ADT7462 Flexible Temperature, Voltage Monitor, and System Fan Controller The ADT7462 is a flexible systems monitor IC, suitable for use in a wide variety of applications. It can monitor temperature in up to three remote locations, as well as its ambient temperature. There are up to four PWM outputs. These can be used to control the speed of a cooling fan by varying the % duty cycle of the PWM drive signal applied to the fan. The ADT7462 supports high frequency PWM for 4−wire fans and low frequency PWM for 2−wire and 3−wire fans. Up to eight TACH inputs can be used to measure the speed of 3−wire and 4−wire fans. There are up to 13 voltage monitoring inputs, ranging from 12 V to 0.9 V. The ADT7462 is fully compatible with SMBus 1.1 and SMBus 1.0. The ADT7462 also includes a THERM I/O and a RESET I/O. The ADT7462 is available in a 32−lead LFCSP_VQ. Many of the pins are multi−functional. Five easy configuration options can be set up using the easy configuration register. Users choose the configuration closest to their requirements; individual pins can be reconfigured after the easy configuration option has been chosen. http://onsemi.com MARKING DIAGRAM LFCSP−32 CASE 932 XX # YYWW AL CC Features = Device Code = Pb−Free Package = Date Code = Assembly Lot = Country Code Applications January, 2010 − Rev. 3 FAN2MAX/CI VR_HOT1/+1.2V1/+3.3V 25 THERM1/+1.5V1/GPIO7/VID6 VR_HOT2/+1.2V2/V BATT THERM2/+1.5V2/GPIO8 28 26 PWM3 29 31 30 VID5/GPIO6/PWM2 VID4/GPIO5/PWM1 32 TACH7/+5V 20 D3–/SCSI_TERM2 6 19 D3+/+1.25V/+0.9V TACH5/+12V1 7 18 D2– TACH6/+12V2 8 17 D2+ 15 16 D1+/+2.5V/+1.8V D1–/SCSI_TERM1 14 RESET 13 GND PWM4/+3.3V 5 11 V CC 23 ADT7462 12 4 ADD VID3/GPIO4/TACH4 ALERT 3 9 2 VID2/GPIO3/TACH3 ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 80 of this data sheet. • Servers and Personal Computers • Telecommunications Equipment • Test Equipment and Measurement Instruments © Semiconductor Components Industries, LLC, 2010 21 VID1/GPIO2/TACH2 24 PIN 1 INDICATOR 10 • • • • • • 22 1 SCL • • • V CCP2/ +1.5V/+1.8V/+2.5V V CCP1 / +1.5V/+1.8V/+2.5V TACH8/+12V3 VID0/GPIO1/TACH1 SDA • Resistance Cancellation On Remote Channels Thermal Protection Using THERM Pins Up to Four PWM Fan Drive Outputs Supports Both High and Low Frequency PWM Drives Up to Eight TACH Inputs Measures the Speed of 3−Wire and 4−Wire Fans Automatic Fan Speed Control Loop Includes Dynamic TMIN Control Monitors Up to 13 V Inputs Monitors Up to 7 VID Inputs; Includes On−The−Fly (OTF) VID Support Bidirectional Reset Chassis Intrusion Detect SMBus 1.1 and SMBus 1.0 Compatible 3.3 V and 5.0 V Operation Extended Operating Range from −40°C to +125°C Space−Saving 32−Lead Chip Scale Package 27 PIN ASSIGNMENT • One Local and Up to Three Remote Temperature Channels Series • • ADT 7462ACPZ #YYWW AL CCCCC 1 Publication Order Number: ADT7462/D ADT7462 ADD SCL SDA ALERT ADT7462 SMBus ADDRESS SELECTION SERIAL BUS INTERFACE VID REGISTER VID0 TO VID6 ACOUSTIC ENHANCEMENT CONTROL PWM REGISTERS PWM1 TO PWM4 FAN2MAX PWM CONFIGURATION REGISTERS DYNAMIC TMIN CONTROL FAN SPEED COUNTER TACH1 TO TACH8 ADDRESS POINTER REGISTER AUTOMATIC FAN SPEED CONTROL INTERRUPT MASKING INTERRUPT STATUS REGISTERS PERFORMANCE MONITORING VR_HOT2 VR_HOT1 THERM2 THERM1 LIMIT COMPARATORS THERMAL PROTECTION VALUE AND LIMIT REGISTERS INPUT SIGNAL CONDITIONING AND ANALOG MULTIPLEXER THERMAL DIODE INPUTS VOLTAGE INPUTS CI RESET CIRCUIT 13−BIT ADC BAND GAP TEMPERATURE SENSOR RESET GPIO STATUS AND CONFIGURATION REGISTERS BAND GAP REFERENCE GPIO1 TO GPIO8 SCSI_TERM1 AND SCSI_TERM2 SCSI STATUS GND Figure 1. Functional Block Diagram ABSOLUTE MAXIMUM RATINGS Parameter Rating Unit Supply Voltage 6.5 V Voltage on +12V Pin 20 V Voltage on VBATT Pin 4.0 V Voltage on Any Other Input or Output Pin −0.3 to +6.5 V Input Current at Any Pin ±5 mA Package Input Current ±20 mA Maximum Junction Temperature (TJMAX) 150 °C Operating Temperature Range −40 to +125 °C Storage Temperature Range −65 to +150 °C Lead Temperature, Soldering Lead Temperature (Soldering, 10 sec) IR Reflow Peak Temperature °C 300 260 ESD Rating 1500 V Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability. NOTE: This device is ESD sensitive. Use standard ESD precautions when handling. THERMAL CHARACTERISTICS Package Type 32−Lead LFCSP_VQ qJA qJC Unit 32.5 32.71 °C/W 1. qJA is specified for the worst−case conditions, that is, a device soldered in a circuit board for surface−mount packages. http://onsemi.com 2 ADT7462 PIN ASSIGNMENT Pin No. Mnemonic Description POR Default 1 VID0/GPIO1/TACH1 VID0: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO1: Open−Drain I/O. General−purpose input/output. TACH1: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 1. TACH1 2 VID1/GPIO2/TACH2 VID1: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO2: Open−Drain I/O. General−purpose input/output. TACH2: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 2. TACH2 3 VID2/GPIO3/TACH3 VID2: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO3: Open−Drain I/O. General−purpose input/output. TACH3: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 3. TACH3 4 VID3/GPIO4/TACH4 VID3: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO4: Open−Drain I/O. General−purpose input/output. TACH4: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 4. TACH4 5 VCC Power Supply. Can be powered by 3.3 V standby if monitoring in low power states is required. The ADT7462 can also be powered from a 5.0 V supply. 6 GND Ground Pin. 7 TACH5/+12V1 TACH5: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 5. +12V1: Analog Input. Monitors 12 V Power Supply 1. Attenuators switched on by default. TACH5 8 TACH6/+12V2 TACH6: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 6. +12V2: Analog Input. Monitors 12 V Power Supply 2. Attenuators switched on by default. TACH6 9 SCL Digital Input (Open Drain). SMBus serial clock input. Requires SMBus pullup. SCL 10 SDA Digital I/O (Open Drain). SMBus bidirectional serial data. Requires SMBus pullup. SDA 11 ADD The state of this pin on powerup determines the SMBus device address. ADD 12 ALERT 13 VCC GND Active Low Open−Drain Digital Output. Requires 10 kW typical pullup. The ALERT pin is used to signal out−of−limit comparisons of temperature, voltage, and fan speed. This is compatible with SMBus ALERT. ALERT PWM4/+3.3V PWM4: Digital Output (Open Drain). Requires 10 kW typical pullup. Pulse−width modulated output to control the speed of Fan 4. +3.3V: Analog Input. Monitors 3.3 V power supply. PWM4 14 RESET Active Low Open−Drain Digital I/O. Power−on reset, 5 mA driver (weak 100 kW pullup), active low output (100 kW pullup) with a 180 ms typical pulse width. RESET is asserted whenever VCC is below the reset threshold. It remains asserted for approximately 180 ms after VCC rises above the reset threshold. Pin 14 also functions as an active low RESET input and resets all unlocked registers to their default values. RESET 15 D1+/+2.5V/+1.8V 16 D1−/SCSI_TERM1 17 D1+: Anode Connection to Thermal Diode 1. +2.5V: Monitors 2.5 V analog input. +1.8V: Monitors 1.8 V analog input. D1+ D1−: Cathode Connection to Thermal Diode 1. SCSI_TERM1: Digital Input, SCSI Termination 1. D1− D2+ Anode Connection to Thermal Diode 2. D2+ 18 D2− Cathode Connection to Thermal Diode 2. D2− 19 D3+/+1.25V/+0.9V D3+: Anode Connection to Thermal Diode 3. +1.25V: Monitors 1.25 V analog input. +0.9V: Monitors 0.9 V analog input. D3+ 20 D3−/SCSI_TERM2 D3−: Cathode connection to Thermal Diode 3. SCSI_TERM2: Digital Input, SCSI Termination 2. D3− 21 TACH7/+5V TACH7: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 7. +5V: Analog Input. Monitors 5.0 V power supply. http://onsemi.com 3 TACH7 ADT7462 Pin No. Mnemonic Description POR Default 22 TACH8/+12V3 TACH8: Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 8. +12V3: Analog Input. Monitors 12 V Power Supply 3. TACH8 23 VCCP1/+1.5V/+1.8V/+2.5V VCCP1: Monitors 1.2 V analog input. +1.5V: Monitors 1.5 V analog input. +1.8V: Monitors 1.8 V analog input. +2.5V: Monitors 2.5 V analog input. +1.8V 24 VCCP2/+1.5V/+1.8V/+2.5V VCCP2: Monitors 1.2 V analog input. +1.5V: Monitors 1.5 V analog input. +1.8V: Monitors 1.8 V analog input. +2.5V: Monitors 2.5 V analog input. +2.5V 25 VR_HOT1/+1.2V1/+3.3V VR_HOT1: Digital Input Indicating Overtemperature Event on Voltage Regulator. +1.2V1: 0 V to 1.2 V Analog Input. For example, can be used to monitor GBIT. +3.3V: Analog Input. Monitors 3.3 V power supply. +3.3V 26 VR_HOT2/+1.2V2/VBATT VR_HOT2: Digital Input Indicating Overtemperature Event on Voltage Regulator. +1.2V2: 0 V to 1.2 V Analog Input. For example, can be used to monitor FSB_VTT. VBATT: Analog Input. Monitors battery voltage, nominally 3.0 V. VBATT 27 FAN2MAX/CI FAN2MAX: Sets fan to maximum speed when a fan fault condition occurs. Bidirectional open drain, active low I/O. CI: An active high input that captures a chassis intrusion event in Bit 7 of the digital status register. This bit remains set until cleared, as long as battery voltage is applied to the VBATT input, even when the ADT7462 is powered off. CI 28 THERM1/+1.5V1/GPIO7/VID6 THERM1: Can be reconfigured as a bidirectional THERM pin. Can be connected to the PROCHOT output of the Intel® Pentium® 4 processor to time and monitor PROCHOT assertions. Can be used as an output to signal overtemperature conditions or for clock modulation purposes. +1.5V1: 0 V to 1.5 V Analog Input. Can be used to monitor ICH. GPIO7: Open−Drain I/O. General−purpose input/output. VID6: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). THERM1 29 THERM2/+1.5V2/GPIO8 THERM2: Can be reconfigured as a bidirectional THERM pin. Can be connected to the PROCHOT output of the Intel Pentium 4 processor to time and monitor PROCHOT assertions. Can be used as an output to signal overtemperature conditions or for clock modulation purposes. +1.5V2: 0 V to 1.5 V Analog Input. Can be used to monitor 3GIO. GPIO8: Open−Drain I/O. General−purpose input/output. THERM2 30 PWM3 31 32 Digital Output (Open Drain). Requires 10 kW typical pullup. Pulse−width modulated output to control the speed of Fan 3. PWM3 VID4/GPIO5/PWM1 VID4: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO5: Open−Drain I/O. General−purpose input/output. PWM1: Digital Output (Open Drain). Requires 10 kW typical pullup. Pulse−width modulated output to control the speed of Fan 1. PWM1 VID5/GPIO6/PWM2 VID5: Digital Input (Open Drain). Voltage supply readouts from CPU. This value is read in to the VID value register (0x97). GPIO6: Open−Drain I/O. General−purpose input/output. PWM2: Digital Output (Open Drain). Requires 10 kW typical pullup. Pulse−width modulated output to control the speed of Fan 2. PWM2 http://onsemi.com 4 ADT7462 ELECTRICAL CHARACTERISTICS TA = TMIN to TMAX, VCC = VMIN to VMAX, unless otherwise noted. (Note 1) Parameter Test Conditions / Comments Min Typ Max Unit 3.0 3.3 5.5 V 1.5 4.0 mA Power Supply Supply Voltage Supply Current, ICC ADC active, Interface inactive (Note 2) Temperature−to−Digital Converter Internal Sensor, TA, Accuracy TA Conditions VCC Conditions 0°C ≤ TA ≤ 85°C −40°C ≤ TA ≤ +100°C 0°C ≤ TA ≤ 85°C −40°C ≤ TA ≤ +100°C 3 V ≤ VCC ≤ 3.6 V 3 V ≤ VCC ≤ 3.6 V 4.5 V ≤ VCC ≤ 5.5 V 4.5 V ≤ VCC ≤ 5.5 V ±0.5 ±2.25 ±3.25 ±3.0 ±4.0 °C 0.25 °C 0°C ≤ TA ≤ 85°C −40°C ≤ TA ≤ +100°C 0°C ≤ TA ≤ 85°C −40°C ≤ TA ≤ +100°C 3 V ≤ VCC ≤ 3.6 V 3 V ≤ VCC ≤ 3.6 V 4.5 V ≤ VCC ≤ 5.5 V 4.5 V ≤ VCC ≤ 5.5 V ±0.5 ±2.25 ±3.25 ±2.75 ±3.5 °C 0.25 °C Resolution Remote Sensor, TD, Accuracy (−40°C ≤ TD ≤ +125°C) Resolution Remote Sensor Source Current (Note 3) High level Mid level Low level 85 34 5.0 mA Series Resistance Cancellation (Note 3) The ADT7462 cancels 2 kW in series with the remote thermal diode 2.0 kW ANALOG−TO−DIGITAL CONVERTER Total Unadjusted Error, TUE (Note 4 and 5) Differential Non−linearity, DNL 8 bits ±3.5 % ±1.0 LSB Conversion Time (Voltage Input) (Note 3) 8.53 9.86 ms Conversion Time (Local Temperature) (Note 3) 9.01 10.38 ms Conversion Time (Remote Temperature) (Note 3) 38.36 42.09 ms INPUT RESISTANCE Pin 7, Pin 8, Pin 13, Pin 21, Pin 22, Pin 25, Pin 28, Pin 29 Attenuators enabled 140 kW Pin 15, Pin 19 Attenuators enabled 225 kW Pin 23, Pin 24 Attenuators enabled 66 Pin 26, VBATT and +1.2V2 (When Measured) Attenuators cannot be disabled VBATT Current Drain (When Measured) VBATT Current Drain (When Not Measured) 100 kW 120 140 kW CR2032 battery life > 10 years 80 100 nA CR2032 battery life > 10 years 16 nA FAN RPM TO DIGITAL CONVERTER ±8.0 % 90 97.2 kHz 0.1 ±1.0 mA 0.4 V Accuracy Internal Clock Frequency 82.8 OPEN−DRAIN OUTPUTS (PWM, GPIO) High Level Output Leakage Current, IOH VOUT = VCC Output Low Voltage, VOL IOUT = −3 mA, VCC = +3.3 V DIGITAL OUTPUT (RESET,ALERT, THERM) Output Low Voltage, VOL IOUT = −3 mA, VCC = +3.3 V RESET Pulse Width (Note 3) RESET Threshold Falling voltage RESET Hysteresis (Note 3) 0.4 140 180 3.0 3.05 70 http://onsemi.com 5 V ms 3.1 V mV ADT7462 ELECTRICAL CHARACTERISTICS TA = TMIN to TMAX, VCC = VMIN to VMAX, unless otherwise noted. (Note 1) Parameter Test Conditions / Comments Min Typ Max Unit 0.4 V ±1.0 mA OPEN−DRAIN SERIAL BUS OUTPUT (SDA) Output Low Voltage, VOL IOUT = −3 mA, VCC = +3.3 V High Level Output Leakage Current, IOH VOUT = VCC 0.1 SERIAL BUS DIGITAL INPUTS (SDA AND SCL) 2.1 Input High Voltage, VIH V Input Low Voltage, VIL 0.8 Hysteresis 500 V mV DIGITAL INPUT LOGIC LEVELS (VID0 to VID6) AND THERM, TACH, GPIO, VR_HOT, SCSI_TERM) Input High Voltage, VIH Bit 3 and Bit 4 of Configuration Register 3 = 0 1.7 V Input Low Voltage, VIL Bit 3 and Bit 4 of Configuration Register 3 = 0 Input High Voltage, VIH (VID0 to VID6) Bit 3 of Configuration Register 3 = 1 0.65 V Input High Voltage, VIH (THERM) Bit 4 of Configuration Register 3 = 1 2/3 VCCP1 V Input Low Voltage, VIL Bit 3 and Bit 4 of Configuration Register 3 = 1 0.8 0.4 Hysteresis 500 V V mV DIGITAL INPUT CURRENTS Input High Current, IIH VIN = VCC Input Low Current, IIL VIN = 0 −1.0 mA +1.0 Input Capacitance (Note 3) 5.0 mA pF SERIAL BUS TIMING (Note 3) Clock Frequency See Figure 2 Glitch Immunity, tSW See Figure 2 400 Bus Free Time See Figure 2 1.3 ms Start Setup Time, tSU;STA See Figure 2 0.6 ms Start Hold Time, tHD;STA See Figure 2 0.6 ms SCL Low Time, tLOW See Figure 2 1.3 ms SCL High Time, tHIGH See Figure 2 0.6 SCL, SDA Rise Time, tR See Figure 2 SCL, SDA Fall Time, tF See Figure 2 Data Setup Time, tSU;DAT See Figure 2 Detect Clock Low Timeout Can be optionally enabled 50 kHz ns ms 100 1000 ns 300 ns ns 25 ms 1. All voltages are measured with respect to GND, unless otherwise specified. Typical values are at TA = 25°C and represent the most likely parametric norm. Logic inputs accept input high voltages up to 5.0 V, even when the device is operating at supply voltages below 5.0 V. Timing specifications are tested at logic levels of VIL = 0.8 V for a falling edge and VIH = 2.0 V for a rising edge. 2. Unused digital inputs connected to GND. 3. Guaranteed by design, not production tested. 4. Note that this specification does not apply if Pin 26 (VBATT, +1.2V) is being measured in single−channel mode. See Figure 16 in the Typical Performance Characteristics section for VBATT accuracy. 5. For Pin 23 and Pin 24 configured as +1.8V or +2.5V only, restricted conditions of VCC ≥ 3.3 V and +25°C ≤ TA ≤ +125°C apply. tR tF tHD;STA tLOW SCL tHIGH tHD;STA tHD;DAT tSU;STA tSU;STO tSU;DAT SDA P tBUF S S Figure 2. Serial Bus Timing Diagram http://onsemi.com 6 P ADT7462 TYPICAL PERFORMANCE CHARACTERISTICS 0.00160 0.00144 0.00142 0.00155 0.00140 DEV2 0.00136 IDD (Amps) IDD (Amps) DEV2 0.00138 0.00150 0.00145 DEV1 0.00140 DEV3 0.00135 DEV3 0.00134 DEV1 0.00132 0.00130 0.00128 0.00126 0.00130 0.00124 0.00125 2.9 3.4 3.9 4.4 4.9 0.00122 –45 5.4 5 55 SUPPLY VOLTAGE (V) Figure 3. Supply Current vs. Supply Voltage Figure 4. Supply Current vs. Temperature 2 TEMPERATURE ERROR (5C) TEMPERATURE ERROR (5C) 2 VCC = 5.5V 1 VCC = 3.3V 0 –1 –40 –20 0 20 40 60 80 100 1 VCC = 5.5V VCC = 3.3V 0 –1 –40 120 –20 TEMPERATURE (5C) 40 60 80 100 120 Figure 6. Remote Sensor Temperature Error 11 16 4 2 7 12 17 3 3 8 13 18 4 9 14 19 5 10 15 20 MEAN 120 LO SPEC TEMPERATURE READING (5C) TEMPERATURE ERROR (5C) 6 HI SPEC 1 0 –1 –2 INT EXT1 EXT2 EXT3 100 80 60 40 20 –3 –4 –40 20 140 1 2 0 TEMPERATURE (5C) Figure 5. Local Sensor Temperature Error 5 105 TEMPERATURE (5C) 0 –20 0 20 40 60 80 100 120 0 20 40 60 80 100 120 TIME (Seconds) TEMPERATURE (5C) Figure 7. Temperature Error Measuring Intel Pentium 4 Processor Figure 8. ADT7462 Response to Thermal Shock http://onsemi.com 7 ADT7462 TYPICAL PERFORMANCE CHARACTERISTICS 15 60 10 TEMPERATURE ERROR (5C) TEMPERATURE ERROR (°C) 40 20 D+ TO GND 0 D+ TO V CC –20 –40 –60 50mV 125mV 5 0 –5 –10 –15 0 20 40 60 80 –20 10 100 Figure 9. Remote Temperature Error vs. Resistance (SRC) 100M 1G 20 4 TEMPERATURE ERROR (5C) TEMPERATURE ERROR (5C) 10M 25 6 50mV 125mV 2 0 –2 –4 –6 –8 100mV 15 10 60mV 5 0 40mV –5 –10 100 1M 10M 100M –10 10 1G 100 POWER SUPPLY NOISE FREQUENCY (kHz) 1M 10M 100M 1G NOISE FREQUENCY (kHz) Figure 11. Remote Temperature Error vs. Power Supply Noise Frequency Figure 12. Remote Temperature Error vs. Common−Mode Noise Frequency 10 7 6 0 TEMPERATURE ERROR (5C) TEMPERATURE ERROR (5C) 1M Figure 10. Local Temperature Error vs. Power Supply Noise Frequency 8 –12 10 100 POWER SUPPLY NOISE FREQUENCY (kHz) RESISTANCE (MΩ) 5 4 10mV 20mV 3 2 1 –10 DEV1, EXT1 DEV1, EXT2 –20 DEV1, EXT3 DEV2, EXT1 –30 DEV2, EXT2 DEV2, EXT3 DEV3, EXT1 –40 0 DEV3, EXT2 DEV3, EXT3 –1 10 100 1M 10M 100M –50 1G 0 2 4 6 8 CAPACITANCE (nF) NOISE FREQUENCY (kHz) Figure 13. Remote Temperature Error vs. Differential−Mode Noise Frequency Figure 14. Remote Temperature Error vs. Capacitance Between D+ and D− http://onsemi.com 8 10 ADT7462 TYPICAL PERFORMANCE CHARACTERISTICS 3.0 0.200 TEMPERATURE (5C) 0.196 VOLTAGE APPLIED TO V BATT (V) 0.198 POWERUP 0.194 0.192 0.190 0.188 0.186 0.184 STANDBY 0.182 0.180 –50 0 50 100 2.5 2.0 1.5 0.5 0 150 DEV1 DEV2 DEV3 1.0 0 0.5 1.0 1.5 Figure 15. Local Temperature vs. Power−On Reset Timeout 5.0 3.0 1.5 DEV2 1.0 4.0 DEV1 0.5 TACH ERROR (%) 3.5 TACH ERROR (%) 2.5 Figure 16. Applied Voltage vs. VBATT Reading 4.5 3.0 2.5 2.0 DEV1 DEV2 DEV3 1.5 1.0 0 DEV3 –0.5 –1.0 –1.5 0.5 0 2.9 2.0 VBATT READING (V) TIMEOUT (Seconds) 3.4 3.9 4.4 4.9 –2.0 –50 5.4 SUPPLY (V) 0 50 100 TEMPERATURE (5C) Figure 17. TACH Accuracy vs. Supply Voltage Figure 18. TACH Accuracy vs. Temperature http://onsemi.com 9 150 ADT7462 Option 4 Bit 3 = 1 Option 5 Bit 4 = 1 26 27 28 29 25 20 19 7 18 8 17 +2.5V +1.8V TACH8 TACH7 D3– D3+ D2– D2+ 16 Bit 2 = 1 6 21 15 Option 3 TOP VIEW (Not to Scale) 14 Bit 1 = 1 5 13 Bit 0 = 1 Option 2 ADT7462 11 Option 1 22 4 12 Register 0x14 Setting 3 23 SCL SDA ADD ALERT PWM4 RESET D1+ D1– Easy Configuration Option 24 PIN 1 INDICATOR 2 9 Table 1. Easy Configuration Register Settings 1 30 32 TACH1 TACH2 TACH3 TACH4 VCC GND TACH5 TACH6 10 There are a number of multifunctional pins on the ADT7462 that need to be configured on powerup to suit the desired application. Note that due to the large number of pins that need to be configured, it could take several SMBus transactions to achieve the required configuration. For this reason, the ADT7462 has five easy configuration options. The user sets a bit in the easy configuration option register (0x14) to set up the required configuration (see Table 1). 31 PWM2 PWM1 PWM3 THERM2 THERM1 CI VBATT +3.3V Function Description: Easy Configuration Options Figure 19. Configuration Option 1 Table 2. Configuration Option 1 Once the most convenient easy configuration option has been set, the user can configure any of the pins individually. The setup complete bit (Bit 5 of Register 0x01) must then be set to 1 to indicate that the ADT7462 is configured correctly, and then monitoring of the selected channels begins. The following is a detailed description of the five easy configuration options that are available. Configuration Option 1 Configuration Option 1 is the default configuration. It is also the most suitable for thermal monitoring, voltage monitoring, and fan control for single and dual processor systems. Features of Configuration Option 1 include the following: • One local and three remote temperature channels • Four PWM drives and eight TACH inputs • Two THERM I/Os • Voltage monitoring • +3.3V • +2.5V • +1.8V • VBATT • RESET I/O • CI (chassis intrusion) or FAN2MAX Figure 19 shows the pin configuration when Configuration Option 1 is chosen. Pin Function Configuration Register 1† Bit Value TACH1 Pin Configuration Reg 1 Bit 4 = 1 2† TACH2 Pin Configuration Reg 1 Bit 3 = 1 3† TACH3 Pin Configuration Reg 1 Bit 2 = 1 4† TACH4 Pin Configuration Reg 1 Bit 1 = 1 7 TACH5 Pin Configuration Reg 1 Bit 0 = 1 8 TACH6 Pin Configuration Reg 2 Bit 7 = 1 13 PWM4 Pin Configuration Reg 2 Bit 6 = 1 15 D1+ Pin Configuration Reg 1 Bit 6 = 1 16 D1− Pin Configuration Reg 1 Bit 6 = 1 19 D3+ Pin Configuration Reg 1 Bit 5 = 1 20 D3− Pin Configuration Reg 1 Bit 5 = 1 21 TACH7 Pin Configuration Reg 2 Bit 3 = 1 22 TACH8 Pin Configuration Reg 2 Bit 2 = 1 23 +1.8V Pin Configuration Reg 2 Bits [1:0] = 10 24 +2.5V Pin Configuration Reg 3 Bits [7:6] = 01 25 +3.3V Pin Configuration Reg 3 Bits [5:4] = 00 26 VBATT Pin Configuration Reg 3 Bits [3:2] = 00 27 CI Pin Configuration Reg 3 Bit 1 = 1 28† THERM1 Pin Configuration Reg 4 Bits [7:6] = 1× 29 THERM2 Pin Configuration Reg 4 Bits [5:4] = 1× 31† PWM1 Pin Configuration Reg 4 Bit 3 = 1 32† PWM2 Pin Configuration Reg 4 Bit 2 = 1 †If VIDs are selected, these pins are configured as VIDs. To enable VIDs, set Bit 7 of Pin Configuration Register 1 (0x10) = 1. http://onsemi.com 10 ADT7462 Configuration Option 2 Table 3. Configuration Option 2 1 25 27 28 29 30 26 24 PIN 1 INDICATOR 2 3 23 22 4 ADT7462 5 TOP VIEW (Not to Scale) 6 21 20 19 16 15 14 VCCP2 VCCP1 TACH8 TACH7 D3– D3+ D2– D2+ SCL SDA ADD ALERT PWM4 RESET D1+ D1– 13 17 11 8 12 18 9 7 10 TACH1 TACH2 TACH3 TACH4 VCC GND TACH5 TACH6 31 32 PWM2 PWM1 PWM3 THERM2 THERM1 FAN2MAX VR_HOT2 VR_HOT1 Configuration Option 2 is used for thermal monitoring and fan control for Processor 1 and Processor 2 in a dual processor system. It can also monitor one set of VIDs, if required. Features of Configuration Option 2 include the following: • One local and three remote thermal channels • Up to four PWM drives and up to eight TACH inputs (VID pins and TACHs/PWMs are muxed together) • Two THERM I/Os • Two VRD inputs • RESET I/O • Two VCCP voltage monitoring channels Figure 20 shows the pin configuration when Configuration Option 2 is chosen. Pin Function Configuration Register 1† TACH1 Pin Configuration Reg 1 Bit 4 = 1 Bit Value 2† TACH2 Pin Configuration Reg 1 Bit 3 = 1 3† TACH3 Pin Configuration Reg 1 Bit 2 = 1 4† TACH4 Pin Configuration Reg 1 Bit 1 = 1 7 TACH5 Pin Configuration Reg 1 Bit 0 = 1 8 TACH6 Pin Configuration Reg 2 Bit 7 = 1 13 PWM4 Pin Configuration Reg 2 Bit 6 = 1 15 D1+ Pin Configuration Reg 1 Bit 6 = 1 16 D1− Pin Configuration Reg 1 Bit 6 = 1 19 D3+ Pin Configuration Reg 1 Bit 5 = 1 20 D3− Pin Configuration Reg 1 Bit 5 = 1 21 TACH7 Pin Configuration Reg 2 Bit 3 = 1 22 TACH8 Pin Configuration Reg 2 Bit 2 = 1 23 VCCP1 Pin Configuration Reg 2 Bits [1:0] = 00 24 VCCP2 Pin Configuration Reg 3 Bits [7:6] = 00 25 VR_HOT1 Pin Configuration Reg 3 Bits [5:4] = 1× 26 VR_HOT2 Pin Configuration Reg 3 Bits [3:2] = 1× 27 FAN2MAX Pin Configuration Reg 3 Bit 1 = 0 28† THERM1 Pin Configuration Reg 4 Bits [7:6] = 1× 29 THERM2 Pin Configuration Reg 4 Bits [5:4] = 1× 31† PWM1 Pin Configuration Reg 4 Bit 3 = 1 32† PWM2 Pin Configuration Reg 4 Bit 2 = 1 †If VIDs are selected, these pins are configured as VIDs. To enable VIDs, set Bit 7 of Pin Configuration Register 1 (0x10) = 1. Figure 20. Configuration Option 2 http://onsemi.com 11 ADT7462 Configuration Option 3 Table 4. Configuration Option 3 1 26 27 28 29 30 25 24 PIN 1 INDICATOR 2 3 23 22 4 ADT7462 5 TOP VIEW (Not to Scale) 6 21 20 19 Function Configuration Register 1† TACH1 Pin Configuration Reg 1 Bit 4 = 1 2† TACH2 Pin Configuration Reg 1 Bit 3 = 1 3† TACH3 Pin Configuration Reg 1 Bit 2 = 1 4† TACH4 Pin Configuration Reg 1 Bit 1 = 1 7 +12V1 Pin Configuration Reg 1 Bit 0 = 0 8 +12V2 Pin Configuration Reg 2 Bit 7 = 0 13 +3.3V Pin Configuration Reg 2 Bit 6 = 0 15 +1.8V Pin Configuration Reg 1 Bit 6 = 0 16 SCSI_ TERM1 Pin Configuration Reg 1 Bit 6 = 0 19 +0.9V Pin Configuration Reg 1 Bit 5 = 0 20 SCSI_ TERM2 Pin Configuration Reg 1 Bit 5 = 0 21 +5V Pin Configuration Reg 2 Bit 3 = 0 22 +12V3 Pin Configuration Reg 2 Bit 2 = 0 23 VCCP1 Pin Configuration Reg 2 Bits [1:0] = 00 24 VCCP2 Pin Configuration Reg 3 Bits [7:6] = 00 25 +1.2V Pin Configuration Reg 3 Bits [5:4] = 01 26 VBATT Pin Configuration Reg 3 Bits [3:2] = 00 27 CI Pin Configuration Reg 3 Bit 1 = 1 28† +1.5V/ GPIO7 Pin Configuration Reg 4 Bits [7:6] = 01 29 +1.5V/ GPIO8 Pin Configuration Reg 4 Bits [5:4] = 01 31† PWM1 Pin Configuration Reg 4 Bit 3 = 1 32† PWM2 Pin Configuration Reg 4 Bit 2 = 1 Bit Value †If VIDs are selected, these pins are configured as VIDs. To enable VIDs, set Bit 7 of Pin Configuration Register 1 (0x10) = 1. 16 15 14 VCCP2 VCCP1 +12V3 +5V SCSI_TERM2 +0.9V D2– D2+ Pin SCL SDA ADD ALERT +3.3V RESET +1.8V SCSI_TERM1 13 17 11 8 12 18 9 7 10 TACH1 TACH2 TACH3 TACH4 VCC GND +12V1 +12V2 31 32 PWM2 PWM1 PWM3 +1.5V/GPIO8 +1.5V/GPIO7 CI VBATT +1.2V Configuration Option 3 is used to monitor all the voltages in the system for Processor 1 and Processor 2. Additional pins can be configured for fan control, VIDs, or GPIOs, as required. Features of Configuration Option 3 include the following: • Up to 13 different voltages monitored • Three +12V • +5V • +3.3V • +2.5V • +1.8V • Two +1.5V • Two +1.2V (VCCP1, VCCP2) • 0.9V • VBATT • One local and one remote temperature channels • Up to three PWM drives and up to four TACH inputs • RESET I/O Figure 21 shows the pin configuration when Configuration Option 3 is chosen. Figure 21. Configuration Option 3 http://onsemi.com 12 ADT7462 Configuration Option 4 Table 5. Configuration Option 4 26 25 27 29 28 30 31 32 PWM2 PWM1 PWM3 THERM2/+1.5V THERM1/+1.5V FAN2MAX VBATT VR_HOT1 Configuration Option 4 is used to monitor temperature, voltages, and fans for Processor 1 in a dual processor system. Features of Configuration Option 4 include the following: • One local and two remote temperature channels • Up to four PWM drives and six TACH inputs • Up to eight voltages monitored • +12V • +5V • +3.3V • Two +1.5V • +1.2V (VCCP1) • +0.984V (Mem_VTT) • VBATT • THERM I/O • VRD input • RESET I/O Figure 22 shows the pin configuration when Configuration Option 4 is chosen. Pin Function Configuration Register 1† TACH1 Pin Configuration Reg 1 Bit 4 = 1 2† TACH2 Pin Configuration Reg 1 Bit 3 = 1 3† TACH3 Pin Configuration Reg 1 Bit 2 = 1 4† TACH4 Pin Configuration Reg 1 Bit 1 = 1 7 TACH5 Pin Configuration Reg 1 Bit 0 = 1 8 TACH6 Pin Configuration Reg 2 Bit 7 = 1 13 PWM4 Pin Configuration Reg 2 Bit 6 = 1 15 D1+ Pin Configuration Reg 1 Bit 6 = 1 16 D1− Pin Configuration Reg 1 Bit 6 = 1 19 +0.9V Pin Configuration Reg 1 Bit 5 = 0 20 SCSI_ TERM2 Pin Configuration Reg 1 Bit 5 = 0 21 +5V Pin Configuration Reg 2 Bit 3 = 0 22 +12V3 Pin Configuration Reg 2 Bit 2 = 0 23 VCCP1 Pin Configuration Reg 2 Bits [1:0] = 00 24 +2.5V Pin Configuration Reg 3 Bits [7:6] = 01 25 VR_HOT1 Pin Configuration Reg 3 Bits [5:4] = 1× 26 VBATT Pin Configuration Reg 3 Bits [3:2] = 00 27 FAN2MAX Pin Configuration Reg 3 Bit 1 = 0 28 THERM1/ +1.5V Pin Configuration Reg 4 See Table 51 29* THERM2/ +1.5V Pin Configuration Reg 4 See Table 51 31† PWM1 Pin Configuration Reg 4 Bit 3 = 1 32† PWM2 Pin Configuration Reg 4 Bit 2 = 1 †* 1 24 PIN 1 INDICATOR 2 3 23 22 4 ADT7462 5 TOP VIEW (Not to Scale) 6 21 20 19 †If VIDs are selected, these pins are configured as VIDs. To enable VIDs, set Bit 7 of Pin Configuration Register 1 (0x10) = 1. *It is not possible to configure +1.5V monitoring on Pin 29 and THERM1 on Pin 28. Pin 28 must both be configured as either +1.5V monitoring or as THERM I/O (see Table 47). 16 15 14 13 +2.5V VCCP1 +12V3 +5V SCSI_TERM2 +0.9V D2− D2+ SCL SDA ADD ALERT PWM4 RESET D1+ D1– 11 17 12 18 8 9 7 10 TACH1 TACH2 TACH3 TACH4 VCC GND TACH5 TACH6 Bit Value Figure 22. Configuration Option 4 http://onsemi.com 13 ADT7462 Configuration Option 5 Table 6. Configuration Option 5 1 25 27 28 29 30 26 24 PIN 1 INDICATOR 2 3 23 22 4 ADT7462 5 TOP VIEW (Not to Scale) 6 21 20 19 Pin Function Configuration Register 1† TACH1 Pin Configuration Reg 1 Bit 4 = 1 2† TACH2 Pin Configuration Reg 1 Bit 3 = 1 3† TACH3 Pin Configuration Reg 1 Bit 2 = 1 4† TACH4 Pin Configuration Reg 1 Bit 1 = 1 7 +12V1 Pin Configuration Reg 1 Bit 0 = 0 8 +12V2 Pin Configuration Reg 2 Bit 7 = 0 13 +3.3V Pin Configuration Reg 2 Bit 6 = 0 15 +2.5V Pin Configuration Reg 1 Bit 6 = 0 16 SCSI_ TERM1 Pin Configuration Reg 1 Bit 6 = 0 19 D3+ Pin Configuration Reg 1 Bit 5 = 1 20 D3− Pin Configuration Reg 1 Bit 5 = 1 21 TACH7 Pin Configuration Reg 2 Bit 3 = 1 22 TACH8 Pin Configuration Reg 2 Bit 2 = 1 23 +1.8V Pin Configuration Reg 2 Bits [1:0] = 10 24 VCCP2 Pin Configuration Reg 3 Bits [7:6] = 00 25 +1.2V Pin Configuration Reg 3 Bits [5:4] = 01 26 VR_HOT2 Pin Configuration Reg 3 Bits [3:2] = 1× 27 FAN2MAX Pin Configuration Reg 3 Bit 1 = 0 28 THERM1/ +1.5V Pin Configuration Reg 4 See Table 51 29* THERM2/ +1.5V Pin Configuration Reg 4 See Table 51 31† PWM1 Pin Configuration Reg 4 Bit 3 = 1 32† PWM2 Pin Configuration Reg 4 Bit 2 = 1 †* 16 15 14 13 VCCP2 +1.8V TACH8 TACH7 D3– D3+ D2− D2+ SCL SDA ADD ALERT +3.3V RESET +2.5V SCSI_TERM1 11 17 12 18 8 9 7 10 TACH1 TACH2 TACH3 TACH4 VCC GND +12V1 +12V2 31 32 PWM2 PWM1 PWM3 THERM2/+1.5V THERM1/+1.5V FAN2MAX VR_HOT2 +1.2V Configuration Option 5 is used to monitor temperature, voltages, and fans for Processor 2 in a dual processor system. Features of Configuration Option 5 include the following: • One local and two remote temperature channels • Up to three PWM drives and up to six TACH inputs • Voltage monitoring • Two +12V • +3.3V • Mem_Core (+1.969V) • +1.8 V • Two +1.5V • +1.2V (VCCP2) • RESET I/O Figure 23 shows the pin configuration when Configuration Option 5 is chosen. Bit Value †If VIDs are selected, these pins are configured as VIDs. To enable VIDs, set Bit 7 of Pin Configuration Register 1 (0x10) = 1. *It is not possible to configure +1.5V monitoring on Pin 29 and THERM1 on Pin 28. Pin 28 must both be configured as either +1.5V monitoring or as THERM I/O (see Table 47). Figure 23. Configuration Option 5 http://onsemi.com 14 ADT7462 Serial Bus Interface 3. Data is sent over the serial bus in sequences of nine clock pulses: eight bits of data followed by an acknowledge bit from the slave device. Transitions on the data line must occur during the low period of the clock signal and remain stable during the high period, because a low−to−high transition when the clock is high can be interpreted as a stop signal. The number of data bytes that can be transmitted over the serial bus in a single read or write operation is limited only by what the master and slave devices can handle. 4. When all data bytes have been read or written, stop conditions are established. In write mode, the master releases the data line during the 10th clock pulse to assert a stop condition. In read mode, the master device overrides the acknowledge bit by pulling the data line high during the low period before the 9th clock pulse. This is known as a no acknowledge. The master then takes the data line low during the low period before the 10th clock pulse and then takes it high during the 10th clock pulse to assert a stop condition. Any number of bytes of data can be transferred over the serial bus in one operation, but it is not possible to mix read and write in one operation because the type of operation is determined at the beginning and cannot subsequently be changed without starting a new operation. For the ADT7462, write operations contain either one or two bytes, and read operations contain one byte. To write data to one of the device data registers or to read data from it, the address pointer register must be set so that the correct data register is addressed. Then data can be written into that register or read from it. The first byte of a write operation always contains an address that is stored in the address pointer register. If data is to be written to the device, the write operation contains a second data byte that is written to the register selected by the address pointer register. This write operation is shown in Figure 24. The device address is sent over the bus, and then R/W is set to 0. This is followed by two data bytes. The first data byte is the address of the internal data register to be written to, which is stored in the address pointer register. The second data byte is the data to be written to the internal data register. When reading data from a register, there are two possibilities. • If the ADT7462 address pointer register value is unknown or not the desired value, it must be set to the correct value before data can be read from the desired data register. This is done by performing a write to the ADT7462 as before, but only the data byte containing the register address is sent because no data is written to the register (see Figure 25). A read operation is then performed, consisting of the serial bus address and the R/W bit set to 1, followed by the data byte read from the data register (see Figure Figure 26). The ADT7462 is controlled through use of the serial system management bus (SMBus). The ADT7462 is connected to this bus as a slave device, under the control of a master controller. The SMBus interface in the ADT7462 is fully SMBus 1.1 and SMBus 1.0 compliant. The SMBus address is determined by the state of the ADD input on powerup. ADD Input The ADD pin is a three−state input to the ADT7462. It is used to determine the SMBus address used. This pin is sampled on powerup only. Any changes subsequent to powerup are not reflected until the ADT7462 is powered down and back up again. The corresponding 7−bit SMBus address for the state of the ADD pin is shown in Table 7. Table 7. Corresponding SMBus Addresses for ADD Input ADD Pin SMBus Version SMBus Address High N/A N/A Float SMBus 1.1 0x5C Low SMBus 1.1 0x58 SMBus Fixed Address The ADT7462 supports SMBus fixed address mode and is fully backward compatible with SMBus 1.1 and SMBus 1.0. The ADT7462 powers up with a fixed SMBus address that cannot be changed by the assign address call. The fixed address is set by the state of the ADD input pin on powerup. The ADT7462 also responds to the SMBus device default address of 0x61. SMBus Operation The SMBus specification defines specific conditions for different types of read and write operations. The general SMBus protocol operates as follows: 1. The master initiates data transfer by establishing a start condition, defined as a high−to−low transition on the serial data line, SDA, while the serial clock line, SCL, remains high. This indicates that an address/data stream follows. All slave peripherals connected to the serial bus respond to the start condition and shift in the next eight bits, consisting of a 7−bit address (MSB first) plus a R/W bit, which determines the direction of the data transfer, that is, whether data is written to or read from the slave device. 2. The peripheral whose address corresponds to the transmitted address responds by pulling the data line low during the low period before the 9th clock pulse, known as the acknowledge bit. All other devices on the bus remain idle while the selected device waits for data to be read from it or written to it. If the R/W bit = 0, the master writes to the slave device. If the R/W bit = 1, the master reads from the slave device. http://onsemi.com 15 ADT7462 • If the address pointer register is known to be already at first data byte of a write is always written to the address pointer register. In addition to supporting the send byte and receive byte protocols, the ADT7462 also supports the read byte protocol (see System Management Bus Specifications Rev. 2.0 for more information). If several read or write operations must be performed in succession, then the master can send a repeat start condition, instead of a stop condition, to begin a new operation. the desired address, data can be read from the corresponding data register without first writing to the address pointer register (see Figure 26). It is possible to read a data byte from a data register without first writing to the address pointer register, if the address pointer register is already at the correct value. However, it is not possible to write data to a register without writing to the address pointer register, because the 1 9 1 9 SCL A6 SDA A5 A4 A3 A2 A1 A0 R/W START BY MASTER D7 D6 D5 D4 D3 D2 D1 D0 ACK. BY ADT7462 ACK. BY ADT7462 FRAME 1 SERIAL BUS ADDRESS BYTE FRAME 2 ADDRESS POINTER REGISTER BYTE 1 9 SCL (CONTINUED) SDA (CONTINUED) D7 D6 D5 D4 D3 D2 D1 D0 ACK. BY ADT7462 STOP BY MASTER FRAME 3 DATA BYTE Figure 24. Writing a Register Address to the Address Pointer Register, then Writing Data to the Selected Register 1 9 1 9 SCL SDA A6 A5 A4 A3 A2 A1 A0 START BY MASTER R/W D7 D6 D5 D4 D3 D2 D1 D0 ACK. BY ADT7462 ACK. BY ADT7462 FRAME 1 SERIAL BUS ADDRESS BYTE STOP BY MASTER FRAME 2 ADDRESS POINTER REGISTER BYTE Figure 25. Writing to the Address Pointer Register Only 1 9 1 9 SCL SDA A6 A5 A4 A3 A2 A1 A0 START BY MASTER R/W D7 D6 D5 D4 D3 D2 D1 ACK. BY ADT7462 FRAME 1 SERIAL BUS ADDRESS BYTE D0 NO ACK. STOP BY BY MASTER MASTER FRAME 2 DATA BYTE FROM ADT7462 Figure 26. Reading Data from a Previously Selected Register Write Operations Send Byte The SMBus specification defines several protocols for different types of read and write operations. The ones used in the ADT7462 are discussed below. The following abbreviations are used in the diagrams: • S ⎯ Start • P ⎯ Stop • R ⎯ Read • W ⎯ Write • A ⎯ Acknowledge • A ⎯ No Acknowledge The ADT7462 uses the following SMBus write protocols. In this operation, the master device sends a single command byte to a slave device as follows: 1. The master device asserts a start condition on SDA. 2. The master sends the 7−bit slave address followed by the write bit (low). 3. The addressed slave device asserts an ACK on SDA. 4. The master sends a command code. 5. The slave asserts an ACK on SDA. 6. The master asserts a stop condition on SDA to end the transaction. http://onsemi.com 16 ADT7462 Block Write For the ADT7462, the send byte protocol is used to write a register address to RAM for a subsequent single byte read from the same address. This operation is shown in Figure 27. 1 2 3 SLAVE W A ADDRESS S 4 5 6 REGISTER ADDRESS A P In this operation, the master device writes a block of data to a slave device. The start address for a block write must be set previously. In the case of the ADT7462, this is done by a send byte operation to set a RAM address. The user writes the number of registers to be written to in the block read command to the #Bytes bits of the Configuration 0 register. 1. The master device asserts a start condition on SDA. 2. The master sends the 7−bit slave address followed by the write bit (low). 3. The addressed slave device asserts an ACK on SDA. 4. The master sends a command code that tells the slave device to expect a block write. The ADT7462 command code for a block write is 0xA0 (1010 0000). 5. The slave asserts an ACK on SDA. 6. The master sends the data bytes (the number of data bytes sent is written to the #Bytes bits of the Configuration 0 register). 7. The slave asserts an ACK on SDA after each data byte. 8. The master sends a packet error checking (PEC) byte. 9. The ADT7462 checks the PEC byte and issues an ACK, if correct. If incorrect (NO ACK), the master resends the data bytes. 10. The master asserts a stop condition on SDA to end the transaction. Figure 27. Setting a Register Address for Subsequent Read If it is required to read data from the register immediately after setting up the address, the master can assert a repeat start condition immediately after the final ACK and carry out a single byte read without asserting an intermediate stop condition. Write Byte In this operation, the master device sends a command byte and one data byte to the slave device as follows: 1. The master device asserts a start condition on SDA. 2. The master sends the 7−bit slave address followed by the write bit (low). 3. The addressed slave device asserts an ACK on SDA. 4. The master sends a command code. 5. The slave asserts an ACK on SDA. 6. The master sends a data byte. 7. The slave asserts an ACK on SDA. 8. The master asserts a stop condition on SDA to end the transaction. 1 2 3 SLAVE S ADDRESS W A 4 5 SLAVE ADDRESS A 6 7 8 DATA A P Figure 28. Single−Byte Write to a Register 1 2 3 4 5 6 7 8 9 10 11 12 COMMAND 0xA0 S SLAVE W A A BYTE A DATA 1 A DATA 2 A DATA A PEC A 32 ADDRESS COUNT BLOCK WRITE P Figure 29. Block Write to ADT7462 Read Operations For the ADT7462, the receive byte protocol is used to read a single byte of data from a register whose address has previously been set by a send byte or write a byte operation. The ADT7462 uses the following SMBus read protocols. Receive Byte 1 The receive byte is useful when repeatedly reading a single register. The register address must be set up previously. In this operation, the master device receives a single byte from a slave device as follows: 1. The master device asserts a start condition on SDA. 2. The master sends the 7−bit slave address followed by the read bit (high). 3. The addressed slave device asserts an ACK on SDA. 4. The master receives a data byte. 5. The master asserts a NO ACK on SDA. 6. The master asserts a stop condition on SDA to end the transaction. 2 3 SLAVE S ADDRESS R A 4 5 6 DATA A P Figure 30. Single−Byte Read from a Register Block Read In this operation, the master device reads a block of data from a slave device. The start address for a block read must be set previously, as well as the number of bytes to be read (maximum = 32). In the case of the ADT7462, the start address is activated by a send byte operation to set a RAM address. The number of bytes to be read should be written to http://onsemi.com 17 ADT7462 master. If a device’s SMBALERT line goes low, the following procedure occurs: 1. SMBALERT is pulled low. 2. The master initiates a read operation and sends the alert response address (ARA = 0001 100). This is a general call address that must not be used as a specific device address. 3. The device whose SMBALERT output is low responds to the ARA, and the master reads its device address. The address of the device is now known and can be interrogated in the usual way. 4. If more than one device’s SMBALERT output is low, the one with the lowest device address has priority in accordance with normal SMBus arbitration. 5. Once the ADT7462 has responded to the ARA, the master must read the status registers, and the SMBALERT is cleared only if the error condition has gone away. the #Bytes bits in the Configuration 0 register. The block read operation consists of a send byte operation that sends a block read command to the slave, immediately followed by a repeated start and a read operation that reads out multiple data bytes, as follows: 1. The master device asserts a start condition on SDA. 2. The master sends the 7−bit slave address followed by the write bit (low). 3. The addressed slave device asserts an ACK on SDA. 4. The master sends a command code that tells the slave device to expect a block read. The ADT7462 command code for a block read is 0xA1 (1010 0001). 5. The slave asserts an ACK on SDA. 6. The master asserts a repeat start condition on SDA. 7. The master sends the 7−bit slave address followed by the read bit (high). 8. The slave asserts an ACK on SDA. 9. The ADT7462 sends a byte count telling the master how many data bytes to expect. The maximum number of bytes is 32. 10. The master asserts an ACK on SDA. 11. The master receives the expected number of data bytes. 12. The master asserts an ACK on SDA after each data byte. 13. The ADT7462 issues a PEC byte to the master. The master should check the PEC byte and issue another block read if the PEC byte is incorrect. 14. A NO ACK is generated after the PEC byte to signal the end of the read. 15. The master asserts a stop condition on SDA to end the transaction. 1 5 6 7 COMMAND SLAVE S W A 0xA1 BLOCK A ADDRESS READ S SLAVE ADDRESS 8 A 2 9 3 10 11 4 12 BYTE A DATA 1 COUNT A 13 DATA 32 A SMBus Timeout The ADT7462 includes an SMBus timeout feature. If there is no SMBus activity for 25 ms, the ADT7462 assumes that the bus is locked and releases the bus. This prevents the device from locking or holding the SMBus while the device is expecting data. Some SMBus controllers cannot handle the SMBus timeout feature, so it can be disabled. Configuration Register 3 (0x03) Bit 1 SCL_Timeout = 1; SCL timeout enabled. Bit 1 SCL_Timeout = 0; SCL timeout disabled (default). Bit 2 SDA_Timeout = 1; SDA timeout enabled. Bit 2 SDA_Timeout = 0; SDA timeout disabled (default). Temperature and Voltage Measurement R Temperature Measurement 14 15 PEC A The ADT7462 can measure its own ambient temperature and the temperature of up to three remote thermal diodes. These diodes can be discrete diode−connected 2N3904/ 2N3906s or they can be located on a processor die. Figure 32 shows how to connect a remote NPN or PNP transistor. P Figure 31. Block Read from RAM Note that although the ADT7462 supports packet error checking (PEC), its use is optional. The PEC byte is calculated using CRC−8. The frame check sequence (FCS) conforms to CRC−8 by the polynomial. ADT7462 2N3904 ADT7462 D+ D+ D– D– 2N3906 C(x) + x 8 ) x 2 ) x 1 ) 1 Figure 32. How to Measure Temperature Using Discrete Transistors Consult the SMBus 1.1 specifications for more information. Remote Thermal Diode 1 connects to Pin 15 and Pin 16. Remote Thermal Diode 2 connects to Pin 17 and Pin 18. Remote Thermal Diode 3 connects to Pin 19 and Pin 20. A simple method of measuring temperature is to exploit the negative temperature coefficient of a diode, measuring the base−emitter voltage (VBE) of a transistor, operated at Alert Response Address Alert Response Address (ARA) is a feature of SMBus devices that allows an interrupting device to identify itself to the host when multiple devices exist on the same bus. The SMBALERT output can be used as either an interrupt output or an SMBALERT. One or more outputs can be connected to a common SMBALERT line connected to the http://onsemi.com 18 ADT7462 The resulting DVBE waveforms are passed through a 65 kHz low−pass filter to remove noise and then to a chopper−stabilized amplifier. This amplifies and rectifies the waveform to produce a dc voltage proportional to DVBE. The ADC digitizes this voltage, and a temperature measurement is produced. To reduce the effects of noise, digital filtering is performed by averaging the results of 16 measurement cycles for low conversion rates. Signal conditioning and measurement of the internal temperature sensor are performed in the same manner (see Figure 33). constant current. Unfortunately, this technique requires calibration to cancel the effect of the absolute value of VBE, which varies from device to device. The technique used in the ADT7462 is to measure the change in VBE when the device is operated at three different currents. Previous devices have used only two operating currents; use of a third current allows automatic cancellation of any resistances in series with the external temperature sensor. Figure 33 shows the input signal conditioning used to measure the output of an external temperature sensor. This figure shows the external sensor as a substrate transistor, but it could equally be a discrete transistor. If a discrete transistor is used, the collector is not grounded and should be linked to the base. To prevent ground noise from interfering with the measurement, the more negative terminal of the sensor is not referenced to ground but is biased above ground by an internal diode at the D− input. C1 can optionally be added as a noise filter (recommended maximum value 1000 pF). However, a better option in noisy environments is to add a filter, as described in the Noise Filtering section. To measure DVBE, the operating current through the sensor is switched among three related currents. As shown in Figure 33, N1 × I and N2 × I are different multiples of the Current I. The currents through the temperature diode are switched between I and N1 × I, giving DVBE1, and then between I and N2 × I, giving DVBE2. The temperature can then be calculated using the two DVBE measurements. This method can also be shown to cancel the effect of any series resistance on the temperature measurement. Temperature Measurement Results The results of the local and remote temperature measurements are stored in the local and remote temperature value registers and are compared with limits programmed into the local and remote high and low limit registers. Table 8. Temperature Measurement Registers Temperature Value Register Address Local Temperature, LSB Register 0x88, Bits [7:6] Local Temperature, MSB Register 0x89 Remote 1 Temperature, LSB Register 0x8A, Bits [7:6] Remote 1 Temperature, MSB Register 0x8B Remote 2 Temperature, LSB Register 0x8C, Bits [7:6] Remote 2 Temperature, MSB Register 0x8D Remote 3 Temperature, LSB Register 0x8E, Bits [7:6] Remote 3 Temperature, MSB Register 0x8F VCC I N1 y I N2 y I IBIAS VOUT+ D+ REMOTE SENSING TRANSISTOR TO ADC C1* D– BIAS DIODE LOW−PASS FILTER fC = 65kHz VOUT– *CAPACITOR C1 IS OPTIONAL. IT SHOULD ONLY BE USED IN NOISY ENVIRONMENTS. Figure 33. Input Signal Conditioning The temperature value is stored in two registers. The MSB has a resolution of 1°C. Only two bits in the temperature LSB register are used, Bit 7 and Bit 6, giving a temperature measurement resolution of 0.25°C. The temperature measurement range for both local and remote measurements is from −64°C to +191°C. However, the ADT7462 itself should never be operated outside its operating temperature range, which is from −40°C to +125°C. For the remote diode, the user should refer to the data sheet of the diode. Table 9. Temperature Data Format Temperature Value MSB LSB http://onsemi.com 19 −64°C 0000 0000 0000 0000 −50.25°C 0000 1110 0100 0000 −25°C 0010 0111 0000 0000 0°C 0100 0000 0000 0000 +25°C 0101 1001 0000 0000 +50.25°C 0111 0010 0100 0000 +100°C 1010 0100 0000 0000 ADT7462 When reading the full temperature value, the LSB should be read first and then the MSB. Reading the LSBs causes the current MSBs to be frozen until they are read. Reading the MSBs only does not cause any register to be locked. This is useful when a temperature reading with 1°C resolution is required. Table 10. Temperature Limit Registers Register Address Default Local Low Temperature Limit 0x44 0x40 Remote 1 Low Temperature Limit 0x45 0x40 Remote 2 Low Temperature Limit 0x46 0x40 Remote 3 Low Temperature Limit 0x47 0x40 Local High Temperature Limit 0x48 0x95 Remote 1 High Temperature Limit 0x49 0x95 Remote 2 High Temperature Limit 0x4A 0x95 Temperature Value Series Resistance Cancellation Parasitic resistance in series with the remote diode D+ and D− inputs can be caused by a variety of factors, including PCB track resistance and track length. This series resistance appears as a temperature offset in the remote sensor’s temperature measurement. This error typically causes a 0.8°C offset per ohm of parasitic resistance in series with the remote diode. The ADT7462 automatically cancels out the effect of this series resistance on the temperature reading, giving a more accurate result, without the need for user characterization of this resistance. The ADT7462 is designed to automatically cancel typically up to 2 kW of resistance. By using an advanced temperature measurement method, the process is transparent to the user. This feature also allows an RCR filter to be added to the sensor path, allowing the part to be used accurately in noisy environments. Remote 3 High Temperature Limit 0x4B 0x95 Local THERM1 Temperature Limit 0x4C 0xA4 Remote 1 THERM1 Temperature Limit 0x4D 0xA4 Remote 2 THERM1 Temperature Limit 0x4E 0xA4 Remote 3 THERM1 Temperature Limit 0x4F 0xA4 Local THERM2 Temperature Limit 0x50 0xA4 Remote 1 THERM2 Temperature Limit 0x51 0xA4 Remote 2 THERM2 Temperature Limit 0x52 0xA4 Remote 3 THERM2 Temperature Limit 0x53 0xA4 Offset Registers The ADT7462 has temperature offset registers at Register 0x56 to Register 0x59 for the local, Remote 1, Remote 2, and Remote 3 temperature channels. By doing a one−time calibration of the system, the user can determine the offset caused by system board noise and cancel it using the offset registers. The offset registers automatically add a twos complement, 8−bit reading to every temperature measurement. The LSBs add 0.5°C offset to the temperature reading so the 8−bit register effectively allows temperature offsets of up to ±64°C with a resolution of 0.5°C. This ensures that the readings in the temperature measurement registers are as accurate as possible. Temperature Limits Each temperature measurement channel has a high and low temperature limit associated with it. The temperature measurements are compared with these limits, and the results of these comparisons are stored in status registers. A Logic 0 indicates an in−limit comparison, and a Logic 1 indicates an out−of−limit comparison. The ADT7462 can generate an ALERT, if configured to do so, after a status bit is set. For more information on the status registers and ALERT, see the Status and Mask Registers ALERT section. Each temperature channel also has a THERM1 and a THERM2 temperature limit associated with it. When these temperature limits are exceeded, the corresponding THERM pin is asserted low (if THERM is configured as an output), and the fans are boosted to full speed (if the boost bit is set). Table 10 shows a complete list of all the temperature limits and their default values. Temperature Offset Registers Register 0x56 Local Temperature Offset = 0x00 (00°C default) Register 0x57 Remote 1 Temperature Offset = 0x00 (0°C default) Register 0x58 Remote 2 Temperature Offset = 0x00 (0°C default) Register 0x59 Remote 3 Temperature Offset = 0x00 (0°C default) http://onsemi.com 20 ADT7462 • For really long distances (up to 100 feet), use shielded Layout Considerations Digital boards can be electrically noisy environments. The ADT7462 measures very small voltages from the remote sensor, so care must be taken to minimize noise induced at the sensor inputs. The following precautions should be taken: • Place the ADT7462 as close as possible to the remote sensing diode. Provided that the worst noise sources, such as clock generators, data/address buses, and CRTs, are avoided, this distance can be 4 inches to 8 inches. • Route the D+ and D− tracks close together, in parallel, with grounded guard tracks on each side. To minimize inductance and reduce noise pickup, a 5 mil track width and spacing is recommended. If possible, provide a ground plane under the tracks. GND • Noise Filtering For temperature sensors operating in noisy environments, the industry−standard practice is to place a capacitor across the D+ and D− pins to help combat the effects of noise. However, large capacitances affect the accuracy of the temperature measurement, leading to a recommended maximum capacitor value of 1000 pF. While this capacitor does reduce noise, it does not eliminate it, making it difficult to use the sensor in a very noisy environment. The ADT7462 has a major advantage over other devices in eliminating the effects of noise on the external sensor. The series resistance cancellation feature allows a filter to be constructed between the external temperature sensor and the device. The effect of any filter resistance seen in series with the remote sensor is automatically canceled from the temperature result. The construction of a filter allows the ADT7462 and the remote temperature sensor to operate in noisy environments. Figure 35 shows a low−pass RCR filter, with the following values: R = 100 W C = 1 nF This filtering reduces both common−mode noise and differential noise. 5MIL 5MIL D+ 5MIL 5MIL D– 5MIL 5MIL GND 5MIL Figure 34. Typical Arrangement of Signal Tracks • Minimize the number of copper/solder joints that can • • • twisted pair, such as Belden No. 8451 microphone cable. Connect the twisted pair to D+ and D− and the shield to GND close to the ADT7462. Leave the remote end of the shield unconnected to avoid ground loops. Because the measurement technique uses switched current sources, excessive cable or filter capacitance can affect the measurement. When using long cables, the filter capacitance can be reduced or removed. cause thermo−couple effects. Where copper/solder joints are used, make sure that they are in both the D+ and D− path and at the same temperature. Thermocouple effects should not be a major problem because 1°C corresponds to about 200 mV, and thermocouple voltages are about 3 mV/°C of temperature difference. Unless there are two thermocouples with a large temperature differential between them, thermocouple voltages should be much less than 200 mV. Place a 0.1 mF bypass capacitor close to the VCC pin. In extremely noisy environments, an input filter capacitor can be placed across D+ and D− close to the ADT7462. This capacitance can affect the temperature measurement, so care must be taken to ensure that any capacitance seen at D+ and D− is a maximum of 1000 pF. This maximum value includes the filter capacitance, plus any cable or stray capacitance between the pins and the sensor diode. If the distance to the remote sensor is more than 8 inches, the use of twisted pair cable is recommended. This works from about 6 feet up to 12 feet. 100Ω REMOTE SENSOR 100Ω D+ 1nF D– Figure 35. Filter Between Remote Sensor and ADT7462 Voltage Measurement The ADT7462 is capable of measuring up to 13 different voltage inputs at one time. Table 11 is a list of the voltage measurement inputs and the corresponding input pins. Each pin can be configured to measure the desired voltage option using the Pin Configuration 1 (0x10) to Pin Configuration 4 (0x13) registers or the easy configuration options. http://onsemi.com 21 ADT7462 Table 11. Voltage Inputs Pin 0.9V 8kΩ 92kΩ Voltage Measured 7 +12V1 8 +12V2 13 +3.3V 15 +2.5V / +1.8V 19 +1.25V / +0.9V 21 +5V 22 +12V3 23 VCCP1 / +1.5V / +1.8V / +2.5V 24 VCCP2 / +1.5V / +1.8V / +2.5V 25 +1.2V1 (GBIT) / +3.3V 26 +1.2V2 (FSB_VTT) / VBATT 28 +1.5V1 (ICH) 29 +1.5V2 (3GIO) GBIT, FSB_VTT, VCCP1, VCCP2 1.25V 32kΩ 77kΩ 1.8V Input Circuit 66kΩ 3.3V MUX 1 LSB Value Full Scale +12V 7, 8, 22 0.0625 16 V +5V 21 0.026 6.67 V VCCP1, VCCP2 23, 24 0.00625 1.6 V VCCP1, when VIDs are enabled 23 0.0125 3.2 V +3.3V 13, 25 0.0172 4.4 V VBATT 26 0.0156 4.0 V +2.5V 15, 23, 24 0.013 3.33 V +1.8V 15, 23, 24 0.0094 2.4 V +1.5V 23, 24, 28, 29 0.0078 2.0 V +1.25V 19 0.0065 1.667 V +1.2V 25, 26 0.00625 1.6 V +0.9V 19 0.00469 1.2 V 5pF 100kΩ 5pF Figure 36. Voltage Input Structures Example Calculations Given the LSB value for each channel, the corresponding code for each voltage (or vice versa) can be calculated. Code + Pin No. 5pF 76kΩ 16kΩ Table 12. Input Range Code Conversion Nominal Input Voltage (3/4 Scale) 10pF 68kΩ 39kΩ 12V 35pF 30kΩ 71kΩ 5V 8pF 8kΩ 72kΩ The internal structure for the voltage inputs is shown in Figure 36. Each input circuit consists of an input protection diode, an attenuator, plus a capacitor to form a first−order, low−pass filter that gives the input immunity to high frequency noise. Voltages with full−scale values greater than the reference are divided so that the full−scale value equals the reference (2.25 V). All analog inputs are multiplexed into the on−chip, successive approximation ADC. This ADC has a resolution of ten bits. The basic input range is from 0 V to 2.25 V, but the inputs have built−in attenuators to allow measurement of larger and smaller voltages. To allow a tolerance for these voltages, the ADC produces an output of 3/4 full scale (decimal 768 or 0x300) for the nominal input voltage and so has enough headroom to cope with overvoltages. A list of corresponding LSB and full−scale values for each input voltage is shown in Table 12. 10pF 51kΩ 91kΩ 2.5V 10pF 30kΩ 72kΩ ICH, 3GIO, 1.5V 35pF Voltage 1 LSB Example: The code for 1.8 V in a 1.8 V channel is: Code + 1.8 + 192 (that is, 3ń4 scale) 0.0094 Similarly, the voltage, given the code in a particular channel, is calculated as follows: Voltage + Code 1 LSB where: 10 V is connected to the 12 V channel. 1 LSB = 0.0625. Code = 160 decimal. http://onsemi.com 22 ADT7462 Voltage Measurement and Limit Registers and a Logic 1 indicates an out−of−limit condition. The ADT7462 can generate an ALERT, if configured to do so, when a status bit is set. For more information on the status registers and ALERT, see the Status and Mask Registers ALERT section. A complete list of all the high and low voltage limits in the ADT7462 and their default values is contained in Table 13. The corresponding register locations for voltage measurements are listed in Table 13. Each voltage measurement channel has a high and low voltage limit associated with it. The voltage measurements are compared with these limits. The results of these comparisons are stored in status registers. A Logic 0 indicates an in−limit condition, Table 13. Voltage Value and Limit Registers Low Limit High Limit Voltage Value Pin No. Value Register Address Register Default Register Default +12V1 7 0xA3 0x6D 0x00 0x7C 0xFF +12V2 8 0xA5 0x6E 0x00 0x7D 0xFF +3.3V 13 0x96 0x70 0x00 0x68 0xFF +1.8V or +2.5V 15 0x8B 0x45 0x40 0x49 0x95 +1.25V or +0.9V 19 0x8F 0x47 0x40 0x4B 0x95 +5V 21 0xA7 0x71 0x00 0x7E 0xFF +12V3 22 0xA9 0x6F 0x00 0x7F 0xFF VCCP1, +1.5V, +1.8V, +2.5V 23 0x90 0x72 0x20 0x69 0xFF VCCP2, +1.5V, +1.8V, +2.5V 24 0x91 0x73 0x00 0x6A 0xFF +1.2V1 (GBIT) or +3.3V 25 0x92 0x74 0x00 0x6B 0xFF +1.2V2 (FSB_VTT) or VBATT 26 0x93 0x75 0x80 0x6C 0xFF +1.5V1 (ICH) 28 0x94 0x76 0x00 0x50 0xA4 +1.5V2 (3GIO) 29 0x95 0x77 0x00 0x4C 0xA4 Battery Measurement Input (VBATT) The VBATT current drain when a measurement is being made is calculated by: The VBATT input allows the condition of a CMOS backup battery to be monitored. This is typically a lithium coin cell, such as a CR2032. The VBATT input is accurate only for voltages greater than 1.2 V. Note that when Pin 26 is configured as a +1.2V input, voltages lower than 1.2 V are not accurately measured. Input voltage and corresponding voltage measured are shown in Figure 16. Typically, the battery in a system is required to keep some devices powered on when the system is in a powered−off state. The VBATT measurement input is designed to minimize battery drain. To reduce current drain from the battery, the lower resistor of the VBATT attenuator is not connected, except when a VBATT measurement is being made. The total current drain on the VBATT pin is 80 nA typical (for a maximum VBATT voltage = 4.0 V), so a CR2032 CMOS battery functions in a system in excess of the expected 10 years. Note that when a VBATT measurement is not being made, the current drain is reduced to 16 nA typical. Under normal voltage measurement operating conditions, all measurements are made in a round−robin format, and each reading is actually the result of 16 digitally averaged measurements. However, averaging is not carried out on the VBATT measurement to reduce measurement time and, therefore, reduce the current drain from the battery. I+ V BATT 100 kW t pulse t period where: tPULSE is the VBATT measurement time (~711 ms typical). tPERIOD is the time required to measure all analog inputs. Monitoring cycle time depends on the ADT7462 configuration. Calculating the monitoring cycle time is described in more detail in the ADC Information section. VBATT Input Battery Protection In addition to minimizing battery current drain, the VBATT measurement circuitry is specifically designed with battery protection in mind. Internal circuitry prevents the battery from being back−biased by the ADT7462 supply or through any other path under normal operating conditions. In the unlikely event of a catastrophic ADT7462 failure, the ADT7462 includes a second level of battery protection, including a series 3 kW resistor to limit current to the battery, as recommended by UL (see Figure 37). Thus, it is not necessary to add a series resistor between the battery and the VBATT input; the battery can be connected directly to the VBATT input to improve voltage measurement accuracy. http://onsemi.com 23 ADT7462 VBATT 49.5kΩ 4.5pF 3kΩ 3kΩ attenuators are disabled, the user should ensure that the voltage on the pin never exceeds 2.25 V. DIGITAL CONTROL Table 15. Voltage Attenuator Configuration Registers ADC Register Name Register Address Voltage Attenuator Configuration Register 1 0x18 Voltage Attenuator Configuration Register 2 0x19 82.7kΩ Figure 37. Equivalent VBATT Input Protection Circuit Single−Channel ADC Conversions ADC Information Setting Bit 2 of the EDO Enable register (0x16) places the ADT7462 into single−channel mode. In this mode, the ADT7462 can be made to convert on a single voltage or temperature channel only. The channel to be converted on is selected by writing to Bits [7:3] of the EDO (single−channel) Enable register (0x16). When the device is in single−channel mode, the pin configuration option should not be changed. Note that when the Pin 26 voltage, which includes the VBATT option, is selected in single−channel mode, this means that voltage measurements are continuously made in this mode. If a battery is connected to this input, this results in an excessive current drain on the battery. The specification of >10 years of battery life is valid only when the battery voltage is measured as part of the round robin and not in single−channel mode. Round Robin Both temperature and voltage measurements are analog inputs that are digitized using the on−board ADC. An internal multiplexer switches between the different analog inputs and digitizes them, in turn, in a round−robin manner. The total conversion time depends upon how the ADT7462 is configured. The conversion times for each measurement channel are shown in Table 14. The complete conversion time is the sum of the time for the voltage and temperature measurements. For example, if the ADT7462 is configured as Easy Configuration Option 1, the round−robin conversion time is calculated as follows: Total Conversion Time = 1 × (Local Conversion Time) + 3 × (Remote Conversion Time) + 4 × (Voltage Measurement Time) The TACH is not measured using the ADC and so is not part of the round−robin monitoring cycle. Table 16. Single−Channel Mode Options Bits [7:3] Table 14. Measurement Channel Conversion Times Channel Conversion Time (ms) Local Temperature 9.01 Remote Temperature 38.36 Voltage 8.53 For each ADC temperature and voltage measurement read from their value registers, 16 readings have actually been made internally and the results averaged before being placed in the value register. Bypass Voltage Attenuators There are up to 13 voltage measurement channels on the ADT7462. Each of these voltage measurement channels has an input structure (see Figure 36 for input structures for each of the voltage channels). Because the ADC has a voltage input range from 0 V to 2.25 V, these input circuits attenuate the voltage input using a resistor divider network to match the input range of the ADC. However, the user may occasionally want to remove the attenuators and directly apply a voltage of between 0 V and 2.25 V to the ADC. These attenuators can be disabled by setting relevant bits in the voltage attenuator configuration registers (see Table 15). This feature also allows the user to rescale the voltage inputs using an external attenuator circuit. However, when the ADC Channel Selected 0000 0 +1.2V2 voltage, Pin 26 0000 1 Remote 1 temperature 0001 0 Remote 2 temperature 0001 1 Remote 3 temperature 0010 0 Local temperature 0010 1 +12V1 voltage, Pin 7 0011 0 +12V2 voltage, Pin 8 0011 1 +12V3 voltage, Pin 22 0100 0 +3.3V voltage, Pin 13 0100 1 +2.5V/+1.8V voltage, Pin 15 0101 0 +1.25V/+0.9V voltage, Pin 19 0101 1 +5V voltage, Pin 21 0110 0 +1.5V/+1.8V/+2.5V voltage, Pin 23 0110 1 +1.5V/+1.8V/+2.5V voltage, Pin 24 0111 0 +1.2V1/+3.3V voltage, Pin 25 1000 0 +1.5V1 voltage, Pin 28 1000 1 +1.5V2 voltage, Pin 29 Dynamic VID Functionality VID Code The ADT7462 can be configured to monitor up to seven VID inputs. The VID code is output on seven lines from the CPU to tell the power controller what input voltage it requires. The ADT7462 can monitor the VID code and the http://onsemi.com 24 ADT7462 Dynamic VID Monitoring voltage applied to the CPU to ensure that they match within an acceptable range. This acceptable range is programmable in the ADT7462. The VID lines are monitored by the ADT7462, and the VID code is stored in the VID Value register (0x97), which can be read back over the SMBus. VID monitoring is enabled by setting Bit 7 (VIDs) of Pin Configuration Register 1 (0x10) to 1. See Table 17 and Table 18 for information on which pin should be connected to each VID line. When VID monitoring is enabled, all seven pins are automatically configured as VID inputs. It is not possible to select six pins as VID inputs and use the remaining pin as an alternate function. The ADT7462 supports dynamic VID monitoring. The purpose of the VID code is to tell the voltage controller what VCCP voltage should be applied to the CPU. The VCCP voltage applied to the processor changes as the power requirements of the processor change. The VID is compared with VCCP1 only. Note that when the VIDs are enabled, the LSB value for VCCP1 becomes 0.0125 V (see Table 12). The VID values can represent voltages from 0.8375 V to 1.6 V. The VID code is sampled by the ADT7462 every 11 ms and is stored in Register 0x97. Once the VID code has been stable (that is, does not change) for 55 ms, the measured VCCP is then compared with the VID code. The comparison table used is for either the VR10 or the VR11 specification (set by Bit 6 of Register 0x00). If the VID code and the measured VCCP do not match within a certain limit, an ALERT is generated. The VID value decoded and the VCCP measurement must be within a window controlled by the VID high and low limits. The VID is compared with VCCP1 only. Register 0x78 holds the 4−bit VID high and low limits. The high limit has a range of 0 mV to 375 mV with a resolution of 25 mV (four bits). The low limit has a range of 0 mV to −187.5 mV with a resolution of 12.5 mV (four bits). The high limit is used in a greater−than comparison, and the low limit is used in a less−than−or−equal−tocomparison. Note that if both limits are set to 0x00, because the low limit is less than or equal to the comparison, an ALERT always results. Therefore, the minimum value for low limit is 0x01. If the VCCP voltage measured and the VID code do not match to within the programmed limit, Status Bit 6 of the digital status register is set (Register 0xBE). This, in turn, can generate an ALERT if it is not masked. VID Value Register (0x97) Bit 0 = VID0 (reflects the logic state of Pin 1) Bit 1 = VID1 (reflects the logic state of Pin 2) Bit 2 = VID2 (reflects the logic state of Pin 3) Bit 3 = VID3 (reflects the logic state of Pin 4) Bit 4 = VID4 (reflects the logic state of Pin 31) Bit 5 = VID5 (reflects the logic state of Pin 32) Bit 6 = VID6 (reflects the logic state of Pin 28) The ADT7462 supports both the VR10 and the VR11 specifications. The default option supports the VR10 specification. To switch to the VR11 specification, set Bit 6 of Configuration Register 0 (0x00) to 1. VR11 is defined as eight bits; the ADT7462 monitors only seven VID lines (see Table 17). Table 17. VR11 VID Codes VID Number Pin No. Voltage VID6 28 400 mV VID5 32 200 mV Example VID4 31 100 mV VID3 4 50 mV VID2 3 25 mV VID1 2 12.5 mV VID0 1 6.25 mV VID high limit: 100 mV (Register 0x78), four MSBs set to 0100. VID low limit: 50 mV (Register 0x78), four LSBs set to 0100. VID value equates to 1.1 V. This is the read VID decoded, using either VR10 or VR11 tables. VCCP1 must be in the window of 1.05 V to 1.2 V. If the VCCP1 value is outside this window, the status bit is set and an ALERT is generated. To clear an ALERT generated in this way, read the digital status register. If the VID code and VCCP are now matching within the programmed window (that is, the error condition that caused the ALERT has gone away), then the status bit is reset and so is the ALERT. The VID to VCCP voltage tables for both VR10 and VR11 can be found on the Intel website. See the Voltage Regulator Module (VRM) and Enterprise Voltage Regulator−Down (EVRD) 10.0 Design Guidelines, Page 18 and Page 19, for additional information. VR10 requires only six VID lines (see Table 18). Pin 28 should be connected to ground when monitoring VR10 VID codes. VID6 reports a 0. Table 18. VR10 VID Codes VID Number Pin No. Voltage VID6 28 Unused, connect to GND VID5 32 12.5 mV VID4 31 400 mV VID3 4 200 mV VID2 3 100 mV VID1 2 60 mV VID0 1 25 mV http://onsemi.com 25 ADT7462 Status and Mask Registers and ALERT corresponding status bit is set to 1. The status bit remains set until the error condition goes away and the status register is read. The status bits are referred to as sticky because they remain set until read by software. This ensures that an out−of−limit event cannot be missed, if software is polling the device periodically. Note that the ALERT output remains low for the entire duration that a reading is out of limit and until the status register has been read. Status Registers Each measured temperature and voltage has an associated high and low limit. The measured values are compared with these programmable limits. The results of these comparisons are stored in the status registers. A Logic 0 in the status register represents an in−limit comparison, while a Logic 1 represents an out−of−limit comparison. Once a status bit is set, it remains set until the status register is read by the SMBus master. Once read, the status bit is cleared if the error condition has gone away. The status registers are duplicated to accommodate situations where there are two SMBus masters. If one master reads the host status registers and consequently clears them, the second master has no way of knowing what bits were set and what bits were cleared. The second SMBus master can read from the duplicate BMC status registers to determine which status bits were set. Table 19 is a list of the status registers and corresponding addresses. Mask Registers The user has the option of masking any of the individual status bits that generate an ALERT. This is achieved by setting the appropriate bit in the mask registers. The ALERT output is not asserted on the setting of a status bit if it has been masked. The status bit itself is not affected and continues to be set when an out−of−limit condition exists. Table 20 is a list of the mask registers and corresponding addresses. Table 20. Mask Registers Register Name Table 19. Status Registers Host Address Register Name BMC Address Register Address Thermal Mask Register 1 0x30 Thermal Mask Register 2 0x31 Voltage Mask Register 1 0x32 0x33 Thermal Status Register 1 0xB8 0xC0 Voltage Mask Register 2 Thermal Status Register 2 0xB9 0xC1 Fan Mask Register 0x34 − Digital Mask Register 0x35 GPIO Mask Register 0x36 Thermal Status Register 3 0xBA Voltage Status Register 1 0xBB 0xC3 Voltage Status Register 2 0xBC 0xC4 Fan Status Register 1 0xBD 0xC5 Digital Status Register 1 0xBE 0xC6 GPIO Status Register 0xBF − Fan Control Fan Drive Using PWM Control The ADT7462 uses pulse−width modulation (PWM) to control fan speed. Control relies on varying the duty cycle (or on/off ratio) of a square wave applied to the fan to vary the fan speed. The advantage of using PWM control is that it uses a very simple external circuit. The specific circuit used depends upon the type of fan. There are three main fan types in use: 2−wire fans, 3−wire fans, and 4−wire fans. The 2−wire fan has only power and ground connections. The 3−wire fan has power and ground connections and a TACH output to indicate the speed of the fan. The 4−wire fan has power and ground connections, a TACH output, and a PWM input. The PWM input is connected directly to the PWM drive of the ADT7462 and is used to control the speed of the fans. For 2−wire and 3−wire fans, the low frequency PWM drive signal should be selected. For 4−wire fans, the high frequency PWM drive signal should be selected. ALERT Output The ADT7462 has an SMBus ALERT output that is asserted when one of the status bits is set. This is to alert the master that an out−of−limit measurement has taken place or that there is a fault on one of the fan channels. An ALERT is generated as a result of a status bit being set in any of the registers. HIGH LIMIT TEMPERATURE CLEARED ON READ (TEMP BELOW LIMIT) STICKY STATUS BIT SMBALERT TEMP BACK IN LIMIT (STATUS BIT STAYS SET) Using the ADT7462 with 2−Wire Fans Figure 39 shows the most typical circuit used with a 2−wire fan and illustrates how a 2−wire fan can be connected to the ADT7462. The low frequency PWM mode must be selected when using a 2−wire fan. Figure 38. ALERT and Status Bit Behavior Figure 38 shows how the ALERT output and “sticky” status bits behave. When a limit is exceeded, the http://onsemi.com 26 ADT7462 Driving a 3−wire fan with a PWM signal makes the fan speed measurement more difficult because the TACH signal is chopped by the PWM drive signal. Pulse stretching is required in this case to make accurate fan speed measurements. For more information, see the Fan Speed Measurement section. +V ADT7462 3.3 V 1N4148 5.0 V or 12 V FAN 10 kΩ TYPICAL Q1 NDT3055L PWM Using the ADT7462 with 4−Wire Fans 0.01 mF TACH Figure 41 shows the most typical circuit used with 4−wire fans. RSENSE 2Ω TYPICAL 12 V 12 V, 4−WIRE FAN 10 kΩ Figure 39. Driving a 2−Wire Fan TACH 10 kΩ 4.7 kΩ Using the ADT7462 with 3−Wire Fans Figure 40 shows the most typical circuit used with a 3−wire fan. 12 V 12 V ADT7462 TACH VCC TACH PWM 3.3 V or 5.0 V 2 kΩ 12 V PWM 10 kΩ TACH/AIN 10 kΩ 4.7 kΩ 12 V FAN 1N4148 Figure 41. Driving a 4−Wire Fan 3.3 V Because the electronics in a 4−wire fan are powered continuously, unlike previous PWM driven/powered fans, 4−wire fans tend to perform better than 3−wire fans, especially for high frequency applications. 4−wire frames also eliminate the requirement for pulse stretching, because the TACH signal is always available. ADT7462 10 kΩ PWM Q1 NDT3055L Figure 40. Driving a 3−Wire Fan Driving Two Fans from Each PWM The external circuitry required is very simple. A MOSFET, such as the NDT3055L, is used as the pass device. The specifications of the MOSFET depend on the maximum current required by the fan being driven. A typical PC fan can draw a nominal current ranging from a few hundred milliamps to over an amp of current. Depending on the current rating of the fan, a SOT device can be used where board space is a concern. If several fans in parallel are driven from a single PWM output or if larger server fans are driven, the MOSFET must handle the higher current requirements. The only other stipulation is that the MOSFET should have a gate voltage drive, VGS < 3.3 V, for direct interfacing to the PWM pins. VGS can be greater than 3.3 V as long as the pullup on the gate is tied to 5.0 V. The MOSFET should also have a low on resistance to ensure that there is not a significant voltage drop across the FET, which would reduce the voltage applied across the fan and reduce the full speed of the fan. Figure 40 uses a 10 kW pullup resistor for the TACH signal. This assumes that the TACH signal is an open−collector from the fan. In all cases, the TACH signal from the fan must be kept below 5.0 V maximum to prevent damaging the ADT7462. If in doubt as to whether the fan used has an open−collector or totem−pole TACH output, use one of the input signal conditioning circuits shown in the Fan Speed Measurement section. Note that the ADT7462 has up to eight TACH inputs available for fan speed measurement, but only four PWM drive outputs. If all eight fans are being used in the system, two fans should be driven in parallel from each PWM output. Figure 42 shows how to drive two fans in parallel using the NDT3055L MOSFET. This information is relevant for low frequency mode only (2−wire and 3−wire fans), because the PWM and TACHs need to be synchronized to obtain accurate fan speed measurements using pulse stretching (see the Fan Speed Measurement with Pulse Stretching section). In high frequency mode and when using 4−wire fans, the TACH signal is always valid because the fan is always powered on. Note that because the MOSFET can handle up to 3.5 A, it is simply a matter of connecting another fan directly in parallel with the first. Care should be taken in designing drive circuits with transistors and FETs to ensure that the PWM pins are not required to source current and that they sink less than the 8 mA maximum current specified on the MOSFET data sheet. http://onsemi.com 27 ADT7462 3.3 V 12 V 10 kΩ TYPICAL TACH7 +V 3.3 V ADT7462 3.3 V TACH PULLUP 4.7 kΩ TYPICAL +V 5.0V or 12 V FAN 1N4148 FAN SPEED COUNTER ADT7462 *CHOOSE ZD1 VOLTAGE APPROXIMATELY 0.8 y VCC. TACH Figure 44. Fan with TACH Pullup to Voltage > 5.0 V, (Example 12 V) Clamped with Zener Diode Q1 NDT3055L If the fan has a strong pullup (less than 1 kW) to 12 V or a totem−pole output, a series resistor can be added to limit the Zener current, as shown in Figure 45. Alternatively, a resistive attenuator can be used, as shown in Figure 46. R1 and R2 should be chosen such that: 2.0 V < VPULLUP × R2/(RPULLUP + R1 + R2) < 5.0 V The fan inputs have an input resistance of nominally 160 kW to ground, so this should be taken into account when calculating resistor values. With a pullup voltage of 12 V and a pullup resistor of less than 1 kW, suitable values for R1 and R2 would be 100 kW and 47 kW. This gives a high input voltage of 3.83 V. Figure 42. Interfacing Two Fans in Parallel to a PWM Output Using a Single N−Channel MOSFET Fan Speed Measurement and Control TACH Inputs Pin 1, Pin 2, Pin 3, Pin 4, Pin 7, Pin 8, Pin 21, and Pin 22 are TACH inputs intended for fan speed measurement. Signal conditioning in the ADT7462 accommodates the slow rise and fall times typical of fan tachometer outputs. The maximum input signal range is 0 V to 5.0 V, even when VCC is less than 5.0 V. In the event that these inputs are supplied from fan outputs that exceed 0 V to 5.0 V, either resistive attenuation of the fan signal or diode clamping must be included to keep inputs within an acceptable range. Figure 43 to Figure 46 show circuits for most common fan TACH circuits. If the fan TACH output has a resistive pullup to VCC, it can be connected directly to the fan input, as shown in Figure 43. 12 V TACH OUTPUT TACH 5.0 V or 12 V FAN PULLUP TYP < 1 kΩ or TOTEM POLE VCC R1 10 kΩ TACH OUTPUT TACH ZD1 ZENER* FAN SPEED COUNTER ADT7462 *CHOOSE ZD1 VOLTAGE APPROXIMATELY 0.8 y VCC. Figure 45. Fan with Strong TACH Pullup to >VCC or Totem−Pole Output, Clamped with Zener Diode and Resistor VCC PULLUP 4.7 kΩ TYPICAL TACH ZD1* 10 kΩ TYPICAL PWM3 TACH OUTPUT 5.0 V or 12 V FAN 10 kΩ TYPICAL TACH3 VCC 12 V FAN SPEED COUNTER ADT7462 VCC < 1 kΩ R1* TACH OUTPUT Figure 43. Fan with TACH Pullup to VCC TACH R2* FAN SPEED COUNTER ADT7462 *SEE TEXT If the fan output has a resistive pullup to 12 V (or other voltage greater than 5.0 V), the fan output can be clamped with a Zener diode, as shown in Figure 44. The Zener diode voltage should be chosen so that it is greater than VIH of the TACH input but less than 5.0 V, allowing for the voltage tolerance of the Zener diode. A value of between 3.0 V and 5.0 V is suitable. Figure 46. Fan with Strong TACH Pullup to >VCC or Totem−Pole Output, Attenuated with R1/R2 Fan Speed Measurement The method of fan speed measurement when using 3−wire fans differs from that used with 4−wire fans. When 3−wire http://onsemi.com 28 ADT7462 Driving and Measuring the Speed of Two Fans from One PWM Output fans are in use, power is continuously applied and removed from the fan, thereby chopping the TACH information. As a result, every time a fan speed measurement is to be made, the fan must be switched on for a long enough period of time that a measurement can be made. This is called pulse stretching. With 4−wire fans, power is always applied to the fan, so fan speed measurements can be made continuously, and there is no need for pulse stretching. Pulse stretching is also not necessary when driving a 3−wire fan with a dc input. The Fan Speed Measurement with Pulse Stretching section, which describes how fan speed is measured both when pulse stretching is required and when it is not. When pulse stretching is enabled, the ADT7462 measures fan speed once a second. The counter then counts up from the first to the third TACH pulse; this value is stored in the TACH value register. The PWM drive returns to its previous programmed value. Each TACH input is synchronized to a particular PWM output. The PWM and TACH pins must be connected as shown in Figure 48 to ensure that pulse stretching is synchronized between the PWM output and the TACH inputs, and an accurate fan speed measurement is made on each fan. PWM1 Fan Speed Measurement Without Pulse Stretching Fan speed is measured by the ADT7462, and the result is stored in the fan TACH value registers. The fan counter does not count the fan TACH output pulses directly because the fan speed can be less than 1000 rpm, and it would take several seconds to accumulate a reasonably large and accurate count. Instead, the period of the fan revolution is measured by gating an on−chip 90 kHz oscillator into the input of a 16−bit counter for N periods of the fan TACH output (see Figure 47), so the accumulated count is actually proportional to the fan tachometer period and inversely proportional to the fan speed. FAN 1 FAN 2 FAN 3 FAN 4 TACH1 TACH5 TACH2 TACH3 TACH4 TACH6 TACH7 TACH8 FAN 5 FAN 6 FAN 7 FAN 8 PWM3 PWM4 Figure 48. Synchronizing Fan PWM Output and TACH Inputs CLOCK Driving and Measuring the Speed of One Fan from One PWM Output PWM TACH PWM2 If four single fans are being controlled and measured by the ADT7462, the following configuration should be used. This applies only to 3−wire fans controlled using low frequency PWM with pulse stretching enabled. Fan 1 is driven by PWM1 and measured using TACH1. Fan 2 is driven by PWM2 and measured using TACH3. Fan 3 is driven by PWM3 and measured using TACH5. Fan 4 is driven by PWM4 and measured using TACH7. 1 2 3 4 Figure 47. Fan Speed Measurement To enable continuous measurement for 3−wire fans, set the corresponding dc bit for the TACH input in the TACH configuration register. This bit is set automatically when the HF PWM is in use with 4−wire fans. PWM1 PWM2 Fan Speed Measurement with Pulse Stretching The method for measuring fan speed for 3−wire fans requiring pulse stretching is similar to the method described in the Fan Speed Measurement without Pulse Stretching section for continuous measurements. The main difference is that the PWM drive must be synchronized to the TACH input so that the ADT7462 knows that pulse stretching is taking place while the TACH is being measured. PWM1 is synchronized with TACH1 and TACH2. PWM2 is synchronized with TACH3 and TACH4. PWM3 is synchronized with TACH5 and TACH6. PWM4 is synchronized with TACH7 and TACH8. FAN 1 FAN 2 TACH1 TACH5 TACH3 TACH7 FAN 3 FAN 4 PWM3 PWM4 Figure 49. Driving and Measuring the Speed on a Single Fan http://onsemi.com 29 ADT7462 The PWM output is pulse stretched until a valid TACH is read on both TACH inputs synchronized to the particular PWM output. If one fan is connected to one PWM output, the PWM output is pulse stretched until the counter has timed out on the disconnected TACH input. In this case, the pulse is stretching longer than necessary in an effort to sense a disconnected fan. The speed of the connected fan may be increased and an audible change in fan speed may be observed. There are two options to prevent the PWM output from being stretched longer than necessary in this case. • Connect the two synchronized TACH inputs together; for example, if PWM1 is driving a single fan being sensed on TACH1 only, connect TACH1 and TACH2 together. • Turn off pulse stretching on the unused TACH input; that is, if PWM1 is driving a single fan being sensed on TACH1 only, turn off pulse stretching on TACH 2 in Register 0x08. In this register: Table 21. Tachometer Value and Limit Registers TACH Low Byte Value Register High Byte Value Register 8−Bit Limit Register TACH1 0x98 0x99 0x78 TACH2 0x9A 0x9B 0x79 TACH3 0x9C 0x9D 0x7A TACH4 0x9E 0x9F 0x7B TACH5 0xA2 0xA3 0x7C TACH6 0xA4 0xA5 0x7D TACH7 0xA6 0xA7 0x7E TACH8 0xA8 0xA9 0x7F Calculating Fan Speed Assuming a fan with two pulses per revolution (and two pulses per revolution being measured), fan speed is calculated by: Fan Speed(RPM) + (freq Bit 0 controls pulse stretching on TACH1 and TACH5. Bit 1 controls pulse stretching on TACH2 and TACH6. Bit 2 controls pulse stretching on TACH3 and TACH7. Bit 3 controls pulse stretching on TACH4 and TACH8. Note that the TACH assignments in this register differ from the TACHs synchronized to each PWM output. Therefore, if the intention is to drive and sense four fans, connecting the TACHs together as described in Option 1 allows pulse stretching on all channels. To enable fan speed measurements four times a second, set the FAST bit (Bit 0) of Configuration Register 2 (0x02). When the FAST bit is set, fan TACH readings are updated every 250 ms. 60)ńFan Tachometer Reading (eq. 1) where: Fan Tachometer Reading is the 16−bit fan tachometer reading. freq is the oscillator frequency, 90 kHz. Example: TACH1 high byte (Register 0x99) = 0x17 TACH1 low byte (Register 0x98) = 0xFF What is the speed of Fan 1 in rpm? Fan 1 Tachometer Reading + 0 17FF + 6143 Decimal (eq. 2) RPM + (freq Fan Speed Measurement Registers RPM + (90000 Fan speed measurement involves a 2−register read for each measurement. The low byte should be read first. This causes the high byte to be frozen until both high and low byte registers have been read, preventing erroneous TACH readings. The fan tachometer reading registers report back the number of 11.11 ms period clocks (90 kHz oscillator) gated to the fan speed counter, from the rising edge of the first fan TACH pulse to the rising edge of the third fan TACH pulse (because two pulses per revolution are being counted). Because the device is essentially measuring the fan TACH period, the higher the count value, the slower the fan is actually running. A 16−bit fan tachometer reading of 0xFFFF indicates either that the fan has stalled or is running very slowly (<100 rpm). The actual fan TACH period is being measured; therefore, an ALERT is generated if the reading falls below a fan TACH limit. This ALERT sets the appropriate status bit and can be used to generate an SMBALERT. The TACH limit is an 8−bit value that is compared with the TACH high byte of the TACH reading. 60)ńFan 1 Tachometer Reading 60)ń6143 Fan Speed + 879 RPM (eq. 3) (eq. 4) (eq. 5) If the fan is a 6−pole fan, the count value is representative of 2/3 of a revolution. Therefore, the result of Equation 5 should be divided by 1.5. Similarly, if the fan used is an 8−pole fan, then the result should be divided by 2. Fan Spin−Up The ADT7462 has a unique fan spin−up function. It spins the fan at 100% PWM duty cycle until two TACH pulses are detected on the TACH input. Once two TACH pulses have been detected, the PWM duty cycle goes to the expected running value, for example, 33%. The advantage of this process is that fans have different spin−up characteristics and require different times to overcome inertia. The ADT7462 runs the fans just fast enough to overcome inertia and the fans are quieter on spin−up than fans programmed to spin up for a given spin−up time. http://onsemi.com 30 ADT7462 Fan Startup Timeout PWM Drive Frequency 4 is set using Bits [7:5] of the PWM3 and PWM4 frequency register (0x26). To prevent false interrupts being generated as a fan spins up (because it is below running speed), the ADT7462 includes a fan startup timeout function. During this time, the ADT7462 looks for two TACH pulses. If two TACH pulses are not detected, an interrupt is generated. Using Configuration Register 1 (0x01), Bit 4, this functionality can be changed to spinning the fans for a programmable time instead of two TACH pulses. The startup timeout for each PWM drive is programmed by Bits [2:0] in the PWMx configuration registers. PWM1 Configuration Register = Register 0x21 PWM2 Configuration Register = Register 0x22 PWM3 Configuration Register = Register 0x23 PWM4 Configuration Register = Register 0x24 Table 23. Low Frequency PWM Options Startup Timeout 000 No startup timeout 001 100 ms 010 250 ms 011 400 ms 100 667 ms 101 1 sec 110 2 sec 111 32 sec Frequency 000 11 Hz 001 14.7 Hz 010 22.1 Hz 011 29.4 Hz 100 35.3 Hz 101 44.1 Hz 110 58.8 Hz 111 88.2 Hz Fan Speed Control The ADT7462 controls fan speed using two different modes: automatic and manual. In automatic fan speed control mode, fan speed is automatically varied with temperature and without CPU intervention, after initial parameters are set up. The advantage of this mode is that if the system hangs, the system is protected from overheating. The automatic fan speed control incorporates a feature called dynamic TMIN calibration. This feature reduces the design effort required to program the automatic fan speed control loop. For more information on how to program the automatic fan speed control loop and dynamic TMIN operation, see the Programming the Automatic Fan Speed Control Loop section. In manual fan speed control mode, the ADT7462 allows the duty cycle of any PWM output to be manually adjusted. This is useful if the user wants to change fan speed in the software or adjust PWM duty cycle output for test purposes. Bits [7:5] of Register 0x21 to Register 0x24 (PWM configuration registers) control the behavior of each PWM output. Under manual control, each PWM output can be manually updated by writing to Register 0xAA to Register 0xAD (PWM duty cycle registers). Table 22. Fan Startup Timeout Bit Code Bit Code PWM Logic State The PWM outputs can be programmed high for 100% duty cycle (non−inverted) or low for 100% duty cycle (inverted). This is programmed for each PWM drive in the PWMx Configuration Registers using the INV bit (Bit 4). 0 = Active high PWM outputs. 1 = Active low PWM outputs. Low Frequency Mode PWM Drive Frequency The PWM drive frequency can be adjusted for the application. The ADT7462 supports both high frequency and low frequency PWM. High or low frequency PWM mode is selected in Register 0x02, Bit 2. In high frequency mode, the PWM drive frequency is always 22.5 kHz and cannot be changed. Register 0x25 and Register 0x26 configure the PWM frequency in low frequency mode for PWM1 to PWM4. PWM Drive Frequency 1 is set using Bits [4:2] of the PWM1 and PWM2 frequency register (0x25). PWM Drive Frequency 2 is set using Bits [7:5] of the PWM1 and PWM2 frequency register (0x25). PWM Drive Frequency 3 is set using Bits [4:2] of the PWM3 and PWM4 frequency register (0x26). Programming the PWM Current Duty Cycle Registers The PWM current duty cycle registers are 8−bit registers that allow the PWM duty cycle for each output to be set anywhere from 0% to 100% in steps of 0.39%. The value to be programmed into the PWMMIN register is given by: Value (decimal) = PWMMIN/0.39 Example 1: For a PWM duty cycle of 50%, Value (decimal) = 50/0.39 = 128 decimal Value = 128 decimal or 0x80 Example 2: For a PWM duty cycle of 33%, Value (decimal) = 33/0.39 = 85 decimal Value = 84 decimal or 0x54 http://onsemi.com 31 ADT7462 PWM Duty Cycle Registers Automatic Fan Control Overview Register 0xAA PWM1 Duty Cycle = 0x00 (0% default) Register 0xAB PWM2 Duty Cycle = 0x00 (0% default) Register 0xAC PWM3 Duty Cycle = 0x00 (0% default) Register 0xAD PWM4 Duty Cycle = 0x00 (0% default) By reading the PWMx current duty cycle registers, the user can keep track of the current duty cycle on each PWM output, even when the fans are running in automatic fan speed control mode or acoustic enhancement mode. The ADT7462 can automatically control the speed of fans based upon the measured temperature. This is done independently from CPU intervention once initial parameters are set up. The ADT7462 has a local temperature sensor and up to three remote temperature channels that can be connected to a CPU on−chip thermal diode (available on Intel Pentium class and other CPUs/GPUs). These four temperature channels can be used as the basis for automatic fan speed control to drive fans using pulse−width modulation (PWM). Automatic fan speed control reduces acoustic noise by optimizing fan speed according to accurately measured temperature. Reducing fan speed can also decrease system current consumption. The automatic fan speed control mode is very flexible, owing to the number of programmable parameters, including TMIN and TRANGE. The TMIN and TRANGE values for a temperature channel and, therefore, for a given fan, are critical because they define the thermal characteristics of the system. The thermal validation of the system is one of the most important steps in the design process, so these values should be selected carefully. Figure 51 gives a top−level overview of the automatic fan control circuitry on the ADT7462. From a systems−level perspective, up to four system temperatures can be monitored and used to control four PWM outputs. The four PWM outputs can be used to control up to eight fans. The ADT7462 allows the speed of eight fans to be monitored. The Remote 1 and Remote 2 temperature channels have a thermal calibration block, allowing the designer to individually configure the thermal characteristics of those temperature channels. For example, the CPU fan can be run when CPU temperature increases above 60°C and a chassis fan can be run when the local temperature increases above 45°C. At this stage, the designer has not assigned these thermal calibration settings to a particular fan drive (PWM) channel. The right side of Figure 51 shows controls that are fan−specific. The designer has control over individual parameters such as minimum PWM duty cycle, fan speed failure thresholds, and even ramp control of the PWM outputs. Automatic fan control, then, ultimately allows graceful fan speed changes that are less perceptible to the system user. VARY PWM DUTY CYCLE WITH 8-BIT RESOLUTION Figure 50. Control PWM Duty Cycle Manually with a Resolution of 0.39% Programming the Automatic Fan Speed Control Loop Note that to better understand the automatic fan speed control loop, use of the ADT7462 evaluation board and software is strongly recommended while reading this section. This section provides the system designer with an understanding of the automatic fan control loop and provides step−by−step guidance on effectively evaluating and selecting critical system parameters. To optimize system characteristics, the designer needs to carefully plan system configuration, including the number of fans, where they are located, and what temperatures are being measured in the particular system. The mechanical or thermal engineer who is tasked with the system thermal characterization should also be involved at the beginning of the process. http://onsemi.com 32 ADT7462 THERMAL CALIBRATION PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) REMOTE 1 TEMP TRANGE TMIN THERMAL CALIBRATION 0% PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) MUX LOCAL TEMP REMOTE 2 TEMP TMIN TRANGE THERMAL CALIBRATION TMIN 0% PWM MIN 100% TRANGE TACHOMETER 1 MEASUREMENT TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% PWM GENERATOR PWM CONFIG PWM GENERATOR PWM CONFIG PWM GENERATOR PWM1 TACH1 PWM2 TACH2 PWM3 TACH3 Figure 51. Automatic Fan Control Block Diagram Step 1—Configuring the MUX The fastest speed calculated options pertain to controlling one PWM output based on multiple temperature channels. The thermal characteristics of the three temperature zones can be set to drive a single fan. An example is the fan turning on when the Remote 1 temperature exceeds 60°C or when the local temperature exceeds 45°C. First, the user needs to decide how many temperature channels are being measured and how many fans need to be controlled and monitored. When these decisions have been made, the fans can be assigned to particular temperature channels. Not only can fans be assigned to individual channels, but the behavior of the fans is also configurable. For example, fans can be run under automatic fan control; they can be run manually (under software control) or they can be run at the fastest speed calculated by multiple temperature channels. The MUX is the bridge between temperature measurement channels and the three PWM outputs. Bits [7:5] (BHVR) of Register 0x21, Register 0x22, Register 0x23, and Register 0x24 (PWM configuration registers) control the behavior of the fans connected to the PWM1, PWM2, PWM3, and PWM4 outputs. The values selected for these bits determine how the MUX connects a temperature measurement channel to a PWM output (see Figure 52). Step 2—TMIN Settings for Thermal Calibration Channels TMIN is the temperature at which the fans start to turn on under automatic fan control. The speed at which the fan runs at TMIN is programmed later. The TMIN values chosen are temperature channel−specific; for example, 25°C for ambient channel, 30°C for VRM temperature, and 40°C for processor temperature. TMIN is an 8−bit value, either twos complement or Offset 64, that can be programmed in 1°C increments. There is a TMIN register associated with each temperature measurement channel: local, Remote 1, Remote 2, and Remote 3. When the TMIN value is exceeded, the fan turns on and runs at the minimum PWM duty cycle. The fan turns off after the temperature has dropped below TMIN − THYST. Automatic Fan Control MUX Options Bits [7:5] (BHVR), of Register 0x21, Register 0x22, Register 0x23, and Register 0x24, control the behavior of the corresponding PWM outputs (see Table 57 and Table 58). http://onsemi.com 33 ADT7462 MUX THERMAL CALIBRATION PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 1 = AMBIENT TEMP TRANGE THERMAL CALIBRATION 0% 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) MUX TMIN LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT PWM MIN 0% PWM MIN 100% TRANGE TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) PWM GENERATOR PWM CONFIG PWM GENERATOR PWM CONFIG TACH1 CPU FAN SINK PWM2 TACH2 FRONT CHASSIS PWM GENERATOR TACHOMETER 3 AND 4 MEASUREMENT 0% PWM1 REMOTE 2 = CPU TEMP Figure 52. Assigning Temperature Channels to Fan Channels PWM3 TACH3 REAR CHASSIS To overcome fan inertia, the fan is spun up until two valid TACH rising edges are counted. See the Fan Spin−Up section for more details. In some cases, primarily for psycho−acoustic reasons, the fan should never switch off below TMIN. The corresponding bits in Register 0x25 and Register 0x26 should be set to keep the fans running at the PWM minimum duty cycle, if the temperature falls below TMIN. Bit 0 (MIN 1) = 1. PWM1 runs at PWM1 minimum duty cycle below TMIN − THYST. Bit 1 (MIN 2) = 0. PWM2 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 1 (MIN 2) = 1. PWM2 runs at PWM2 minimum duty cycle below TMIN − THYST. TMIN Registers Bit 0 (MIN 3) = 0. PWM3 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 0 (MIN 3) = 1. PWM3 runs at PWM3 minimum duty cycle below TMIN − THYST. Bit 1 (MIN 4) = 0. PWM4 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 1 (MIN 4) = 1. PWM4 runs at PWM4 minimum duty cycle below TMIN − THYST. PWM3 and PWM4 Frequency Register (0x26) Register 0x5C, Local Temperature TMIN = 0x9A (90°C) Register 0x5D, Remote 1 Temperature TMIN = 0x9A (90°C) Register 0x5E, Remote 2 Temperature TMIN = 0x9A (90°C) Register 0x5F, Remote 3 Temperature TMIN = 0x9A (90°C) PWM1 and PWM2 Frequency Register (0x25) Bit 0 (MIN 1) = 0. PWM1 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. http://onsemi.com 34 ADT7462 PWM DUTYCYCLE 100% 0% TMIN THERMAL CALIBRATION PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION 0% TACHOMETER 1 MEASUREMENT PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) MUX TMIN LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN TACHOMETER 2 MEASUREMENT 0% PWM MIN 100% TRANGE RAMP CONTROL (ACOUSTIC ENHANCEMENT) PWM GENERATOR PWM CONFIG PWM GENERATOR PWM CONFIG TACH1 CPU FAN SINK PWM2 TACH2 FRONT CHASSIS PWM GENERATOR TACHOMETER 3 AND 4 MEASUREMENT 0% PWM1 PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS Figure 53. Understanding the TMIN Parameter Step 3—PWMMIN for Each PWM (Fan) Output Remote 1 temperature can control PWM1 and PWM2 outputs. If two different fans are used on PWM1 and PWM2, the fan characteristics can be set up differently. As a result, Fan 1, driven by PWM1, can have a different PWMMIN value than that of Fan 2 connected to PWM2. Figure 55 illustrates this as PWM1MIN (the front fan) turns on at a minimum duty cycle of 20%, while PWM2MIN (the rear fan) turns on at a minimum duty cycle of 40%. Note, however, that both fans turn on at exactly the same temperature, defined by TMIN. PWMMIN is the minimum PWM duty cycle at which each fan in the system runs. It is also the start speed for each fan under automatic fan control when the temperature rises above TMIN. For maximum system acoustic benefit, PWMMIN should be as low as possible. Depending on the fan used, the PWMMIN setting is usually in the 20% to 33% duty cycle range. This value can be found through fan validation. 100% PWM DUTY CYCLE PWM DUTY CYCLE 100% PWMMIN 0% PWM2 PWM2MIN PWM1 PWM1MIN 0% TMIN TEMPERATURE Figure 54. PWMMIN Determines Minimum PWM Duty Cycle TMIN TEMPERATURE Figure 55. Operating Two Different Fans from a Single Temperature Channel More than one PWM output can be controlled from a single temperature measurement channel. For example, http://onsemi.com 35 ADT7462 Programming the PWMMIN Registers 100% PWM DUTY CYCLE The PWMMIN registers are 8−bit registers that allow the minimum PWM duty cycle for each output to be configured anywhere from 0% to 100%. This allows the minimum PWM duty cycle to be set in steps of 0.39%. The value to be programmed into the PWMMIN register is given by: Value (decimal) = PWMMIN /0.39 Example 1: For a minimum PWM duty cycle of 50%, Value (decimal) = 50/0.39 = 128 (decimal) Value = 128 (decimal) or 0x80 (hexadecimal) Example 2: For a minimum PWM duty cycle of 33%, Value (decimal) = 33/0.39 = 85 (decimal) Value = 85 (decimal) or 0x54 (hexadecimal) PWMMIN 0% TMIN TEMPERATURE Figure 56. PWMMAX Determines Maximum PWM Duty Cycle Below the THERM Temperature Limit Programming the PWMMAX Register The PWMMAX register (0x2C) is an 8−bit register that allows the maximum PWM duty cycle for the outputs to be configured anywhere from 0% to 100%. This allows the maximum PWM duty cycle to be set in steps of 0.39%. The value to be programmed into the PWMMAX register is given by: Value (decimal) = PWMMAX/0.39 Example 1: For a maximum PWM duty cycle of 50%, Value (decimal) = 50/0.39 = 128 (decimal) Value = 128 (decimal) or 0x80 (hexadecimal) Example 2: For a maximum PWM duty cycle of 75%, Value (decimal) = 75/0.39 = 192 (decimal) Value = 192 (decimal) or 0xC0 (hexadecimal) PWMMIN Registers Register 0x28, Minimum PWM1 Duty Cycle = 0x80 (50% default) Register 0x29, Minimum PWM2 Duty Cycle = 0x80 (50% default) Register 0x2A, Minimum PWM3 Duty Cycle = 0x80 (50% default) Register 0x2B, Minimum PWM4 Duty Cycle = 0x80 (50% default) Note on Fan Speed and PWM Duty Cycle The PWM duty cycle does not directly correlate to fan speed in rpm. Running a fan at 33% PWM duty cycle does not equate to running the fan at 33% speed. Driving a fan at 33% PWM duty cycle actually runs the fan at closer to 50% of its full speed. This is because fan speed in % rpm generally relates to the square root of PWM duty cycle. Given a PWM square wave as the drive signal, fan speed in rpm approximates to: % fanspeed + ǸPWM duty cycle PWMMAX PWMMAX Register Register 0x2C, Maximum PWM1 to PWM4 Duty Cycle = 0xC0 (75% default) See the Note on Fan Speed and PWM Duty Cycle section for more information. 10 Step 5—TRANGE for Temperature Channels TRANGE is the range of temperatures over which automatic fan control occurs when the programmed TMIN temperature is exceeded. TRANGE is a temperature slope, not an arbitrary value; that is, a TRANGE of 40°C holds true only for PWMMIN = 33%. If PWMMIN is increased or decreased, the effective TRANGE changes. Step 4—PWMMAX for PWM (Fan) Outputs PWMMAX is the maximum duty cycle that each fan in the system runs at under the automatic fan speed control loop. For maximum system acoustic benefit, PWMMAX should be as low as possible but should be capable of maintaining the processor temperature limit at an acceptable level. If the THERM temperature limit is exceeded, the fans are still boosted to 100% for fail−safe cooling. There is one PWMMAX limit (Register 0x2C) for all fan channels. TRANGE PWM DUTY CYCLE 100% PWMMIN 0% TMIN TEMPERATURE Figure 57. TRANGE Parameter Affects Cooling Slope http://onsemi.com 36 ADT7462 where: TMAX is the temperature at which the fan runs full speed. TMIN is the temperature at which the fan turns on. Max DC is the maximum duty cycle (100%) = 255 decimal. Min DC is equal to PWMMIN. TRANGE is the PWM duty cycle vs. temperature slope. The TRANGE or fan control slope is determined by the following procedure: 1. Determine the maximum operating temperature for that channel (for example, 70°C). 2. Determine experimentally the fan speed (PWM duty cycle value) that does not exceed the temperature at the worst−case operating points. (For example, 70°C is reached when the fans are running at 50% PWM duty cycle.) 3. Determine the slope of the required control loop to meet these requirements. 4. Using the ADT7462 evaluation software, this functionality can be graphically programmed and visualized. Example 1 Calculate TMAX, given that TMIN = 30°C, TRANGE = 40°C, and PWMMIN = 10% duty cycle = 26 (decimal). TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 TMAX = 30°C + (100% − 10%) × 40°C/170 TMAX = 30°C + (255 − 26) × 40°C/170 TMAX = 84°C (effective TRANGE = 54°C) Example 2 PWM DUTY CYCLE 100% Calculate TMAX, given that TMIN = 30°C, TRANGE = 40°C, and PWMMIN = 25% duty cycle = 64 (decimal). TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 TMAX = 30°C + (100% − 25%) × 40°C/170 TMAX = 30°C + (255 − 64) × 40°C/170 TMAX = 75°C (effective TRANGE = 45°C) 50% 33% 0% Example 3 Calculate TMAX, given that TMIN = 30°C, TRANGE = 40°C, and PWMMIN = 33% duty cycle = 85 (decimal). TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 TMAX = 30°C + (100% − 33%) × 40°C/170 TMAX = 30°C + (255 − 85) × 40°C/170 TMAX = 70°C (effective TRANGE = 40°C) 305C 405C TMIN Figure 58. Adjusting PWMMIN Affects TRANGE TRANGE is implemented as a slope, which means that as PWMMIN is changed, TRANGE changes, but the actual slope remains the same. The higher the PWMMIN value, the smaller the effective TRANGE; that is, the fan reaches full speed (100%) at a lower temperature. Example 4 Calculate TMAX, given that TMIN = 30°C, TRANGE = 40°C, and PWMMIN = 50% duty cycle = 128 (decimal). TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 TMAX = 30°C + (100% − 50%) × 40°C/170 TMAX = 30°C + (255 − 128) × 40°C/170 TMAX = 60°C (effective TRANGE = 30°C) PWM DUTY CYCLE 100% 50% 33% Selecting a TRANGE Slope 25% The TRANGE value can be selected for each temperature channel: local, Remote 1, Remote 2, and Remote 3. Bits [7:4] (RANGE) of Register 0x60 to Register 0x63 define the TRANGE value for each temperature channel (see Table 81 and Table 82). 10% 0% 305C 405C 455C 545C Summary of TRANGE Function TMIN When using the automatic fan control function, the temperature at which the fan reaches full speed can be calculated by: Figure 59. Increasing PWMMIN Changes Effective TRANGE For a given TRANGE value, the temperature at which the fan runs at full speed for different PWMMIN values can be easily calculated by: TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 T MAX + T MIN ) T RANGE (eq. 6) Equation 6 holds true only when PWMMIN is equal to 33% PWM duty cycle. Increasing or decreasing PWMMIN changes the effective TRANGE, although the fan control still follows the same PWM duty cycle to temperature slope. The effective http://onsemi.com 37 ADT7462 Example: Determining TRANGE for Each Temperature Channel TRANGE for different PWMMIN values can be calculated using Equation 7. T MAX + T MIN ) (Max DC * Min DC) The following example shows how the different TMIN and TRANGE settings can be applied to three different thermal zones. In this example, the following TRANGE values apply: TRANGE = 80°C for ambient temperature TRANGE = 53.3°C for CPU temperature TRANGE = 40°C for VRM temperature T RANGEń170 (eq. 7) where (Max DC − Min DC) × TRANGE/170 is the effective TRANGE value. Figure 60 shows PWM duty cycle vs. temperature for each TRANGE setting. The lower graph shows how each TRANGE setting affects fan speed vs. temperature. As shown in the graph, the effect on fan speed is nonlinear. 100 55C 6.675C 85C 105C 50 13.35C 205C 30 405C 85C 105C 50 13.35C 165C 40 205C 30 26.65C 325C 405C 53.35C 20 53.35C 20 40 60 80 TEMPERATURE ABOVE T MIN 100 120 805C 120 3.335C 80 45C 55C 70 6.675C 60 85C 105C 50 13.35C 165C 40 25C 325C 53.35C 100 120 55C 70 6.675C 60 85C 105C 50 13.35C 40 165C 205C 30 0 0 405C 10 45C 26.65C 325C 405C 10 26.65C 20 3.335C 20 205C 30 805C 2.55C 80 2.55C 90 40 60 80 TEMPERATURE ABOVE T MIN 100 100 25C 20 40 60 80 TEMPERATURE ABOVE T MIN 90 100 FAN SPEED (% OF MAX) 6.675C 60 0 0 325C 10 55C 10 26.65C 20 45C 70 20 165C 40 FAN SPEED (% OF MAX) PWM DUTY CYCLE (%) 45C 60 0 0 PWM DUTY CYCLE (%) 3.335C 70 3.335C 80 2.55C 80 25C 2.55C 90 25C 90 0 0 100 53.35C 20 40 60 80 TEMPERATURE ABOVE T MIN 100 120 805C Figure 61. TRANGE vs. % Fan Speed Slopes with PWMMIN = 20% 805C Figure 60. TRANGE vs. Actual Fan Speed Profile This example uses the MUX configuration described in the Step 1 − Configuring the MUX section. Both CPU temperature and VRM temperature drive the CPU fan connected to PWM1. Ambient temperature drives the front chassis fan and rear chassis fan connected to PWM2 and PWM3. The front chassis fan is configured to run at PWMMIN = 20%. The rear chassis fan is configured to run at PWMMIN = 30%. The CPU fan is configured to run at PWMMIN = 10%. The graphs in Figure 60 assume that the fan starts from 0% PWM duty cycle. Clearly, the minimum PWM duty cycle, PWMMIN, needs to be factored in to see how the loop actually performs in the system. Figure 61 shows how TRANGE is affected when the PWMMIN value is set to 20%. It can be seen that the fan runs about 45% fan speed when the temperature exceeds TMIN. http://onsemi.com 38 ADT7462 Note on 4−Wire Fans exceeding any TTHERM limit runs all fans at 100%, it has very negative acoustic effects. Ultimately, this limit should be set up as a fail−safe, and it must not be exceeded under normal system operating conditions. Note that the TTHERM limits cannot be masked, and they affect the fan speed no matter how the automatic fan control settings are configured. This allows some flexibility because a TRANGE value can be selected based on its slope, while a hard limit (such as 70°C), can be programmed as TMAX (the temperature at which the fan reaches full speed) by setting TTHERM to that limit (for example, 70°C). The control range for 4−wire fans is much wider than that of 2−wire or 3−wire fans. In many cases, 4−wire fans can start with a PWM drive of as little as 20%. 100 90 PWM DUTY CYCLE (%) 80 70 60 50 40 THERM Registers 30 Register 0x4C, Local THERM1 temperature limit = 0xA4 (100°C default) Register 0x4D, Remote 1 THERM1 temperature limit = 0xA4 (100°C default) Register 0x4E, Remote 2 THERM1 temperature limit = 0xA4 (100°C default) Register 0x4F Remote 3 THERM1 temperature limit = 0xA4 (100°C default) Register 0x50, Local THERM2 temperature limit = 0xA4 (100°C default) Register 0x51, Remote 1 THERM2 temperature limit = 0xA4 (100°C default) Register 0x52, Remote 2 THERM2 temperature limit = 0xA4 (100°C default) Register 0x53 Remote 3 THERM2 temperature limit = 0xA4 (100°C default) 20 10 0 0 10 20 30 40 50 60 70 80 90 100 80 90 100 TEMPERATURE ABOVE TMIN 100 90 FAN SPEED (% MAX RPM) 80 70 60 50 40 30 20 10 0 0 10 20 30 40 50 60 70 Hysteresis Registers TEMPERATURE ABOVE TMIN Register 0x54, Local/Remote 1 Temperature Hysteresis Register Figure 62. TRANGE and % Fan Speed Slopes for VRM, Ambient, and CPU Temperature Channels Bits [7:4], local temperature hysteresis (4°C default) Bits [3:0], Remote 1 temperature hysteresis (4°C default) Step 6—TTHERM for Temperature Channels TTHERM is the absolute maximum temperature allowed on a temperature channel. Above this temperature, a component such as the CPU or VRM might be operating beyond its safe operating limit. When the measured temperature exceeds TTHERM, all fans are driven at 100% PWM duty cycle (full speed) to provide critical system cooling. The fans remain running at 100% until the temperature drops below TTHERM minus hysteresis, where hysteresis is the number programmed into Local/Remote 1 Hysteresis Register 0x54 and Remote 2/Remote 3 Hysteresis Register 0x55. The default hysteresis value is 4°C. The TTHERM limit should be considered as the maximum worst−case operating temperature of the system. Because Register 0x55, Remote 2/Remote 3 Temperature Hysteresis Register Bits [7:4], Remote 2 temperature hysteresis (4°C default) Bits [3:0], Remote 3 temperature hysteresis (4°C default) Because each hysteresis setting is four bits, hysteresis values are programmable from 1°C to 15°C. It is not recommended that hysteresis values ever be programmed to 0°C, because this value disables hysteresis. In effect, this value causes the fans to cycle between normal speed and 100% speed, creating unsettling acoustic noise. http://onsemi.com 39 ADT7462 Dynamic TMIN Control Mode TRANGE In addition to the automatic fan speed control mode described in the Automatic Fan Control Overview section, the ADT7462 has a mode that extends the basic automatic fan speed control loop. Dynamic TMIN control allows the ADT7462 to intelligently adapt the system’s cooling solution for best system performance or lowest possible system acoustics, depending on user or design requirements. Use of dynamic TMIN control alleviates the need to design for worst−case conditions and significantly reduces system design and validation time. HYSTERESIS PWM DUTY CYCLE 100% 0% TMIN TTHERM Figure 63. How TTHERM Relates to Automatic Fan Control Designing for Worst−Case Conditions System design must always allow for worst−case conditions. In PC design, the worst−case conditions include, but are not limited to, the following: • Worst−Case Altitude A computer can be operated at different altitudes. Altitude affects the relative air density, which alters the effectiveness of the fan cooling solution. For example, when comparing 40°C air temperature at 10,000 feet to 20°C air temperature at sea level, relative air density is increased by 40%. This means that the fan can spin 40% slower and make less noise at sea level than at 10,000 feet while keeping the system at the same temperature at both locations. • Worst−Case Fan Due to manufacturing tolerances, fan speeds in rpm are normally quoted with a tolerance of ±20%. The designer must assume that the fan rpm can be 20% below tolerance. This translates to reduced system airflow and elevated system temperature. Note that fans 20% out of tolerance can negatively impact system acoustics because they run faster and generate more noise. • Worst−Case Chassis Airflow The same motherboard can be used in a number of different chassis configurations. The design of the chassis and the physical location of fans and components determine the system’s thermal characteristics. Moreover, for a given chassis, the addition of add−in cards, cables, or other system configuration options can alter the system airflow and reduce the effectiveness of the system cooling solution. The cooling solution can also be inadvertently altered by the end user. (For example, placing a computer against a wall can block the air ducts and reduce system airflow.) Step 7—THYST for Temperature Channels THYST is the amount of extra cooling a fan provides after the temperature measured has dropped back below TMIN before the fan turns off. The premise for temperature hysteresis (THYST) is that without it, the fan would merely chatter or cycle on and off regularly whenever the temperature hovers near the TMIN setting. The THYST value chosen determines the amount of time needed for the system to cool down or heat up as the fan is turning on and off. Values of hysteresis are programmable in the range of 1°C to 15°C. Larger values of THYST prevent the fans from chattering on and off. The THYST default value is set at 4°C. Hysteresis Register Register 0x60, Bits [3:0] Local HYS Register 0x61, Bits [3:0] Remote 1 HYS Register 0x62, Bits [3:0] Remote 2 HYS Register 0x63, Bits [3:0] Remote 3 HYS In some applications, it is required that fans not turn off below TMIN but remain running at PWMMIN. Bits [1:0] of the PWM1, PWM2 Frequency Register (0x25) and the PWM3, PWM4 Frequency Register (0x26) allow the fans to be turned off or to be kept spinning below TMIN. If the fans are always on, the THYST value has no effect on the fan when the temperature drops below TMIN. TRANGE PWM DUTY CYCLE 100% THYST 0% TMIN TTHERM Figure 64. THYST Value Applies to Fan On/Off Hysteresis http://onsemi.com 40 ADT7462 VENTS FAN Dynamic TMIN Control Overview FAN VENTS Dynamic TMIN control mode builds upon the basic automatic fan control loop by adjusting the TMIN value based on system performance and measured temperature. This is important because, instead of designing for the worst case, the system thermals can be defined as operating zones. The ADT7462 can self−adjust its fan control loop to maintain either an operating zone temperature or a system target temperature. For example, it can be specified that ambient temperature in a system be maintained at 50°C. If the temperature is below 50°C, the fans might not need to run or might run very slowly. If the temperature is higher than 50°C, the fans need to throttle up. The challenge presented by any thermal design is finding the right settings to suit the system’s fan control solution. This can involve designing for the worst case, followed by weeks of system thermal characterization and, finally, fan acoustic optimization (for psycho−acoustic reasons). Obtaining the greatest benefit from the automatic fan control mode involves characterizing the system to find the best TMIN and TRANGE settings for the control loop and the best PWMMIN value for the quietest fan speed setting. Using the ADT7462 dynamic TMIN control mode, however, shortens the characterization time and alleviates tweaking the control loop settings, because the device can self−adjust during system operation. Dynamic TMIN control mode is operated by specifying the operating zone temperatures required for the system. Remote 1 and Remote 2 channels have dedicated operating point registers. This allows the system thermal solution to be broken down into distinct thermal zones. For example, CPU operating temperature is 70°C, VRM operating temperature is 80°C, and ambient operating temperature is 50°C. The ADT7462 dynamically alters the control solution to maintain each zone temperature as close as possible to its target operating point. Figure 67 shows an overview of the parameters that affect the operation of the dynamic TMIN control loop. I/O CARDS POWER SUPPLY I/O CARDS GOOD CPU AIRFLOW FAN CPU POWER SUPPLY CPU POOR CPU AIRFLOW DRIVE BAYS DRIVE BAYS VENTS GOOD VENTING = GOOD AIR EXCHANGE POOR VENTING = POOR AIR EXCHANGE Figure 65. Chassis Airflow Issues • Worst−Case Processor Power Consumption • • This data sheet maximum does not necessarily reflect the true processor power consumption. Designing for worst−case CPU power consumption can result in a processor becoming over−cooled (generating excess system noise). Worst−Case Peripheral Power Consumption The tendency is to design to data sheet maximums for peripheral components (again over−cooling the system). Worst−Case Assembly Every system manufactured is unique because of manufacturing variations. Heat sinks may be loose fitting or slightly misaligned. Too much or too little thermal grease may be used. Variations in application pressure for thermal interface material can affect the efficiency of the thermal solution. Accounting for manufacturing variations in every system is difficult; therefore, the system must be designed for the worst−case. TA θSA HEAT SINK θTIMS THERMAL INTERFACE MATERIAL TTIM TC θCA θCS θJA θTIMC PROCESSOR θJTIM SUBSTRATE EPOXY THERMAL INTERFACE MATERIAL TTIM PWM DUTY CYCLE INTEGRATED HEAT SPREADER θCTIM TS TJ Figure 66. Thermal Model Although a design usually accounts for worst−case conditions in all these cases, the actual system is almost never operated at worst−case conditions. The alternative to designing for the worst case is to use the dynamic TMIN control function. TEMPERATURE TLOW TMIN OPERATING THIGH TTHERM TRANGE POINT Figure 67. Dynamic TMIN Control Loop http://onsemi.com 41 ADT7462 Operating Point Registers Table 24 provides a brief description of each parameter. Register 0x5A, Remote 1 Operating Point = 0xA4 (100°C default) Register 0x5B, Remote 2 Operating Point = 0xA4 (100°C default) Table 24. TMIN Control Loop Parameters Parameter Description TLOW If the temperature drops below the TLOW limit, an error flag is set in a status register and an SMBALERT interrupt can be generated. THIGH If the temperature exceeds the THIGH limit, an error flag is set in a status register and an SMBALERT interrupt can be generated. TMIN The temperature at which the fan turns on under automatic fan speed control. Operating Point The maximum target temperature for a particular temperature zone. The system attempts to maintain system temperature around the operating point by adjusting the TMIN parameter of the control loop. TTHERM If the temperature exceeds this critical limit, the fans can be run at 100% for maximum cooling. TRANGE Programs the PWM duty cycle vs. temperature control slope. Operating Point Hysteresis Register The operating point hysteresis register sets the value below the operating point at which TMIN begins to reduce. Register 0x64, Bits [7:4] Operating Point Hysteresis = 0x40 (4°C default) Step 9—High and Low Limits for Temperature Channels The low limit defines the temperature at which the TMIN value starts to be increased, if temperature falls below this value. This has the net effect of reducing the fan speed, allowing the system to get hotter. An interrupt can be generated when the temperature drops below the low limit. The high limit should be set above the operating point but below the critical THERM point. An interrupt can be generated when the temperature rises above the high limit. Dynamic TMIN Control Programming Because the dynamic TMIN control mode is a basic extension of the automatic fan control mode, the automatic fan control mode parameters should be programmed first (see Step 1 − Configuring the MUX through Step 8 − Operating Points for Temperature Channels). Then proceed with dynamic TMIN control mode programming. How Dynamic TMIN Control Works The basic operation of dynamic TMIN control is as follows: 1. Set the target temperature for the temperature zone, which could be, for example, the Remote 1 thermal diode. This value is programmed to the Remote 1 operating point register. 2. As the temperature in that zone rises toward and exceeds the operating point temperature minus hysteresis, TMIN is reduced and fan speed increases. 3. As the temperature drops below the low limit value, TMIN is increased and the fan speed is reduced. Step 8—Operating Points for Temperature Channels The operating point for each temperature channel is the optimal temperature for that thermal zone. The hotter each zone is allowed to be, the quieter the system, because the fans are not required to run as fast. The ADT7462 increases or decreases fan speeds as necessary to maintain the operating point temperature, allowing for system−to−system variation and removing the need for worst−case design. If a sensible operating point value is chosen, any TMIN value can be selected in the system characterization. If the TMIN value is too low, the fans run sooner than required, and the temperature is below the operating point. In response, the ADT7462 increases TMIN to keep the fans off longer and to allow the temperature zone to get closer to the operating point. Likewise, too high a TMIN value causes the operating point to be exceeded, and in turn, the ADT7462 reduces TMIN to turn the fans on sooner to cool the system. Short Cycle and Long Cycle The ADT7462 implements two loops: a short (or decrease) cycle and a long (or increase) cycle. The short cycle takes place every n monitoring cycles. The long cycle takes place every 2n monitoring cycles. The value of n is programmable for each temperature channel. The bits are located at the following register locations. Dynamic TMIN Control Register 2 (0x0C) Programming the Operating Point Registers Bits [2:0] (CYR1) = Remote 1 Bits [5:3] (CYR2) = Remote 2 There are two operating point registers, one for the Remote 1 temperature channel and one for the Remote 2 temperature channel. These 8−bit registers allow the operating point temperatures to be programmed with 1°C resolution. http://onsemi.com 42 ADT7462 The following examples illustrate some of the circumstances that may cause TMIN to increase, decrease, or stay the same. Example 1: Normal Operation, No TMIN Adjustment 1. If the measured temperature never exceeds the programmed operating point minus the hysteresis temperature, TMIN is not adjusted; that is, it remains at its current setting. 2. If the measured temperature never drops below the low temperature limit, TMIN is not adjusted. Table 25. Cycle Bit Assignments Code Short Cycle Duration Long Cycle Duration 000 8 cycles 1 sec 16 cycles 2 sec 001 16 cycles 2 sec 32 cycles 4 sec 010 32 cycles 4 sec 64 cycles 8 sec 011 64 cycles 8 sec 128 cycles 16 sec 100 128 cycles 16 sec 256 cycles 32 sec 101 256 cycles 32 sec 512 cycles 64 sec 110 512 cycles 64 sec 1024 cycles 128 sec 111 1024 cycles 128 sec 2048 cycles 256 sec THERM LIMIT HIGH TEMP LIMIT OPERATING POINT The cycle time must be chosen carefully. A long cycle time means that TMIN is updated less often. If a system has very fast temperature transients, the dynamic TMIN control loop is always lagging. If a cycle time that is too short is chosen, the full benefit of changing TMIN is not realized and TMIN needs to change again on the next cycle. In effect, it is overshooting. It is necessary to carry out some calibration to identify the most suitable response time. Figure 68 shows the steps taken during the short cycle. ACTUAL TEMP LOW TEMP LIMIT TMIN Figure 70. Temperature Between the Operating Point and the Low Temperature Limit Because neither the operating point minus the hysteresis temperature nor the low temperature limit has been exceeded, the TMIN value is not adjusted, and the fan runs at a speed determined by the fixed TMIN and TRANGE values defined in the automatic fan speed control mode. Example 2: Operating Point Exceeded, TMIN Reduced When the measured temperature is below the operating point temperature minus the hysteresis, TMIN remains the same. Once the temperature exceeds the operating temperature minus the hysteresis (OP − Hyst), TMIN starts to decrease as illustrated in Figure 71. This occurs during the short cycle (see Figure 68). The rate at which TMIN decreases depends on the programmed value of n. It also depends on how much the temperature has increased between this monitoring cycle and the last monitoring cycle; that is, if the temperature has increased by 1°C, then TMIN is reduced by 2°C. Decreasing TMIN has the effect of increasing the fan speed, thus providing more cooling to the system. If the temperature is slowly increasing only in the range (OP − Hyst), that is, ≤0.25°C per short monitoring cycle, then TMIN does not decrease. This allows small changes in temperature in the desired operating zone without changing TMIN. The long cycle makes no change to TMIN in the temperature range (OP − Hyst), because the temperature has not exceeded the operating temperature. When the temperature exceeds the operating temperature, the long cycle causes TMIN to be reduced by 1°C every long cycle while the temperature remains above the operating temperature. This takes place in addition to the decrease in TMIN that would occur due to the short cycle. In Figure 70, because the temperature is increasing at a rate ≤0.25°C per short cycle, no reduction in TMIN takes place during the short cycle. WAIT n MONITORING CYCLES CURRENT TEMPERATURE MEASUREMENT T1(n) IS T1(n) > (OP1 – HYS) OPERATING POINT TEMPERATURE OP1 NO DO NOTHING YES PREVIOUS TEMPERATURE MEASUREMENT T1 (n – 1) IS T1(n) – T1(n – 1) ≤ 0.25°C YES DO NOTHING (SYSTEM COOLING IS OFF OR CONSTANT) NO IS T1(n) − T1(n − 1) = 0.5 − 0.755C DECREASE T MIN BY 15C IS T1(n) − T1(n − 1) = 1.0 − 1.755C DECREASE T MIN BY 25C DECREASE T MIN BY 45C IS T1(n) − T1(n − 1) > 2.05C Figure 68. Short Cycle Steps Figure 69 shows the steps taken during the long cycle. WAIT 2n MONITORING CYCLES CURRENT TEMPERATURE MEASUREMENT T1(n) OPERATING POINT TEMPERATURE OP1 IS T1(n) > OP1 YES DECREASE TMIN BY 15C NO IS T1(n) < LOW TEMP LIMIT AND TMIN < HIGH TEMP LIMIT YES AND TMIN < OP1 AND T1(n) > TMIN NO HYSTERESIS INCREASE TMIN BY 15C DO NOT CHANGE Figure 69. Long Cycle Steps http://onsemi.com 43 ADT7462 Figure 72 shows how TMIN increases when the current temperature is above TMIN and below the low temperature limit, and TMIN is below the high temperature limit and below the operating point. When the temperature rises above the low temperature limit, TMIN stays the same. When the temperature falls below the operating temperature, TMIN stays the same. Even when the temperature starts to increase slowly, TMIN stays the same, because the temperature increases at a rate of ≤0.25°C per cycle. THERM LIMIT THERM LIMIT HIGH TEMP LIMIT HIGH TEMP LIMIT OPERATING POINT OPERATING POINT HYSTERESIS HYSTERESIS ACTUAL TEMP TMIN NO CHANGE IN TMIN HERE DUE TO ANY CYCLE BECAUSE T1(n) – T1 (n – 1) ≤ 0.255C AND T1(n) < OP = > TMIN STAYS THE SAME LOW TEMP LIMIT ACTUAL TEMP TMIN LOW TEMP LIMIT Figure 72. Increasing TMIN for Quieter Operation Example 4: Preventing TMIN from Reaching Full Scale DECREASE HERE DUE TO SHORT CYCLE ONLY T1(n) – T1 (n – 1) ≤ 0.255C OR 0.755C = > TMIN DECREASES BY 15C EVERY SHORT CYCLE Because TMIN is dynamically adjusted, it is undesirable for TMIN to reach full scale (191°C), because the fan would never switch on. As a result, TMIN is allowed to vary only within a specified range. • The lowest possible value for TMIN is −64°C. • TMIN cannot exceed the high temperature limit. • If the temperature is below TMIN, the fan is switched off or is running at minimum speed, and dynamic TMIN control is disabled. DECREASE HERE DUE TO LONG CYCLE ONLY T1(n) – T1 (n – 1) ≤ 0.255C AND T1(n) > OP = > TMIN DECREASES BY 15C EVERY LONG CYCLE Figure 71. Effect of Exceeding Operating Point Minus Hysteresis Temperature Example 3: Temperature Below Low Limit, TMIN Increased When the temperature drops below the low temperature limit, TMIN may increase, as shown in Figure 72. Increasing TMIN has the effect of running the fan more slowly and, therefore, more quietly. The long cycle diagram in Figure 69 shows the conditions that need to be true for TMIN to increase. The following is a quick summary of those conditions and the reasons they need to be true: TMIN may increase, if • The measured temperature has fallen below the low temperature limit. This means the user must choose the low limit carefully. It should not be so low that the temperature never falls below it, because TMIN would never increase and the fans would run faster than necessary. • TMIN is below the high temperature limit. TMIN is never allowed to increase above the high temperature limit. As a result, the high limit should be sensibly chosen, because it determines how high TMIN can go. • TMIN is below the operating point temperature. TMIN should never be allowed to increase above the operating point temperature, because the fans do not switch on until the temperature rises above the operating point. • The temperature is above TMIN. The dynamic TMIN control is turned off below TMIN. THERM LIMIT OPERATING POINT HYSTERESIS ACTUAL LOW TEMP TEMP LIMIT HIGH TEMP LIMIT TMIN TMIN PREVENTED FROM INCREASING Figure 73. TMIN Adjustments Limited by High Temperature Limit Enabling Dynamic TMIN Control Mode Bits [1:0] of Dynamic TMIN Control Register 1 (0x0B) enable/disable dynamic TMIN control on the temperature channels (see Table 39). Dynamic TMIN Control Register 1 (0x0B) Bit 1 (Remote 2 En) = 1 enables dynamic TMIN control on the Remote 2 temperature channel. The chosen TMIN value is dynamically adjusted based on the current temperature, operating point, and high and low limits for this zone. Bit 1 (Remote 2 En) = 0 disables dynamic TMIN control. The TMIN value chosen is not adjusted and the channel behaves as described in the Automatic Fan Control Overview section. http://onsemi.com 44 ADT7462 Bit 0 (Remote 1 En) = 1 enables dynamic TMIN control on the Remote 1 temperature channel. The chosen TMIN value is dynamically adjusted based on the current temperature, operating point, and high and low limits for this zone. Bit 0 (Remote 1 En) = 0 disables dynamic TMIN control. The TMIN value chosen is not adjusted, and the channel behaves as described in the Automatic Fan Control Overview section. temperatures can be copied into the operating point registers on a THERM assertion. Setting these bits to 1 uses the remote temperature as the operating point temperature, overwriting the programmed operating point value in the event of a THERM assertion. Setting these bits to 0 ignores a THERM assertion, and the operating point register remains at the programmed value. Step 10—Monitoring THERM Automatic fan speed control mode reacts instantaneously to changes in temperature; that is, the PWM duty cycle responds immediately to temperature change. Any impulses in temperature can cause an impulse in fan noise. For psycho−acoustic reasons, the ADT7462 can prevent the PWM output from reacting instantaneously to temperature changes. Enhanced acoustic mode controls the maximum change in PWM duty cycle at a given time. The objective is to prevent the fan from cycling up and down, annoying the user. Enhancing System Acoustics Using the operating point limit ensures that the dynamic TMIN control mode is operating in the best possible acoustic position, while ensuring that the temperature never exceeds the maximum operating temperature. Using the operating point limit allows TMIN to be independent of system−level issues because of its self−corrective nature. In PC design, the operating point for the chassis is usually the worst−case internal chassis temperature. The optimal operating point for the processor is determined by monitoring the thermal monitor in the Intel Pentium 4 processor. To do this, the PROCHOT output of the Pentium 4 is connected to the THERM input of the ADT7462. The operating point for the processor can be determined by allowing the current temperature to be copied to the operating point register when the PROCHOT output pulls the THERM input low on the ADT7462. This gives the maximum temperature at which the Pentium 4 can run before clock modulation occurs. Acoustic Enhancement Mode Overview Figure 74 gives a top−level overview of the automatic fan control circuitry on the ADT7462 and shows where acoustic enhancement fits in. Acoustic enhancement is intended as a post−design tweak made by a system or mechanical engineer evaluating best settings for the system. Having determined the optimal settings for the thermal solution, the engineer can adjust the system acoustics. The goal is to implement a system that is acoustically pleasing without causing user annoyance due to fan cycling. It is important to realize that although a system might pass an acoustic noise requirement specification (for example, 36 dB), if the fan is annoying, it fails the consumer test. Enabling the THERM Trip Point as the Operating Point Bits [5:2] of Dynamic TMIN Control Register 1 (0x0B) enable/disable THERM monitoring to program the operating point. Table 39 details how the remote ACOUSTIC ENHANCEMENT THERMAL CALIBRATION PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION 0% PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) MUX TMIN LOCAL = VRM TEMP THERMAL CALIBRATION TMIN REMOTE 1 = AMBIENT TEMP TRANGE 0% PWM MIN 100% TRANGE TACHOMETER 1 MEASUREMENT TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) PWM GENERATOR PWM CONFIG PWM GENERATOR PWM CONFIG Figure 74. Acoustic Enhancement Smoothes Fan Speed Variations Under Automatic Fan Speed Control http://onsemi.com 45 TACH1 CPU FAN SINK PWM2 TACH2 FRONT CHASSIS PWM GENERATOR TACHOMETER 3 AND 4 MEASUREMENT 0% PWM1 PWM3 TACH3 REAR CHASSIS ADT7462 Approaches to System Acoustic Enhancement Effect of Ramp Rate on Enhanced Acoustic Mode There are two different approaches to implementing system acoustic enhancement: temperature−centric and fan−centric. The temperature−centric approach involves smoothing transient temperatures as they are measured by a temperature source (for example, Remote 1 temperature). The temperature values used to calculate the PWM duty cycle values are smoothed, reducing fan speed variation. However, this approach causes an inherent delay in updating fan speed and causes the thermal characteristics of the system to change. It also causes the system fans to stay on longer than necessary, because the fan’s reaction is merely delayed. The user has no control over noise from different fans driven by the same temperature source. Consider, for example, a system in which control of a CPU cooler fan (on PWM1) and a chassis fan (on PWM2) uses Remote 1 temperature. Because the Remote 1 temperature is smoothed, both fans are updated at exactly the same rate. If the chassis fan is much louder than the CPU fan, there is no way to improve its acoustics without changing the thermal solution of the CPU cooling fan. The fan−centric approach to system acoustic enhancement controls the PWM duty cycle, driving the fan at a fixed rate (for example, 6%). Each time the PWM duty cycle is updated, it is incremented by a fixed 6%. As a result, the fan ramps smoothly to its newly calculated speed. If the temperature starts to drop, the PWM duty cycle immediately decreases by 6% at every update. Therefore, the fan ramps smoothly up or down without inherent system delay. Consider, for example, controlling the same CPU cooler fan (on PWM1) and chassis fan (on PWM2) using Remote 1 temperature. The TMIN and TRANGE settings have already been defined in automatic fan speed control mode; that is, thermal characterization of the control loop has been optimized. The chassis fan is noisier than the CPU cooling fan. Using the fan−centric approach, PWM2 can be placed into acoustic enhancement mode independently of PWM1. The acoustics of the chassis fan can, therefore, be adjusted without affecting the acoustic behavior of the CPU cooling fan, even though both fans are controlled by Remote 1 temperature. The fan−centric approach is how acoustic enhancement works on the ADT7462. The PWM signal driving the fan has a period, t, given by the PWM drive frequency, f, because t = 1/f. For a given PWM period, t, the PWM period is subdivided into 255 equal time slots. One time slot corresponds to the smallest possible increment in the PWM duty cycle. A PWM signal of 33% duty cycle is, therefore, high for 1/3 × 255 time slots and low for 2/3 × 255 time slots. Therefore, a 33% PWM duty cycle corresponds to a signal that is high for 85 time slots and low for 170 time slots. PWM_OUT 33% DUTY CYCLE 85 TIME SLOTS 170 TIME SLOTS PWM OUTPUT (ONE PERIOD) = 255 TIME SLOTS Figure 75. 33% PWM Duty Cycle Represented in Time Slots The ramp rates in the enhanced acoustics mode are selectable from 1 to 8. The ramp rates are discrete time slots. For example, if the ramp rate is 8, then eight time slots are added to the PWM high duty cycle each time the PWM duty cycle needs to be increased. If the PWM duty cycle value needs to be decreased, it is decreased by eight time slots. Figure 76 shows how the enhanced acoustics mode algorithm operates. READ TEMPERATURE CALCULATE NEW PWM DUTY CYCLE IS NEW PWM VALUE > PREVIOUS VALUE? NO DECREMENT PREVIOUS PWM VALUE BY RAMP RATE YES INCREMENT PREVIOUS PWM VALUE BY RAMP RATE Figure 76. Enhanced Acoustics Mode Algorithm The enhanced acoustics mode algorithm calculates a new PWM duty cycle based on the temperature measured. If the new PWM duty cycle value is greater than the previous PWM value, the previous PWM duty cycle value is incremented by either 1, 2, 3, 5, 8, 12, 24, or 48 time slots, depending on the settings of the enhanced acoustics registers. If the new PWM duty cycle value is less than the previous PWM value, the previous PWM duty cycle is decremented by 1, 2, 3, 5, 8, 12, 24, or 48 time slots. Each time the PWM duty cycle is incremented or decremented, its value is stored as the previous PWM duty cycle for the next comparison. Enabling Acoustic Enhancement for Each PWM Output Enhanced Acoustics Register 1 (0x1A) Bit 0 (En1) = 1 enables acoustic enhancement on PWM1 output. Bit 1 (En2) = 1 enables acoustic enhancement on PWM2 output. Enhanced Acoustics Register 2 (0x1B) Bit 0 (En3) = 1 enables acoustic enhancement on PWM3 output. Bit 1 (En4) = 1 enables acoustic enhancement on PWM4 output. http://onsemi.com 46 ADT7462 Another way to view the ramp rates is to measure the time it takes for the PWM output to ramp up from 0% to 100% duty cycle for an instantaneous change in temperature. This can be tested by putting the ADT7462 into manual mode and changing the PWM output from 0% to 100% PWM duty cycle. The PWM output takes 35 seconds to reach 100% when a ramp rate of one time slot is selected. Figure 77 shows remote temperature plotted against PWM duty cycle for enhanced acoustics mode. The ramp rate is set to 48, which corresponds to the fastest ramp rate. Assume that a new temperature reading is available every 115 ms. With these settings, it takes approximately 0.76 seconds to go from 33% duty cycle to 100% duty cycle (full speed). Even though the temperature increases very rapidly, the fan ramps up to full speed gradually. A ramp rate of 1 corresponds to one time slot, which is 1/255 of the PWM period. In enhanced acoustics mode, incrementing or decrementing by 1 changes the PWM output by 1/255 × 100%. Step 11—Ramp Rate for Acoustic Enhancement The optimal ramp rate for acoustic enhancement can be found through system characterization after the thermal optimization has been finished. The effect of each ramp rate should be logged, if possible, to determine the best setting for a given solution. Enhanced Acoustics Register 1 (0x1A) Bits [4:2] RR1 select the ramp rate for PWM1. 000 = 1 time slot = 35 seconds 001 = 2 time slots = 17.6 seconds 010 = 3 time slots = 11.8 seconds 011 = 5 time slots = 7 seconds 100 = 8 time slots = 4.4 seconds 101 = 12 time slots = 3 seconds 110 = 24 time slots = 1.6 seconds 111 = 48 time slots = 0.8 seconds Bits [7:5] RR2 select the ramp rate for PWM2. 000 = 1 time slot = 35 seconds 001 = 2 time slots = 17.6 seconds 010 = 3 time slots = 11.8 seconds 011 = 5 time slots = 7 seconds 100 = 8 time slots = 4.4 seconds 101 = 12 time slots = 3 seconds 110 = 24 time slots = 1.6 seconds 111 = 48 time slots = 0.8 seconds 140 120 120 RTEMP (5C) 100 100 80 80 60 60 PWM CYCLE (%) 40 40 20 20 0 0 0 0.76 TIME (s) Figure 77. Enhanced Acoustics Mode with Ramp Rate = 48 Figure 78 shows how changing the ramp rate from 48 to 8 affects the control loop. The overall response of the fan is slower. Because the ramp rate is reduced, it takes longer for the fan to achieve full running speed. In this case, it takes approximately 4.4 seconds for the fan to reach full speed. Enhanced Acoustics Register 2 (0x1B) Bits [4:2] RR3 select the ramp rate for PWM3. 000 = 1 time slot = 35 seconds 001 = 2 time slots = 17.6 seconds 010 = 3 time slots = 11.8 seconds 011 = 5 time slots = 7 seconds 100 = 8 time slots = 4.4 seconds 101 = 12 time slots = 3 seconds 110 = 24 time slots = 1.6 seconds 111 = 48 time slots = 0.8 seconds Bits [7:5] RR4 select the ramp rate for PWM4. 000 = 1 time slot = 35 seconds 001 = 2 time slots = 17.6 seconds 010 = 3 time slots = 11.8 seconds 011 = 5 time slots = 7 seconds 100 = 8 time slots = 4.4 seconds 101 = 12 time slots = 3 seconds 110 = 24 time slots = 1.6 seconds 111 = 48 time slots = 0.8 seconds 120 140 RTEMP (5C) 120 100 100 80 PWM DUTY CYCLE (%) 80 60 60 40 40 20 0 20 0 TIME (s) 4.4 0 Figure 78. Enhanced Acoustics Mode with Ramp Rate = 8 http://onsemi.com 47 ADT7462 Figure 79 shows the PWM output response for a ramp rate of 2. In this instance, the fan takes about 17.6 seconds to reach full running speed. 140 90 80 PWM DUTY CYCLE (%) 70 120 RTEMP (5C) 60 120 100 100 50 RTEMP (5C) 40 80 30 80 60 PWM DUTY CYCLE (%) 20 60 10 40 40 0 Figure 81. How Fan Reacts to Temperature Variations in Enhanced Acoustics Mode 20 20 0 0 TIME (s) 0 17.6 Slower Ramp Rates The ADT7462 can be programmed for much longer ramp times by slowing the ramp rates. Each ramp rate can be slowed by a factor of 4. PWM1 Configuration Register (0x21) PWM2 Configuration Register (0x22) PWM3 Configuration Register (0x23) PWM4 Configuration Register (0x24) Setting Bit 3 (the SLOW bit) to 1 in the PWM1 to PWM4 configuration registers slows the ramp rate for PWM1 to PWM4 by 4. Figure 79. Enhanced Acoustics Mode with Ramp Rate = 2 Figure 80 shows how the control loop reacts to temperature with the slowest ramp rate. The ramp rate is set to 1, while all other control parameters remain the same. With the slowest ramp rate selected, it takes 35 seconds for the fan to reach full speed. 140 120 RTEMP (5C) 120 100 100 80 Fan Freewheeling Test Mode 80 The fan freewheeling test mode is intended to diagnose whether fans connected to the ADT7462 are working properly. It is particularly useful where fans coupled in the duct can affect the airflow of another fan. If one fan has failed, it may not be apparent, because moving air from other fans can cause air to flow through the faulty fan, which in turn can cause the faulty fan to rotate. The fan freewheeling test is most useful in a system using primary and redundant setup. In such a system, the following setup is recommended. The primary fans are Fan 1, Fan 2, Fan 3, and Fan 4. The redundant fans are Fan 5, Fan 6, Fan 7, and Fan 8. In this setup, each primary and redundant fan can be driven separately because they are driven by different PWMs. 60 60 PWM DUTY CYCLE (%) 40 40 20 20 0 0 TIME (s) 35 0 Figure 80. Enhanced Acoustics Mode with Ramp Rate = 1 As Figure 77 to Figure 80 show, the rate at which the fan reacts to temperature change is dependent on the ramp rate selected in the enhanced acoustics registers. The higher the ramp rate, the faster the fan reaches the newly calculated fan speed. Figure 81 shows the behavior of the PWM output as temperature varies. As the temperature increases, the fan speed ramps up. Small drops in temperature do not affect the ramp−up function, because the newly calculated fan speed is still higher than the previous PWM value. Enhanced acoustics mode allows the PWM output to be made less sensitive to temperature variations. This is dependent on the ramp rate selected and programmed into the enhanced acoustics registers. PWM 1 PWM 2 FAN 1 FAN 2 FAN 3 FAN 4 TACH CCT 1 TACH CCT 2 TACH CCT 3 TACH CCT 4 FAN 5 FAN 6 FAN 7 FAN 8 PWM 3 PWM 4 Figure 82. Fan Freewheeling Test Mode Setup http://onsemi.com 48 ADT7462 register (0xBD) should be read directly after completion of the test. The freewheeling test procedure is as follows: 1. PWM1 and PWM2 go to full speed, and PWM3 and PWM4 are switched off. 2. After the spin−up time of PWM1 and PWM2 has elapsed, the speed of Fan 1, Fan 2, Fan 3, and Fan 4 is measured. 3. After the speed of Fan 1 and Fan 2 is measured, PWM1 is switched off and PWM3 is spun up. After the spin−up time for PWM3 has elapsed, the speed of Fan 5 and Fan 6 is measured. 4. After the speed of Fan 3 and Fan 4 is measured, PWM2 is switched off and PWM4 is switched on. After the spin−up time of PWM4 has elapsed, the speed of Fan 7 and Fan 8 is measured. 5. After the speed of all eight fans has been measured, the TACH and PWM configurations return to their previous values. • Fans must be in continuous mode for the freewheeling test; that is, the dc bits must be set (Register 0x08). • To enable the freewheeling test, set the freewheeling test enable register (0x1E) to a nonzero value. Set Bit 0 = 1 to enable the freewheeling test for Fan 1, and set Bit 1 for Fan 2, all the way to Bit 7 for Fan 8. The freewheeling test enable register should be programmed after the fans present register is programmed. If the fans present register is not programmed first, then the values in the two registers do not match, and the ADT7462 assumes that a fan is missing. The following registers must be programmed for the fan freewheeling test: Fans Present Register (0x1D) Set Bit 0 to 1 when a fan is connected to TACH1. Set Bit 1 to 1 when a fan is connected to TACH2. Set Bit 2 to 1 when a fan is connected to TACH3. Set Bit 3 to 1 when a fan is connected to TACH4. Set Bit 4 to 1 when a fan is connected to TACH5. Set Bit 5 to 1 when a fan is connected to TACH6. Set Bit 6 to 1 when a fan is connected to TACH7. Set Bit 7 to 1 when a fan is connected to TACH8. Fan Freewheeling Test Enable Register (0x1E) Set Bit 0 to 1 to enable the freewheeling test for Fan 1. Set Bit 1 to 1 to enable the freewheeling test for Fan 2. Set Bit 2 to 1 to enable the freewheeling test for Fan 3. Set Bit 3 to 1 to enable the freewheeling test for Fan 4. Set Bit 4 to 1 to enable the freewheeling test for Fan 5. Set Bit 5 to 1 to enable the freewheeling test for Fan 6. Set Bit 6 to 1 to enable the freewheeling test for Fan 7. Set Bit 7 to 1 to enable the freewheeling test for Fan 8. Fan Freewheeling Test Register (0x1C) Both the Fans Present register (0x1D) and the freewheeling test enable register (0x1E) should be programmed before setting the relevant bits in the fan freewheeling test register (0x1C). The host fan status THERM I/O Operation This section describes the operation of THERM1 and THERM2. Pin 28 and Pin 29 can both be configured as THERM inputs or outputs. THERM Output THERM is not enabled as an output by default on powerup, but it can be enabled by setting the appropriate bits in Register 0x0E (THERM1 configuration register) and Register 0x0F (THERM2 configuration register). THERM1 and THERM2 can be configured to assert whenever a specific channel exceeds the specified THERM limit (see Table 30). Table 26. THERM Output Channel Select and Limits Configuration Limit Registers Channel Enable THERM1, Register 0x0E THERM2, Register 0x0F THERM1 THERM2 Local Bit 1 = 1 Bit 1 = 1 0x4C 0x50 Remote 1 Bit 2 = 1 Bit 2 = 1 0x4D 0x51 Remote 2 Bit 3 = 1 Bit 3 = 1 0x4E 0x52 Remote 3 Bit 4 = 1 Bit 4 = 1 0x4F 0x53 As an output, THERM is asserted low to signal that the measured THERM temperature has exceeded pre− programmed THERM temperature limits. The output is automatically pulled high again when the temperature falls below the (THERM − Hysteresis) limit. The value of hysteresis for each channel is programmable in Register 0x54 and Register 0x55, where 1 LSB = 1°C, and the maximum hysteresis for each channel is 15°C. Setting the THERM boost bits, Bit 0 and Bit 1, to Logic 0 (default setting) in the THERM configuration register (0x0D), sets the fans to full speed on an internal THERM event. THERM Input To configure THERM as an input, the THERM1_Timer_Enable (T1TE) bit (Bit 0) in the THERM1 configuration register (0x0E) and the THERM2_Timer_Enable (T2TE) bit (Bit 0) in the THERM2 configuration register (0x0F) must be set to Logic 1. The ADT7462 can then be used to detect when the THERM pins are asserted low. The THERM pins can be connected to a trip point temperature sensor or to the PROCHOT output of a CPU. With processor core voltages reducing all the time, the threshold for the AGTL + PROCHOT output is also reduced as new processors become available. Because the THERM input is typically an AGTL + input, the thresholds can be referenced to VCCP. By setting Bit 4 of Configuration Register 3 (0x03) to 1, the THERM threshold is 2/3 × VCCP, the correct threshold for an AGTL + signal. The THERM assert bits in Host Thermal Status Register 2 http://onsemi.com 49 ADT7462 (0xB9) are set to Logic 1 whenever the THERM input is asserted low. The THERM state bits in Host Thermal Status Register 2 (0xB9) indicate that a high−to−low transition has taken place on the THERM pin. When the measured percentage exceeds the corresponding percentage limit, the T1% bit in Host Thermal Status Register 2 (0xB9) is asserted, and an ALERT is generated (that is, if the mask bit is not set). If the limit is set to 0x00, an ALERT is generated on the first assertion. If the limit is set to 0xFF, an ALERT is never generated because 0xFF corresponds to the THERM input being asserted all the time. When THERM is configured as an input only, setting Bits [4:1] of the THERM zone in the THERM1 configuration register (0x0E) and the THERM2 configuration register (0x0F) allows Pin 28/Pin 29 to operate as an I/O. TEMPERATURE 1005C 905C THERM LIMIT 805C HIGH TEMP LIMIT 705C THERM LIMIT HYSTERESIS 605C 505C 405C THERM Timer Limit Register RESET BY MASTER ALERT 1 THERM The THERM timer limit is programmed to Register 0x80 and Register 0x81. If THERM is asserted for longer than the programmed percentage limit, then an ALERT is generated. The limit is programmed as a percentage of the chosen THERM timer window. EXAMPLE: The THERM timer window is eight seconds, and an ALERT should be generated if THERM is asserted for more than one second. 4 2 3 Figure 83. THERM Behavior THERM Timer The ADT7462 can also measure assertion times on the THERM inputs as a percentage of a timer window. The timer window for the THERM1 input is programmed using Bits [4:2] of the THERM configuration register (0x0D). The timer window for the THERM2 input is programmed using Bits [7:5] of the THERM configuration register (0x0D). Values from 0.25 sec to 8 sec are programmable (see Table 27). %Limit + 1 8 The THERM timer limit register is an 8−bit register. 0 THERM Timer Window 000 0.25 sec 001 0.5 sec 010 1 sec 011 2 sec 100 4 sec 101 8 sec 110 8 sec 111 8 sec 00 + 0%; 0 FF + 100% Therefore, 1 LSB = 0.39% 12.5% + 32 decimal + 0 0.39% Table 27. THERM Timer Window Code 100 + 12.5% 20 + 00100000 When the time window has elapsed, if the THERM limit has been exceeded, then an ALERT is generated. General−Purpose I/O Pins The ADT7462 has eight open−drain GPIO pins. GPIO1 to GPIO4 can be configured to enable event driven outputs (EDOs), and GPIO5 and GPIO6 can act as EDOs, if the EDO functionality is enabled. Two other GPIOs (GPIO7 and GPIO8) are standard GPIO pins that are dedicated to general−purpose logic input/output. Each GPIO pin has five data bits associated with it: three bits in a GPIO configuration register (0x09 and 0x0A), one in the GPIO status register (0xBF), and one in the GPIO mask register (0x36). Setting a direction bit to 1 in a GPIO configuration register makes the corresponding GPIO pin an output. Clearing the direction bit to 0 makes the corresponding GPIO pin an input. Setting a polarity bit to 1 in a GPIO configuration register makes the corresponding GPIO pin active high. Clearing the polarity bit to 0 makes the corresponding GPIO pin active low. When a GPIO pin is configured as an input, the corresponding bit in the GPIO status register is read−only, and it is set when the input is asserted (“asserted” can be high or low, depending on the setting of the polarity bit). The assertion time as a percentage of the timer window is stored in the THERM % on−time registers. This is a cumulative sum of the percentage of time during the THERM timer window that THERM is asserted. The % on−time and associated timer limit registers are listed in Table 28. Table 28. THERM On−Time and Timer Limit Register Channel % On−Time Register % Timer Limit Register THERM1 0xAE 0x80 THERM2 0xAF 0x81 http://onsemi.com 50 ADT7462 The polarity of the EDOs is set in the GPIO configuration registers (0x09 and 0x0A). Setting a polarity bit to 1 in one of the GPIO configuration registers makes the corresponding GPIO pin active high. Clearing the polarity bit to 0 makes it active low. When a GPIO pin is configured as an output, the corresponding bit in the GPIO status register becomes read/write. Setting this bit then asserts the GPIO output. (Again, “asserted” can be high or low, depending on the setting of the polarity bit.) The effect of a GPIO status register bit on the ALERT output can be masked by setting the corresponding bit in one of the GPIO mask registers. When the pin is configured as an output, the corresponding status bit is automatically masked to prevent the data written to the status bit from causing an interrupt. When configured as inputs, the GPIO pins can be connected to external interrupt sources such as temperature sensors with digital output. GPIO1 EDO (GPIO5) GPIO2 EVENT MASK LATCH GPIO3 EDO (GPIO6) GPIO4 Figure 84. EDO Circuit Bits [7:5] of each event mask register (0x37 and 0x38) allow the EDO output to be driven high or low (depending on the polarity bit of the configuration register) and latched (depending on the EDO latch bit of the configuration register), if the ADT7462 detects an overtemperature, an over/undervoltage, or a fan failure condition. EDO Circuitry The ADT7462 has the added functionality that the assertion of one of the four GPIOs (GPIO1 to GPIO4) can be used to latch one of the two EDOs high or low. The ADT7462 has two EDO event mask registers (0x37 and 0x38): one mask for each EDO. See Table 29 for an explanation of event mask register functionality. Table 29. EDO Control (Mask) Register 0x37 and Register 0x38 Bit 7: Overvoltage/ Undervoltage Bit 6: THERM Bit 5: Fan Fail Bit 3 Bit 2 Bit 1 Bit 0 0 = Drive Output X 0 = Drive Output X 0 = Drive Output X 0 0 0 0 G4 or G3 or G2 or G1 1 = Ignore Event 1 = Ignore Event 1 = Ignore Event 0 0 0 1 G4 or G3 or G2 0 0 1 0 G4 or G3 or G1 0 0 1 1 G4 or G3 0 1 0 0 G4 or G2 or G1 0 1 0 1 G4 or G2 0 1 1 0 G4 or G1 0 1 1 1 G4 1 0 0 0 G3 or G2 or G1 1 0 0 1 G3 or G2 1 0 1 0 G3 or G1 1 0 1 1 G3 1 1 0 0 G2 or G1 1 1 0 1 G2 1 1 1 0 G1 1 1 1 1 GPIO events ignored by Output X Behavior: What Drives and Latches Output X (G = GPIO) monitored and configured for actions to occur on their assertion. Table 29 shows that any of the four designated GPIO pins can be used to set or reset either one of the two EDO outputs. Using this functionality, it is possible to have the ADT7462 drive LEDs or signals based on rules. For example, if a GPIO1 (power fail), a GPIO2 (overcurrent), or an overtemperature condition occurs, EDO1 (power supply fault LED) can be latched. This does not require software handling and makes the part more autonomous. VR_HOT Inputs Pin 25 and Pin 26 can be configured as VR_HOT inputs. These are specific digital signals from the CPU voltage regulator that indicate an overtemperature. On assertion of these inputs, the relevant status bits are set in Thermal Status Register 2 (Host Register 0xB9 or BMC Register 0xC1). Assertion of these inputs can also be used to boost the fans to full speed, thus providing emergency cooling in the event of VR overtemperature. This is set using Bit 3 (VRD1) and Other Digital Inputs The ADT7462 contains other specific digital inputs that can be found on PC motherboards. These inputs can be http://onsemi.com 51 ADT7462 Chassis Intrusion Input Bit 4 (VRD2) of Configuration Register 2 (0x02). There is also an associated mask bit in Register 0x31 to mask the assertion of these inputs from the ALERT output. The chassis intrusion (CI) input is an active high input intended for detection and signaling of unauthorized tampering with the system. When this input goes high, the event is latched in Bit 7 of Host Digital Status Register (0xBE), and an interrupt is generated. The bit remains set until cleared by writing a 1 to CI reset (CI_R), Bit 5 of Configuration Register 3 (0x03). The CI reset bit is cleared by writing a 0 to it. The CI circuit is powered from the VBATT voltage channel. Pin 26 must be configured to monitor VBATT and a battery must be connected to monitor CI events. CI monitoring is disabled if the measured VBATT value (0x93) is less than the lower voltage limit (0x75) of Pin 26. The CI input detects chassis intrusion events even when the ADT7462 is powered off (provided battery voltage is applied to VBATT) but does not immediately generate an interrupt. When a chassis intrusion event is detected and latched, an interrupt is generated when the system is powered on. The actual detection of chassis intrusion is performed by an external circuit that detects, for example, when the cover has been removed. A wide variety of techniques can be used for chassis detection. For example, • A microswitch that opens or closes when the cover is removed • A reed switch operated by a magnet affixed to the cover • A hall−effect switch operated by a magnet affixed to the cover • A photo−transistor that detects light when the cover is removed SCSI_TERM Inputs Pin 16 and Pin 20 can be configured as SCSI_TERM inputs. An assertion on the SCSI_TERM is recorded in Bit 4 and Bit 5 of Host Digital Status Register (0xBE) or BMC Digital Status Register (0xC6). There is also an associated mask bit in Register 0x35 to mask the assertion of these inputs from the ALERT output. Reset I/O The ADT7462 includes an active low reset pin (Pin 14). The RESET pin can be both a reset input and output. RESET monitors the VCC input to the ADT7462. At powerup, RESET is asserted (pulled low) until 180 ms after the power supply has risen above the supply threshold. A power−on reset initializes all registers to the default values. VCC 1.0 V RESET 180 ms Figure 85. Operation of RESET Output on Powerup The RESET pin can also function as a reset input. Pulling this pin low externally resets the ADT7462. The user should wait at least 180 ms after powerup before doing a hardware reset. The reset pulse width should be greater than 0.8 ms to ensure that a reset is registered. A hardware reset differs from a power−on reset in that not all of the registers are reinitialized to the default values. For example, limit registers are not all restored to the default values. This can be useful if the user needs to reset the part but does not want to completely reprogram the device. The Register Map section show, which registers, are reset. Locked registers are not restored to default values by a hardware reset. Note that if two ADT7462 devices are used in one system, the RESET pins should not be connected together between devices. Doing so causes one device to reset the other on a power−on reset. Powerup Sequence The powerup sequence of the ADT7462 is as follows: 1. The temperature of the thermal diode connected to Pin 17 and Pin 18 (only dedicated thermal diode channel) is monitored immediately on powerup of the ADT7462. Ideally, the hottest zone should be connected to this channel so protection is provided immediately on powerup. 2. VCCP1 is also monitored immediately on powerup. VCCP1 is typically connected to a main power rail. Switching on the VCCP1 rail gates the fan’s quiet startup counter. 3. VBATT is monitored immediately on powerup before the setup complete bit (Register 0x01, Bit 5) is set. The chassis intrusion circuit (CI) is powered from VBATT. If the measured VBATT reading is lower than the lower limit (default = 0x80), the CI circuit is turned off. 4. PWM1, PWM2, and PWM4 are not on dedicated pins. Because these pins are shared with inputs, they are allowed to float high on powerup. This means that if a fan is connected to these pins, it spins at full speed on powerup. Software Reset The ADT7462 can be reset in software by setting Bit 7 of Configuration Register 0 (0x00). The code 0x6D must be written to Register 0x7B before setting the software reset bit. This register is cleared to the power−on default after the software reset. Note that not all registers are restored to their default values on a reset. The same registers are reset by a hardware and software reset. The Register Map section provides a complete reference of registers that are reset. http://onsemi.com 52 ADT7462 3. Program all appropriate limits for monitored inputs. Program device parameters, fan control parameters, mask bits, and anything else required for the application. 4. Set the setup complete bit. Do not set this bit until the device is fully set up. 5. PWM3 is switched off by default (because this is a dedicated pin). If no SMBus communication takes place within 4.6 seconds of the VCCP rail switching on, this PWM drive is driven to full speed. If SMBus communication does take place, this pin behaves as programmed. 6. No temperature or voltage (other than VCCP1, Diode 2, and VBATT) is monitored until the setup complete bit (Bit 5) is set in Configuration Register 1 (0x01). This allows the user to program the ADT7462 as required before monitoring of all channels is enabled, thereby not generating false ALERTs. The setup complete bit should not be set until the device is fully configured for the desired monitoring functions. The following steps describe how to set up the ADT7462: 1. Powerup the device. 2. Choose the best−suited easy configuration option for the application, changing pin functions as required. XOR Tree Test The ADT7462 includes an XOR tree test mode. This mode is useful for in−circuit test equipment at board−level testing. By applying stimulus to the pins included in the XOR test, it is possible to detect opens or shorts on the system board. Figure 86 shows the signals exercised in the XOR tree test. The XOR tree test is invoked by setting Bit 6 (XOR) of Configuration Register 3 (0x03). Note that the digital inputs must be selected on multifunctional pins for the XOR tree test mode. Pin 13 is the open−drain output of the XOR tree test. PIN 1 PIN 25 PIN 2 PIN 3 PIN 26 PIN 4 PIN 27 PIN 7 PIN 28 PIN 8 PIN 29 PIN 16 PIN 31 PIN 20 PIN 32 PIN 13 PIN 21 PIN 22 Figure 86. XOR Tree Test http://onsemi.com 53 ADT7462 Register Tables Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0x00 Config 0 R/W SW Reset VID # Bytes # Bytes #Bytes # Bytes # Bytes # Bytes 0x20 Yes Yes 0x01 Config 1 R/W RDY Lock SC DFS ALERT Res Res Mon 0x81 Yes Yes 0x02 Config 2 R/W #FP #FP FMS VRD2 VRD1 PWM Res FAST 0x80 Yes Yes 0x03 Config 3 R/W V_Core_ Low XOR CI_R TT VID_T SDA SCL GPIO 0x00 Yes Yes 0x07 TACH Enable R/W T8E T7E T6E T5E T4E T3E T2E T1E 0x00 Yes Yes 0x08 TACH Config R/W Res Res Res Res DC 4/8 DC 3/7 DC 2/6 DC 1/5 0x0F Yes Yes 0x09 GPIO1_ Bhvr R/W D4 P4 D3 P3 D2 P2 D1 P1 0x00 Yes Yes 0x0A GPIO2_ Bhvr R/W D8 P8 D7 P7 D6 P6 D5 P5 0x00 Yes Yes 0x0B TMIN_Cal1 R/W Res Res P2R2 P2R1 P1R2 P1R1 R2 R1 0x00 Yes Yes 0x0C TMIN_Cal2 R/W Res Ctrl Loop Select CYR2 CYR2 CYR2 CYR1 CYR1 CYR1 0x40 Yes Yes 0x0D THERM Conf R/W TW2 TW2 TW2 TW1 TW1 TW1 B2 B1 0x00 Yes Yes 0x0E Conf_ THERM1 R/W Res Res Res R3 R2 R1 Local T1TE 0x00 Yes Yes 0x0F Conf_ THERM2 R/W Res Res Res R3 R2 R1 Local T2TE 0x00 Yes Yes 0x10 Pin Conf 1 R/W VID D1 D3 Pin 1 Pin 2 Pin 3 Pin 4 Pin 7 0x7F Yes Yes 0x11 Pin Conf 2 R/W Pin 8 Pin 13 Pin 15 Pin 19 Pin 21 Pin 22 Pin 23 Pin 23 0xCE Yes Yes 0x12 Pin Conf 3 R/W Pin 24 Pin 24 Pin 25 Pin 25 Pin 26 Pin 26 Pin 27 Res 0x42 Yes Yes 0x13 Pin Conf 4 R/W Pin 28 Pin 28 Pin 29 Pin 29 Pin 31 Pin 32 Res Res 0xFC Yes Yes 0x14 Easy Conf R/W Res Res Res Op5 Op4 Op3 Op2 Op1 0x01 Yes Yes 0x16 EDO Enable R/W CS CS CS CS CS SC EDO2 EDO1 0x00 Yes Yes 0x18 Attenuators 1 En R/W Pin 22 Pin 21 Pin 19 Pin 15 Pin 13 Pin 8 Pin 7 Res 0xFF Yes Yes 0x19 Attenuators 2 En R/W Res Res Pin 29 Pin 28 Res Pin 25 Pin 24 Pin 23 0x37 Yes Yes 0x1A Enhanced Acoustics 1 R/W RR2 RR2 RR2 RR1 RR1 RR1 En2 En1 0x00 Yes Yes 0x1B Enhanced Acoustics 2 R/W RR4 RR4 RR4 RR3 RR3 RR3 En4 En3 0x00 Yes Yes 0x1C Fan Freewheel Test R/W Fan 8 Fan 7 Fan 6 Fan 5 Fan 4 Fan 3 Fan 2 Fan 1 0x00 Yes Yes 0x1D Fans Present R/W F8P F7P F6P F5P F4P F3P F2P F1P 0x00 Yes Yes 0x1E Fan Freewheel TestEn R/W Fan 8 Fan 7 Fan 6 Fan 5 Fan 4 Fan 3 Fan 2 Fan 1 0x00 Yes Yes 0x21 PWM1 Config R/W BHVR BHVR BHVR INV SLOW Spin Spin Spin 0x11 Yes Yes 0x22 PWM2 Config R/W BHVR BHVR BHVR INV SLOW Spin Spin Spin 0x31 Yes Yes 0x23 PWM3 Config R/W BHVR BHVR BHVR INV SLOW Spin Spin Spin 0x51 Yes Yes 0x24 PWM4 Config R/W BHVR BHVR BHVR INV SLOW Spin Spin Spin 0x71 Yes Yes 0x25 PWM1, PWM2 Freq R/W F2 F2 F2 F1 F1 F1 Min 2 Min 1 0x90 Yes Yes 0x26 PWM3, PWM4 Freq R/W F4 F4 F4 F3 F3 F3 Min 4 Min 3 0x90 Yes Yes 0x28 PWM1 Min R/W 7 6 5 4 3 2 1 0 0x80 Yes Yes http://onsemi.com 54 ADT7462 Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0x29 PWM2 Min R/W 7 6 5 4 3 2 1 0 0x80 Yes Yes 0x2A PWM3 Min R/W 7 6 5 4 3 2 1 0 0x80 Yes Yes 0x2B PWM4 Min R/W 7 6 5 4 3 2 1 0 0x80 Yes Yes 0x2C PWM1 to PWM4 Max R/W 7 6 5 4 3 2 1 0 0xC0 Yes Yes 0x30 Thermal Mask 1 R/W R3D R2D R1D R3 R2 R1 Local Res 0x00 Yes No 0x31 Thermal Mask 2 R/W VRD2 VRD1 T2S T2A T2% T1S T1A T1% 0xC0 Yes No 0x32 Voltage Mask 1 R/W P23 +5V P19 P15 +3.3V +12V3 +12V2 +12V1 0x00 Yes No 0x33 Voltage Mask 2 R/W +1.5V1 (ICH) +1.5V2 (3GIO) P26 P25 P24 Res Res Res 0x00 Yes No 0x34 Fan Mask R/W Fan 8 Fan 7 Fan 6 Fan 5 Fan 4 Fan 3 Fan 2 Fan 1 0x00 Yes No 0x35 Digital Mask R/W CI VID SCSI2 SCSI1 FAN2MAX Res Res Res 0x38 Yes No 0x36 GPIO Mask R/W GPIO8 GPIO7 GPIO6 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 0x00 Yes No 0x37 EDO Mask 1 R/W Volt Temp Fan Res GPIO4 GPIO3 GPIO2 GPIO1 0x00 Yes No 0x38 EDO Mask 2 R/W Volt Temp Fan Res GPIO4 GPIO3 GPIO2 GPIO1 0x00 Yes No 0x3D Device ID R 7 6 5 4 3 2 1 0 0x62 No N/A 0x3E Comp ID R 7 6 5 4 3 2 1 0 0x41 No N/A 0x3F Rev No R 7 6 5 4 3 2 1 0 0x04 No N/A 0x44 Local Low Temp Limit R/W 7 6 5 4 3 2 1 0 0x40 No No 0x45 Remote 1/Pin 15 Low Temp Limit R/W 7 6 5 4 3 2 1 0 0x40 No No 0x46 Remote 2 Low Temp Limit R/W 7 6 5 4 3 2 1 0 0x40 No No 0x47 Remote 3/Pin 19 Low Temp Limit R/W 7 6 5 4 3 2 1 0 0x40 No No 0x48 Local High Limit R/W 7 6 5 4 3 2 1 0 0x95 No No 0x49 Remote 1/Pin 15 High Limit R/W 7 6 5 4 3 2 1 0 0x95 No No 0x4A Remote 2 High Limit R/W 7 6 5 4 3 2 1 0 0x95 No No 0x4B Remote 3/Pin 19 High Limit R/W 7 6 5 4 3 2 1 0 0x95 No No 0x4C Local THERM1/ +1.5V2 (3GIO) High R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x4D Remote 1 THERM1 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x4E Remote 2 THERM1 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x4F Remote 3 THERM1 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes http://onsemi.com 55 ADT7462 Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0x50 Local THERM2/ +1.5V1 (ICH) High R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x51 Remote 1 THERM2 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x52 Remote 2 THERM2 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x53 Remote 3 THERM2 Limit R/W 7 6 5 4 3 2 1 0 0xA4 No Yes 0x54 Local/Remote1 Temp Hyst R/W LH LH LH LH R1H R1H R1H R1H 0x44 No Yes 0x55 Remote 2/ Remote 3 Temp Hyst R/W R2H R2H R2H R2H R3H R3H R3H R3H 0x44 No Yes 0x56 Local Offset R/W 7 6 5 4 3 2 1 0 0x00 No Yes 0x57 Remote 1 Offset R/W 7 6 5 4 3 2 1 0 0x00 No Yes 0x58 Remote 2 Offset R/W 7 6 5 4 3 2 1 0 0x00 No Yes 0x59 Remote 3 Offset R/W 7 6 5 4 3 2 1 0 0x00 No Yes 0x5A Remote 1 Operating Point R/W 7 6 5 4 3 2 1 0 0xA4 Yes Yes 0x5B Remote 2 Operating Point R/W 7 6 5 4 3 2 1 0 0xA4 Yes Yes 0x5C Local Temp TMIN R/W 7 6 5 4 3 2 1 0 0x9A Yes Yes 0x5D Remote 1 Temp TMIN R/W 7 6 5 4 3 2 1 0 0x9A Yes Yes 0x5E Remote 2 Temp TMIN R/W 7 6 5 4 3 2 1 0 0x9A Yes Yes 0x5F Remote 3 Temp TMIN R/W 7 6 5 4 3 2 1 0 0x9A Yes Yes 0x60 Local TRANGE/ Hyst R/W Range Range Range Range Hys Hys Hys Hys 0xC4 Yes Yes 0x61 Remote 1 TRANGE/ Hyst R/W Range Range Range Range Hys Hys Hys Hys 0xC4 Yes Yes 0x62 Remote 2 TRANGE/ Hyst R/W Range Range Range Range Hys Hys Hys Hys 0xC4 Yes Yes 0x63 Remote 3 TRANGE/ Hyst R/W Range Range Range Range Hys Hys Hys Hys 0xC4 Yes Yes 0x64 Operating Point Hyst R/W Hys Hys Hys Hys Res Res Res Res 0x40 Yes Yes 0x68 +3.3V High Limit R/W 7 6 5 4 3 2 1 0 0xFF No No 0x69 Pin 23 Voltage High Limit R/W 7 6 5 4 3 2 1 0 0xFF No No 0x6A Pin 24 Voltage High Limit R/W 7 6 5 4 3 2 1 0 0xFF No No 0x6B Pin 25 Voltage High Limit R/W 7 6 5 4 3 2 1 0 0xFF No No http://onsemi.com 56 ADT7462 Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0x6C Pin 26 Voltage High Limit R/W 7 6 5 4 3 2 1 0 0xFF No No 0x6D +12V1 Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x6E +12V2 Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x6F +12V3 Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x70 +3.3V Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x71 +5V Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x72 Pin 23 Voltage Low Limit R/W 7 6 5 4 3 2 1 0 0x20 No No 0x73 Pin 24 Voltage Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x74 Pin 25 Voltage Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x75 Pin 26 Voltage Low Limit R/W 7 6 5 4 3 2 1 0 0x80 No No 0x76 +1.5V1 (ICH) Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x77 +1.5V2 (3GIO) Low Limit R/W 7 6 5 4 3 2 1 0 0x00 No No 0x78 TACH1 Limit/VID R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x79 TACH2 Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7A TACH3 Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7B TACH4 Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7C TACH5/+12 V1 High Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7D TACH6/+12 V2 High Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7E TACH7/+5V High Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x7F TACH8/+12 V3 High Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x80 THERM1 Timer Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x81 THERM2 Timer Limit R/W 7 6 5 4 3 2 1 0 0xFF No Yes 0x88 Local Temp Value, LSBs R 7 6 5 4 3 2 1 0 0x00 No No 0x89 Local Temp Value, MSBs R 7 6 5 4 3 2 1 0 0x00 No No 0x8A Remote 1 Temp, LSBs R 7 6 5 4 3 2 1 0 0x00 No No http://onsemi.com 57 ADT7462 Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0x8B Remote 1 Temp, MSBs, Pin 15 Volt R 7 6 5 4 3 2 1 0 0x00 No No 0x8C Remote 2 Temp, LSBs R 7 6 5 4 3 2 1 0 0x00 No No 0x8D Remote 2 Temp, MSBs R 7 6 5 4 3 2 1 0 0x00 No No 0x8E Remote 3 Temp, LSBs R 7 6 5 4 3 2 1 0 0x00 No No 0x8F Remote 3 Temp, MSBs, Pin 19 Volt R 7 6 5 4 3 2 1 0 0x00 No No 0x90 Pin 23 Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x91 Pin 24 Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x92 Pin 25 Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x93 Pin 26 Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x94 +1.5V1 (ICH) Volt R 7 6 5 4 3 2 1 0 0x00 No No 0x95 +1.5V2 (3GIO) Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x96 +3.3V Voltage R 7 6 5 4 3 2 1 0 0x00 No No 0x97 VID Value R 7 6 5 4 3 2 1 0 0x00 No No 0x98 TACH1 Value, LSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x99 TACH1 Value, MSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9A TACH2 Value, LSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9B TACH2 Value, MSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9C TACH3 Value, LSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9D TACH3 Value, MSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9E TACH4 Value, LSBs R 7 6 5 4 3 2 1 0 0xFF No No 0x9F TACH4 Value, MSBs R 7 6 5 4 3 2 1 0 0xFF No No 0xA0 Unused R 7 6 5 4 3 2 1 0 N/A No No 0xA1 Unused R 7 6 5 4 3 2 1 0 N/A No No 0xA2 TACH5 Value, LSB R 7 6 5 4 3 2 1 0 0xFF No No 0xA3 TACH5 MSB/ +12V1V R 7 6 5 4 3 2 1 0 0xFF No No 0xA4 TACH6 Value, LSB R 7 6 5 4 3 2 1 0 0xFF No No http://onsemi.com 58 ADT7462 Table 30. Register Map Addr Description R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 De− fault SW Reset Lock able 0xA5 TACH6 MSB/+12V 2 Voltage R 7 6 5 4 3 2 1 0 0xFF No No 0xA6 TACH7 Value, LSB R 7 6 5 4 3 2 1 0 0xFF No No 0xA7 TACH7 MSB/+5V Voltage R 7 6 5 4 3 2 1 0 0xFF No No 0xA8 TACH8 Value, LSB R 7 6 5 4 3 2 1 0 0xFF No No 0xA9 TACH8 MSB/+12V 3 Voltage R 7 6 5 4 3 2 1 0 0xFF No No 0xAA PWM1 Duty Cycle R/W 7 6 5 4 3 2 1 0 0x00 No No 0xAB PWM2 Duty Cycle R/W 7 6 5 4 3 2 1 0 0x00 No No 0xAC PWM3 Duty Cycle R/W 7 6 5 4 3 2 1 0 0xC0 No No 0xAD PWM4 Duty Cycle R/W 7 6 5 4 3 2 1 0 0x00 No No 0xAE THERM1 %On−Time R 7 6 5 4 3 2 1 0 0x00 No No 0xAF THERM2 %On−Time R 7 6 5 4 3 2 1 0 0x00 No No 0xB8 Thermal Status 1, Host R R3D R2D R1D R3 R2 R1 Local Res 0x00 Yes No 0xB9 Thermal Status 2, Host R VR2 VR1 T2S T2A T2% T1S T1A T1% 0x00 Yes No 0xBA Thermal Status 3, Host R R3T2 R2T2 R1T2 LT2 R3T1 R2T1 R1T1 LT1 0x00 Yes No 0xBB Voltage Status 1, Host R Pin 23 +5V Pin 19 Pin 15 +3.3V +12V3 +12V2 +12V1 0x00 Yes No 0xBC Voltage Status 2, Host R +1.5V1 (ICH) +1.5V2 (3GIO) Pin 26 Pin 25 Pin 24 Res Res Res 0x00 Yes No 0xBD Fan Status, Host R Fan 8 Fan 7 Fan 6 Fan 5 Fan 4 Fan 3 Fan 2 Fan 1 0x00 Yes No 0xBE Digital Status, Host R CI VID SCSI2 SCSI1 FAN2MAX Res Res Res 0x00 Yes No 0xBF GPIO Status, Host R/W GPIO8 GPIO7 GPIO6 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 0x00 Yes No 0xC0 Thermal Status 1, BMC R R3D R2D R1D R3 R2 R1 Local Res 0x00 Yes No 0xC1 Thermal Status 2, BMC R VR2 VR1 T2S T2A T2% T1S T1A T1% 0x00 Yes No 0xC3 Voltage Status 1, BMC R Pin 23 +5V Pin 19 Pin 15 +3.3V +12V3 +12V2 +12V1 0x00 Yes No 0xC4 Voltage Status 2, BMC R +1.5V1 (ICH) +1.5V2 (3GIO) Pin 26 Pin 25 Pin 24 Res Res Res 0x00 Yes No 0xC5 Fan Status, BMC R Fan 8 Fan 7 Fan 6 Fan 5 Fan 4 Fan 3 Fan 2 Fan 1 0x00 Yes No 0xC6 Digital Status, BMC R CI VID SCSI2 SCSI1 FAN2MAX Res Res Res 0x00 Yes No http://onsemi.com 59 ADT7462 Table 31. Register 0x00 — Configuration Register 0 (Note 1) Bit Name R/W [5:0] #Bytes Block Read R/W These bits set the number of registers to be read in a block read. Default = 0x20. 6 VID Decoder R/W 0 = VR10 Decoding Spec; 1 = VR11 Decoding Spec. Default = 0. 7 SW Reset R/W Setting this bit to 1 restores all unlocked registers to their default values. Self−clearing. Write 0x6D to register 0x7B before setting this bit to get a software reset. Default = 0. Description 1. POR = 0x20, Lock = Y, SW Reset = Y. Table 32. Register 0x01 — Configuration Register 1 (Note 1) Bit Name R/W 0 Monitor R/W Setting this bit to 1 enables temperature and voltage measurements. When this bit is set to 0, temperature and voltage measurements are disabled. Default = 1. 1 Reserved R/W Reserved. Default = 0. 2 Reserved R/W Reserved. Default = 0. 3 ALERT Mode R/W This bit sets the ALERT mode in the ADT7462. 1 = comparator mode, 0 = SMBALERT mode (default). 4 Disable Fast Spin−Up R/W Setting this bit to 1 disables the fast spin−up (for two TACH pulses) for the fans. Instead, the fans spin up for the programmed fan startup timeout. Default = 0. 5 Setup Complete R/W Setting this bit to 1 tells the ADT7462 that setup is complete and that monitoring of all selected channels should begin. Default = 0. 6 Lock Write Once Logic 1 locks all limit values at their current settings. When this bit is set, all lockable registers become read−only and cannot be modified until the ADT7462 is powered down and powered up again. This prevents rogue programs, such as viruses, from modifying critical system limit settings. Lockable. 7 RDY R Description This bit is set to 1 to indicate that the ADT7462 is fully powered up and ready to start monitoring. 1. POR = 0x81, Lock = Y, SW Reset = Y. Table 33. Register 0x02 — Configuration Register 2 (Note 1) Bit Name R/W Description 0 FAST R/W In low frequency, PWM fan speed measurements are made once a second. Setting this bit to 1 increases the frequency of the fan speed measurements to 4 times a second. Default = 0. 1 Reserved R/W Reserved. Default = 0. 2 PWM Mode R/W This bit sets the PWM frequency mode. 0 = low frequency PWM; frequency programmable between 11 Hz and 88.2 Hz. Default = 35.3 Hz. 1 = high frequency mode, 22.5 kHz. 3 VRD1 Boost R/W Setting this bit to 0 causes the fans to go to full speed on assertion of VRD1. Default = 0. When this bit is set to 1, VRD1 assertions have no effect on the fan speed. 4 VRD2 Boost R/W Setting this bit to 0 causes the fans to go to full speed on assertion of VRD2. Default = 0. When this bit is set to 1, VRD2 assertions have no effect on the fan speed. 5 Fans Full Speed R/W Setting this bit to 1 drives the fans to full speed. Default = 0. [7:6] #TACH Pulses R/W In low frequency mode, the ADT7462 must pulse stretch to get an accurate fan speed measurement. The speed is always measured between the 2nd rising edge and one × TACH pulses later. This bit determines the last TACH pulse. Therefore, if the fan speed is to be measured between the second and fourth TACH pulse, 01 is written to these bits. x = 1 = 00 x = 2 = 01 x = 3 = 10 (default) x = 4 = 11 1. POR = 0x80, Lock = Y, SW Reset = Y. http://onsemi.com 60 ADT7462 Table 34. Register 0x03 — Configuration Register 3 (Note 1) Bit Name R/W 0 GPIO_En R/W Setting this bit to 1 enables the GPIOs. Default = 0. 1 SCL_Timeout R/W 1 = SCL timeout enabled. 0 = SCL timeout disabled = default. 2 SDA_Timeout R/W 1 = SDA timeout enabled. 0 = SDA timeout disabled = default. 3 VID_Threshold R/W This bit sets the digital threshold for the VID digital inputs. 0 =default. 1 = low thresholds selected = 0.65 V. 4 THERM_ Threshold R/W This bit sets the digital threshold for the THERM digital inputs. 0 =default. 1 = low thresholds selected = 2/3 VCCP1 (Pin 23). 5 CI Reset R/W Setting this bit to 1 resets the chassis intrusion circuit. This bit clears itself. Default = 0. 6 XOR Tree R/W Setting this bit to 1 enables the XOR tree test. Default = 0. 7 V_Core_Low R/W Setting this bit to 1 enables V_core_low. Default = 0. Description 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 35. Register 0x07 — TACH Enable Register (Note 1) Bit Name R/W 0 TACH1 R/W Setting this bit to 1 enables the TACH1 measurement. Default = 0. Description 1 TACH2 R/W Setting this bit to 1 enables the TACH2 measurement. Default = 0. 2 TACH3 R/W Setting this bit to 1 enables the TACH3 measurement. Default = 0. 3 TACH4 R/W Setting this bit to 1 enables the TACH4 measurement. Default = 0. 4 TACH5 R/W Setting this bit to 1 enables the TACH5 measurement. Default = 0. 5 TACH6 R/W Setting this bit to 1 enables the TACH6 measurement. Default = 0. 6 TACH7 R/W Setting this bit to 1 enables the TACH7 measurement. Default = 0. 7 TACH8 R/W Setting this bit to 1 enables the TACH8 measurement. Default = 0. 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 36. Register 0x08 — TACH Configuration Register (Note 1) Bit Name R/W Description 0 DC 1/5 R/W Setting this bit to 1 enables continuous measurements on TACH1 and TACH5 in low frequency PWM mode. Continuous measurement means that pulse stretching is turned off and the PWM output and TACH inputs are no longer synchronized. Default = 1. 1 DC 2/6 R/W Setting this bit to 1 enables continuous measurements on TACH2 and TACH6 in low frequency PWM mode. Continuous measurement means that pulse stretching is turned off and the PWM output and TACH inputs are no longer synchronized. Default = 1. 2 DC 3/7 R/W Setting this bit to 1 enables continuous measurements on TACH3 and TACH7 in low frequency PWM mode. Continuous measurement means that pulse stretching is turned off and the PWM output and TACH inputs are no longer synchronized. Default = 1. 3 DC 4/8 R/W Setting this bit to 1 enables continuous measurements on TACH4 and TACH8 in low frequency PWM mode. Continuous measurement means that pulse stretching is turned off and the PWM output and TACH inputs are no longer synchronized. Default = 1. [7:4] Reserved R Reserved for future use. 1. POR = 0x0F, Lock = Y, SW Reset = Y. http://onsemi.com 61 ADT7462 Table 37. Register 0x09 — GPIO Configuration Register 1 (Note 1) Bit Name R/W 0 GPIO1_P R/W This bit sets the polarity of GPIO1. 0 = default = active low. 1= active high. 1 GPIO1_D R/W This bit sets the direction of GPIO1. 0 = default = input. 1= output. 2 GPIO2_P R/W This bit sets the polarity of GPIO2. 0 = default = active low. 1= active high. 3 GPIO2_D R/W This bit sets the direction of GPIO2. 0 = default = input. 1= output. 4 GPIO3_P R/W This bit sets the polarity of GPIO3. 0 = default = active low. 1= active high. 5 GPIO3_D R/W This bit sets the direction of GPIO3. 0 = default = input. 1= output. 6 GPIO4_P R/W This bit sets the polarity of GPIO4. 0 = default = active low. 1= active high. 7 GPIO4_D R/W This bit sets the direction of GPIO4. 0 = default = input. 1= output. Description 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 38. Register 0x0A — GPIO Configuration Register 2 (Note 1) Bit Name R/W Description 0 GPIO5_P R/W This bit sets the polarity of GPIO5. 0 = default = active low. 1= active high. 1 GPIO5_D R/W This bit sets the direction of GPIO5. 0 = default = input. 1= output. 2 GPIO6_P R/W This bit sets the polarity of GPIO6. 0 = default = active low. 1= active high. 3 GPIO6_D R/W This bit sets the direction of GPIO6. 0 = default = input. 1= output. 4 GPIO7_P R/W This bit sets the polarity of GPIO7. 0 = default = active low. 1= active high. 5 GPIO7_D R/W This bit sets the direction of GPIO7. 0 = default = input. 1= output. 6 GPIO8_P R/W This bit sets the polarity of GPIO8. 0 = default = active low. 1= active high. 7 GPIO8_D R/W This bit sets the direction of GPIO8. 0 = default = input. 1= output. 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 39. Register 0x0B — Dynamic TMIN Control Register 1 (Note 1) Bit Name R/W 0 Remote 1 En R/W Setting this bit to 1 enables dynamic TMIN control for the Remote 1 channel. Default = 0. 1 Remote 2 En R/W Setting this bit to 1 enables dynamic TMIN control for the Remote 2 channel. Default = 0. 2 P1R1 R/W P1R1 = 1 copies the Remote 1 current temperature to the Remote 1 operating point register if THERM1 is asserted externally. This happens only if the current temperature is less than the value in the operating point register. The operating point contains the temperature at which THERM1 is asserted. P1R1 = 0 (default) ignores any THERM1 assertions on the THERM1 pin. The Remote 1 operating point register reflects its programmed value. 3 P1R2 R/W P1R2 = 1 copies the Remote 2 current temperature to the Remote 2 operating point register if THERM1 is asserted externally. This happens only if the current temperature is less than the value in the operating point register. The operating point contains the temperature at which THERM1 is asserted. P1R2 = 0 (default) ignores any THERM1 assertions on the THERM1 pin. The Remote 2 operating point register reflects its programmed value. 4 P2R1 R/W P2R1 = 1 copies the Remote 1 current temperature to the Remote 1 operating point register if THERM2 is asserted externally. This happens only if the current temperature is less than the value in the operating point register. The operating point contains the temperature at which THERM2 is asserted. P2R1 = 0 (default) ignores any THERM2 assertions on the THERM2 pin. The Remote 1 operating point register reflects its programmed value. 5 P2R2 R/W P2R2 = 1 copies the Remote 2 current temperature to the Remote 2 operating point register if THERM2 is asserted externally. This happens only if the current temperature is less than the value in the operating point register. The operating point contains the temperature at which THERM2 is asserted. P2R2 = 0 (default) ignores any THERM2 assertions on the THERM2 pin. The Remote 2 operating point register reflects its programmed value. [7:6] Reserved R/W Reserved for future use. Description 1. POR = 0x00, Lock = Y, SW Reset = Y. http://onsemi.com 62 ADT7462 Table 40. Register 0x0C — Dynamic TMIN Control Register 2 (Note 1) Bit Name R/W Description [2:0] CYR1 R/W Three−bit Remote 1 cycle value. These three bits define the delay time between making subsequent TMIN adjustments in the control loop for the Remote 1 temperature channel, in terms of number of monitoring cycles. The system has associated thermal time constants that must be found to optimize the response of fans and the control loop. [5:3] CYR2 R/W 6 Control Loop Select R/W 7 Reserved R Bits Decrease cycle Increase cycle 000 001 010 011 100 101 110 111 8 cycles (1 sec) 16 cycles (2 sec) 32 cycles (4 sec) 64 cycles (8 sec) 128 cycles (16 sec) 256 cycles (32 sec) 512 cycles (64 sec) 1024 cycles (128 sec) 16 cycles (2 sec) 32 cycles (4 sec) 64 cycles (8 sec) 128 cycles (16 sec) 256 cycles (32 sec) 512 cycles (64 sec) 1024 cycles (128 sec) 2048 cycles (256 sec) Three−bit Remote 2 cycle value. These three bits define the delay time between making subsequent TMIN adjustments in the control loop for the Remote 2 temperature channel, in terms of number of monitoring cycles. The system has associated thermal time constants that must be found to optimize the response of fans and the control loop. Bits Decrease cycle Increase Cycle 000 001 010 011 100 101 110 111 8 cycles (1 sec) 16 cycles (2 sec) 32 cycles (4 sec) 64 cycles (8 sec) 128 cycles (16 sec) 256 cycles (32 sec) 512 cycles (64 sec) 1024 cycles (128 sec) 16 cycles (2 sec) 32 cycles (4 sec) 64 cycles (8 sec) 128 cycles (16 sec) 256 cycles (32 sec) 512 cycles (64 sec) 1024 cycles (128 sec) 2048 cycles (256 sec) This bit allows the user to select between two control loops. 0 makes the control loop backwards compatible with the ADT7463 and ADT7468. 1 = ADT7462 control loop (default). Reserved for future use. 1. POR = 0x40, Lock = Y, SW Reset = Y. Table 41. Register 0x0D — THERM Configuration Register (Note 1) Bit Name R/W Description 0 Boost 1 R/W Setting this bit to 0 causes the fans to go to maximum PWM on assertion of THERM1 as an output. Setting this bit to 1 means that the fan speed is not affected when the THERM1 temperature limit is exceeded. Default = 0. 1 Boost 2 R/W Setting this bit to 0 causes the fans to go to maximum PWM on assertion of THERM2 as an output. Setting this bit to 1 means that the fan speed is not affected when the THERM2 temperature limit is exceeded. Default = 0. [4:2] THERM1 Timer Window R/W These bits set the timer window for measuring THERM1 assertions. 000 = 0.25 sec 001 = 0.5 sec 010 = 1 sec 011 = 2 sec 100 = 4 sec 101 = 8 sec 110 = 8 sec 111 = 8 sec [7:5] THERM2 Timer Window R/W These bits set the timer window for measuring THERM2 assertions. 000 = 0.25 sec 001 = 0.5 sec 010 = 1 sec 011 = 2 sec 100 = 4 sec 101 = 8 sec 110 = 8 sec 111 = 8 sec 1. POR = 0x00, Lock = Y, SW Reset = Y. http://onsemi.com 63 ADT7462 Table 42. Register 0x0E — THERM1 Configuration Register (Note 1) Bit Name R/W 0 THERM1 Timer Enable R/W Enables the THERM1 timer circuit. Default = 0. 1 THERM1_Local R/W Setting the bit to 1 means that the THERM1 pin is asserted low as an output whenever the local temperature exceeds the local THERM1 temperature limit. Default = 0. 2 THERM1_ Remote 1 R/W Setting the bit to 1 means that the THERM1 pin is asserted low as an output whenever the Remote 1 temperature exceeds the Remote 1 THERM1 temperature limit. Default = 0. 3 THERM1_ Remote 2 R/W Setting the bit to 1 means that the THERM1 pin is asserted low as an output whenever the Remote 2 temperature exceeds the Remote 2 THERM1 temperature limit. Default = 0. 4 THERM1_ Remote 3 R/W Setting the bit to 1 means that the THERM1 pin is asserted low as an output whenever the Remote 3 temperature exceeds the Remote 3 THERM1 temperature limit. Default = 0. [7:5] Reserved R Description Reserved for future use. 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 43. Register 0x0F — THERM2 Configuration Register (Note 1) Bit Name R/W Description 0 THERM2 Timer Enable R/W Enables the THERM2 timer circuit. Default = 0. 1 THERM2_Local R/W Setting the bit to 1 means that the THERM2 pin is asserted low as an output whenever the local temperature exceeds the local THERM2 temperature limit. Default = 0. 2 THERM2_ Remote 1 R/W Setting the bit to 1 means that the THERM2 pin is asserted low as an output whenever the Remote 1 temperature exceeds the Remote 1 THERM2 temperature limit. Default = 0. 3 THERM2_ Remote 2 R/W Setting the bit to 1 means that the THERM2 pin is asserted low as an output whenever the Remote 2 temperature exceeds the Remote 2 THERM2 temperature limit. Default = 0. 4 THERM2_ Remote 3 R/W Setting the bit to 1 means that the THERM2 pin is asserted low as an output whenever the Remote 3 temperature exceeds the Remote 3 THERM2 temperature limit. Default = 0. [7:5] Reserved R Reserved for future use. 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 44. Register 0x10 — Pin Configuration Register 1 (Note 1) Bit Name R/W 0 Pin 7 R/W 0 = +12V1; 1 = TACH5 input. Default =1. 1 Pin 4 R/W 0 = GPIO4; 1= TACH4 input (that is, if the VIDs are not selected). Default = 1. 2 Pin 3 R/W 0 = GPIO3; 1= TACH3 input (that is, if the VIDs are not selected). Default = 1. 3 Pin 2 R/W 0 = GPIO2; 1= TACH2 input (that is, if the VIDs are not selected). Default = 1. 4 Pin 1 R/W 0 = GPIO1; 1= TACH1 input (that is, if the VIDs are not selected). Default = 1. 5 Diode 3 R/W 1 enables the D3+ and D3− inputs on Pin 19 and Pin 20. 0 enables the voltage measurement input and SCSI_TERM2 input. Default = 1. 6 Diode 1 R/W 1 enables the D1+ and D1− inputs on Pin 15 and Pin 16. 0 enables the voltage measurement input and SCSI_TERM1 input. Default = 1. 7 VIDs R/W Setting this bit to 1 enables the VIDs on Pin 1 to Pin 4, Pin 28, Pin 31, and Pin 32. Default = 0. Description 1. POR = 0x7F, Lock = Y, SW Reset = Y. http://onsemi.com 64 ADT7462 Table 45. Register 0x11 — Pin Configuration Register 2 (Note 1) Bit Name R/W [1:0] Pin 23 R/W 00 = VCCP1 selected. 01 = +2.5V. 10 = +1.8V (default). 11 = +1.5V. 2 Pin 22 R/W 0 = +12V3; 1 = TACH8. Default = 1. 3 Pin 21 R/W 0 = +5V; 1 = TACH7. Default = 1. 4 Pin 19 R/W 0 = +1.25V; 1 = +0.9V (that is, if RT3 is not selected). Default = 0. 5 Pin 15 R/W 0 = +2.5V, 1 = +1.8V (that is, if RT1 is not selected). Default = 0. 6 Pin 13 R/W 0 = +3.3V; 1 = PWM4. Default = 1. 7 Pin 8 R/W 0 = +12V2; 1 = TACH6. Default = 1. Description 1. POR = 0xCE, Lock = Y, SW Reset = Y. Table 46. Register 0x12 — Pin Configuration Register 3 (Note 1) Bit Name 0 Reserved R 1 Pin 27 R/W 0 = FAN2MAX; 1 = chassis intrusion (default). [3:2] Pin 26 R/W 00 = VBATT selected (default). 01 = +1.2V2 (FSB_VTT). 10 = VR_HOT2. 11 = VR_HOT2. [5:4] Pin 25 R/W 00 = +3.3V selected (default). 01 = +1.2V1 (GBIT). 10 = VR_HOT1. 11 = VR_HOT1. [7:6] Pin 24 R/W 00 = VCCP2 selected. 01 = +2.5V (default). 10 = +1.8V. 11 = +1.5V. R/W Description Reserved for future use. 1. POR = 0x42, Lock = Y, SW Reset = Y. Table 47. Register 0x13 — Pin Configuration Register 4 (Note 1) Bit Name [1:0] Reserved R 2 Pin 32 R/W 0 = GPIO6; 1 = PWM2 (Pin 32 is VID5 if VIDs are selected). Default = 1. R/W Description Reserved. 3 Pin 31 R/W 0 = GPIO5; 1 = PWM1 (Pin 31 is VID4 if VIDs are selected). Default = 1. [5:4] Pin 29 (Pin 28, +1.5V Monitoring) (Note 2) R/W 00 = GPIO8. 01 = +1.5V (measured on Pin 28). 10 = THERM2. 11 = THERM2 (default).(Pin 28 is VID6 if VIDs are selected.) [7:6] Pin 28 (Pin 29, +1.5V Monitoring) (Note 3) R/W 00 = GPIO7. 01 = +1.5V (measured on Pin 29). 10 = THERM1. 11 = THERM1 (default). 1. POR = 0xFC, Lock = Y, SW Reset = Y. 2. +1.5V can be monitored on Pin 28 and 29 only when both are configured as +1.5V inputs. This means that +1.5V is measured on both pins or on neither. +1.5V monitoring cannot be combined with another function on the other pin. For example, if Pin 29 is configured as +1.5V, then THERM1 cannot be selected on Pin 28, because they share the same selection bits. http://onsemi.com 65 ADT7462 Table 48. Register 0x14 — Easy Configuration Options (Note 1) Bit Name R/W 0 Easy Option 1 Select R/W Setting this bit to 1 enables Easy Option 1. 1 Easy Option 2 Select R/W Setting this bit to 1 enables Easy Option 2. 2 Easy Option 3 Select R/W Setting this bit to 1 enables Easy Option 3. 3 Easy Option 4 Select R/W Setting this bit to 1 enables Easy Option 4. 4 Easy Option 5 Select R/W Setting this bit to 1 enables Easy Option 5. [7:5] Reserved R Description Reserved for future use. 1. POR = 0x01, Lock = Y, SW Reset = Y. Table 49. Register 0x16 — EDO/Single Channel Enable (Note 1) Bit Name R/W Description 0 EDO_En1 R/W Enable EDO on GPIO5. Default = 0. 1 EDO_En2 R/W Enable EDO on GPIO6. Default = 0. 2 Single−Channel Mode Select R/W Setting this bit to 1 places the ADT7462 in single−channel mode. This means that it converts on one channel only. The channel it converts on is set using the channel select bits in this register. Default = 0. [7:3] Channel Select R/W These bits are used to set the single channel that the ADT7462 measures in single−channel mode. 0000 0 = Pin 26 (default) 0000 1 = Remote 1 temperature 0001 0 = Remote 2 temperature 0001 1 = Remote 3 temperature 0010 0 = Local temperature 0010 1 = +12V1 0011 0 = +12V2 0011 1 = +12V3 0100 0 = +3.3V 0100 1 = Pin 15 voltage 0101 0 = Pin 19 voltage 0101 1 = +5V 0110 0 = Pin 23 voltage 0110 1 = Pin 24 voltage 0111 0 = Pin 25 voltage 1000 0 = +1.5V1 (ICH) voltage 1000 1 = +1.5V2 (3GIO) voltage 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 50. Register 0x18 — Voltage Attenuator Configuration 1 (Note 1) Bit Name R/W 0 Reserved R 1 Attenuator Pin 7 R/W Setting this bit to 0 removes the attenuators for Pin 7. Default = 1 = attenuators enabled. 2 Attenuator Pin 8 R/W Setting this bit to 0 removes the attenuators for Pin 8. Default = 1 = attenuators enabled. 3 Attenuator Pin 13 R/W Setting this bit to 0 removes the attenuators for Pin13. Default = 1 = attenuators enabled. 4 Attenuator Pin 15 R/W Setting this bit to 0 removes the attenuators for Pin 15. Default = 1 = attenuators enabled. 5 Attenuator Pin 19 R/W Setting this bit to 0 removes the attenuators for Pin 19. Default = 1 = attenuators enabled. 6 Attenuator Pin 21 R/W Setting this bit to 0 removes the attenuators for Pin 21. Default = 1 = attenuators enabled. 7 Attenuator Pin 22 R/W Setting this bit to 0 removes the attenuators for Pin 22. Default = 1 = attenuators enabled. Description Reserved for future use. 1. POR = 0xFF, Lock = Y, SW Reset = Y. http://onsemi.com 66 ADT7462 Table 51. Register 0x19 — Voltage Attenuator Configuration 2 (Note 1) Bit Name R/W 0 Attenuator Pin 23 R/W Setting this bit to 0 removes the attenuators for Pin 23. Default = 1 = attenuators enabled. 1 Attenuator Pin 24 R/W Setting this bit to 0 removes the attenuators for Pin 24. Default = 1 = attenuators enabled. 2 Attenuator Pin 25 R/W Setting this bit to 0 removes the attenuators for Pin 25. Default = 1 = attenuators enabled. 3 Reserved R/W Reserved for future use. Default = 0. 4 Attenuator Pin 28 R/W Setting this bit to 0 removes the attenuators for Pin 28. Default = 1 = attenuators enabled. 5 Attenuator Pin 29 R/W Setting this bit to 0 removes the attenuators for Pin 29. Default = 1 = attenuators enabled. [7:6] Reserved R/W Reserved for future use. Default = 00. Description 1. POR = 0x37, Lock = Y, SW Reset = Y. Table 52. Register 0x1A — Enhanced Acoustics Register 1 Bit Mnemonic R/W Description 0 En1 R/W Setting this bit to 1 enables the enhanced acoustics mode for PWM1; 0 disables it. Default = 0. 1 En2 R/W Setting this bit to 1 enables the enhanced acoustics mode for PWM2; 0 disables it. Default = 0. [4:2] Ramp Rate 1 R/W These bits set the ramp rate for the enhanced acoustics mode for PWM1. Default = 000. Time Slot Increase 000 = 1 001 = 2 010 = 3 011 = 5 100 = 8 101 = 12 110 = 24 111 = 48 [7:5] Ramp Rate 2 R/W Time for 33% to 100% 35 sec 17.6 sec 11.8 sec 7.0 sec 4.4 sec 3.0 sec 1.6 sec 0.8 sec These bits set the ramp rate for the enhanced acoustics mode for PWM2. Default = 000. Time Slot Increase 000 = 1 001 = 2 010 = 3 011 = 5 100 = 8 101 = 12 110 = 24 111 = 48 Time for 33% to 100% 35 sec 17.6 sec 11.8 sec 7.0 sec 4.4 sec 3.0 sec 1.6 sec 0.8 sec 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 53. Register 0x1B — Enhanced Acoustics Register 2 Bit Mnemonic R/W 0 En3 R/W Setting this bit to 1 enables the enhanced acoustics mode for PWM3; 0 disables it. Default = 0. Description 1 En4 R/W Setting this bit to 1 enables the enhanced acoustics mode for PWM4; 0 disables it. Default = 0. [4:2] Ramp Rate 3 R/W These bits set the ramp rate for the enhanced acoustics mode for PWM3. Default = 000. Time Slot Increase 000 = 1 001 = 2 010 = 3 011 = 5 100 = 8 101 = 12 110 = 24 111 = 48 [7:5] Ramp Rate 4 R/W Time for 33% to 100% 37.5 sec 18.8 sec 12.5 sec 7.5 sec 4.7 sec 3.1 sec 1.6 sec 0.8 sec These bits set the ramp rate for the enhanced acoustics mode for PWM4. Default = 000. Time Slot Increase 000 = 1 001 = 2 010 = 3 011 = 5 100 = 8 101 = 12 110 = 24 111 = 48 Time for 33% to 100% 35 sec 17.6 sec 11.8 sec 7.0 sec 4.4 sec 3.0 sec 1.6 sec 0.8 sec 1. POR = 0x00, Lock = Y, SW Reset = Y. http://onsemi.com 67 ADT7462 Table 54. Register 0x1C — Fan Freewheeling Test (Note 1) Bit Name R/W 0 Test Fan 1 R/W Fan freewheeling test bit for Fan 1. This bit self−clears when the test is complete. 1 Test Fan 2 R/W Fan freewheeling test bit for Fan 2. This bit self−clears when the test is complete. 2 Test Fan 3 R/W Fan freewheeling test bit for Fan 3. This bit self−clears when the test is complete. 3 Test Fan 4 R/W Fan freewheeling test bit for Fan 4. This bit self−clears when the test is complete. 4 Test Fan 5 R/W Fan freewheeling test bit for Fan 5. This bit self−clears when the test is complete. 5 Test Fan 6 R/W Fan freewheeling test bit for Fan 6. This bit self−clears when the test is complete. 6 Test Fan 7 R/W Fan freewheeling test bit for Fan 7. This bit self−clears when the test is complete. 7 Test Fan 8 R/W Fan freewheeling test bit for Fan 8. This bit self−clears when the test is complete. Description 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 55. Register 0x1D — Fans Present (Note 1) Bit Name R/W Description 0 Fan 1 Present R/W Set this bit to 1 when Fan 1 is present. 1 Fan 2 Present R/W Set this bit to 1 when Fan 2 is present. 2 Fan 3 Present R/W Set this bit to 1 when Fan 3 is present. 3 Fan 4 Present R/W Set this bit to 1 when Fan 4 is present. 4 Fan 5 Present R/W Set this bit to 1 when Fan 5 is present. 5 Fan 6 Present R/W Set this bit to 1 when Fan 6 is present. 6 Fan 7 Present R/W Set this bit to 1 when Fan 7 is present. 7 Fan 8 Present R/W Set this bit to 1 when Fan 8 is present. 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 56. Register 0x1E — Fan Freewheeling Test Enable (Note 1) Bit Name R/W 0 Test Fan 1 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 1. 1 Test Fan 2 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 2. 2 Test Fan 3 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 3. 3 Test Fan 4 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 4. 4 Test Fan 5 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 5. 5 Test Fan 6 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 6. 6 Test Fan 7 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 7. 7 Test Fan 8 R/W Setting this bit to 1 enables the fan freewheeling test for Fan 8. Description 1. POR = 0x00, Lock = Y, SW Reset = Y. Table 57. PWM Configuration Registers (Note 1) Register Address R/W Description 0x21 R/W PWM1 Configuration Register 0x11 0x22 R/W PWM2 Configuration Register 0x31 0x23 R/W PWM3 Configuration Register 0x51 0x24 R/W PWM4 Configuration Register 0x71 1. Lock = Y, SW Reset = Y. http://onsemi.com 68 Power−On Default ADT7462 Table 58. Register 0x21, Register 0x22, Register 0x23, Register 0x24 — PWM1, PWM2, PWM3 and PWM4 Configuration Registers Bit Name R/W Description [2:0] Spin−Up Timeout R/W These bits set the duration of the fan startup timeout and the timeout for the fan freewheeling test. 000 = No startup timeout 001 = 100 ms 010 = 250 ms 011 = 400 ms 100 = 667 ms 101 = 1 sec 110 = 2 sec 111 = 32 sec 3 SLOW R/W Setting this bit to 1 makes the ramp rate of the enhance acoustics mode four times longer. 4 INV R/W Setting this bit to 0, the PWM outputs are active low. Setting this bit to 1, the PWM outputs are active high (default). [7:5] BHVR R/W These bits determine which temperature channel controls the fans in the automatic fan speed control loop. 000 = Local temperature 001 = Remote 1 temperature 010 = Remote 2 temperature 011 = Remote 3 temperature 100 = Off 101 = Maximum fan speed calculated by the local and Remote 3 temperature channels 110 = Maximum fan speed calculated by all four channels 111 = Manual mode Table 59. Register 0x25 — PWM1, PWM2 Frequency (Note 1) Bit Name R/W Description 0 Min 1 R/W When the ADT7462 is in automatic fan control mode, this bit defines whether PWM1 is off (0% duty cycle) or at minimum PWM1 duty cycle when the controlling temperature is below its TMIN − hysteresis value. 0 = 0% duty cycle below TMIN − hysteresis (default); 1 = minimum PWM1 duty cycle below TMIN − hysteresis. 1 Min 2 R/W When the ADT7462 is in automatic fan control mode, this bit defines whether PWM2 is off (0% duty cycle) or at minimum PWM2 duty cycle when the controlling temperature is below its TMIN − hysteresis value. 0 = 0% duty cycle below TMIN − hysteresis (default); 1 = minimum PWM2 duty cycle below TMIN − hysteresis. [4:2] Low Freq 1 R/W These bits set the frequency of PWM1 when configured in low frequency mode. 000 = 11 Hz 001 = 14.7 Hz 010 = 22.1 Hz 011 = 29.4 Hz 100 = 35.3 Hz (default) 101 = 44.1 Hz 110 = 58.8 Hz 111 = 88.2 Hz [7:5] Low Freq 2 R/W These bits set the frequency of PWM2 when configured in low frequency mode. 000 = 11 Hz 001 = 14.7 Hz 010 = 22.1 Hz 011 = 29.4 Hz 100 = 35.3 Hz (default) 101 = 44.1 Hz 110 = 58.8 Hz 111 = 88.2 Hz 1. POR = 0x90, Lock = Y, SW Reset = Y. http://onsemi.com 69 ADT7462 Table 60. Register 0x26 — PWM3, PWM4 Frequency (Note 1) Bit Name R/W Description 0 Min 3 R/W When the ADT7462 is in automatic fan control mode, this bit defines whether PWM3 is off (0% duty cycle) or at minimum PWM3 duty cycle when the controlling temperature is below its TMIN − hysteresis value. 0 = 0% duty cycle below TMIN − hysteresis (default); 1 = minimum PWM3 duty cycle below TMIN − hysteresis. 1 Min 4 R/W When the ADT7462 is in automatic fan control mode, this bit defines whether PWM4 is off (0% duty cycle) or at minimum PWM4 duty cycle when the controlling temperature is below its TMIN − hysteresis value. 0 = 0% duty cycle below TMIN − hysteresis (default); 1 = minimum PWM4 duty cycle below TMIN − hysteresis. [4:2] Low Freq 3 R/W These bits set the frequency of PWM3 when configured in low frequency mode. 000 = 11 Hz 001 = 14.7 Hz 010 = 22.1 Hz 011 = 29.4 Hz 100 = 35.3 Hz (default) 101 = 44.1 Hz 110 = 58.8 Hz 111 = 88.2 Hz [7:5] Low Freq 4 R/W These bits set the frequency of PWM4 when configured in low frequency mode. 000 = 11 Hz 001 = 14.7 Hz 010 = 22.1 Hz 011 = 29.4 Hz 100 = 35.3 Hz (default) 101 = 44.1 Hz 110 = 58.8 Hz 111 = 88.2 Hz 1. POR = 0x90, Lock = Y, SW Reset = Y. Table 61. Minimum PWMx Duty Cycle (Note 1) Register Address R/W Description POR Default 0x28 R/W Minimum PWM1 duty cycle 0x80 0x29 R/W Minimum PWM2 duty cycle 0x80 0x2A R/W Minimum PWM3 duty cycle 0x80 0x2B R/W Minimum PWM4 duty cycle 0x80 1. Lock = Y, SW Reset = Y. Table 62. Register 0x2C — Maximum PWM Duty Cycle (Note 1) Bit Name R/W Description [7:0] Maximum PWM Duty Cycle R/W This register sets the maximum % duty cycle output in automatic fan speed control mode for all four PWM outputs. 1. POR = 0xC0, Lock = Y, SW Reset = Y. Table 63. Register 0x30 — Thermal Mask Register 1 (Note 1) Bit Name R/W Description 0 Reserved R/W Reserved for future use. 1 Local Temp R/W 1 masks ALERTs for an out−of−limit condition on the local temperature channel. 2 Remote 1 Temp R/W 1 masks ALERTs for an out−of−limit condition on the Remote 1 temperature channel. 3 Remote 2 Temp R/W 1 masks ALERTs for an out−of−limit condition on the Remote 2 temperature channel. 4 Remote 3 Temp R/W 1 masks ALERTs for an out−of−limit condition on the Remote 3 temperature channel. 5 Diode 1 Error R/W 1 masks ALERTs for an open or short condition on the Remote 1 channel. 6 Diode 2 Error R/W 1 masks ALERTs for an open or short condition on the Remote 2 channel. 7 Diode 3 Error R/W 1 masks ALERTs for an open or short condition on the Remote 3 channel. 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 70 ADT7462 Table 64. Register 0x31 — Thermal Mask Register 2 (Note 1) Bit Name R/W 0 THERM1 % R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 1 THERM1 Assert R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 2 THERM1 State R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 3 THERM2 % R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 4 THERM2 Assert R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 5 THERM2 State R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 6 VRD1_Assert R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 1. 7 VRD2_Assert R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 1. Description 1. POR = 0xC0, Lock = N, SW Reset = Y. Table 65. Register 0x32 — Voltage Mask Register 1 (Note 1) Bit Name R/W Description 0 +12V1 R/W 1 masks ALERTs for the corresponding interrupt status bit. 1 +12V2 R/W 1 masks ALERTs for the corresponding interrupt status bit. 2 +12V3 R/W 1 masks ALERTs for the corresponding interrupt status bit. 3 +3.3V R/W 1 masks ALERTs for the corresponding interrupt status bit. 4 Pin 15 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 5 Pin 19 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 6 +5V R/W 1 masks ALERTs for the corresponding interrupt status bit. 7 Pin 23 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 66. Register 0x33 — Voltage Mask Register 2 (Note 1) Bit Name R/W Description [2:0] Reserved R/W Reserved for future use. 3 Pin 24 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 4 Pin 25 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 5 Pin 26 Voltage R/W 1 masks ALERTs for the corresponding interrupt status bit. 6 +1.5V2 (3GIO) R/W 1 masks ALERTs for the corresponding interrupt status bit. 7 +1.5V1 (ICH) R/W 1 masks ALERTs for the corresponding interrupt status bit. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 67. Register 0x34 — Fan Mask Register (Note 1) Bit Name R/W 0 Fan 1 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 1 Fan 2 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 2 Fan 3 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 3 Fan 4 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 4 Fan 5 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 5 Fan 6 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 6 Fan 7 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. 7 Fan 8 Fault R/W 1 masks ALERTs for the corresponding interrupt status bit. Description 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 71 ADT7462 Table 68. Register 0x35 — Digital Mask Register (Note 1) Bit Name R/W [2:0] Reserved R 3 FAN2MAX R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 1. 4 SCSI1 R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 1. 5 SCSI2 R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 1. 6 VID Comparison R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. 7 Chassis Intrusion R/W 1 masks ALERTs for the corresponding interrupt status bit. Default = 0. Description Reserved for future use. 1. POR = 0x38, Lock = N, SW Reset = Y. Table 69. Register 0x36 — GPIO Mask Register (Note 1) Bit Name R/W 0 GPIO1 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 1 GPIO2 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 2 GPIO3 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 3 GPIO4 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 4 GPIO5 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 5 GPIO6 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 6 GPIO7 R/W A 1 masks ALERTs for the corresponding interrupt status bit. 7 GPIO8 R/W A 1 masks ALERTs for the corresponding interrupt status bit. Description 1. POR = 0x00, Lock = N, SW Reset = Y. Table 70. Register 0x37 — EDO 1 Mask Register (Note 1) Bit Name R/W 0 GPIO1 R/W A 1 masks GPIO1 from causing an EDO1 assertion. 1 GPIO2 R/W A 1 masks GPIO2 from causing an EDO1 assertion. 2 GPIO3 R/W A 1 masks GPIO3 from causing an EDO1 assertion. 3 GPIO4 R/W A 1 masks GPIO4 from causing an EDO1 assertion. 4 Reserved R/W Unused. 5 Fan R/W A 1 masks a fan−fail condition from causing an EDO1 assertion. 6 Temp R/W A 1 masks a THERM condition from causing an EDO1 assertion. 7 Volt R/W A 1 masks a voltage exceed limit condition from causing an EDO1 assertion. Description 1. POR = 0x00, Lock = N, SW Reset = Y. Table 71. Register 0x38 — EDO 2 Mask Register (Note 1) Bit Name R/W 0 GPIO1 R/W A 1 masks GPIO1 from causing an EDO2 assertion. 1 GPIO2 R/W A 1 masks GPIO2 from causing an EDO2 assertion. 2 GPIO3 R/W A 1 masks GPIO3 from causing an EDO2 assertion. 3 GPIO4 R/W A 1 masks GPIO4 from causing an EDO2 assertion. 4 Reserved R/W Unused. 5 Fan R/W A 1 masks a fan−fail condition from causing an EDO2 assertion. 6 Temp R/W A 1 masks a THERM condition from causing an EDO2 assertion. 7 Volt R/W A 1 masks a voltage exceed limit condition from causing an EDO2 assertion. Description 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 72 ADT7462 Table 72. Register 0x3D — Device ID Register (Note 1) Bit Name R/W [7:0] Device ID R Description This register contains the device ID (0x62) for the ADT7462. 1. POR = 0x62, SW Reset = N. Table 73. Register 0x3E — Company ID Register (Note 1) Bit Name R/W [7:0] Company ID R Description This register contains the company ID (0x41) for the ADT7462. 1. POR = 0x41, SW Reset = N. Table 74. Register 0x3F — Revision Register (Note 1) Bit Name R/W [7:0] Revision ID R Description This register contains the revision ID (0x04) for the ADT7462. 1. POR = 0x04, SW Reset = N. Table 75. Temperature Limit Registers (Note 1) Register Address R/W 0x44 R/W 0x45 R/W 0x46 0x47 Description Lockable POR Default Local low temperature limit. No 0x40 Remote 1 low temperature/Pin 15 voltage low limit. No 0x40 R/W Remote 2 low temperature limit. No 0x40 R/W Remote 3 low temperature/Pin 19 voltage low limit. No 0x40 0x48 R/W Local high temperature limit. No 0x95 0x49 R/W Remote 1 high temperature/Pin 15 voltage high limit. No 0x95 0x4A R/W Remote 2 high temperature limit. No 0x95 0x4B R/W Remote 3 high temperature/Pin 19 voltage high limit. No 0x95 0x4C R/W Local THERM1 temperature limit/+1.5V2 (3GIO) voltage high limit. Yes 0xA4 0x4D R/W Remote 1 THERM1 temperature limit. Yes 0xA4 0x4E R/W Remote 2 THERM1 temperature limit. Yes 0xA4 0x4F R/W Remote 3 THERM1 temperature limit. Yes 0xA4 0x50 R/W Local THERM2 temperature limit/+1.5V1 (ICH) voltage high limit. Yes 0xA4 0x51 R/W Remote 1 THERM2 temperature limit. Yes 0xA4 0x52 R/W Remote 2 THERM2 temperature limit. Yes 0xA4 0x53 R/W Remote 3 THERM2 temperature limit. Yes 0xA4 1. SW Reset = N. Table 76. Register 0x54 — Local/Remote 1 Temperature Hysteresis (Note 1) Bit Name R/W Description [3:0] Remote 1 Hysteresis R/W These four bits set the Remote 1 THERM hysteresis value, 1 LSB = 1°C. [7:4] Local Hysteresis R/W These four bits set the local THERM hysteresis value, 1 LSB = 1°C. 0000 = 0°C 0001 = 1°C 0010 = 2°C 0011 = 3°C 0100 = 4°C (default) 0101 = 5°C 0110 = 6°C 0111 = 7°C 1000 = 8°C 1001 = 9°C 1010 = 10°C 1011 = 11°C 1100 = 12°C 1101 = 13°C 1110 = 14°C 1111 = 15°C 1. POR = 0x44, Lock = Y, SW Reset = N. http://onsemi.com 73 ADT7462 Table 77. Register 0x55 — Remote 2/Remote 3 Temperature Hysteresis (Note 1) Bit Name R/W [3:0] Remote 3 Hysteresis R/W These four bits set the Remote 3 THERM hysteresis value, 1 LSB = 1°C. [7:4] Remote 2 Hysteresis R/W These four bits set the Remote 2 THERM hysteresis value, 1 LSB = 1°C. 0000 = 0°C 0001 = 1°C 0010 = 2°C 0011 = 3°C 0100 = 4°C (default) 0101 = 5°C 0110 = 6°C 0111 = 7°C 1000 = 8°C 1001 = 9°C 1010 = 10°C 1011 = 11°C 1100 = 12°C 1101 = 13°C 1110 = 14°C 1111 = 15°C Description 1. POR = 0x44, Lock = Y, SW Reset = N. Table 78. Offset Registers (Note 1) Register Address R/W 0x56 R/W Local offset, resolution = 0.5°C. Description POR Default 0x00 0x57 R/W Remote 1 offset, resolution = 0.5°C. 0x00 0x58 R/W Remote 2 offset, resolution = 0.5°C. 0x00 0x59 R/W Remote 3 offset, resolution = 0.5°C. 0x00 1. Lock = Y, SW Reset = N. Table 79. Operating Point Registers (Note 1) Register Address R/W 0x5A R/W Remote 1 operating point. Description POR Default 0xA4 0x5B R/W Remote 2 operating point. 0xA4 1. Lock = Y, SW Reset = Y. Table 80. Timing Registers (Note 1) Register Address R/W 0x5C R/W Local temperature TMIN. Description POR Default 0x9A 0x5D R/W Remote 1 temperature TMIN. 0x9A 0x5E R/W Remote 2 temperature TMIN. 0x9A 0x5F R/W Remote 3 temperature TMIN. 0x9A 1. Lock = Y, SW Reset = Y. Table 81. TRANGE/Hysteresis Registers (Note 1) Register Address R/W Description 0x60 R/W Local TRANGE/Hysteresis 0xC4 0x61 R/W Remote 1 TRANGE/Hysteresis 0xC4 0x62 R/W Remote 2 TRANGE/Hysteresis 0xC4 0x63 R/W Remote 3 TRANGE/Hysteresis 0xC4 1. Lock = Y, SW Reset = Y. http://onsemi.com 74 POR Default ADT7462 Table 82. Register 0x60, Register 61, Register 62, Register 63 — Local, Remote 1, Remote 2, and Remote 3 TRANGE/Hysteresis Bit Name R/W Description [3:0] Hysteresis R/W These four bits set the hysteresis in the automatic fan speed control loop and in the dynamic TMIN control loop, 1 LSB = 1°C. 0000 = 0°C 0001 = 1°C 0010 = 2°C 0011 = 3°C 0100 = 4°C (default) 0101 = 5°C 0110 = 6°C 0111 = 7°C 1000 = 8°C 1001 = 9°C 1010 = 10°C 1011 = 11°C 1100 = 12°C 1101 = 13°C 1110 = 14°C 1111 = 15°C [7:4] Range R/W These four bits set the TRANGE value, that is, the slope or rate of change of fan speed with respect to temperature in the automatic fan speed control loop. 0000 = 2°C 0001 = 2.5°C 0010 = 3.3°C 0011 = 4°C 0100 = 5°C 0101 = 6.7°C 0110 = 8°C 0111 = 10°C 1000 = 13.3°C 1001 = 16°C 1010 = 20°C 1011 = 26.7°C 1100 = 32°C (default) 1101 = 40°C 1110 = 53.3°C 1111 = 80°C Table 83. Register 0x64 — Operating Point Hysteresis (Note 1) Bit Name R/W [3:0] Reserved R [7:4] Operating Point Hysteresis R/W Description Reserved for future use. These four bits set the operating point hysteresis for the dynamic TMIN control loop, 1 LSB = 1°C. 0000 = 0°C 0001 = 1°C 0010 = 2°C 0011 = 3°C 0100 = 4°C (default) 0101 = 5°C 0110 = 6°C 0111 = 7°C 1000 = 8°C 1001 = 9°C 1010 = 10°C 1011 = 11°C 1100 = 12°C 1101 = 13°C 1110 = 14°C 1111 = 15°C 1. POR = 0x40, Lock = Y, SW Reset = Y. Table 84. Voltage Limit Registers (Note 1) Register Address R/W Description 0x68 R/W +3.3V high limit. 0xFF 0x69 R/W Pin 23 voltage high limit. 0xFF 0x6A R/W Pin 24 voltage high limit. 0xFF 0x6B R/W Pin 25 voltage high limit. 0xFF 0x6C R/W Pin 26 voltage high limit. 0xFF 0x6D R/W +12V1 voltage low limit. 0x00 0x6E R/W +12V2 voltage low limit. 0x00 0x6F R/W +12V3 voltage low limit. 0x00 0x70 R/W +3.3V low limit. 0x00 0x71 R/W +5V low limit. 0x00 0x72 R/W Pin 23 voltage low limit. 0x20 0x73 R/W Pin 24 voltage low limit. 0x00 0x74 R/W Pin 25 voltage low limit. 0x00 0x75 R/W Pin 26 voltage low limit. 0x80 0x76 R/W +1.5V1 (ICH) voltage low limit. 0x00 0x77 R/W +1.5V2 (3GIO) voltage low limit. 0x00 1. Lock = N, SW Reset = N. http://onsemi.com 75 POR Default ADT7462 Table 85. TACH Limit Registers (Note 1) Register Address R/W 0x78 R/W TACH1 limit/VID limit. Description POR Default 0xFF 0x79 R/W TACH2 limit. 0xFF 0x7A R/W TACH3 limit. 0xFF 0x7B R/W TACH4 limit. 0xFF 0x7C R/W TACH5 limit/+12V1 voltage high limit. 0xFF 0x7D R/W TACH6 limit/+12V2 voltage high limit. 0xFF 0x7E R/W TACH7 limit/+5V voltage high limit. 0xFF 0x7F R/W TACH8 limit/+12V3 voltage high limit. 0xFF 1. Lock = Y, SW Reset = N. Table 86. THERM Timer Limit Registers (Note 1) Register Address R/W 0x80 R/W THERM1 Timer Limit. Description POR Default 0xFF 0x81 R/W THERM2 Timer Limit. 0xFF 1. Lock = Y, SW Reset = N. Table 87. Temperature Value Registers (Note 1) Register Address R/W 0x88 R Bits [7:6] Local temperature value, LSBs. Description POR Default 0x00 0x89 R Local temperature value, MSBs. 0x00 0x8A R Bits [7:6] Remote 1 temperature value, LSBs. 0x00 0x8B R Remote 1 temperature value, MSBs/Pin 15 voltage. 0x00 0x8C R Bits [7:6] Remote 2 temperature value, LSBs. 0x00 0x8D R Remote 2 temperature value, MSBs. 0x00 0x8E R Bits [7:6] Remote 3 temperature value, LSBs. 0x00 0x8F R Remote 3 temperature value, MSBs/Pin 19 voltage. 0x00 1. Lock = N, SW Reset = N. Table 88. Voltage Value Registers (Note 1) Register Address R/W 0x90 R Pin 23 voltage value. Description POR Default 0x00 0x91 R Pin 24 voltage value. 0x00 0x92 R Pin 25 voltage value. 0x00 0x93 R Pin 26 voltage value. 0x00 0x94 R +1.5V1 (ICH) voltage value. 0x00 0x95 R +1.5V2 (3GIO) voltage value. 0x00 0x96 R +3.3V voltage value. 0x00 1. Lock = N, SW Reset = N. Table 89. VID Value Registers (Note 1) Register Address R/W 0x97 R Description This register reports the state of the seven VID inputs. 1. Lock = N, SW Reset = N. http://onsemi.com 76 POR Default 0x00 ADT7462 Table 90. TACH Value Registers (Note 1) Register Address R/W 0x98 R TACH1, LSB. Description POR Default 0xFF 0x99 R TACH1, MSB. 0xFF 0x9A R TACH2, LSB. 0xFF 0x9B R TACH2, MSB. 0xFF 0x9C R TACH3, LSB. 0xFF 0x9D R TACH3, MSB. 0xFF 0x9E R TACH4, LSB. 0xFF 0x9F R TACH4, MSB. 0xFF 0xA2 R TACH5, LSB. 0xFF 0xA3 R TACH5, MSB/+12V1 voltage value register. 0xFF 0xA4 R TACH6, LSB. 0xFF 0xA5 R TACH6, MSB/+12V2 voltage value register. 0xFF 0xA6 R TACH7, LSB. 0xFF 0xA7 R TACH7, MSB/+5V voltage value register. 0xFF 0xA8 R TACH8, LSB. 0xFF 0xA9 R TACH8, MSB/+12V3 voltage value register. 0xFF 1. Lock = N, SW Reset = N. Table 91. PWM Current Duty Cycle Registers (Note 1) Register Address R/W Description POR Default 0xAA R/W PWM1 current duty cycle. 0x00 0xAB R/W PWM2 current duty cycle. 0x00 0xAC R/W PWM3 current duty cycle. 0xC0 0xAD R/W PWM4 current duty cycle. 0x00 1. Lock = N, SW Reset = N. Table 92. THERM Timer Value Registers (Note 1) Register Address R/W 0xAE R THERM1 timer % on−time value. Description POR Default 0x00 0xAF R THERM2 timer % on−time value. 0x00 1. Lock = N, SW Reset = N. Table 93. Register 0xB8 — Host Thermal Status Register 1 (Note 1); Register 0xC0 — BMC Thermal Status Register 1 (Note 1) Bit Name R/W Description 0 Reserved R Reserved for future use. 1 Local Temp R A 1 indicates that a local temperature limit has been tripped. 2 Remote 1 Temp R A 1 indicates that a Remote 1 temperature limit has been tripped. 3 Remote 2 Temp R A 1 indicates that a Remote 2 temperature limit has been tripped. 4 Remote 3 Temp R A 1 indicates that a Remote 3 temperature limit has been tripped. 5 Diode 1 Error R A 1 indicates that a Remote 1 diode error, either an open or a short, has occurred. 6 Diode 2 Error R A 1 indicates that a Remote 2 diode error, either an open or a short, has occurred. 7 Diode 3 Error R A 1 indicates that a Remote 3 diode error, either an open or a short, has occurred. 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 77 ADT7462 Table 94. Register 0xB9 — Host Thermal Status Register 2 (Note 1); Register 0xC1 — BMC Thermal Status Register 2 (Note 1) Bit Name R/W Description 0 THERM1 % R A 1 indicates that THERM1 has been asserted for longer than the programmed THERM1 timer limit. 1 THERM1 Assert R A 1 indicates that THERM1 is asserted. 2 THERM1 State R A 1 indicates that a transition from high to low has taken place on the THERM1 pin. 3 THERM2 % R A 1 indicates that THERM2 has been asserted for longer than the programmed THERM2 timer limit. 4 THERM2 Assert R A 1 indicates that THERM2 is asserted. 5 THERM2 State R A 1 indicates that a transition from high to low has taken place on the THERM2 pin. 6 VRD1_Assert R A 1 indicates that VRD1 is asserted. 7 VRD2_Assert R A 1 indicates that VRD2 is asserted. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 95. Register 0xBA — Host Thermal Status Register 3 (Note 1) Bit Name R/W Description 0 Local THERM1 R A 1 indicates that the local THERM1 limit has been exceeded. 1 Remote 1 THERM1 R A 1 indicates that the Remote 1 THERM1 limit has been exceeded. 2 Remote 2 THERM1 R A 1 indicates that the Remote 2 THERM1 limit has been exceeded. 3 Remote 3 THERM1 R A 1 indicates that the Remote 3 THERM1 limit has been exceeded. 4 Local THERM2 R A 1 indicates that the Local THERM2 limit has been exceeded. 5 Remote 1 THERM2 R A 1 indicates that the Remote 1 THERM2 limit has been exceeded. 6 Remote 2 THERM2 R A 1 indicates that the Remote 2 THERM2 limit has been exceeded. 7 Remote 3 THERM2 R A 1 indicates that the Remote 3 THERM2 limit has been exceeded. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 96. Register 0xBB — Host Voltage Status Register 1 (Note 1); Register 0xC3 — BMC Voltage Register 1 (Note 1) Bit Name R/W Description 0 +12V1 R A 1 indicates that a +12V1 voltage limit has been tripped. 1 +12V2 R A 1 indicates that a +12V2 voltage limit has been tripped. 2 +12V3 R A 1 indicates that a +12V3 voltage limit has been tripped. 3 +3.3V R A 1 indicates that a +3.3V voltage limit has been tripped. 4 Pin 15 Voltage R A 1 indicates that a Pin 15 voltage limit has been tripped. 5 Pin 19 Voltage R A 1 indicates that a Pin 19 voltage limit has been tripped. 6 +5V R A 1 indicates that a +5V voltage limit has been tripped. 7 Pin 23 Voltage R A 1 indicates that a Pin 23 voltage limit has been tripped. 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 78 ADT7462 Table 97. Register 0xBC — Host Voltage Status Register 2 (Note 1); Register 0xC4 — BMC Voltage Status Register 2 (Note 1) Bit Name R/W Description [2:0] Reserved R Reserved for future use. 3 Pin 24 Voltage R A 1 indicates that a Pin 24 voltage limit has been tripped. 4 Pin 25 Voltage R A 1 indicates that a Pin 25 voltage limit has been tripped. 5 Pin 26 Voltage R A 1 indicates that a Pin 26 voltage limit has been tripped. 6 +1.5V2 (3GIO) R A 1 indicates that a +1.5V2 (3GIO) voltage limit has been tripped. 7 +1.5V1 (ICH) R A 1 indicates that a +1.5V1 (ICH) voltage limit has been tripped. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 98. Register 0xBD — Host Fan Status Register (Note 1); Register 0xC5 — BMC Fan Status Register (Note 1) Bit Name R/W Description 0 Fan 1 Fault R A 1 indicates a Fan 1 fault. 1 Fan 2 Fault R A 1 indicates a Fan 2 fault. 2 Fan 3 Fault R A 1 indicates a Fan 3 fault. 3 Fan 4 Fault R A 1 indicates a Fan 4 fault. 4 Fan 5 Fault R A 1 indicates a Fan 5 fault. 5 Fan 6 Fault R A 1 indicates a Fan 6 fault. 6 Fan 7 Fault R A 1 indicates a Fan 7 fault. 7 Fan 8 Fault R A 1 indicates a Fan 8 fault. 1. POR = 0x00, Lock = N, SW Reset = Y. Table 99. Register 0xBE — Host Digital Status Register (Note 1); Register 0xC6 — BMC Digital Status Register (Note 1) Name R/W [2:0] Reserved R Reserved for future use. 3 FAN2MAX R A 1 indicates that the FAN2MAX has been asserted as an input. 4 SCSI1 R A 1 indicates that the SCSI_TERM1 digital input has been asserted. 5 SCSI2 R A 1 indicates that the SCSI_TERM2 digital input has been asserted. 6 VID Comparison R A 1 indicates a VID comparison fault. 7 Chassis Intrusion R A 1 indicates that the chassis intrusion digital input has been asserted. Bit Description 1. POR = 0x00, Lock = N, SW Reset = Y. Table 100. Register 0xBF — Host GPIO Status Register (Note 1) Bit Name R/W 0 GPIO1 R/W A 1 indicates that GPIO1 is asserted. 1 GPIO2 R/W A 1 indicates that GPIO2 is asserted. 2 GPIO3 R/W A 1 indicates that GPIO3 is asserted. 3 GPIO4 R/W A 1 indicates that GPIO4 is asserted. 4 GPIO5 R/W A 1 indicates that GPIO5 is asserted. 5 GPIO6 R/W A 1 indicates that GPIO6 is asserted. 6 GPIO7 R/W A 1 indicates that GPIO7 is asserted. 7 GPIO8 R/W A 1 indicates that GPIO8 is asserted. Description 1. POR = 0x00, Lock = N, SW Reset = Y. http://onsemi.com 79 ADT7462 ORDERING INFORMATION Device Number Temperature Range Package Type Package Option Shipping† −40°C to +125°C 32−Lead LFCSP_VQ CP−32−2 1500 Tape & Reel ADT7462ACPZ−5RL7 ADT7462ACPZ−R7 ADT7462ACPZ−REEL 500 Tape & Reel 5000 Tape & Reel †For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. *The “Z’’ suffix indicates Pb−Free part. http://onsemi.com 80 ADT7462 PACKAGE DIMENSIONS LFCSP32 5x5, 0.5P CASE 932AE−01 ISSUE A D A NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSIONS: MILLIMETERS. 3. DIMENSION b APPLIES TO PLATED TERMINAL AND IS MEASURED BETWEEN 0.15 AND 0.30mm FROM THE TERMINAL TIP. 4. COPLANARITY APPLIES TO THE EXPOSED PAD AS WELL AS THE TERMINALS. B D1 PIN ONE REFERENCE E1 E DIM A A1 A3 b D D1 D2 E E1 E2 e H K L M 0.20 C 0.20 C TOP VIEW H (A3) 0.10 C A NOTE 4 0.08 C 4X A1 SIDE VIEW C SEATING PLANE M 9 K D2 4X SOLDERING FOOTPRINT* M 5.30 17 PIN 1 INDICATOR 3.14 E2 32X L 32 25 32X 0.05 C 5.30 3.14 b 0.10 C A B BOTTOM VIEW 32X 0.63 1 1 e MILLIMETERS MIN MAX 0.80 1.00 0.00 0.05 0.20 REF 0.18 0.30 5.00 BSC 4.75 BSC 2.95 3.25 5.00 BSC 4.75 BSC 2.95 3.25 0.50 BSC −−− 12 ° 0.20 −−− 0.30 0.50 −−− 0.60 PACKAGE OUTLINE NOTE 3 32X 0.50 PITCH 0.28 DIMENSIONS: MILLIMETERS *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. Pentium is a registered trademark of Intel Corporation. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner. PUBLICATION ORDERING INFORMATION LITERATURE FULFILLMENT: Literature Distribution Center for ON Semiconductor P.O. Box 5163, Denver, Colorado 80217 USA Phone: 303−675−2175 or 800−344−3860 Toll Free USA/Canada Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada Email: [email protected] N. American Technical Support: 800−282−9855 Toll Free USA/Canada Europe, Middle East and Africa Technical Support: Phone: 421 33 790 2910 Japan Customer Focus Center Phone: 81−3−5773−3850 http://onsemi.com 81 ON Semiconductor Website: www.onsemi.com Order Literature: http://www.onsemi.com/orderlit For additional information, please contact your local Sales Representative ADT7462/D