ry2 18 ry3 17 ry4 14 ry5 12 gnd 11 +12v 1 dy1 5 dy2 6 dy3 8 ra1 2 ra2 3 ra3 4 ra4 7 ra9 9 -12v 10 u1 1 2 3 4 5 jp1 header 5 dcdn1 dtrn1 dsrn1 sinn1 5 9 4 8 3 7 2 6 1 p1 uart db9 rtsn1 c19 180p soutn1 c10 180p c20 180p uart 1 port interface c11 180p uart 2 port interface c21 180p c12 180p c22 180p c13 180p c24 0.1u rin1 rin1 ir interface c23 180p vcc5v +12v -12v irrx irtx
oct., 2011 v0.19p 151 F71869A q13 pnp 3906 for system c59 3300p d3+ diode sensing circuit d- d3 led d2 led r50 4.7k vcc3v ovt# pull-up ovt# r43 10k 1% d1+ vref t rt1 th er mi stor 10k 1% (for system) q1 pnp 3906 for system d1+ from cpu vref d2+ r46 10k 1% t rt2 th er mi stor 10k 1% (for system) thermistor sensing circuit d- d+ d- c32 3300p c33 3300p temperature sensing d2+ diode sensing circuit d- c31 100p c34 100p c38 100p c39 100p vin5 r45 20k r47 2.9k r42 20k r44 8.6k r32 1k vldt(1.5v) 5vcc vcore +12v voltage sensing. the best voltage input level is about 1v. vin6 vldt(vin2) vcore(vin1) c37 100p vdimm r40 10k r38 10k vdimm(vin4) tit le size document number rev date: sheet of hardware monitor 2.0 feature integration technology inc. b 38 friday , july 02, 2010 r33 2m c35 1000p copen# vbat 1 2 sw1 case open circuit led_vsb sus_led vsb3v q3 npn vsb5v r49 4.7k r48 330 led p_led led_vcc vsb5v vsb3v r39 330 q2 npn r41 4.7k d3+ vref r114 10k 1% t rt3 th er mi stor 10k 1% thermistor sensing circuit (for system) 5vsb( for intel) 100p r37 10k r36 10k vdda vdda(vin3) must scale the voltage under 2.048v to vin if use force mode voltage protect, the voltage must to scale become1.5v to vin. r131 10k r132 10k
oct., 2011 v0.19p 152 F71869A fanctl2 r65 4.7k fanctl3 r78 4.7k fanctl3 vcc3v r51 4.7k vcc3v r63 4.7k r76 4.7k c47 0.1u r71 10k r70 27k r64 4.7k q6 pnp r62 4.7k r66 4.7k + c44 47u +12v 1 2 3 jp4 header 3 r69 330 q7 mosf et n 2n7002 d6 1n4148 c51 0.1u r83 10k fanctl1 r82 27k r77 4.7k q9 pnp r75 4.7k r79 4.7k + c48 47u +12v 1 2 3 jp6 header 3 r81 330 q10 mosf et n 2n7002 d8 1n4148 1 2 3 4 jp2 4 header vcc5v r53 4.7k r52 10k r55 27k r58 10k +12v + c40 47u d4 1n4148 c43 0.1u fanin1 r57 100 (4 pin fan control) fanctl1 tit le size document number rev date: sheet of fan control 2.0 feature integration technology inc. b 48 friday , april 09, 2010 pwm fan 3 speed control pwm fan 1 speed control pwm fan 2 speed control r61 3.9k r59 10k dc fan control with op 1 r72 10k 1 2 3 jp5 con3 fanin1 r74 3.9k r73 10k d7 1n4148 5 6 7 8 4 + - u3b lm358 dc fan control with op 2 r68 27k 12v r67 4.7k c45 47u q5 pmos c46 0.1u fanin2 12v q8 pmos r80 4.7k d9 1n4148 dc fan control with op 3 1 2 3 jp7 con3 12v c50 0.1u c49 47u r86 10k r85 10k r87 3.9k r84 27k 3 2 1 8 4 + - u4a lm358 fan control for pwm or dc fanin2 fanin3 q4 pmos fanin3 r56 27k 1 2 3 jp3 con3 r60 10k d5 1n4148 r54 4.7k c41 47u c42 0.1u 3 2 1 8 4 + - u3a lm358 fanctl2
oct., 2011 v0.19p 153 F71869A vcc3v vcc3v vsb3v power sequence pull-up client peci_client intel peci client r88 300 amd_tsi r89 300 vddio sid sic r92 100k slp_s3# timing_4(vldt_en) timing_3(vcore_en) timing_2(vdda) pwrok timing_1(vdimm_en) 2.5v r97 4.7k cpu_pwrgd cpu_pwrgd pull-up peci ti mi n g_3 ti mi n g_2 timing_1 ti mi n g_4 r93 4.7k r94 4.7k r95 4.7k r96 4.7k peci cirled# intel ibex client r91 300 r90 300 vcc3v ibx_clk ibx_dat (avoid pre-bios floating) smlink[1] tit le size document number rev date: sheet of amdsi/peci 2.0 feature integration technology inc. b 58 friday , april 15, 2011 vcc3v
oct., 2011 v0.19p 154 F71869A v3a r128 10k pson# psout# dpwrok dsw r102 1k dsw pull up pme# 5va for amd for intel ti mi n g_4 slp_sus# r107 r r108 r sus_warn# r129 0 r101 10k r130 0 slp_sus#/timing_4 r100 10k r99 10k 5vsb c54 10u c52 10u tit le size document number rev date: sheet of 2.0 b 68 friday , june 25, 2010 for intel ti mi n g_2 sus_ack# r109 for amd r110 r sus_ack#/timing_2 q11 mosfet p c53 1u timi n g_1 sus_warn# for amd for intel r112 r r111 r sus_warn#/timing_1 sus_warn#(chipset) for intel ti mi n g_3 dpwrok r113 r for amd r126 r dpwrok/timing_3 5va ctrl0# 5v_dual r106 1k 5va c57 10u 5vusb c55 10u q12 mosfet p c56 1u ctrl1# eup control vsb r105 10k r104 10k vsb3v select sus_warn# to chipset or 5v_dual event_in sus_ack# psin# eup acpi pull up v3a r98 10k r103 10k r127 10k <br> oct., 2011 v0.19p 155 <a href='http://www.datasheet.hk/search.php?part=f71869a&stype=part'>F71869A</a> tit le size document number rev date: sheet of <doc> <rev code> feature integration technology inc. a 11 friday , april 09, 2010 sin2 rts2# sout2 ri2# cts2# dcd2# dtr2# 80 port 1 (output by com2 interface) dsr2# h# h# r125 4.7k dsr2# vcc3v g d s q17 mosfet n nc 2 segg 1 sega 3 segf 4 h# 10 segc 8 segb 9 sege 7 l# 5 segd 6 u8 dual digit display r138 100 r139 100 <br> oct., 2011 v0.19p 156 <a href='http://www.datasheet.hk/search.php?part=f71869a&stype=part'>F71869A</a> tit le size document number rev date: sheet of <doc> <rev code> feature integration technology inc. a 11 friday , april 09, 2010 choose power and capacitance by ir receiver 2 1 3 q15 npn3904 vcc3v r116 330 c60 10nf r117 100 c61 0.1u r118 1.8k r119 330 r120 12k wide band ir receiver cirwb# 1 2 q16 ltr-301 q14 2n7002 vsb3v r121 0r r122 0r vsb5v out 1 vcc 2 gnd 3 case 4 u7 gp1ud260y k c62 0.1u cirrx# c63 10u long rang ir receiver 1 2 3 j5 tx1 j ac k cirtx r123100 vsb3v r124 330 tx port cirled# 1 2 d10 led ir led cirtx cirled# cirtx cirwb# cirled# cirwb# <br></td> </tr> </table> <table border="0" width="980" id="table32" style="font-size:1px" height="10"> <tr> <td></td> </tr> </table> <table border="0" width="980" id="table31" style="font-size:1px" height="40"> <tr> <td background="images/bg03.gif"> <p align="right"><br> <font color="#FF0000"><a href="#top">▲Up To Search▲</a> </font></td> </tr> </table> <table border="0" width="980" id="table27"> <tr> <td> </td> </tr> <tr> <td> <b><font size="5">Price & Availability of F71869A </font></b> <a target="_blank" href="https://www.findchips.com/search/F71869A"><img border="0" src="images/fc_logo.jpg" width="265" height="25"></a></td> </tr> <tr> <td><script src="http://www.findchips.com/api/inventory/search/F71869A?limit=5&partner=18"></script> <script>document.getElementById("poweredBy").style.visibility="hidden";</script></td> </tr> </table> </div> <div align="center"> <table border="0" width="980" id="table13" style="font-size:12px"> <tr> <td> <table border="0" width="980" id="table26" style="font-size:1px"> <tr> <td background="images/bg03.gif"></td> </tr> </table> </td> </tr> <tr> <td> <p align="right">All Rights Reserved © <span lang="zh-cn"> IC-ON-LINE 2003 - 2022</span> </td> </tr> </table> </div> <div align="center"> <table border="0" width="980" id="table13" style="font-size:12px"> <tr> <td>[<a href="javascript:addbookmark()">Add Bookmark</a>] [<a href="mailto:ioldatasheet@gmail.com" target="_blank">Contact Us</a>] [<a href="link.php">Link exchange</a>] [<a href="privacy.php">Privacy policy</a>]</td> </tr> <tr> <td> Mirror Sites : [<a href="http://www.datasheet.hk">www.datasheet.hk</a>] [<a href="http://www.maxim4u.com">www.maxim4u.com</a>] [<a href="http://www.ic-on-line.cn">www.ic-on-line.cn</a>] [<a href="http://www.ic-on-line.com">www.ic-on-line.com</a>] [<a href="http://www.ic-on-line.net">www.ic-on-line.net</a>] [<a href="http://www.alldatasheet.com.cn">www.alldatasheet.com.cn</a>] [<a href="http://www.gdcy.com">www.gdcy.com</a>] [<a href="http://www.gdcy.net">www.gdcy.net</a>]<br><br><br></td> </tr> </table> </div> <style type="text/css"> .style1 { background-color: #333333; } .style2 { color: #FFFFFF; } .style3 { color: #0000FF; } .style4 { color: #FFFFFF; font-size: large; } .style5 { text-decoration: none; } .style6 { color: #6EF3F2; } .style7 { border-width: 0px; } </style> <a href="http://www.maxim4u.com/che_s1.php" rel="nofollow">.</a> <a href="http://www.maxim4u.com/che_s2.php" rel="nofollow">.</a> <a href="http://www.maxim4u.com/che_s3.php" rel="nofollow">.</a> <a href="http://www.maxim4u.com/che_s4.php" rel="nofollow">.</a> <a href="http://www.maxim4u.com/che_s5.php" rel="nofollow">.</a> <br> <div style="position:fixed ;bottom:0px;width:100%" id="id_cookies"> <table height="33" align="center" class="style1" style="width: 100%"> <tr> <td align="left" class="style2" style="width: 23px"> </td> <td align="left" class="style2">We use cookies to deliver the best possible web experience and assist with our advertising efforts. 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