dBCool™ Remote Thermal Monitor and Fan Controller ADT7467 FEATURES GENERAL DESCRIPTION Controls and monitors up to 4 fans High and low frequency fan drive signal 1 on-chip and 2 remote temperature sensors Series resistance cancellation on the remote channel Extended temperature measurement range, up to 191°C Dynamic TMIN control mode optimizes system acoustics intelligently Automatic fan speed control mode controls system cooling based on measured temperature Enhanced acoustic mode dramatically reduces user perception of changing fan speeds Thermal protection feature via THERM output Monitors performance impact of Intel® Pentium™ 4 processor Thermal control circuit via THERM input 2-wire, 3-wire, and 4-wire fan speed measurement Limit comparison of all monitored values Meets SMBus 2.0 electrical specifications (fully SMBus 1.1 compliant) The ADT7467 dBCOOLTM controller is a thermal monitor and multiple PWM fan controller for noise-sensitive or powersensitive applications requiring active system cooling. The ADT7467 can drive a fan using either a low or high frequency drive signal, monitor the temperature of up to two remote sensor diodes plus its own internal temperature, and measure and control the speed of up to four fans, so that they operate at the lowest possible speed for minimum acoustic noise. The automatic fan speed control loop optimizes fan speed for a given temperature. A unique dynamic TMIN control mode enables the system thermals/acoustics to be intelligently managed. The effectiveness of the system's thermal solution can be monitored using the THERM input. The ADT7467 also provides critical thermal protection to the system using the bidirectional THERM pin as an output to prevent system or component overheating. FUNCTIONAL BLOCK DIAGRAM SCL SDA SMBALERT SERIAL BUS INTERFACE PWM1 PWM2 PWM3 PWM REGISTERS AND CONTROLLERS HF & LF ACOUSTIC ENHANCEMENT CONTROL TACH1 TACH2 AUTOMATIC FAN SPEED CONTROL ADDRESS POINTER REGISTER DYNAMIC TMIN CONTROL PWM CONFIGURATION REGISTERS FAN SPEED COUNTER TACH3 TACH4 INTERRUPT MASKING PERFORMANCE MONITORING THERMAL PROTECTION THERM VCC INTERRUPT STATUS REGISTERS VCC TO ADT7467 ADT7467 D1+ SRC D2– VCCP INPUT SIGNAL CONDITIONING AND ANALOG MULTIPLEXER 10-BIT ADC BAND GAP REFERENCE BAND GAP TEMP SENSOR GND LIMIT COMPARATORS VALUE AND LIMIT REGISTERS 04498-0-001 D1– D2+ Figure 1. Rev. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.326.8703 © 2004 Analog Devices, Inc. All rights reserved. ADT7467 TABLE OF CONTENTS Specifications..................................................................................... 3 Laying Out 2-Wire and 3-Wire Fans ....................................... 28 Absolute Maximum Ratings............................................................ 5 Operating from 3.3 V Standby.................................................. 32 Thermal Characteristics .............................................................. 5 XNOR Tree Test Mode .............................................................. 33 ESD Caution.................................................................................. 5 Power-On Default ...................................................................... 33 Pin Configuration and Function Descriptions............................. 6 Programming the Automatic Fan Speed Control Loop ............ 34 Typical Performance Characteristics ............................................. 7 Automatic Fan Control Overview............................................ 34 Product Description......................................................................... 9 Step 1: Hardware Configuration.............................................. 35 Comparison between ADT7460 and ADT7467 ....................... 9 Recommended Implementation 1 ........................................... 36 Recommended Implementation............................................... 10 Recommended Implementation 2 ........................................... 37 Serial Bus Interface..................................................................... 11 Step 2: Configuring the MUX................................................... 38 Write Operations ........................................................................ 12 Step 3: TMIN Settings for Thermal Calibration Channels....... 40 Read Operations ......................................................................... 13 Step 4: PWMMIN for Each PWM (Fan) Output....................... 41 SMBus Timeout .......................................................................... 13 Step 5: PWMMAX for PWM (Fan) Outputs.............................. 41 Voltage Measurement Input...................................................... 13 Step 6: TRANGE for Temperature Channels................................ 42 Analog-to-Digital Converter .................................................... 13 Step 7: TTHERM for Temperature Channels ............................... 45 Input Circuitry............................................................................ 14 Step 8: THYST for Temperature Channels .................................. 46 Voltage Measurement Registers................................................ 14 Dynamic TMIN Control Mode ................................................... 48 VCCP Limit Registers ................................................................... 14 Step 9: Operating Points for Temperature Channels ............. 50 Additional ADC Functions for Voltage Measurements ........ 14 Step 10: High and Low Limits for Temperature Channels ... 51 Temperature Measurement Method ........................................ 15 Step 11: Monitoring THERM ................................................... 53 Series Resistance Cancellation.................................................. 17 Enhancing System Acoustics .................................................... 54 Factors Affecting Diode Accuracy ........................................... 17 Step 12: Ramp Rate for Acoustic Enhancement..................... 56 Additional ADC Functions for Temperature Measurement. 19 Register Tables ................................................................................ 59 Limits, Status Registers, and Interrupts ....................................... 20 ADT7467 Programming Block Diagram .................................... 77 Limit Values................................................................................. 20 Outline Dimensions ....................................................................... 78 Status Registers ........................................................................... 21 Ordering Guide .......................................................................... 78 THERM Timer............................................................................ 23 REVISION HISTORY Revision 0: Initial Version Rev. 0 | Page 2 of 80 ADT7467 SPECIFICATIONS TA = TMIN to TMAX, VCC = VMIN to VMAX, unless otherwise noted. All voltages are measured with respect to GND, unless otherwise specified. Typicals are at TA = 25°C and represent most likely parametric norm. Logic inputs accept input high voltages up to VMAX even when device is operating down to VMIN. 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. SMBus timing specifications are guaranteed by design and are not production tested. Table 1. Parameter POWER SUPPLY Supply Voltage Supply Current, ICC Min Typ Max Unit Test Conditions/Comments 3.0 3.3 5.5 3 20 V mA µA Interface inactive, ADC active Standby mode ±1.5 +2 +2 °C °C °C °C °C °C °C °C µA µΑ µΑ TEMP-TO-DIGITAL CONVERTER Local Sensor Accuracy −3.5 −4 Resolution Remote Diode Sensor Accuracy 0.25 ±0.5 −3.5 −4.5 0.25 6 36 96 ANALOG-TO-DIGITAL CONVERTER (INCLUDING MUX AND ATTENUATORS) Total Unadjusted Error (TUE) Differential Nonlinearity (DNL) Power Supply Sensitivity ±0.1 Conversion Time (Voltage Input) 11 Conversion Time (Local Temperature) 12 Conversion Time (Remote Temperature) 38 Total Monitoring Cycle Time 145 Total Monitoring Cycle Time 19 Input Resistance 40 80 80 140 FAN RPM-TO-DIGITAL CONVERTER Accuracy ±1.5 +2 +2 Resolution Remote Sensor Source Current Full-Scale Count Nominal Input RPM Internal Clock Frequency ±1.5 ±1 100 200 ±5 ±7 ±10 65,535 109 329 5000 10000 85.5 83.7 81 90 90 90 94.5 96.3 99 Rev. 0| Page 3 of 80 0°C ≤ TA ≤ 70°C −40°C ≤ TA ≤ +100°C −40°C ≤ TA ≤ +120°C 0°C ≤ TA ≤ 70°C; 0°C ≤ TD ≤ 120°C 0°C ≤ TA ≤ 105°C; 0°C ≤ TD ≤ 120°C −40°C ≤ TA ≤ +120°C; 0°C ≤ TD ≤ +120°C First current Second current Third current % LSB %/V ms ms ms ms ms kΩ kΩ Averaging enabled Averaging enabled Averaging enabled Averaging enabled Averaging disabled For VCC channel For all other channels % % % 0°C ≤ TA ≤ 70°C, 3.3 V −40°C ≤ TA ≤ +120°C, 3.3 V −40°C ≤ TA ≤ +120°C, 5.5 V RPM RPM RPM RPM Fan count = 0xBFFF Fan count = 0x3FFF Fan count = 0x0438 Fan count = 0x021C kHz kHz kHz 0°C ≤ TA ≤ 70°C, Vcc = 3.3V −40°C ≤ TA ≤ +120°C, VCC = 3.3 V −40°C ≤ TA ≤ +120°C, VCC = 5.5 V 8 bits ADT7467 Parameter Min OPEN-DRAIN DIGITAL OUTPUTS, PWM1 to PWM3, XTO Current Sink, IOL Output Low Voltage, VOL High Level Output Current, IOH OPEN-DRAIN SERIAL DATA BUS OUTPUT (SDA) Output Low Voltage, VOL High Level Output Current, IOH SMBUS DIGITAL INPUTS (SCL, SDA) Input High Voltage, VIH Input Low Voltage, VIL Hysteresis DIGITAL INPUT LOGIC LEVELS (TACH INPUTS) Input High Voltage, VIH Typ Max Unit Test Conditions/Comments 0.1 8.0 0.4 1.0 mA V µA IOUT = −8.0 mA, VCC = +3.3 V VOUT = VCC 0.1 0.4 1.0 V µA IOUT = −4.0 mA, VCC = +3.3 V VOUT = VCC 0.4 V V mV 2.0 500 2.0 V V V V V p-p 5.5 0.8 Input Low Voltage, VIL −0.3 Hysteresis DIGITAL INPUT LOGIC LEVELS (THERM) ADTL+ Input High Voltage, VIH Input Low Voltage, VIL DIGITAL INPUT CURRENT Input High Current, IIH Input Low Current, IIL Input Capacitance, CIN SERIAL BUS TIMING5 Clock Frequency, fSCLK Glitch Immunity, tSW Bus Free Time, tBUF Start Setup Time, tSU;STA Start Hold Time, tHD;STA SCL Low Time, tLOW SCL High Time, tHIGH SCL, SDA Rise Time, tR SCL, SDA Fall Time, tF Data Setup Time, tSU;DAT Data Hold Time, tHD;DAT Detect Clock Low Timeout, tTIMEOUT tLOW 0.5 0.75 × VCCP Maximum input voltage Minimum input voltage V V 0.4 −1 µA µA pF 1 5 VIN = VCC VIN = 0 See Figure 2 10 400 50 4.7 4.7 4.0 4.7 4.0 50 1000 300 250 300 15 tR kHz ns µs µs µs µs µs ns µs ns ns ms 35 tF Can be optionally disabled tHD; STA SCL tHIGH tHD; DAT tSU; STA tSU; STO tSU; DAT SDA tBUF P S S Figure 2. Serial Bus Timing Diagram Rev. 0 | Page 4 of 80 P 04498-0-002 tHD; STA ADT7467 ABSOLUTE MAXIMUM RATINGS Table 2. Parameter Positive Supply Voltage (VCC) Voltage on Any Input or Output Pin Input Current at Any Pin Package Input Current Maximum Junction Temperature (TJMAX) Storage Temperature Range Lead Temperature, Soldering IR Reflow Peak Temperature Lead Temperature (Soldering 10 s) ESD Rating Rating 5.5 V −0.3 V to +6.5 V ±5 mA ±20 mA 150°C −65°C to +150°C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. THERMAL CHARACTERISTICS 220°C 300°C 1000 V 16-lead QSOP package: θJA = 150°C/W θJC = 39°C/W ESD CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although this product features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. Rev. 0| Page 5 of 80 ADT7467 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS SCL 1 16 SDA GND 2 15 PWM1/XTO VCC 3 14 VCCP ADT7467 TACH1 6 11 D2+ TACH2 7 10 D2– PWM3 8 9 TACH4/GPIO/THERM/SMBALERT 04498-0-003 13 D1+ TACH3 4 TOP VIEW PWM2/SMBALERT 5 (NOT TO SCALE) 12 D1– Figure 3. Pin Configuration Table 3. Pin Function Descriptions Pin No. 1 2 3 Mnemonic SCL GND VCC 4 TACH3 5 PWM2 SMBALERT 6 TACH1 7 TACH2 8 PWM3 9 TACH4 GPIO THERM SMBALERT 10 11 12 13 14 15 16 D2− D2+ D1− D1+ VCCP PWM1 XTO SDA Description Digital Input (Open Drain). SMBus serial clock input. Requires SMBus pull-up. Ground Pin for the ADT7467. Power Supply. Can be powered by 3.3 V standby, if monitoring in low power states is required. VCC is also monitored through this pin. The ADT7467 can also be powered from a 5 V supply. Setting Bit 7 of Configuration Register 1 (Reg. 0x40) rescales the VCC input attenuators to correctly measure a 5 V supply. Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 3. Can be reconfigured as an analog input (AIN3) to measure the speed of 2-wire fans (low frequency mode only). Digital Output (Open Drain). Requires 10 kΩ typical pull-up. Pulse width modulated output to control Fan 2 speed. Can be configured as a high or low frequency drive. Digital Output (Open Drain). This pin can be reconfigured as an SMBALERT interrupt output to signal out-of-limit conditions. Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 1. Can be reconfigured as an analog input (AIN1) to measure the speed of 2-wire fans (low frequency mode only). Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 2. Can be reconfigured as an analog input (AIN2) to measure the speed of 2-wire fans (low frequency mode only). Digital I/O (Open Drain). Pulse width modulated output to control the speed of Fan 3 and Fan 4. Requires 10 kΩ typical pull-up. Can be configured as a high or low frequency drive. Digital Input (Open Drain). Fan tachometer input to measure speed of Fan 4. Can be reconfigured as an analog input (AIN4) to measure the speed of 2-wire fans (low frequency mode only). General Purpose Open Drain Digital I/O. Alternatively, the pin can be reconfigured as a bidirectional THERM pin, which can be used to time and monitor assertions on the THERM input. For example, the pin can be connected to the PROCHOT output of an Intel Pentium 4 processor or to the output of a trip point temperature sensor. This pin can be used as an output to signal overtemperature conditions. Digital Output (Open Drain). This pin can be reconfigured as an SMBALERT interrupt output to signal out-of-limit conditions. Cathode Connection to Second Thermal Diode. Anode Connection to Second Thermal Diode. Cathode Connection to First Thermal Diode. Anode Connection to First Thermal Diode. Analog Input. Monitors processor core voltage (0 V − 3 V). Digital Output (Open Drain). Pulse-width modulated output to control Fan 1 speed. Requires 10 kΩ typical pull-up. Also functions as the output from the XNOR tree in XNOR test mode. Digital I/O (Open Drain). SMBus bidirectional serial data. Requires 10 kΩ typical pull-up. Rev. 0 | Page 6 of 80 ADT7467 0 20 –10 15 TEMPERATURE ERROR (°C) TEMPERATURE ERROR (°C) TYPICAL PERFORMANCE CHARACTERISTICS –20 –30 –40 100mV 10 40mV 5 0 –5 –50 –60 0 1 2.2 3.3 CAPACITANCE (nF) 4.7 10 –10 10 1M 10M FREQUENCY (kHz) 100M 1G Figure 7. Remote Temperature Error vs. Common Mode Noise Frequency 0 6 –10 5 –20 4 TEMPERATURE ERROR (°C) –30 –40 –50 –60 –70 –80 20mV 3 2 1 0 10mV –1 –2 –3 –100 0 5 10 15 CAPACITANCE (nF) 20 25 04498-0-046 –90 –4 10 Figure 5. External Temperature Error vs. D+/D− Capacitance 100 1M 10M FREQUENCY (kHz) 100M 04498-0-049 TEMPERATURE ERROR (°C) Figure 4. Temperature Error vs. Capacitance between D+ and D− 100 04498-0-048 04498-0-045 60mV 1G Figure 8. Remote Temperature Error vs. Differential Mode Noise Frequency 60 1.40 1.35 20 1.30 0 1.25 D+ TO VCC –20 1.20 –40 1.15 –60 1.10 –80 0 1 3.3 10 RESISTANCE (MΩ) 20 100 Figure 6. Temperature Error vs. PCB Resistance 1.05 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 5.2 5.4 POWER SUPPLY VOLTAGE (V) Figure 9. Normal IDD vs. Power Supply Rev. 0| Page 7 of 80 04498-0-050 IDD (mA) 40 04498-0-047 TEMPERATURE ERROR (°C) D+ TO GND ADT7467 1.0 7 0.5 6 TEMPERATURE ERROR (°C) 0 5 IDD (µA) 4 3 2 –0.5 –1.0 –1.5 –2.0 –2.5 –3.0 1 –4.0 –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 04498-0-091 04498-0-051 –3.5 0 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 5.2 5.4 POWER SUPPLY VOLTAGE (V) Figure 13. Internal Temperature Error vs. ADT7467 Temperature Figure 10. Shutdown IDD vs. Power Supply 1.0 20 0.5 15 TEMPERATURE ERROR (°C) 5 0 –5 –10 INT ERROR, 100mV –15 100 1M 10M 100M POWER SUPPLY NOISE FREQUENCY (kHz) 1G 20 EXT ERROR, 250mV 15 TEMPERATURE ERROR (°C) –1.5 –2.0 –2.5 –3.0 10 5 0 EXT ERROR, 100mV –5 –10 1G 04498-0-053 –15 100 1M 10M 100M POWER SUPPLY NOISE FREQUENCY (kHz) –4.0 –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 Figure 14. Remote Temperature Error vs. ADT7467 Temperature Figure 11. Internal Temperature Error vs. Power Supply –20 10 –1.0 –3.5 04498-0-052 –20 10 –0.5 Figure 12. Remote Temperature Error vs. Power Supply Noise Frequency Rev. 0 | Page 8 of 80 04498-0-092 TEMPERATURE ERROR (°C) 0 INT ERROR, 250mV 10 ADT7467 PRODUCT DESCRIPTION The ADT7467 is a complete thermal monitor and multiple fan controller for any system requiring thermal monitoring and cooling. The device communicates with the system via a serial system management bus. The serial bus controller has a serial data line for reading and writing addresses and data (Pin 16), and an input line for the serial clock (Pin 1). All control and programming functions for the ADT7467 are performed over the serial bus. In addition, a pin can be reconfigured as an SMBALERT output to signal out-of-limit conditions. 5. The ADT7467 has an extended temperature measurement range. The measurement range goes from–64°C to +191°C. On the ADT7460, the measurement range is from −127°C to +127°C. This means that the ADT7467 can measure higher temperatures. The ADT7467 also includes the ADT7460 temperature range; the temperature measurement range can be switched by setting Bit 0 of Configuration Register 5. 6. The ADT7467 maximum fan speed (% duty cycle) in the automatic fan speed control loop can be programmed. The maximum fan speed is 100% duty cycle on the ADT7460 and is not programmable. 7. The offset register in the ADT7467 is programmable up to ±64°C with 0.50°C resolution. The offset register of the ADT7460 is programmable up to ±32°C with 0.25°C resolution. 8. VCCP is monitored on Pin 14 of the ADT7467 and can be used to set the threshold for THERM (PROCHOT) (2/3 of VCCP). 2.5 V is monitored on Pin 14 of the ADT7460. The threshold for THERM (PROCHOT) is set at VIH = 1.7 V and VIL = 0.8 V on the ADT7460. 9. On the ADT7460, Pin 14 could be reconfigured as SMBus ALERT. This is not available on the ADT7467. SMBus ALERT can be enabled instead on Pin 9. COMPARISON BETWEEN ADT7460 AND ADT7467 The ADT7467 is an upgrade to the ADT7460. The ADT7467 and ADT7460 are almost pin and register map compatible. The ADT7467 and ADT7460 have the following differences: 1. 2. 3. On the ADT7467, the PWM drive signals can be configured as either high frequency or low frequency drives. The low frequency option is programmable between 10 Hz and 100 Hz. The high frequency option is 22.5 kHz. On the ADT7460, only the low frequency option is available. Once VCC is powered up, monitoring of temperature and fan speeds is enabled on the ADT7467 when VCCP is powered up, or if VCCP is never powered up, when the first SMBus transaction with the ADT7467 is completed. On the ADT7460, the STRT bit in Configuration Register 1 must be set to enable monitoring. The fans are switched off by default on power-up on the ADT7467. On the ADT7460, the fans run at full speed on power-up. Fail-safe cooling is provided on the ADT7467 in that, if the measured temperature exceeds the THERM limit (100°C), the fans run at full speed. Fail-safe cooling is also provided 4.6 s after VCCP is powered up. The fans go to full speed, if the ADT7467 has not been addressed via the SMBus within 4.6 s of when the VCCP is powered up. This protects the system in the event that the SMBus fails. The ADT7467 can be programmed at any time, either before or after the 4.6 s has elapsed, and it behaves as programmed. If VCCP is never powered up, failsafe cooling is effectively disabled. If VCCP is disabled, writing to the ADT7467 at any time causes the ADT7467 to operate normally. 4. 10. A GPIO can also be made available on Pin 9 on the ADT7467. This is not available on the ADT7460. Set the GPIO polarity and direction in Configuration Register 5. The GPIO status bit is Bit 5 of Status Register 2 (shared with TACH4 and THERM, because only one can be enabled at a time). 11. The ADT7460 has three possible SMBus addresses, which are selectable using the address select and address enable pins. The ADT7467 has one SMBus address available at Address 0x2E. Due to the inclusion of extra functionality, the register map has changed, including an additional configuration register: Configuration Register 5 at Address 0x7C. Series resistance cancellation (SRC) is provided on the remote temperature channels on the ADT7467, but not on the ADT7460. SRC automatically cancels linear offset introduced by a series resistance between the thermal diode and the sensor. Rev. 0| Page 9 of 80 ADT7467 Configuration Register 5 Table 4. Pin 9 Settings Bit 0: If Bit 0 is set to 1, the ADT7467 is backward compatible temperature-wise with the ADT7460. Measurements, TMIN calibration circuit, fan control, etc., work in the range −127°C to +127°C. Also, care should be taken in reprogramming the temperature limits (TMIN, operating point, THERM limits) to their desired twos complement value, because the power-on default for them is at Offset 64. The extended temperature range is −64°C to 191°C. The default is 1, which is in the −64°C to +191°C temperature range. Bit 0 00 01 10 11 Bit 1 Function TACH4 THERM SMBALERT GPIO RECOMMENDED IMPLEMENTATION Configuring the ADT7467 as in Figure 15 allows the system designer to use the following features: Bit 1 = 0 is the high frequency (22.5 kHz) fan drive signal. • Two PWM outputs for fan control of up to three fans (the front and rear chassis fans are connected in parallel). • Three TACH fan speed measurement inputs. Bit 2 sets the direction for the GPIO: 0 = input, 1 = output. • VCC measured internally through Pin 3. Bit 3 sets the GPIO polarity: 0 = active low, 1 = active high. • CPU temperature measured using Remote 1 temperature channel. • Ambient temperature measured through Remote 2 temperature channel. • Bidirectional THERM pin. This feature allows Intel Pentium 4 PROCHOT monitoring and can function as an overtemperature THERM output. It can alternatively be programmed as an SMBALERT system interrupt output. Bit 1 = 1 switches the fan drive to low frequency PWM, programmable between 10 Hz and 100 Hz, the same as the ADT7460. The default = 0 = HF PWM. How to Set the Functionality of Pin 9 Pin 9 on the ADT7467 has four possible functions: SMBALERT, THERM, GPIO, and TACH4. The user chooses the required functionality by setting Bit 0 and Bit 1 of Configuration Register 4 at Address 0x7D. CPU FAN FRONT CHASSIS FAN ADT7467 TACH2 PWM1 TACH1 REAR CHASSIS FAN PWM3 TACH3 D2+ D2– THERM PROCHOT D1+ CPU D1– SDA SCL SMBALERT GND Figure 15. ADT7467 Configuration Rev. 0 | Page 10 of 80 ICH 04498-0-004 AMBIENT TEMPERATURE ADT7467 SERIAL BUS INTERFACE In the ADT7467, write operations contain either one or two bytes, and read operations contain one byte and perform the following functions. To write data to one of the device data registers or 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, then the write operation contains a second data byte that is written to the register selected by the address pointer register. On PCs and servers, control of the ADT7467 is carried out using the serial system management bus (SMBus). The ADT7467 is connected to this bus as a slave device, under the control of a master controller, which is usually (but not necessarily) the ICH. The ADT7467 has a fixed 7-bit serial bus address of 0101110 or 0x2E. The read/write bit must be added to get the 8-bit address (01011100 or 0x5C). 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 might 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. This write operation is illustrated in Figure 16. 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: When all data bytes have been read or written, stop conditions are established. In write mode, the master pulls the data line high during the tenth 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 ninth clock pulse. This is known as No Acknowledge. The master then takes the data line low during the low period before the tenth clock pulse, and then high during the tenth clock pulse to assert a stop condition. • A read operation is then performed consisting of the serial bus address, R/W bit set to 1, followed by the data byte read from the data register. This is shown in Figure 18. 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. 1 If the ADT7467’s address pointer register value is unknown or not the desired value, it must first 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 ADT7467 as before, but only the data byte containing the register address is sent, because no data is written to the register. This is shown in Figure 17. • 9 If the address pointer register is known to be already at the desired address, data can be read from the corresponding data register without first writing to the address pointer register, as shown in Figure 18. 9 1 SCL 0 1 0 1 1 1 0 START BY MASTER FRAME 1 SERIAL BUS ADDRESS BYTE D7 R/W D6 ACK. BY ADT7467 D5 D4 D3 D2 D1 D0 ACK. BY ADT7467 FRAME 2 ADDRESS POINTER REGISTER BYTE 1 9 SCL (CONTINUED) SDA (CONTINUED) D7 D6 D5 D4 D3 D2 FRAME 3 DATA BYTE D1 D0 ACK. BY ADT7467 Figure 16. Writing a Register Address to the Address Pointer Register, then Writing Data to the Selected Register Rev. 0| Page 11 of 80 STOP BY MASTER 04498-0-005 SDA ADT7467 1 9 9 1 SCL 0 1 START BY MASTER 0 1 1 1 0 D7 R/W D6 ACK. BY ADT7467 FRAME 1 SERIAL BUS ADDRESS BYTE D4 D5 D2 D3 D1 D0 ACK. BY ADT7467 FRAME 2 ADDRESS POINTER REGISTER BYTE STOP BY MASTER 04498-0-006 SDA Figure 17. Writing to the Address Pointer Register Only 1 9 9 1 SCL 0 1 START BY MASTER 0 1 1 1 0 R/W FRAME 1 SERIAL BUS ADDRESS BYTE D7 D6 ACK. BY ADT7467 D5 D4 D2 D3 D1 FRAME 2 DATA BYTE FROM ADT7467 D0 NO ACK. BY STOP BY MASTER MASTER 04498-0-007 SDA Figure 18. Reading Data from a Previously Selected Register In addition to supporting the send byte and receive byte protocols, the ADT7467 also supports the read byte protocol. (See System Management Bus Specifications Rev. 2 for more information. This document is available from Intel.) If several read or write operations must be performed in succession, the master can send a repeat start condition instead of a stop condition to begin a new operation. 2. The master sends the 7-bit slave address followed by the write bit (low). 3. The addressed slave device asserts ACK on SDA. 4. The master sends a command code. 5. The slave asserts ACK on SDA. 6. The master asserts a stop condition on SDA and the transaction ends. For the ADT7467, 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 illustrated in Figure 19. 1 WRITE OPERATIONS The SMBus specification defines several protocols for different types of read and write operations. The ones used in the ADT7467 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 ADT7467 uses the following SMBus write protocols. Send Byte 3 4 5 6 REGISTER ADDRESS A P Figure 19. Setting a Register Address for Subsequent Read If the master is required to read data from the register immediately after setting up the address, it 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 ACK on SDA. 4. The master sends a command code. In this operation, the master device sends a single command byte to a slave device as follows: 1. 2 SLAVE S W A ADDRESS 04498-0-008 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 first data byte of a write is always written to the address pointer register. The master device asserts a start condition on SDA. Rev. 0 | Page 12 of 80 ADT7467 5. The slave asserts ACK on SDA. 6. The master sends a data byte. 7. The slave asserts ACK on SDA. 8. The master asserts a stop condition on SDA to end the transaction. master. If a device’s SMBALERT line goes low, the following procedure occurs: This operation is illustrated in Figure 20. S 2 3 SLAVE W A ADDRESS 4 5 SLAVE ADDRESS 6 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 alert response address, 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 ADT7467 has responded to the alert response address, the master must read the status registers and the SMBALERT is cleared only if the error condition has gone away. 7 8 A DATA A P 04498-0-009 1 1. Figure 20. Single Byte Write to a Register READ OPERATIONS The ADT7467 uses the following SMBus read protocols. Receive Byte This operation is useful when repeatedly reading a single register. The register address must have been set up previously. In this operation, the master device receives a single byte from a slave device, as follows: SMBUS TIMEOUT 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 ACK on SDA. 4. The master receives a data byte. 5. The master asserts NO ACK on SDA. <6> TODIS = 0, SMBus timeout enabled (default). 6. The master asserts a stop condition on SDA and the transaction ends. <6> TODIS = 1, SMBus timeout disabled. Configuration Register 1(Reg. 0x40) In the ADT7467, 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 byte operation. This operation is illustrated in Figure 21. S 2 3 SLAVE R A ADDRESS 4 5 6 DATA A P 04498-0-010 1 The ADT7467 includes an SMBus timeout feature. If there is no SMBus activity for 35 ms, the ADT7467 assumes that the bus is locked and releases the bus. This prevents the device from locking or holding the SMBus expecting data. Some SMBus controllers cannot handle the SMBus timeout feature, so it can be disabled. The ADT7467 has one external voltage measurement channel. It can also measure its own supply voltage, VCC. Pin 14 can measure VCCP. The VCC supply voltage measurement is carried out through the VCC pin (Pin 3). Setting Bit 7 of Configuration Register 1 (Reg. 0x40) allows a 5 V supply to power the ADT7467 and be measured without overranging the VCC measurement channel. The VCCP input can be used to monitor a chipset supply voltage in computer systems. ANALOG-TO-DIGITAL CONVERTER Figure 21. Single Byte Read from a Register 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 VOLTAGE MEASUREMENT INPUT All analog inputs are multiplexed into the on-chip, successive approximation, analog-to-digital converter. This has a resolution of 10 bits. The basic input range is 0 V to 2.25 V, but the input has built-in attenuators to allow measurement of VCCP without any external components. To allow for the tolerance of the supply voltage, the ADC produces an output of 3/4 full scale (decimal 768 or 300 hex) for the nominal input voltage and so has adequate headroom to deal with overvoltages. Rev. 0| Page 13 of 80 ADT7467 INPUT CIRCUITRY The internal structure for the VCCP analog input is shown in Figure 22. The input circuit consists of an input protection diode, an attenuator, plus a capacitor to form a first-order lowpass filter that gives the input immunity to high frequency noise. 52.5kΩ 35pF A number of other functions are available on the ADT7467 to offer the system designer increased flexibility. Turn-Off Averaging For each voltage measurement read from a value register, 16 readings have actually been made internally and the results averaged before being placed into the value register. For instances where faster conversions are needed, setting Bit 4 of Configuration Register 2 (Reg. 0x73) turns averaging off. This effectively gives a reading 16 times faster (0.7 ms), but the reading may be noisier. 17.5kΩ 04498-0-011 VCCP ADDITIONAL ADC FUNCTIONS FOR VOLTAGE MEASUREMENTS Figure 22. Structure of Analog Inputs VOLTAGE MEASUREMENT REGISTERS Bypass Voltage Input Attenuator Reg. 0x21 VCCP Reading = 0x00 default Setting Bit 5 of Configuration Register 2 (Reg. 0x73) removes the attenuation circuitry from the VCCP input. This allows the user to directly connect external sensors or to rescale the analog voltage measurement inputs for other applications. The input range of the ADC without the attenuators is 0 V to 2.25 V. Reg. 0x22 VCC Reading = 0x00 default VCCP LIMIT REGISTERS Associated with the VCCP and VCC measurement channels is a high and low limit register. Exceeding the programmed high or low limit causes the appropriate status bit to be set. Exceeding either limit can also generate SMBALERT interrupts. Reg. 0x46 VCCP Low Limit = 0x00 default Reg. 0x47 VCCP High Limit = 0xFF default Reg. 0x48 VCC Low Limit = 0x00 default Reg. 0x49 VCC High Limit = 0xFF default Table 5 shows the input ranges of the analog inputs and output codes of the 10-bit ADC. When the ADC is running, it samples and converts a voltage input in 0.7 ms and averages 16 conversions to reduce noise; a measurement takes nominally 11 ms. Single-Channel ADC Conversion Setting Bit 6 of Configuration Register 2 (Reg. 0x73) places the ADT7467 into single-channel ADC conversion mode. In this mode, the ADT7467 can be made to read a single voltage channel only. If the internal ADT7467 clock is used, the selected input is read every 0.7 ms. The appropriate ADC channel is selected by writing to Bits <7:5> of the TACH1 minimum high byte register (0x55). Bits <7:5> Reg. 0x55 001 010 101 110 111 Channel Selected VCCP VCC Remote 1 Temperature Local Temperature Remote 2 Temperature Configuration Register 2 (Reg. 0x73) <4> = 1, averaging off. <5> = 1, bypass input attenuators. <6> = 1, single-channel convert mode. TACH1 Minimum High Byte (Reg. 0x55) <7:5> selects ADC channel for single-channel convert mode. Rev. 0 | Page 14 of 80 ADT7467 Table 5. 10-Bit A/D Output Code vs. VIN VCC (+5 VIN) <0.0065 0.0065–0.0130 0.0130–0.0195 0.0195–0.0260 0.0260–0.0325 0.0325–0.0390 0.0390–0.0455 0.0455–0.0521 0.0521–0.0586 Input Voltage VCC (3.3 VIN) <0.0042 0.0042–0.0085 0.0085–0.0128 0.0128–0.0171 0.0171–0.0214 0.0214–0.0257 0.0257–0.0300 0.0300–0.0343 0.0343–0.0386 VCCP <0.00293 0.0293–0.0058 0.0058–0.0087 0.0087–0.0117 0.0117–0.0146 0.0146–0.0175 0.0175–0.0205 0.0205–0.0234 0.0234–0.0263 1.6675–1.6740 1.100–1.1042 0.7500–0.7529 3.330–3.3415 2.200–2.2042 1.5000–1.5029 5.0025–5.0090 3.300–3.3042 2.2500–2.2529 6.5983–6.6048 6.6048–6.6113 6.6113–6.6178 6.6178–6.6244 6.6244–6.6309 6.6309–6.6374 6.6374–6.4390 6.6439–6.6504 6.6504–6.6569 6.6569–6.6634 >6.6634 4.3527–4.3570 4.3570–4.3613 4.3613–4.3656 4.3656–4.3699 4.3699–4.3742 4.3742–4.3785 4.3785–4.3828 4.3828–4.3871 4.3871–4.3914 4.3914–4.3957 >4.3957 2.9677–2.9707 2.9707–2.9736 2.9736–2.9765 2.9765–2.9794 2.9794–2.9824 2.9824–2.9853 2.9853–2.9882 2.9882–2.9912 2.9912–2.9941 2.9941–2.9970 >2.9970 TEMPERATURE MEASUREMENT METHOD A simple method of measuring temperature is to exploit the negative temperature coefficient of a diode, measuring the baseemitter voltage (VBE) of a transistor, operated at constant current. Unfortunately, this technique requires calibration to null out the effect of the absolute value of VBE, which varies from device to device. The technique used in the ADT7467 is to measure the change in VBE when the device is operated at three different currents. Previous devices have used only two operating currents, but the use of a third current allows automatic cancellation of resistances in series with the external temperature sensor. Decimal 0 1 2 3 4 5 6 7 8 • • • 256 (1/4-scale) • • • 512 (1/2-scale) • • • 768 (3/4 scale) • • • 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023 A/D Output Binary (10 Bits) 00000000 00 00000000 01 00000000 10 00000000 11 00000001 00 00000001 01 00000001 10 00000001 11 00000010 00 01000000 00 10000000 00 11000000 00 11111101 01 11111101 10 11111101 11 11111110 00 11111110 01 11111110 10 11111110 11 11111111 00 11111111 01 11111111 10 11111111 11 Figure 24 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. Rev. 0| Page 15 of 80 ADT7467 Local Temperature Measurement The ADT7467 contains an on-chip band gap temperature sensor whose output is digitized by the on-chip 10-bit ADC. The 8-bit MSB temperature data is stored in the local temperature register (Address 26h). Because both positive and negative temperatures can be measured, the temperature data is stored in Offset 64 format or twos complement format, as shown in Table 6 and Table 7. Theoretically, the temperature sensor and ADC can measure temperatures from −128°C to +127°C (or −61°C to +191°C in the extended temperature range) with a resolution of 0.25°C. However, this exceeds the operating temperature range of the device, so local temperature measurements outside the ADT7467 operating temperature range are not possible. Remote Temperature Measurement The ADT7467 can measure the temperature of two remote diode sensors or diode-connected transistors connected to Pins 10 and 11, or 12 and 13. The forward voltage of a diode or diode-connected transistor operated at a constant current exhibits a negative temperature coefficient of about –2 mV/°C. Unfortunately, the absolute value of VBE varies from device to device and individual calibration is required to null this out, so the technique is unsuitable for mass production. The technique used in the ADT7467 is to measure the change in VBE when the device is operated at three different currents. This is given by ∆V BE = KT / q × 1n( N ) where: K is Boltzmann’s constant. q is the charge on the carrier. T is the absolute temperature in Kelvin. N is the ratio of the two currents. N2 × I N1 × I IBIAS To measure ∆VBE, the operating current through the sensor is switched among three related currents. Shown in Figure 23, 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 ∆VBE1, and then between I and N2 × I, giving ∆VBE2. The temperature can then be calculated using the two ∆VBE measurements. This method can also cancel the effect of any series resistance on the temperature measurement. The resulting ∆VBE 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 ∆VBE. 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. The results of remote temperature measurements are stored in 10-bit, twos complement format, as listed in Table 6. The extra resolution for the temperature measurements is held in the Extended Resolution Register 2 (Reg. 0x77). This gives temperature readings with a resolution of 0.25°C. Noise Filtering Figure 23 shows the input signal conditioning used to measure the output of a remote temperature sensor. This figure shows the external sensor as a substrate transistor, provided for temperature monitoring on some microprocessors. It could also be a discrete transistor such as a 2N3904/2N3906. I If a discrete transistor is used, the collector is not grounded and should be linked to the base. If a PNP transistor is used, the base is connected to the D– input and the emitter to the D+ input. If an NPN transistor is used, the emitter is connected to the D– input and the base to the D+ input. Figure 25 and Figure 26 show how to connect the ADT7467 to an NPN or PNP transistor for temperature measurement. 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. For temperature sensors operating in noisy environments, previous practice was 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. This capacitor reduces the noise, but does not eliminate it, making use of the sensor difficult in a very noisy environment. VDD REMOTE SENSING TRANSISTOR VOUT+ D+ TO ADC LPF fC = 65kHz VOUT– 04498-0-012 D– Figure 23. Signal Conditioning for Remote Diode Temperature Sensors Rev. 0 | Page 16 of 80 ADT7467 The ADT7467 has a major advantage over other devices for eliminating the effects of noise on the external sensor. Using the series resistance cancellation feature, a filter can be constructed between the external temperature sensor and the part. The effect of any filter resistance seen in series with the remote sensor is automatically canceled from the temperature result. To reduce the error due to variations in both substrate and discrete transistors, a number of factors should be taken into consideration: • The construction of a filter allows the ADT7467 and the remote temperature sensor to operate in noisy environments. Figure 24 shows a low-pass R-C-R filter, with the following values: R = 100 Ω, C = 1 nF ∆T = (nf − 1.008)/1.008 × (273.15 K + T) This filtering reduces both common-mode noise and differential noise. To factor this in, the user can write the ∆T value to the offset register. The ADT7467 then automatically adds it to or subtracts it from the temperature measurement. 100Ω 1nF 100Ω D– 04498-0-093 D+ REMOTE TEMPERATURE SENSOR The ideality factor, nf, of the transistor is a measure of the deviation of the thermal diode from ideal behavior. The ADT7467 is trimmed for an nf value of 1.008. Use the following equation to calculate the error introduced at a temperature T (°C), when using a transistor whose nf does not equal 1.008. See the processor data sheet for the nf values. • Figure 24. Filter between Remote Sensor and ADT7467 SERIES RESISTANCE CANCELLATION Parasitic resistance to the ADT7467 D+ and D− inputs (seen in series with the remote diode) is 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 0.5°C offset per 1 Ω of parasitic resistance in series with the remote diode. The ADT7467 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 ADT7467 is designed to automatically cancel, typically, up to 3 kΩ of resistance. By using an advanced temperature measurement method, this is transparent to the user. This feature allows resistances to be added to the sensor path to produce a filter, allowing the part to be used in noisy environments. See the Noise Filtering section for details. FACTORS AFFECTING DIODE ACCURACY Remote Sensing Diode The ADT7467 is designed to work with either substrate transistors built into processors or discrete transistors. Substrate transistors are generally PNP types with the collector connected to the substrate. Discrete types can be either PNP or NPN transistors connected as a diode (base-shorted to the collector). If an NPN transistor is used, the collector and base are connected to D+ and the emitter is connected to D−. If a PNP transistor is used, the collector and base are connected to D− and the emitter is connected to D+. Some CPU manufacturers specify the high and low current levels of the substrate transistors. The high current level of the ADT7467, IHIGH, is 96 µA and the low level current, ILOW, is 6 µA. If the ADT7467 current levels do not match the current levels specified by the CPU manufacturer, it might be necessary to remove an offset. The CPU’s data sheet advises whether this offset needs to be removed and how to calculate it. This offset can be programmed to the offset register. It is important to note that, if more than one offset must be considered, the algebraic sum of these offsets must be programmed to the offset register. If a discrete transistor is used with the ADT7467, the best accuracy is obtained by choosing devices according to the following criteria: • Base-emitter voltage greater than 0.25 V at 6 µA, at the highest operating temperature. • Base-emitter voltage less than 0.95 V at 100 µA, at the lowest operating temperature. • Base resistance less than 100 Ω. • Small variation in hFE (say 50 to 150) that indicates tight control of VBE characteristics. Transistors, such as 2N3904, 2N3906, or equivalents in SOT-23 packages, are suitable devices to use. Rev. 0| Page 17 of 80 ADT7467 Nulling Out Temperature Errors Table 6. Temperature Data Format 1 Temperature –128°C –125°C –100°C –75°C –50°C –25°C –10°C 0°C 10.25°C 25.5°C 50.75°C 75°C 100°C 125°C 127°C Digital Output (10-Bit) 1000 0000 00 1000 0011 00 1001 1100 00 1011 0101 00 1100 1110 00 1110 0111 00 1111 0110 00 0000 0000 00 0000 1010 01 0001 1001 10 0011 0010 11 0100 1011 00 0110 0100 00 0111 1101 00 0111 1111 00 1 Bold numbers denote 2 LSB of measurement in Extended Resolution Register 2 (Reg. 0x77) with 0.25°C resolution. As CPUs run faster, it is getting more difficult to avoid high frequency clocks when routing the D+/D– traces around a system board. Even when recommended layout guidelines are followed, some temperature errors may still be attributable to noise coupled onto the D+/D– lines. Constant high frequency noise usually attenuates or increases temperature measurements by a linear, constant value. The ADT7467 has temperature offset registers at Addresses 0x70, 0x72 for the Remote 1 and Remote 2 temperature channels. By doing a one-time calibration of the system, the user can determine the offset caused by system board noise and null it out using the offset registers. The offset registers automatically add an Offset 64/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 Offset Registers Table 7. Extended Range, Temperature Data Format Digital Output (10-Bit)1 0000 0000 00 0011 1111 00 0100 0000 00 0100 0001 00 0100 1010 00 0101 1001 00 0111 0010 00 1000 1001 00 1010 0100 00 1011 1101 00 1111 1111 00 Temperature –64°C –1°C 0°C 1°C 10°C 25°C 50°C 75°C 100°C 125°C 191°C Bold numbers denote 2 LSB of measurement in Extended Resolution Register 2 (Reg. 0x77) with 0.25°C resolution. ADT7467 Figure 25. Measuring Temperature Using an NPN Transistor ADT7460/ADT7467 Backwards Compatible Mode By setting Bit 1 of Configuration Register 5 (0x7C), all temperature measurements are stored in the Zone Temp value registers (0x25, 0x26, and 0x27) in twos complement in the range −64°C to +127°C. (The ADT7468 still makes calculations based on the Offset64 extended range and clamps the results, if necessary.) The temperature limits must be reprogrammed in twos complement. If a twos complement temperature below −63°C is entered, the temperature is clamped to −63°C. In this mode, the diode fault condition remains −128°C = 1000 0000, while in the extended temperature range (−64°C to +191°C), the fault condition is represented by −64°C = 0000 0000. Reg. 0x26 Local Temperature Reg. 0x27 Remote 2 Temperature Reg. 0x77 Extended Resolution 2 = 0x00 default ADT7467 2N3906 PNP Reg. 0x72 Remote 2 Temperature Offset = 0x00 (0°C default) Reg. 0x25 Remote 1 Temperature D+ D– Reg. 0x71 Local Temperature Offset = 0x00 (0°C default) Temperature Measurement Registers 04498-0-013 2N3904 NPN <7:6> TDM2, Remote 2 temperature LSBs. D+ D– 04498-0-014 1 Reg. 0x70 Remote 1 Temperature Offset = 0x00 (0°C default) <5:4> LTMP, local temperature LSBs. <3:2> TDM1, Remote 1 temperature LSBs. Figure 26. Measuring Temperature Using a PNP Transistor Rev. 0 | Page 18 of 80 ADT7467 Temperature Measurement Limit Registers Table 9. Conversion Time with Averaging Enabled Associated with each temperature measurement channel are high and low limit registers. Exceeding the programmed high or low limit causes the appropriate status bit to be set. Exceeding either limit can also generate SMBALERT interrupts. Channel Voltage Channels Remote Temperature Local Temperature Reg. 0x4E Remote 1 Temperature Low Limit = 0x01 default Single-Channel ADC Conversions Reg. 0x4F Remote 1 Temperature High Limit = 0x7F default Setting Bit 6 of Configuration Register 2 (Reg. 0x73) places the ADT7467 into single-channel ADC conversion mode. In this mode, the ADT7467 can be made to read a single temperature channel only. The appropriate ADC channel is selected by writing to Bits <7:5> of the TACH1 minimum high byte register (0x55). Reg. 0x50 Local Temperature Low Limit = 0x01 default Reg. 0x51 Local Temperature High Limit = 0x7F default Reg. 0x52 Remote 2 Temperature Low Limit = 0x01 default Reg. 0x53 Remote 2 Temperature High Limit = 0x7F default Reading Temperature from the ADT7467 It is important to note that temperature can be read from the ADT7467 as an 8-bit value (with 1°C resolution) or as a 10-bit value (with 0.25°C resolution). If only 1°C resolution is required, the temperature readings can be read back at any time and in no particular order. Measurement Time 11 ms 39 ms 12 ms Table 10. Channel Selection Bits <7:5> Reg. 0x55 101 110 111 Channel Selected Remote 1 temperature Local temperature Remote 2 temperature Configuration Register 2 (Reg. 0x73) <4> = 1, averaging off. If the 10-bit measurement is required, this involves a 2-register read for each measurement. The extended resolution register (Reg. 0x77) should be read first. This causes all temperature reading registers to be frozen until all temperature reading registers have been read from. This prevents an MSB reading from being updated while its two LSBs are being read and vice versa. ADDITIONAL ADC FUNCTIONS FOR TEMPERATURE MEASUREMENT A number of other functions are available on the ADT7467 to offer the system designer increased flexibility. Turn-Off Averaging For each temperature measurement read from a value register, 16 readings have actually been made internally and the results averaged before being placed into the value register. Sometimes it is necessary to take a very fast measurement. Setting Bit 4 of Configuration Register 2 (Reg. 0x73) turns averaging off. Channel Voltage Channel Remote Temperature 1 Remote Temperature 2 Local Temperature Measurement Time 0.7 ms 7 ms 7 ms 1.3 ms TACH1 Minimum High Byte (Reg. 0x55) <7:5> selects ADC channel for single-channel convert mode. Overtemperature Events Overtemperature events on any of the temperature channels can be detected and dealt with automatically in automatic fan speed control mode. Reg. 0x6A to Reg. 0x6C are the THERM temperature limits. When a temperature exceeds its THERM temperature limit, all PWM outputs run at the maximum PWM duty cycle (Reg. 0x38, Reg. 0x39, Reg. 0x3A). This effectively runs the fans at the fastest allowed speed. The fans stay running at this speed until the temperature drops below THERM minus hysteresis. (This can be disabled by setting the boost bit in Configuration Register 3, Bit 2, Reg. 0x78.) The hysteresis value for that THERM temperature limit is the value programmed into Reg. 0x6D and Reg. 0x6E (hysteresis registers). The default hysteresis value is 4°C. THERM LIMIT HYSTERESIS (°C) TEMPERATURE FANS 100% Figure 27. THERM Temperature Limit Operation Rev. 0| Page 19 of 80 04498-0-015 Table 8. Conversion Time with Averaging Disabled <6> = 1, single-channel convert mode, ADT7467 LIMITS, STATUS REGISTERS, AND INTERRUPTS LIMIT VALUES Reg. 0x57 TACH2 Minimum High Byte = 0x00 default Associated with each measurement channel on the ADT7467 are high and low limits. These can form the basis of system status monitoring; a status bit can be set for any out-of-limit condition and detected by polling the device. Alternatively, SMBALERT interrupts can be generated to flag a processor or microcontroller of out-of-limit conditions. Reg. 0x58 TACH3 Minimum Low Byte = 0x00 default Reg. 0x59 TACH3 Minimum High Byte = 0x00 default Reg. 0x5A TACH4 Minimum Low Byte = 0x00 default Reg. 0x5B TACH4 Minimum High Byte = 0x00 default 8-Bit Limits Out-of-Limit Comparisons The following is a list of 8-bit limits on the ADT7467. Once all limits have been programmed, the ADT7467 can be enabled for monitoring. The ADT7467 measures all voltage and temperature measurements in round-robin format and sets the appropriate status bit for out-of-limit conditions. TACH measurements are not part of this round-robin cycle. Comparisons are done differently depending on whether the measured value is being compared to a high or low limit. Voltage Limit Registers Reg. 0x46 VCCP Low Limit = 0x00 default Reg. 0x47 VCCP High Limit = 0xFF default Reg. 0x48 VCC Low Limit = 0x00 default Reg. 0x49 VCC High Limit = 0xFF default High Limit: > Comparison Performed Temperature Limit Registers Low Limit: ≤ Comparison Performed Reg. 0x4E Remote 1 Temperature Low Limit = 0x01 default Reg. 0x4F Remote 1 Temperature High Limit = 0x7F default Reg. 0x6A Remote 1 THERM Limit = 0x64 default Voltage and temperature channels use a window comparator for error detecting and, therefore, have high and low limits. Fan speed measurements use only a low limit. This fan limit is needed only in manual fan control mode. Analog Monitoring Cycle Time Reg. 0x50 Local Temperature Low Limit = 0x01 default Reg. 0x51 Local Temperature High Limit = 0x7F default Reg. 0x6B Local THERM Limit = 0x64 default Reg. 0x52 Remote 2 Temperature Low Limit = 0x01 default Reg. 0x53 Remote 2 Temperature High Limit = 0x7F default Reg. 0x6C Remote 2 THERM Limit = 0x64 default The analog monitoring cycle begins when a 1 is written to the start bit (Bit 0) of Configuration Register 1 (Reg. 0x40). By default, the ADT7463 powers up with this bit set. The ADC measures each analog input in turn and, as each measurement is completed, the result is automatically stored in the appropriate value register. This round-robin monitoring cycle continues unless disabled by writing a 0 to Bit 0 of Configuration Register 1. As the ADC is normally left to free-run in this manner, the time taken to monitor all the analog inputs is normally not of interest, because the most recently measured value of any input can be read out at any time. THERM Limit Register Reg. 0x7A THERM Limit = 0x00 default 16-Bit Limits The fan TACH measurements are 16-bit results. The fan TACH limits are also 16 bits, consisting of a high byte and low byte. Because fans running under speed or stalled are normally the only conditions of interest, only high limits exist for fan TACHs. Because the fan TACH period is actually being measured, exceeding the limit indicates a slow or stalled fan. For applications where the monitoring cycle time is important, it can easily be calculated. The total number of channels measured is • One dedicated supply voltage input (VCCP) • Supply voltage (VCC pin) Fan Limit Registers • Local temperature Reg. 0x54 TACH1 Minimum Low Byte = 0x00 default • Two remote temperatures Reg. 0x55 TACH1 Minimum High Byte = 0x00 default Reg. 0x56 TACH2 Minimum Low Byte = 0x00 default Rev. 0 | Page 20 of 80 ADT7467 As mentioned previously, the ADC performs round-robin conversions . The total monitoring cycle time for averaged voltage and temperature monitoring is 145 ms. The total monitoring cycle time for voltage and temperature monitoring with averaging disabled is 19 ms. The ADT7467 is a derivative of the ADT7468. As a result, the total conversion time in the ADT7467 is the same as the total conversion time of the ADT7468, even though the ADT7467 has less monitored channels. Fan TACH measurements are made in parallel and are not synchronized with the analog measurements in any way. Status Register 2 (Reg. 0x42) Bit 7 (D2) = 1, indicates an open or short on D2+/D2– inputs. Bit 6 (D1) = 1, indicates an open or short on D1+/D1– inputs. Bit 5 (F4P) = 1, indicates Fan 4 has dropped below minimum speed. Alternatively, indicates that the THERM limit has been exceeded, if the THERM function is used. Bit 4 (FAN3) = 1, indicates Fan 3 has dropped below minimum speed. Bit 3 (FAN2) = 1, indicates Fan 2 has dropped below minimum speed. STATUS REGISTERS The results of limit comparisons are stored in Status Registers 1 and 2. The status register bit for each channel reflects the status of the last measurement and limit comparison on that channel. If a measurement is within limits, the corresponding status register bit is cleared to 0. If the measurement is out-of-limits, the corresponding status register bit is set to 1. Bit 2 (FAN1) = 1, indicates Fan 1 has dropped below minimum speed. The state of the various measurement channels can be polled by reading the status registers over the serial bus. In Bit 7 (OOL) of Status Register 1 (Reg. 0x41), 1 means that an out-of-limit event has been flagged in Status Register 2. This means that the user also needs to read Status Register 2. Alternatively, Pin 5 or Pin 9 can be configured as an SMBALERT output. This hardware interrupt automatically notifies the system supervisor of an outof-limit condition. Reading the status registers clears the appropriate status bit as long as the error condition that caused the interrupt has cleared. Status register bits are “sticky.” Whenever a status bit is set, indicating an out-of-limit condition, it remains set even if the event that caused it has gone away (until read). The only way to clear the status bit is to read the status register after the event has gone away. Interrupt status mask registers (Reg. 0x74, 0x75) allow individual interrupt sources to be masked from causing an SMBALERT. However, if one of these masked interrupt sources goes out-oflimit, its associated status bit is set in the interrupt status registers. The ADT7467 can be polled for status, or an SMBALERT interrupt can be generated for out-of-limit conditions. It is important to note how the SMBALERT output and status bits behave when writing interrupt handler software. Status Register 1 (Reg. 0x41) Figure 28 shows how the SMBALERT output and “sticky” status bits behave. Once a limit is exceeded, the corresponding status bit is set to 1. The status bit remains set until the error condition subsides 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 SMBALERT output remains low for the entire duration that a reading is out-of-limit and until the status register has been read. This has implications on how software handles the interrupt. Bit 7 (OOL) = 1, denotes a bit in Status Register 2 is set and Status Register 2 should be read. Bit 6 (R2T) = 1, Remote 2 temperature high or low limit has been exceeded. Bit 5 (LT) = 1, local temperature high or low limit has been exceeded. Bit 4 (R1T) = 1, Remote 1 temperature high or low limit has been exceeded. Bit 1 (OVT) = 1, indicates a THERM overtemperature limit has been exceeded. SMBALERT Interrupt Behavior HIGH LIMIT TEMPERATURE CLEARED ON READ (TEMP BELOW LIMIT) “STICKY” STATUS BIT TEMP BACK IN LIMIT (STATUS BIT STAYS SET) 04498-0-022 SMBALERT Figure 28. SMBALERT and Status Bit Behavior Bit 2 (VCC) = 1, VCC high or low limit has been exceeded. Bit 1 (VCCP) = 1, VCCP high or low limit has been exceeded. Rev. 0| Page 21 of 80 ADT7467 Handling SMBALERT Interrupts Bit 2 (VCC) = 1, masks SMBALERT for VCC channel. To prevent the system from being tied up servicing interrupts, it is recommend to handle the SMBALERT interrupt as follows: Bit 0 (VCCP) = 1, masks SMBALERT for VCCP channel. Interrupt Mask Register 2 (Reg. 0x75) 1. Detect the SMBALERT assertion. Bit 7 (D2) = 1, masks SMBALERT for Diode 2 errors. 2. Enter the interrupt handler. Bit 6 (D1) = 1, masks SMBALERT for Diode 1 errors. 3. Read the status registers to identify the interrupt source. 4. Mask the interrupt source by setting the appropriate mask bit in the interrupt mask registers (Reg. 0x74, Reg. 0x75). 5. Take the appropriate action for a given interrupt source. 6. Exit the interrupt handler. 7. Periodically poll the status registers. If the interrupt status bit has cleared, reset the corresponding interrupt mask bit to 0. This causes the SMBALERT output and status bits to behave as shown in Figure 29. Bit 5 (FAN4) = 1, masks SMBALERT for Fan 4 failure. If the TACH4 pin is being used as the THERM input, this bit masks SMBALERT for a THERM event. Bit 4 (FAN3) = 1, masks SMBALERT for Fan 3. Bit 3 (FAN2) = 1, masks SMBALERT for Fan 2. Bit 2 (FAN1) = 1, masks SMBALERT for Fan 1. Bit 1 (OVT) = 1, masks SMBALERT for overtemperature (exceeding THERM temperature limits). HIGH LIMIT Enabling the SMBALERT Interrupt Output The SMBALERT interrupt function is disabled by default. Pin 5 or Pin 9 can be reconfigured as an SMBALERT output to signal out-of-limit conditions. TEMPERATURE CLEARED ON READ (TEMP BELOW LIMIT) “STICKY” STATUS BIT Table 11. Configuring Pin 5 as SMBALERT Output TEMP BACK IN LIMIT (STATUS BIT STAYS SET) INTERRUPT MASK BIT SET 04498-0-023 SMBALERT Register Configuration Register 3 (Reg. 0x78) INTERRUPT MASK BIT CLEARED (SMBALERT REARMED) Figure 29. How Masking the Interrupt Source Affects SMBALERT Output Masking Interrupt Sources Interrupt Mask Registers 1 and 2 are located at Addresses 0x74 and 0x75. These allow individual interrupt sources to be masked out to prevent SMBALERT interrupts. Note that masking an interrupt source prevents only the SMBALERT output from being asserted; the appropriate status bit is set normally. Bit Setting <0> ALERT = 1 Assigning THERM Functionality to a Pin Pin 9 on the ADT7467 has four possible functions: SMBus ALERT, THERM, GPIO, and TACH4. The user chooses the required functionality by setting Bit 0 and Bit 1 of Configuration Register 4 at Address 0x7D. Table 12. Configuring Pin 9 Bit 0 00 01 10 11 Bit 1 Function TACH4 THERM SMBus ALERT GPIO Once Pin 9 is configured as THERM, it must be enabled (Bit 1, Configuration Register 3 at Address 0x78). Interrupt Mask Register 1 (Reg. 0x74) THERM as an Input Bit 7 (OOL) = 1, masks SMBALERT for any alert condition flagged in Status Register 2. Bit 6 (R2T) = 1, masks SMBALERT for Remote 2 temperature. Bit 5 (LT) = 1, masks SMBALERT for local temperature. When THERM is configured as an input, the user can time assertions on the THERM pin. This can be useful for connecting to the PROCHOT output of a CPU to gauge system performance. Bit 4 (R1T) = 1, masks SMBALERT for Remote 1 temperature. Rev. 0 | Page 22 of 80 ADT7467 The user can also set up the ADT7467 so that, when the THERM pin is driven low externally, the fans run at 100%. The fans run at 100% for the duration of the time that the THERM pin is pulled low. This is done by setting the BOOST bit (Bit 2) in Configuration Register 3 (Address = 0x78) to 1. This works only if the fan is already running, for example, in manual mode when the current duty cycle is above 0x00, or in automatic mode when the temperature is above TMIN. If the temperature is below TMIN or if the duty cycle in manual mode is set to 0x00, then pulling the THERM low externally has no effect. See Figure 30 for more information. The 8-bit THERM timer register (Reg. 0x79) is designed such that Bit 0 is set to 1 on the first THERM assertion. Once the cumulative THERM assertion time has exceeded 45.52 ms, Bit 1 of the THERM timer is set and Bit 0 now becomes the LSB of the timer with a resolution of 22.76 ms (see Figure 31). When using the THERM timer, be aware of the following. After a THERM timer read (Reg. 0x79): 1. The contents of the timer are cleared on read. 2. The F4P bit (Bit 5) of Status Register 2 needs to be cleared (assuming that the THERM timer limit has been exceeded). TMIN If the THERM timer is read during a THERM assertion, then the following happens: THERM THERM ASSERTED TO LOW AS AN INPUT: FANS DO NOT GO TO 100%, BECAUSE TEMPERATURE IS ABOVE TMIN AND FANS ARE ALREADY RUNNING The contents of the timer are cleared. 2. Bit 0 of the THERM timer is set to 1 (because a THERM assertion is occurring). 3. The THERM timer increments from zero. 4. If the THERM timer limit (Reg. 0x7A) = 0x00, then the F4P bit is set. 04498-0-024 THERM ASSERTED TO LOW AS AN INPUT: FANS DO NOT GO TO 100%, BECAUSE TEMPERATURE IS BELOW TMIN 1. Figure 30. Asserting THERM Low as an Input in Automatic Fan Speed Control Mode THERM THERM TIMER (REG. 0x79) THERM TIMER 0 0 0 0 0 0 0 1 7 6 5 4 3 2 1 0 THERM ASSERTED ≤ 22.76ms THERM The timer is started on the assertion of the ADT7467’s THERM input and stopped when THERM is unasserted. The timer counts THERM times cumulatively, that is, the timer resumes counting on the next THERM assertion. The THERM timer continues to accumulate THERM assertion times until the timer is read (it is cleared on read) or until it reaches full scale. If the counter reaches full scale, it stops at that reading until cleared. Rev. 0| Page 23 of 80 ACCUMULATE THERM LOW ASSERTION TIMES THERM TIMER (REG. 0x79) 0 0 0 0 0 0 1 0 7 6 5 4 3 2 1 0 THERM ASSERTED ≥ 45.52ms THERM ACCUMULATE THERM LOW ASSERTION TIMES THERM TIMER (REG. 0x79) 0 0 0 0 0 1 0 1 7 6 5 4 3 2 1 0 THERM ASSERTED ≥ 113.8ms (91.04ms + 22.76ms) Figure 31.Understanding the THERM Timer 04498-0-025 The ADT7467 has an internal timer to measure THERM assertion time. For example, the THERM input can be connected to the PROCHOT output of a Pentium 4 CPU to measure system performance. The THERM input can also be connected to the output of a trip point temperature sensor. ADT7467 Generating SMBALERT Interrupts from THERM Timer Events value, then the F4P bit (Bit 5) of Status Register 2 is set, and an SMBALERT is generated. Note that the F4P bit (Bit 5) of Mask Register 2 (Reg. 0x75) masks out SMBALERTs, if this bit is set to 1; although the F4P bit of Interrupt Status Register 2 still is set, if the THERM timer limit is exceeded. The ADT7467 can generate SMBALERTs when a programmable THERM timer limit has been exceeded. This allows the system designer to ignore brief, infrequent THERM assertions, while capturing longer THERM timer events. Register 0x7A is the THERM timer limit register. This 8-bit register allows a limit from 0 s (first THERM assertion) to 5.825 s to be set before an SMBALERT is generated. The THERM timer value is compared with the contents of the THERM timer limit register. If the THERM timer value exceeds the THERM timer limit Figure 32 is a functional block diagram of the THERM timer, limit, and associated circuitry. Writing a value of 0x00 to the THERM timer limit register (Reg. 0x7A) causes SMBALERT to be generated on the first THERM assertion. A THERM timer limit value of 0x01 generates an SMBALERT, once cumulative THERM assertions exceed 45.52 ms. 2.914s 1.457s 728.32ms THERM 364.16ms TIMER LIMIT (REG. 0x7A) 182.08ms 91.04ms 45.52ms 22.76ms 2.914s 1.457s 728.32ms 364.16ms THERM TIMER (REG. 0x79) 182.08ms 91.04ms 45.52ms 22.76ms 0 1 2 3 4 5 6 7 7 6 5 4 3 2 1 0 THERM THERM TIMER CLEARED ON READ COMPARATOR IN OUT F4P BIT (BIT 5) STATUS REGISTER 2 SMBALERT LATCH RESET 1 = MASK F4P BIT (BIT 5) MASK REGISTER 2 (REG. 0x75) Figure 32. Functional Block Diagram of ADT7467’s THERM Monitoring Circuitry Rev. 0 | Page 24 of 80 04498-0-026 CLEARED ON READ ADT7467 Configuring the THERM Behavior 1. Alternatively, OS or BIOS level software can timestamp when the system is powered on. If an SMBALERT is generated due to the THERM timer limit being exceeded, another timestamp can be taken. The difference in time can be calculated for a fixed THERM timer limit time. For example, if it takes one week for a THERM timer limit of 2.914 s to be exceeded and the next time it takes only 1 hour, then this is an indication of a serious degradation in system performance. Configure the relevant pin as the THERM timer input. Setting Bit 1 (THERM timer enable) of Configuration Register 3 (Reg. 0x78) enables the THERM timer monitoring functionality. This is disabled on Pin 9 by default. Setting Bits 0 and 1 (PIN9FUNC) of Configuration Register 4 (Reg. 0x7D) enables THERM timer/output functionality on Pin 9 (Bit 1 of Configuration Register 3, THERM, must also be set). Pin 9 can also be used as TACH4. 2. Select the desired fan behavior for THERM timer events. Assuming that the fans are running, setting Bit 2 (BOOST bit) of Configuration Register 3 (Reg. 0x78) causes all fans to run at 100% duty cycle whenever THERM gets asserted. This allows fail-safe system cooling. If this bit is 0, the fans run at their current settings and are not affected by THERM events. If the fans are not already running when THERM is asserted, the fans do not run to full speed. 3. Select whether THERM timer events should generate SMBALERT interrupts. Bit 5 (F4P) of Mask Register 2 (Reg. 0x75), when set, masks out SMBALERTs when the THERM timer limit value gets exceeded. This bit should be cleared if SMBALERTs based on THERM events are required. 4. Select a suitable THERM limit value. This value determines whether an SMBALERT is generated on the first THERM assertion, or only if a cumulative THERM assertion time limit is exceeded. A value of 0x00 causes an SMBALERT to be generated on the first THERM assertion. Configuring the THERM Pin as an Output In addition to monitoring THERM as an input, the ADT7467 can optionally drive THERM low as an output. In cases where PROCHOT is bidirectional, THERM can be used to throttle the processor by asserting PROCHOT. The user can preprogram system-critical thermal limits. If the temperature exceeds a thermal limit by 0.25°C, THERM asserts low. If the temperature is still above the thermal limit on the next monitoring cycle, THERM stays low. THERM remains asserted low until the temperature is equal to or below the thermal limit. Because the temperature for that channel is measured only once for every monitoring cycle, after THERM asserts it is guaranteed to remain low for at least one monitoring cycle. The THERM pin can be configured to assert low, if the Remote 1, local, or Remote 2 THERM temperature limits are exceeded by 0.25°C. The THERM temperature limit registers are at Registers 0x6A, 0x6B, and 0x6C, respectively. Setting Bit 3 of Registers 0x5F, 0x60, and 0x61 enables the THERM output feature for the Remote 1, local, and Remote 2 temperature channels, respectively. Figure 33 shows how the THERM pin asserts low as an output in the event of a critical overtemperature. THERM LIMIT +0.25°C THERM LIMIT TEMP Select a THERM monitoring time. THERM This value specifies how often OS or BIOS level software checks the THERM timer. For example, BIOS could read the THERM timer once an hour to determine the cumulative THERM assertion time. If, for example, the total THERM assertion time is <22.76 ms in Hour 1, >182.08 ms in Hour 2, and >5.825 s in Hour 3, this can indicate that system performance is degrading significantly because THERM is asserting more frequently on an hourly basis. ADT7467 MONITORING CYCLE 04498-0-027 5. Figure 33. Asserting THERM as an Output, Based on Tripping THERM Limits An alternative method of disabling THERM is to program the THERM temperature limit to –64°C or less in Offset 64 mode, or −128°C or less in twos complement mode; that is, for THERM temperature limit values less than –63°C or –128°C, respectively, THERM is disabled. Rev. 0| Page 25 of 80 ADT7467 The ADT7467 uses pulse-width modulation (PWM) to control fan speed. This relies on varying the duty cycle (or on/off ratio) of a square wave applied to the fan to vary the fan speed. The external circuitry required to drive a fan using PWM control is extremely simple. For 4-wire fans, the PWM drive might need only a pull-up resistor. In many cases, the 4-wire fan PWM input has a built-in pull-up resistor. The ADT7467 PWM frequency can be set to a selection of low frequencies or a single high PWM frequency. The low frequency options are usually used for 2-wire and 3-wire fans, while the high frequency option us usually used with 4-wire fans. For 2-wire or 3-wire fans, a single N-channel MOSFET is the only drive device required. The specifications of the MOSFET depend on the maximum current required by the fan being driven. Typical notebook fans draw a nominal 170 mA, and so SOT devices can be used where board space is a concern. In desktops, fans can typically draw 250 mA to 300 mA each. If you drive several fans in parallel from a single PWM output or drive larger server fans, 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_OUT pin. VGS can be greater than 3.3 V as long as the pull-up on the gate is tied to 5 V. The MOSFET should also have a low on resistance to ensure that there is not significant voltage drop across the FET, which would reduce the voltage applied across the fan and, therefore, the maximum operating speed of the fan. Figure 35 shows a fan drive circuit using an NPN transistor such as a general-purpose MMBT2222. While these devices are inexpensive, they tend to have much lower current handling capabilities and higher on resistance than MOSFETs. When choosing a transistor, care should be taken to ensure that it meets the fan’s current requirements. Ensure that the base resistor is chosen such that the transistor is saturated when the fan is powered on. Because 4-wire fans are powered continuously, the fan speed is not switched on or off as with previous PWM driven/powered fans. This enables it to perform better than 3-wire fans, especially for high frequency applications. Figure 36 shows a typical drive circuit for 4-wire fans. 12V 12V 10kΩ 10kΩ TACH 4.7kΩ 3.3V TACH 12V FAN 1N4148 ADT7467 665Ω Q1 MMBT2222 PWM 04498-0-029 FAN DRIVE USING PWM CONTROL Figure 35. Driving a 3-Wire Fan Using an NPN Transistor 12V 12V Figure 34 shows how to drive a 3-wire fan using PWM control. 12V TACH/AIN 4.7kΩ 3.3V 10kΩ TACH/AIN 10kΩ 12V FAN 1N4148 VCC 10kΩ TACH TACH PWM ADT7467 4.7kΩ 3.3V 2kΩ ADT7467 04498-0-041 12V 12V, 4-WIRE FAN 10kΩ PWM 10kΩ Q1 NDT3055L Figure 36. Driving a 4-Wire Fan 04498-0-028 PWM Driving Two Fans from PWM3 Figure 34. Driving a 3-Wire Fan Using an N-Channel MOSFET Figure 34 uses a 10 kΩ pull-up 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 V maximum to prevent damaging the ADT7467. 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. The ADT7467 has four TACH inputs available for fan speed measurement, but only three PWM drive outputs. If a fourth fan is being used in the system, it should be driven from the PWM3 output in parallel with the third fan. Figure 37 shows how to drive two fans in parallel using low cost NPN transistors. Figure 38 shows the equivalent circuit using a MOSFET. Rev. 0 | Page 26 of 80 ADT7467 12V 3.3V 3.3V 1N4148 ADT7467 TACH3 1kΩ PWM3 TACH4 Q1 MMBT3904 2.2kΩ 10Ω Q2 MMBT2222 04498-0-030 10Ω Q3 MMBT2222 Figure 37. Interfacing Two Fans in Parallel to the PWM3 Output Using Low Cost NPN Transistors 3.3V 10kΩ TYPICAL TACH4 +V 3.3V ADT7467 +V 10kΩ TYPICAL TACH3 3.3V 5V OR 12V FAN TACH 1N4148 TACH 5V OR 12V FAN 10kΩ TYPICAL 04498-0-031 Q1 NDT3055L PWM3 Figure 38. Interfacing Two Fans in Parallel to the PWM3 Output Using a Single N-Channel MOSFET 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 5 mA maximum current specified on the data sheet. Driving up to Three Fans from PWM3 TACH measurements for fans are synchronized to particular PWM channels, for example, TACH1 is synchronized to PWM1. TACH3 and TACH4 are both synchronized to PWM3, so PWM3 can drive two fans. Alternatively, PWM3 can be programmed to synchronize TACH2, TACH3, and TACH4 to the PWM3 output. This allows PWM3 to drive two or three fans. In this case, the drive circuitry looks the same, as shown in Figure 37 and Figure 38. The SYNC bit in Register 0x62 enables this function. Synchronization is not required in high frequency mode when used with 4-wire fans. <4> (SYNC) Enhance Acoustics Register 1 (Reg. 0x62) SYNC = 1, synchronizes TACH2, TACH3, and TACH4 to PWM3. Driving 2-Wire Fans The ADT7467 can support 2-wire fans only when low frequency PWM mode is selected in Configuration Register 5, Bit 2. If this bit is not set to 1, the ADT7467 cannot measure the speed of 2-wire fans. Figure 39 shows how a 2-wire fan can be connected to the ADT7467. This circuit allows the speed of a 2-wire fan to be measured, even though the fan has no dedicated TACH signal. A series resistor, RSENSE, in the fan circuit converts the fan commutation pulses into a voltage, which is ac-coupled into the ADT7467 through the 0.01 µF capacitor. On-chip signal conditioning allows accurate monitoring of fan speed. The value of RSENSE chosen depends upon the programmed input threshold and the current drawn by the fan. For fans drawing approximately 200 mA, a 2 Ω RSENSE value is suitable when the threshold is programmed as 40 mV. For fans that draw more current, such as larger desktop or server fans, RSENSE can be reduced for the same programmed threshold. The smaller the threshold programmed the better, because more voltage is developed across the fan and the fan spins faster. Figure 40 shows a typical plot of the sensing waveform at the TACH/AIN pin. Rev. 0| Page 27 of 80 ADT7467 TACH Inputs Note that when the voltage spikes (either negative going or positive going) are more than 40 mV in amplitude, the fan speed can be reliably determined. Pins 4, 6, 7, and 9 (when configured as TACH inputs) are opendrain TACH inputs intended for fan speed measurement. +V ADT7467 3.3V Signal conditioning in the ADT7467 accommodates the slow rise and fall times typical of fan tachometer outputs. The maximum input signal range is 0 V to 5 V, even when VCC is less than 5 V. In the event that these inputs are supplied from fan outputs that exceed 0 V to 5 V, either resistive attenuation of the fan signal or diode clamping must be included to keep inputs within an acceptable range. 1N4148 5V OR 12V FAN 10kΩ TYPICAL Q1 NDT3055L PWM Figure 42 to Figure 45 show circuits for most common fan TACH outputs. 0.01µF 04498-0-032 RSENSE 2Ω TYPICAL TACH If the fan TACH output has a resistive pull-up to VCC, it can be connected directly to the fan input, as shown in Figure 42. Figure 39. Driving a 2-Wire Fan VCC 12V TACH OUTPUT TACH FAN SPEED COUNTER ADT7467 04498-0-034 PULL-UP 4.7kΩ TYPICAL Figure 42. Fan with TACH Pull-Up to VCC VCC 12V Figure 40. Fan Speed Sensing Waveform at TACH/AIN Pin PULL-UP 4.7kΩ TYPICAL LAYING OUT 2-WIRE AND 3-WIRE FANS Figure 41 shows how to lay out a common circuit arrangement for 2-wire and 3-wire fans. Some components are not populated, depending on whether a 2-wire or 3-wire fan is used. TACH OUTPUT TACH ZD1* FAN SPEED COUNTER ADT7467 *CHOOSE ZD1 VOLTAGE APPROXIMATELY 0.8 × VCC 12V OR 5V R1 Figure 43. Fan with TACH Pull-Up to Voltage > 5 V. (for example, 12 V) Clamped with Zener Diode 1N4148 If the fan has a strong pull-up (less than 1 kΩ) to 12 V or a totem-pole output, then a series resistor can be added to limit the Zener current, as shown in Figure 44. 3.3V OR 5V R2 R5 PWM TACH R3 Q1 MMBT2222 R4 FOR 3-WIRE FANS: POPULATE R1, R2, R3 R4 = 0W C1 = UNPOPULATED FOR 2-WIRE FANS: POPULATE R4, C1 R1, R2, R3 UNPOPULATED 04498-0-042 C1 Figure 41. Planning for 2-Wire or 3-Wire Fans on a PCB Rev. 0 | Page 28 of 80 04498-0-035 04498-0-033 If the fan output has a resistive pull-up to 12 V (or other voltage greater than 5 V) then the fan output can be clamped with a Zener diode, as shown in Figure 43. The Zener diode voltage should be chosen so that it is greater than VIH of the TACH input but less than 5 V, allowing for the voltage tolerance of the Zener. A value of between 3 V and 5 V is suitable. ADT7467 VCC 5V OR 12V FAN CLOCK R1 10kΩ TACH OUTPUT TACH ZD1 ZENER* PWM FAN SPEED COUNTER ADT7467 04498-0-036 PULL-UP TYP <1kΩ OR TOTEM POLE *CHOOSE ZD1 VOLTAGE APPROXIMATELY 0.8 × VCC TACH 1 04498-0-038 2 Figure 44. Fan with Strong TACH Pull-Up to > VCC or Totem-Pole Output, Clamped with Zener and Resistor 3 4 Alternatively, a resistive attenuator can be used, as shown in Figure 45. R1 and R2 should be chosen such that Figure 46. Fan Speed Measurement Fan Speed Measurement Registers 2 V < VPULL-UP × R2/(RPULL-UP + R1 + R2) < 5 V The fan inputs have an input resistance of nominally 160 kΩ to ground, which should be taken into account when calculating resistor values. The fan tachometer readings are 16-bit values consisting of a 2byte read from the ADT7467. Reg. 0x28 TACH1 Low Byte = 0x00 default Reg. 0x29 TACH1 High Byte = 0x00 default With a pull-up voltage of 12 V and pull-up resistor less than 1 kΩ, suitable values for R1 and R2 would be 100 kΩ and 47 kΩ, respectively. This gives a high input voltage of 3.83 V. Reg. 0x2A TACH2 Low Byte = 0x00 default Reg. 0x2B TACH2 High Byte = 0x00 default VCC 12V Reg. 0x2C TACH3 Low Byte = 0x00 default Reg. 0x2D TACH3 High Byte = 0x00 default <1kΩ TACH R2* Reg. 0x2E TACH4 Low Byte = 0x00 default FAN SPEED COUNTER ADT7467 04498-0-037 R1* TACH OUTPUT *SEE TEXT Figure 45. Fan with Strong TACH Pull-Up to > VCC or Totem-Pole Output, Attenuated with R1/R2 Fan Speed Measurement The fan counter does not count the fan TACH output pulses directly, because the fan speed could be less than 1,000 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 (Figure 46), so the accumulated count is actually proportional to the fan tachometer period and inversely proportional to the fan speed. N, the number of pulses counted, is determined by the settings of Register 0x7B (TACH pulses per revolution register). This register contains two bits for each fan, allowing one, two (default), three, or four TACH pulses to be counted. Reg. 0x2F TACH4 High Byte = 0x00 default Reading Fan Speed from the ADT7467 The measurement of fan speeds 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 µs 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 (assuming 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). High Limit: > Comparison Performed Because the actual fan TACH period is being measured, falling below a fan TACH limit by 1 sets the appropriate status bit and can be used to generate an SMBALERT. Rev. 0| Page 29 of 80 ADT7467 Fan TACH Limit Registers Fan Pulses per Revolution The fan TACH limit registers are 16-bit values consisting of two bytes. Reg. 0x57 TACH2 Minimum High Byte = 0xFF default Different fan models can output either 1, 2, 3, or 4 TACH pulses per revolution. Once the number of fan TACH pulses has been determined, it can be programmed into the fan pulses per revolution register (Reg. 0x7B) for each fan. Alternatively, this register can be used to determine the number or pulses per revolution output by a given fan. By plotting fan speed measurements at 100% speed with different pulses per revolution setting, the smoothest graph with the lowest ripple determines the correct pulses per revolution value. Reg. 0x58 TACH3 Minimum Low Byte = 0xFF default Fan Pulses per Revolution Register Reg. 0x59 TACH3 Minimum High Byte = 0xFF default <1:0> Fan 1 default = 2 pulses per revolution. Reg. 0x5A TACH4 Minimum Low Byte = 0xFF default <3:2> Fan 2 default = 2 pulses per revolution. Reg. 0x5B TACH4 Minimum High Byte = 0xFF default <5:4> Fan 3 default = 2 pulses per revolution. Fan Speed Measurement Rate <7:6> Fan 4 default = 2 pulses per revolution. The fan TACH readings are normally updated once every second. 00 = 1 pulse per revolution. Reg. 0x54 TACH1 Minimum Low Byte = 0xFF default Reg. 0x55 TACH1 Minimum High Byte = 0xFF default Reg. 0x56 TACH2 Minimum Low Byte = 0xFF default The FAST bit (Bit 3) of Configuration Register 3 (Reg. 0x78), when set, updates the fan TACH readings every 250 ms. If any of the fans are not being driven by a PWM channel but are powered directly from 5 V or 12 V, their associated dc bit in Configuration Register 3 should be set. This allows TACH readings to be taken on a continuous basis for fans connected directly to a dc source. For optimal results, the associated dc bit should always be set when using 4-wire fans. Calculating Fan Speed Assuming a fan with a two pulses per revolution (and two pulses per revolution being measured) fan speed is calculated by Fan Speed (RPM) = (90,000 × 60)/Fan TACH Reading 01 = 2 pulses per revolution. 10 = 3 pulses per revolution. 11 = 4 pulses per revolution. 2-Wire Fan Speed Measurements (Low Frequency Mode Only) The ADT7467 is capable of measuring the speed of 2-wire fans, that is, fans without TACH outputs. To do this, the fan must be interfaced as shown in the Driving 2-Wire Fans section. In this case, the TACH inputs should be reprogrammed as analog inputs, AIN. Configuration Register 2 (Reg. 0x73) Bit 3 (AIN4) = 1, Pin 9 is reconfigured to measure the speed of a 2-wire fan using an external sensing resistor and coupling capacitor. where Fan TACH Reading is the 16-bit fan tachometer reading. Example: TACH1 High Byte (Reg. 0x29) = 0x17 TACH1 Low Byte (Reg. 0x28) = 0xFF What is Fan 1 speed in RPM? Bit 2 (AIN3) = 1, Pin 4 is reconfigured to measure the speed of a 2-wire fan using an external sensing resistor and coupling capacitor. Bit 1 (AIN2) = 1, Pin 7 is reconfigured to measure the speed of a 2-wire fan using an external sensing resistor and coupling capacitor. RPM = (f × 60)/Fan 1 TACH Reading Bit 0 (AIN1) = 1, Pin 6 is reconfigured to measure the speed of a 2-wire fan using an external sensing resistor and coupling capacitor. RPM = (90000 × 60)/6143 AIN Switching Threshold Fan 1 TACH Reading = 0x17FF = 6143 (decimal) Fan Speed = 879 RPM Having configured the TACH inputs as AIN inputs for 2-wire measurements, a user can select the sensing threshold for the AIN signal. Rev. 0 | Page 30 of 80 ADT7467 Configuration Register 4 (Reg. 0x7D) 101 = 1 s <3:2> AINL, input threshold for 2-wire fan speed measurements. 110 = 2 s 111 = 4 s 00 = ±20 mV PWM3 Configuration (Reg. 0x5E) 01 = ±40 mV <2:0> SPIN, start-up timeout for PWM3. 10 = ±80 mV 000 = no startup timeout 11 = ±130 mV 001 = 100 ms Fan Spin-Up 010 = 250 ms default The ADT7467 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 is that fans have different spin-up characteristics and take different times to overcome inertia. The ADT7467 runs the fans just fast enough to overcome inertia and is quieter on spin-up than fans programmed to spin up for a given spin-up time. Fan Startup Timeout To prevent the generation of false interrupts as a fan spins up (because it is below running speed), the ADT7467 includes a fan startup timeout function. During this time, the ADT7467 looks for two TACH pulses. If two TACH pulses are not detected, then an interrupt is generated. Using Configuration Register 4 (0x40) Bit 5 (FSPDIS), this functionality can be changed (see the Disabling Fan Startup Timeout section). 011 = 400 ms 100 = 667 ms 101 = 1 s 110 = 2 s 111 = 4 s Disabling Fan Startup Timeout Although fan startup makes fan spin-ups much quieter than fixed-time spin-ups, the option exists to use fixed spin-up times. Setting Bit 5 (FSPDIS) to 1 in Configuration Register 1 (Reg. 0x40) disables the spin-up for two TACH pulses. Instead, the fan spins up for the fixed time as selected in Reg. 0x5C to Reg. 0x5E. PWM Logic State The PWM outputs can be programmed high for 100% duty cycle (noninverted) or low for 100% duty cycle (inverted). PWM1 Configuration (Reg. 0x5C) PWM1 Configuration (Reg. 0x5C) <2:0> SPIN, startup timeout for PWM1. <4> INV. 0 = Logic high for 100% PWM duty cycle. 1 = Logic low for 100% PWM duty cycle. 000 = no startup timeout 001 = 100 ms 010 = 250 ms default PWM2 Configuration (Reg. 0x5D) 100 = 667 ms <4> INV. 0 = Logic high for 100% PWM duty cycle. 1 = Logic low for 100% PWM duty cycle. 101 = 1 s PWM3 Configuration (Reg. 0x5E) 110 = 2 s <4> INV. 0 = Logic high for 100% PWM duty cycle. 1 = Logic low for 100% PWM duty cycle. 011 = 400 ms 111 = 4 s PWM2 Configuration (Reg. 0x5D) <2:0> SPIN, startup timeout for PWM2. 000 = no startup timeout 001 = 100 ms 010 = 250 ms default 011 = 400 ms Low Frequency Mode PWM Drive Frequency The PWM drive frequency can be adjusted for the application. Reg. 0x5F to Reg. 0x61 configure the PWM frequency for PWM1 to PWM3, respectively. In high frequency mode, the PWM drive frequency is always 22.5 kHz and cannot be changed. 100 = 667 ms Rev. 0| Page 31 of 80 ADT7467 PWM1 Frequency Registers (Reg. 0x5F to Reg. 0x61) Example 1: For a PWM duty cycle of 50%, <2:0> FREQ. Value (decimal) = 50/0.39 = 128 (decimal) Value = 128 (decimal) or 0x80 (hex) 000 = 11.0 Hz 001 = 14.7 Hz Example 2: For a PWM duty cycle of 33%, 010 = 22.1 Hz Value (decimal) = 33/0.39 = 85 (decimal) Value = 85 (decimal) or 0x54 (hex) 011 = 29.4 Hz 100 = 35.3 Hz default PWM Duty Cycle Registers 101 = 44.1 Hz Reg. 0x30 PWM1 Duty Cycle = 0x00 (0% default) 110 = 58.8 Hz Reg. 0x31 PWM2 Duty Cycle = 0x00 (0% default) 111 = 88.2 Hz Fan Speed Control Reg. 0x32 PWM3 Duty Cycle = 0x00 (0% default) The ADT7467 controls fan speed using two modes: automatic and manual. In automatic fan speed control mode, fan speed is automatically varied with temperature and without CPU intervention, once initial parameters are set up. The advantage of this is that, if the system hangs, the user is guaranteed that 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 and how to program the automatic fan speed control loop and dynamic TMIN calibration, see the Programming the Automatic Fan Speed Control Loop section. In manual fan speed control mode, the ADT7467 allows the duty cycle of any PWM output to be manually adjusted. This can be useful, if the user wants to change fan speed in software or adjust PWM duty cycle output for test purposes. Bits <7:5> of Reg. 0x5C to Reg. 0x5E (PWM Configuration) control the behavior of each PWM output. PWM Configuration Register (Reg. 0x5C to Reg. 0x5E) <7:5> BHVR. 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. See the Programming the Automatic Fan Speed Control Loop section for details. OPERATING FROM 3.3 V STANDBY The ADT7467 has been specifically designed to operate from a 3.3 V STBY supply. In computers that support S3 and S5 states, the core voltage of the processor is lowered in these states. If using the dynamic TMIN mode, lowering the core voltage of the processor changes the CPU temperature and changes the dynamics of the system under dynamic TMIN control. Likewise, when monitoring THERM, the THERM timer should be disabled during these states. Dynamic TMIN Control Register 1 (Reg. 0x36) <1> VCCPLO = 1 When the power is supplied from 3.3 V STBY and the VCCP voltage drops below the VCCP low limit, the following occurs: 1. Status Bit 1 (VCCP) in Status Register 1 is set. 2. SMBALERT is generated if enabled. 3. THERM monitoring is disabled. The THERM timer should hold its value prior to the S3 or S5 state. 4. Dynamic TMIN control is disabled. This prevents TMIN from being adjusted due to an S3 or S5 state. 5. The ADT7467 is prevented from entering the shutdown state. 111 = manual mode. Once under manual control, each PWM output can be manually updated by writing to Reg. 0x30 to Reg. 0x32 (PWMx current duty cycle registers). 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 Once the core voltage, VCCP, goes above the VCCP low limit, everything is re-enabled and the system resumes normal operation. Value (decimal) = PWMMIN/0.39 Rev. 0 | Page 32 of 80 ADT7467 XNOR TREE TEST MODE The ADT7467 includes an XNOR 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 XNOR tree, it is possible to detect opens or shorts on the system board. If VCCP goes high (the system processor power rail is powered up), then a fail-safe timer begins to count down. If the ADT7467 is addressed by a valid SMBus transaction before the fail-safe timeout (4.6 s) lapses, then the ADT7467 operates normally, assuming the functionality of all the default registers. See the flow chart in Figure 48. Figure 47 shows the signals that are exercised in the XNOR tree test mode. The XNOR tree test is invoked by setting Bit 0 (XEN) of the XNOR tree test enable register (Reg. 0x6F). ADT7467 IS POWERED UP HAS THE ADT7467 BEEN ACCESSED BY A VALID SMBUS TRANSACTION? TACH1 Y TACH2 N TACH3 IS VCCP ABOVE 0.75V? CHECK VCCP N Y TACH4 START FAIL-SAFE TIMER PWM3 PWM1/XTO 04498-0-040 PWM2 HAS THE ADT7467 BEEN ACCESSED BY A VALID SMBUS TRANSACTION? Y N Figure 47. XNOR Tree Test FAIL-SAFE TIMER ELAPSES AFTER THE FAIL-SAFE TIMEOUT POWER-ON DEFAULT When the ADT7467 is powered up, it polls the VCCP input. If VCC goes high (the system processor power rail is powered up), then a fail-safe timer begins to count down. If the ADT7467 is not addressed by any valid SMBus transaction before the failsafe timeout (4.6 s) lapses, then the ADT7467 drives the fans to full speed. If the ADT7467 is addressed by a valid SMBus transaction after this point, the fans stop, and the ADT7467 assumes its default settings and begins normal operation. Rev. 0| Page 33 of 80 HAS THE ADT7467 BEEN ACCESSED BY A VALID SMBUS TRANSACTION? RUN THE FANS TO FULL SPEED N Y HAS THE ADT7467 BEEN ACCESSED BY A VALID SMBUS TRANSACTION? N Y START UP THE ADT7467 NORMALLY SWITCH OFF FANS Figure 48. Power-On Flow Chart 04498-0-043 If VCCP stays below 0.75 V (the system CPU power rail is not powered up), then the ADT7467 assumes the functionality of the default registers after the ADT7467 is addressed via any valid SMBus transaction. ADT7467 PROGRAMMING THE AUTOMATIC FAN SPEED CONTROL LOOP Note: To more efficiently understand the automatic fan speed control loop, it is strongly recommended to use the ADT7467 evaluation board and software 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 the system characteristics, the designer needs to give some thought to 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. AUTOMATIC FAN CONTROL OVERVIEW The ADT7467 can automatically control the speed of fans based upon the measured temperature. This is done independently of CPU intervention once initial parameters are set up. The ADT7467 has a local temperature sensor and two remote temperature channels that can be connected to a CPU on-chip thermal diode (available on Intel Pentium class and other CPUs). These three temperature channels can be used as the basis for automatic fan speed control to drive fans using pulsewidth modulation (PWM). Automatic fan speed control reduces acoustic noise by optimizing fan speed according to accurately measured Figure 49 gives a top-level overview of the automatic fan control circuitry on the ADT7467. From a systems-level perspective, up to three system temperatures can be monitored and used to control three PWM outputs. The three PWM outputs can be used to control up to four fans. The ADT7467 allows the speed of four fans to be monitored. Each temperature channel has a thermal calibration block, allowing the designer to individually configure the thermal characteristics of each temperature channel. For example, one can decide to run the CPU fan when CPU temperature increases above 60°C and a chassis fan 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 49 shows controls that are fan-specific. The designer has individual control over 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. PWM CONFIG PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) REMOTE 1 TEMP TMIN TRANGE THERMAL CALIBRATION TMIN PWM MIN 100% TRANGE THERMAL CALIBRATION REMOTE 2 TEMP TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX LOCAL TEMP PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% Figure 49. Automatic Fan Control Block Diagram Rev. 0 | Page 34 of 80 TACH1 PWM CONFIG PWM GENERATOR PWM2 TACH2 PWM CONFIG PWM GENERATOR PWM3 TACH3 04498-0-054 THERMAL CALIBRATION 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. ADT7467 STEP 1: HARDWARE CONFIGURATION During system design, the motherboard sensing and control capabilities should be addressed early in the design stages. Decisions about how these capabilities are used should involve the system thermal/mechanical engineer. Ask the following questions: How many fans will be supported in system, three or four? This influences the choice of whether to use the TACH4 pin or to reconfigure it for the THERM function. 3. Is the CPU fan to be controlled using the ADT7467 or will it run at full speed 100% of the time? If run at 100%, this frees up a PWM output, but the system is louder. What ADT7467 functionality will be used? • PWM2 or SMBALERT? • TACH4 fan speed measurement or overtemperature THERM function? 4. • 5 V voltage monitoring or overtemperature THERM function? • 12 V voltage monitoring or VID5 input? Where will the ADT7467 be physically located in the system? This influences the assignment of the temperature measurement channels to particular system thermal zones. For example, locating the ADT7467 close to the VRM controller circuitry allows the VRM temperature to be monitored using the local temperature channel. The ADT7467 offers multifunctional pins that can be reconfigured to suit different system requirements and physical layouts. These multifunction pins are software programmable. THERMAL CALIBRATION PWM CONFIG PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 1 = AMBIENT TEMP TRANGE THERMAL CALIBRATION PWM MIN 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX TMIN PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% REMOTE 2 = CPU TEMP TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REAR CHASSIS Figure 50. Hardware Configuration Example Rev. 0| Page 35 of 80 04499-0-055 1. 2. ADT7467 RECOMMENDED IMPLEMENTATION 1 7. 5 V measurement input. Configuring the ADT7467 as in Figure 51 provides the system designer with the following features: 8. VRM temperature using local temperature sensor. 9. CPU temperature measured using the Remote 1 temperature channel. 1. Six VID inputs (VID0 to VID5) for VRM10 support. 2. Two PWM outputs for fan control of up to three fans. (The front and rear chassis fans are connected in parallel.) 10. Ambient temperature measured through the Remote 2 temperature channel. 3. Three TACH fan speed measurement inputs. 4. VCC measured internally through Pin 4. 11. If not using VID5, this pin can be reconfigured as the 12 V monitoring input. 5. CPU core voltage measurement (VCORE). 6. 2.5 V measurement input used to monitor CPU current (connected to VCOMP output of ADP316x VRM controller). This is used to determine CPU power consumption. FRONT CHASSIS FAN 12. Bidirectional THERM pin allows the monitoring of PROCHOT output from an Intel® P4 processor, for example, or can be used as an overtemperature THERM output. 13. SMBALERT system interrupt output. TACH2 PWM1 TACH1 CPU FAN PWM3 REAR CHASSIS FAN 5(VRM9)/6(VRM10) VID[0:4]/VID[0.5] TACH3 D2+ D2– THERM PROCHOT CPU AMBIENT TEMPERATURE D1+ D1– ADT7467 3.3VSB 5V 12V/VID5 SDA SCL VCOMP SMBALERT CURRENT VCORE GND Figure 51. Recommended Implementation 1 Rev. 0 | Page 36 of 80 ICH 04498-0-056 ADP316x VRM CONTROLLER ADT7467 RECOMMENDED IMPLEMENTATION 2 7. 5 V measurement input. Configuring the ADT7467 as in Figure 52 provides the system designer with the following features: 8. VRM temperature using local temperature sensor. 9. CPU temperature measured using the Remote 1 temperature channel. 1. Six VID inputs (VID0 to VID5) for VRM10 support. 2. Three PWM outputs for fan control of up to three fans. (All three fans can be individually controlled.) 10. Ambient temperature measured through the Remote 2 temperature channel. 3. Three TACH fan speed measurement inputs. 4. VCC measured internally through Pin 4. 11. If not using VID5, this pin can be reconfigured as the 12 V monitoring input. 5. CPU core voltage measurement (VCORE). 6. 2.5 V measurement input used to monitor CPU current (connected to VCOMP output of ADP316x VRM controller). This is used to determine CPU power consumption. FRONT CHASSIS FAN 12. Bidirectional THERM pin allows the monitoring of PROCHOT output from an Intel P4 processor, for example, or can be used as an overtemperature THERM output. TACH2 PWM1 TACH1 CPU FAN PWM3 REAR CHASSIS FAN 5(VRM9)/6(VRM10) VID[0:4]/VID[0.5] TACH3 D2+ D2– THERM PROCHOT AMBIENT TEMPERATURE CPU D1+ D1– ADT7467 3.3VSB 5V 12V/VID5 SDA SCL VCOMP CURRENT ICH VCORE GND Figure 52. Recommended Implementation 2 Rev. 0| Page 37 of 80 04498-0-057 ADP316x VRM CONTROLLER ADT7467 101 = Fastest speed calculated by local and Remote 2 temperature controls PWMx STEP 2: CONFIGURING THE MUX After the system hardware configuration is determined, 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, can be run manually (under software control), or 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. 110 = Fastest speed calculated by all three temperature channels controls PWMx 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 would be the fan turning on when Remote 1 temperature exceeds 60°C or if the local temperature exceeds 45°C. Bits <7:5> (BHVR) of Registers 0x5C, 0x5D, and 0x5E (PWM configuration registers) control the behavior of the fans connected to the PWM1, PWM2, and PWM3 outputs. The values selected for these bits determine how the MUX connects a temperature measurement channel to a PWM output. Other MUX Options <7:5> (BHVR), Registers 0x5C, 0x5D, 0x5E. 011 = PWMx runs full speed Automatic Fan Control MUX Options 100 = PWMx disabled (default) <7:5> (BHVR), Registers 0x5C, 0x5D, 0x5E. 111 = manual mode. PWMx is runner under software control. In this mode, PWM duty cycle registers (Registers 0x30 to 0x32) are writable and control the PWM outputs. 000 = Remote 1 temperature controls PWMx 001 = local temperature controls PWMx 010 = Remote 2 temperature controls PWMx MUX PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 1 = AMBIENT TEMP TRANGE THERMAL CALIBRATION PWM MIN 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX TMIN PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% REMOTE 2 = CPU TEMP TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REAR CHASSIS Figure 53. Assigning Temperature Channels to Fan Channels Rev. 0 | Page 38 of 80 04498-0-058 THERMAL CALIBRATION ADT7467 MUX Configuration Example Example MUX Settings This is an example of how to configure the MUX in a system using the ADT7467 to control three fans. The CPU fan sink is controlled by PWM1, the front chassis fan is controlled by PWM2, and the rear chassis fan is controlled by PWM3. The MUX is configured for the following fan control behavior: <7:5> (BHVR), PWM1 Configuration Register 0x5C. PWM1 (CPU fan sink) is controlled by the fastest speed calculated by the local (VRM temperature) and Remote 2 (processor) temperature. In this case, the CPU fan sink is also being used to cool the VRM. • PWM2 (front chassis fan) is controlled by the Remote 1 temperature (ambient). • PWM3 (rear chassis fan) is controlled by the Remote 1 temperature (ambient). THERMAL CALIBRATION <7:5> (BHVR), PWM2 Configuration Register 0x5D. 000 = Remote 1 temperature controls PWM2 <7:5> (BHVR), PWM3 Configuration Register 0x5E. 000 = Remote 1 temperature controls PWM3 These settings configure the MUX, as shown in Figure 54. PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION MUX 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN PWM MIN 0% PWM MIN 100% TRANGE PWM1 0% TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS Figure 54. MUX Configuration Example Rev. 0| Page 39 of 80 04498-0-059 • 101 = Fastest speed calculated by local and Remote 2 temperature controls PWM1 ADT7467 STEP 3: TMIN SETTINGS FOR THERMAL CALIBRATION CHANNELS TMIN Registers 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. Reg. 0x68, Local Temperature TMIN = 0x9A (90°C) Reg. 0x67, Remote 1 Temperature TMIN = 0x9A (90°C) 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: Remote 1 Local, and Remote 2 Temp. Once the TMIN value is exceeded, the fan turns on and runs at the minimum PWM duty cycle. The fan turns off once the temperature has dropped below TMIN – THYST. To overcome fan inertia, the fan is spun up until two valid TACH rising edges are counted. See the Fan Startup Timeout section for more details. In some cases, primarily for psychoacoustic reasons, it is desirable that the fan never switch off below TMIN. Bits <7:5> of Enhanced Acoustics Register 1 (Reg. 0x62), when set, keep the fans running at the PWM minimum duty cycle, if the temperature should fall below TMIN. Reg. 0x69, Remote 2 Temperature TMIN = 0x9A (90°C) Enhance Acoustics Register 1 (Reg. 0x62) Bit 7 (MIN3) = 0, PWM3 is off (0% PWM duty cycle) when temperature is below TMIN – THYST. Bit 7 (MIN3) = 1, PWM3 runs at PWM3 minimum duty cycle below TMIN – THYST. Bit 6 (MIN2) = 0, PWM2 is off (0% PWM duty cycle) when temperature is below TMIN – THYST. Bit 6 (MIN2) = 1, PWM2 runs at PWM2 minimum duty cycle below TMIN – THYST. Bit 5 (MIN1) = 0, PWM1 is off (0% PWM duty cycle) when temperature is below TMIN – THYST. Bit 5 (MIN1) = 1, PWM1 runs at PWM1 minimum duty cycle below TMIN – THYST. PWM DUTYCYCLE 100% 0% TMIN PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION PWM MIN 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN PWM MIN 0% TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% 100% TRANGE PWM1 0% MUX TMIN PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS Figure 55. Understanding the TMIN Parameter Rev. 0 | Page 40 of 80 04498-0-060 THERMAL CALIBRATION ADT7467 STEP 4: PWMMIN FOR EACH PWM (FAN) OUTPUT Programming the PWMMIN Registers 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 once 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. 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 PWM DUTY CYCLE 100% Example 1: For a minimum PWM duty cycle of 50%, Value (decimal) = 50/0.39 = 128 (decimal) Value = 128 (decimal) or 80 (hex) Example 2: For a minimum PWM duty cycle of 33%, PWMMIN Value (decimal) = 33/0.39 = 85 (decimal) Value = 85 (decimal)l or 54 (hex) TMIN TEMPERATURE 04498-0-061 0% PWMMIN Registers Figure 56. PWMMIN Determines Minimum PWM Duty Cycle More than one PWM output can be controlled from a single temperature measurement channel. For example, Remote 1 temperature can control PWM1 and PWM2 outputs. If two different fans are used on PWM1 and PWM2, then 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 57 illustrates this as PWM1MIN (front fan) is turned on at a minimum duty cycle of 20%, while PWM2MIN (rear fan) turns on at a minimum of 40% duty cycle. Note, however, that both fans turn on at exactly the same temperature, defined by TMIN. 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 = PWM duty cycle × 10 STEP 5: PWMMAX FOR PWM (FAN) OUTPUTS 100% PWM DUTY CYCLE Reg. 0x64, PWM1 Minimum Duty Cycle = 0x80 (50% default) Reg. 0x65 PWM2 Minimum Duty Cycle = 0x80 (50% default) Reg. 0x66, PWM3 Minimum Duty Cycle = 0x80 (50% default) 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. M2 PW M1 PW PWM2MIN PWM1MIN TMIN TEMPERATURE 04498-0-062 0% Figure 57. Operating Two Different Fans from a Single Temperature Channel There is a PWMMAX limit for each fan channel. The default value of this register is 0xFF and so has no effect unless it is programmed. Rev. 0| Page 41 of 80 ADT7467 STEP 6: TRANGE FOR TEMPERATURE CHANNELS TRANGE is the range of temperature over which automatic fan control occurs once the programmed TMIN temperature has been 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. PWMMAX PWMMIN 0% TEMPERATURE 04498-0-063 TMIN TRANGE 100% PWM DUTY CYCLE Figure 58. PWMMAX Determines Maximum PWM Duty Cycle below the THERM Temperature Limit Programming the PWMMAX Registers The PWMMAX registers are 8-bit registers that allow the maximum PWM duty cycle for each output 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 80 (hex) 0% TMIN 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 worstcase 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 ADT7467 evaluation software, can graphically program and visualize this functionality. Ask your local Analog Devices representative for details. PWMMAX Registers Reg. 0x38, PWM1 Maximum Duty Cycle = 0xFF (100% default) TEMPERATURE Figure 59. TRANGE Parameter Affects Cooling Slope Example 2: For a minimum PWM duty cycle of 75%, Value (decimal) = 75/0.39 = 85 (decimal) Value = 192 (decimal) or C0 (hex) PWMMIN 04498-0-064 PWM DUTY CYCLE 100% Reg. 0x39, PWM2 Maximum Duty Cycle = 0xFF (100% default) See the Note on Fan Speed and PWM Duty Cycle on Page 41. PWM DUTY CYCLE 100% Reg. 0x3A, PWM3 Maximum Duty Cycle = 0xFF (100% default) 50% 33% 30°C 40°C TMIN Figure 60. Adjusting PWMMIN Affects TRANGE Rev. 0 | Page 42 of 80 04498-0-065 0% ADT7467 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: 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) PWM DUTY CYCLE 100% Example: 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) 50% 33% 25% 10% 0% Selecting a TRANGE Slope 30°C The TRANGE value can be selected for each temperature channel: Remote 1, local, and Remote 2 temperature. Bits <7:4> (TRANGE) of Registers 0x5F to 0x61 define the TRANGE value for each temperature channel. 45°C 54°C TMIN 04498-0-066 40°C Figure 61. Increasing PWMMIN Changes Effective TRANGE Table 13. Selecting a TRANGE Value For a given TRANGE value, the temperature at which the fan runs at full speed for different PWMMIN values can be easily calculated: TMAX = TMIN + (Max DC − Min DC) × TRANGE /170 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 duty PWM duty cycle vs. temperature slope. Example: Calculate T, 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) 1 Example: 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) Bits <7:4>1 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 TRANGE (°C) 2 2.5 3.33 4 5 6.67 8 10 13.33 16 20 26.67 32 (default) 40 53.33 80 Register 0x5F configures Remote 1 TRANGE. Register 0x60 configures Local TRANGE. Register 0x61 configures Remote 2 TRANGE. Summary of TRANGE Function When using the automatic fan control function, the temperature at which the fan reaches full speed can be calculated by TMAX = TMIN + TRANGE Equation 1 holds true only when PWMMIN is equal to 33% PWM duty cycle. Rev. 0| Page 43 of 80 (1) ADT7467 (2) where: (Max DC − Min DC) × TRANGE/170 is the effective TRANGE value. 2°C 2.5°C 90 3.33°C 4°C 80 5°C 70 6.67°C 8°C 60 10°C 50 13.3°C 16°C 40 20°C 30 26.6°C 32°C 20 See the Note on Fan Speed and PWM Duty Cycle. 40°C 10 Figure 62 shows PWM duty cycle versus temperature for each TRANGE setting. The lower graph shows how each TRANGE setting affects fan speed versus temperature. As can be seen from the graph, the effect on fan speed is nonlinear. 0 0 53.3°C 20 40 60 80 TEMPERATURE ABOVE TMIN 100 120 100 2°C 2.5°C 90 100 3.33°C 4°C 5°C 70 6.67°C 60 8°C 10°C 50 13.3°C 16°C 40 30 26.6°C 5°C 70 6.67°C 60 8°C 10°C 50 13.3°C 40 16°C 20°C 30 26.6°C 32°C 40°C 10 53.3°C 32°C 20 0 0 40°C 10 53.3°C 20 40 60 80 TEMPERATURE ABOVE TMIN 100 120 100 5°C 6.67°C 8°C 10°C 50 16°C 20°C 30 26.6°C 32°C 20 40°C 10 53.3°C 20 40 60 80 TEMPERATURE ABOVE TMIN 100 120 80°C TRANGE = 80°C for ambient temperature TRANGE = 53.3°C for CPU temperature TRANGE = 40°C for VRM temperature 13.3°C 40 120 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: 4°C 60 100 Example: Determining TRANGE for Each Temperature Channel 3.33°C 70 40 60 80 TEMPERATURE ABOVE TMIN Figure 63. TRANGE and % Fan Speed Slopes with PWMMIN = 20% 2.5°C 80 20 80°C 2°C 90 FAN SPEED (% OF MAX) 4°C 20 20°C 80°C 04498-0-067 PWM DUTY CYCLE (%) 80 0 0 80 FAN SPEED (% OF MAX) 90 0 0 3.33°C 2°C 2.5°C 80°C 04498-0-068 TMAX = TMIN + (Max DC − Min DC) × TRANGE/170 100 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 TRANGE for different PWMMIN values can be calculated using Equation 2: Figure 62. TRANGE vs. Actual Fan Speed Profile The graphs in Figure 62 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 63 shows how TRANGE is affected when the PWMMIN value is set to 20%. It can be seen that the fan actually runs at about 45% fan speed when the temperature exceeds TMIN. This example uses the MUX configuration described in Step 2, with the ADT7467 connected as shown in Figure 54. 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%. Note on 4-Wire Fans 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%. Rev. 0 | Page 44 of 80 ADT7467 100 The fans remain running at 100% until the temperature drops below TTHERM minus hysteresis, where hysteresis is the number 90 PWM DUTY CYCLE (%) 80 programmed into the Hysteresis Registers 0x6D and 0x6E. The default hysteresis value is 4°C. 70 60 The TTHERM limit should be considered the maximum worst-case 50 operating temperature of the system. Because exceeding any TTHERM limit runs all fans at 100%, it has very negative acoustic 40 30 effects. Ultimately, this limit should be set up as a fail-safe, and one should ensure that it is not exceeded under normal system operating conditions. 20 10 0 0 10 20 30 40 50 60 70 80 90 Note that the TTHERM limits are nonmaskable and affect the fan 100 TEMPERATURE ABOVE TMIN speed no matter how 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 100 90 FAN SPEED (% MAX RPM) 80 70 example, 70°C). 60 THERM Registers 50 Reg. 0x6A, Remote 1 THERM limit = 0xA4 (100°C default) 40 30 Reg. 0x6B, Local THERM limit = 0xA4 (100°C default) 20 Reg. 0x6C, Remote 2 THERM limit = 0xA4 (100°C default) 0 0 10 20 30 40 50 60 70 80 90 100 TEMPERATURE ABOVE TMIN 04498-0-069 10 Hysteresis Registers Reg. 0x6D, Remote 1, Local Hysteresis Register <7:4>, Remote 1 temperature hysteresis (4°C default). Figure 64. TRANGE and % Fan Speed Slopes for VRM, Ambient, and CPU Temperature Channels <3:0>, Local temperature hysteresis (4°C default). STEP 7: TTHERM FOR TEMPERATURE CHANNELS Reg. 0x6E, Remote 2 Temperature Hysteresis Register 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 temperature measured exceeds TTHERM, all fans are driven at 100% PWM duty cycle (full speed) to provide critical system cooling. <7:4>, Remote 2 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 disables hysteresis. In effect, this would cause the fans to cycle between normal speed and 100% speed, creating unsettling acoustic noise. Rev. 0| Page 45 of 80 ADT7467 TRANGE PWM DUTYCYCLE 100% 0% TMIN TTHERM PWM CONFIG PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION TMIN PWM MIN 100% TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX LOCAL = VRM TEMP PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACH1 PWM CONFIG PWM GENERATOR PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR TACHOMETER 3 AND 4 MEASUREMENT 0% CPU FAN SINK PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS 04498-0-070 THERMAL CALIBRATION Figure 65. How TTHERM Relates to Automatic Fan Control STEP 8: THYST FOR TEMPERATURE CHANNELS Hysteresis Registers 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 temperature is hovering at about the TMIN setting. Reg. 0x6D, Remote 1, Local Hysteresis Register 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 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. <7:4>, Remote 2 temperature hysteresis (4°C default). The THYST setting applies not only to the temperature hysteresis for fan on/off, but the same setting is used for the TTHERM <7:4>, Remote 1 temperature hysteresis (4°C default). <3:0>, local temperature hysteresis (4°C default). Reg. 0x6E, Remote 2 Temp Hysteresis Register In some applications, it is required that fans not turn off below TMIN, but remain running at PWMMIN. Bits <7:5> of Enhanced Acoustics Register 1 (Reg. 0x62) 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. hysteresis value, described in Step 6. Therefore, programming Registers 0x6D and 0x6E sets the hysteresis for both fan on/off and the THERM function. Rev. 0 | Page 46 of 80 ADT7467 TRANGE PWM DUTYCYCLE 100% 0% TTHERM THERMAL CALIBRATION PWM CONFIG PWM MIN 100% RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION TMIN PWM MIN 100% TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX LOCAL = VRM TEMP PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS 04498-0-071 TMIN Figure 66. The THYST Value Applies to Fan On/Off Hysteresis and THERM Hysteresis Enhance Acoustics Register 1 (Reg. 0x62) Bit 6 (MIN2) = 1, PWM2 runs at PWM2 minimum duty cycle below TMIN − THYST. Bit 7 (MIN3) = 0, PWM3 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 7 (MIN3) = 1, PWM3 runs at PWM3 minimum duty cycle below TMIN − THYST. Bit 6 (MIN2) = 0, PWM2 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 5 (MIN1) = 0, PWM1 is off (0% PWM duty cycle) when temperature is below TMIN − THYST. Bit 5 (MIN1) = 1, PWM1 runs at PWM1 minimum duty cycle below TMIN − THYST. Rev. 0| Page 47 of 80 ADT7467 VENTS DYNAMIC TMIN CONTROL MODE FAN FAN I/O CARDS I/O CARDS GOOD CPU AIRFLOW FAN POWER SUPPLY VENTS CPU POWER SUPPLY CPU POOR CPU AIRFLOW DRIVE BAYS DRIVE BAYS 04498-0-072 In addition to the automatic fan speed control mode described in the Automatic Fan Control Overview section, the ADT7467 has a mode that extends the basic automatic fan speed control loop. Dynamic TMIN control allows the ADT7467 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. VENTS GOOD VENTING = GOOD AIR EXCHANGE POOR VENTING = POOR AIR EXCHANGE Designing for Worst-Case Conditions • • • Worst-Case Altitude A computer can be operated at different altitudes. The altitude affects the relative air density, which alters the effectiveness of the fan cooling solution. For example, comparing 40°C air temperature at 10,000 ft. 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 ft. while keeping the system at the same temperature at both locations. Figure 67. Chassis Airflow Issues • Worst-Case Processor Power Consumption This data sheet maximum does not necessarily reflect the true processor power consumption. Designing for worstcase CPU power consumption can result in a processor becoming overcooled (generating excess system noise). • Worst-Case Peripheral Power Consumption The tendency is to design to data sheet maximums for peripheral components (again overcooling 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 might be used, or variations in application pressure for thermal interface material could 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. Worst-Case Fan Due to manufacturing tolerances, fan speeds in RPM are normally quoted with a tolerance of ±20%. The designer needs to 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 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.) TA θSA HEAT SINK THERMAL INTERFACE MATERIAL INTEGRATED HEAT SPREADER TS θCA θTIMS TTIM θCTIM TC θCS θJA θTIMC PROCESSOR θJTIM SUBSTRATE EPOXY THERMAL INTERFACE MATERIAL TTIM TJ 04498-0-073 System design must always allow for worst-case conditions. In PC design, the worst-case conditions include, but are not limited to the following: Figure 68. 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. Rev. 0 | Page 48 of 80 ADT7467 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). Getting the most 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 ADT7467’s dynamic TMIN control mode, however, shortens the characterization time and alleviates tweaking the control loop settings, because the device can selfadjust during system operation. Dynamic TMIN control mode is operated by specifying the operating zone temperatures required for the system. Associated with this control mode are three operating point registers, one for each temperature channel. 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 ADT7467 dynamically alters the control solution to maintain each zone temperature as closely as possible to its target operating point. Operating Point Registers Reg. 0x33, Remote 1 Operating Point = 0xA4 (100°C default) Figure 69 shows an overview of the parameters that affect the operation of the dynamic TMIN control loop. TEMPERATURE TLOW TMIN OPERATING THIGH TTHERM TRANGE POINT 04498-0-074 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. ADT7467 can selfadjust its fan control loop to maintain either an operating zone temperature or a system target temperature. For example, one can specify that the ambient temperature in a system should 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. PWM DUTY CYCLE Dynamic TMIN Control Overview Figure 69. Dynamic TMIN Control Loop Table 14 provides a brief description of each parameter. Table 14. TMIN Control Loop Parameters Parameter TLOW THIGH TMIN Operating point TTHERM TRANGE Description If the temperature drops below the TLOW limit, an error flag is set in a status register and an SMBALERT interrupt can be generated. If the temperature exceeds the THIGH limit, an error flag is set in a status register and an SMBALERT interrupt can be generated. The temperature at which the fan turns on under automatic fan speed control. The target temperature for a particular temperature zone. The ADT7467 attempts to maintain system temperature at about the operating point by adjusting the TMIN parameter of the control loop. If the temperature exceeds this critical limit, the fans can be run at 100% for maximum cooling. Programs the PWM duty cycle vs. temperature control slope. Dynamic TMIN Control Programming Because the dynamic TMIN control mode is a basic extension of the automatic fan control mode, program the automatic fan control mode parameters first, as described in Step 1 to Step 8, then proceed with dynamic TMIN control mode programming. Reg. 0x34, Local Operating Point = 0xA4 (100°C default) Reg. 0x35, Remote 2 Operating Point = 0xA4 (100°C default) Rev. 0| Page 49 of 80 ADT7467 STEP 9: OPERATING POINTS FOR TEMPERATURE CHANNELS the operating point to be exceeded, and in turn, the ADT7467 reduces TMIN to turn the fans on sooner to cool the system. 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 ADT7467 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 ADT7467 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 Programming Operating Point Registers Operating Point Registers Reg. 0x33, Remote 1 Operating Point = 0xA4 (100°C default) Reg. 0x34, Local Operating Point = 0xA4 (100°C default) Reg. 0x35, Remote 2 Operating Point = 0xA4 (100°C default) PWM MIN 100% OPERATING POINT TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION RAMP CONTROL (ACOUSTIC ENHANCEMENT) PWM MIN 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN PWM MIN 0% TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% 100% TRANGE PWM GENERATOR PWM1 0% MUX TMIN PWM CONFIG TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS Figure 70. Operating Point Value Dynamically Adjusts Automatic Fan Control Settings Rev. 0 | Page 50 of 80 04498-0-075 THERMAL CALIBRATION There are three operating point registers, one for each temperature channel. These 8-bit registers allow the operating point temperatures to be programmed with 1°C resolution. ADT7467 Short Cycle and Long Cycle STEP 10: 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 defines the temperature at which the TMIN value starts to be reduced, if temperature increases above this value. This has the net effect of increasing fan speed to cool down the system. An interrupt can be generated when the temperature rises above the high limit. Programming High and Low Limits There are six limit registers; a high limit and low limit are associated with each temperature channel. These 8-bit registers allow the high and low limit temperatures to be programmed with 1°C resolution. Temperature Limit Registers Reg. 0x4E, Remote 1 Temperature Low Limit = 0x01 Reg. 0x4F, Remote 1 Temperature High Limit = 0x7F Reg. 0x50, Local Temperature Low Limit = 0x01 Reg. 0x52, Remote 2 Temperature Low Limit = 0x01 Reg. 0x53, Remote 2 Temperature High Limit = 0x7F How Dynamic TMIN Control Works The basic premise is as follows: 3. Local = CYL = Bits <5:3> of Calibration Control Register 2 (Address = 0x37). Remote 2 = CYR2 = Bits <7:6> of Calibration Control Register 2 and Bit 0 of Calibration Control Register 1 (Address = 0x36). Table 15. Cycle Bit Assignments Code 000 001 010 011 100 101 110 111 Short Cycle 8 cycles 16 cycles 32 cycles 64 cycles 128 cycles 256 cycles 512 cycles 1024 cycles (1 s) (2 s) (4 s) (8 s) (16 s) (32 s) (64 s) (128 s) Long Cycle 16 cycles 32 cycles 64 cycles 128 cycles 256 cycles 512 cycles 1024 cycles 2048 cycles (2 s) (4 s) (8 s) (16 s) (32 s) (64 s) (128 s) (256 s) 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 temperature register. As the temperature in that zone (Remote 1 temperature) rises toward and exceeds the operating point temperature, TMIN is reduced and the fan speed increases. As the temperature drops below the operating point temperature, TMIN is increased and the fan speed is reduced. Figure 71 shows the steps taken during the short cycle. WAIT n MONITORING CYCLES CURRENT TEMPERATURE MEASUREMENT T1(n) OPERATING POINT TEMPERATURE OP1 PREVIOUS TEMPERATURE MEASUREMENT T1 (n – 1) However, the loop operation is not as simple as described in these steps. A number of conditions govern the situations in which TMIN can increase or decrease. IS T1(n) > (OP1 – HYS) NO DO NOTHING YES IS T1(n) – T1(n – 1) ≤ 0.25°C DO NOTHING (SYSTEM IS COOLING OF FOR CONSTANT) YES NO IS T1(n) – T1(n – 1) = 0.5 – 0.75°C IS T1(n) – T1(n – 1) = 1.0 – 1.75°C IS T1(n) – T1(n – 1) > 2.0°C DECREASE TMIN BY 1°C DECREASE TMIN BY 2°C DECREASE TMIN BY 4°C Figure 71. Short Cycle Steps Figure 72 shows the steps taken during the long cycle. Rev. 0| Page 51 of 80 04498-0-077 2. Remote 1 = CYR1 = Bits <2:0> of Calibration Control Register 2 (Address = 0x37). Care should be taken when choosing the cycle time. A long cycle time means that TMIN is updated less often. If your system has very fast temperature transients, the dynamic TMIN control loop will always be lagging. If you choose a cycle time that is too fast, the full benefit of changing TMIN might not be realized and 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. Reg. 0x51, Local Temperature High Limit = 0x7F 1. The ADT7467 implements two loops: a short cycle and a long 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: ADT7467 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. WAIT 2n MONITORING CYCLES IS T1(n) > OP1 OPERATING POINT TEMPERATURE OP1 YES DECREASE TMIN BY 1°C 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. NO IS T1(n) < LOW TEMP LIMIT AND TMIN < HIGH TEMP LIMIT YES AND TMIN < OP1 AND T1(n) > TMIN NO INCREASE TMIN BY 1°C 04498-0-078 CURRENT TEMPERATURE MEASUREMENT T1(n) DO NOT CHANGE Figure 72. Long Cycle Steps The following examples illustrate some of the circumstances that might cause TMIN to increase, decrease, or stay the same. Example: Normal Operation—No TMIN Adjustment 1. If measured temperature never exceeds the programmed operating point minus the hysteresis temperature, then TMIN is not adjusted, that is, remains at its current setting. 2. If measured temperature never drops below the low temperature limit, then TMIN is not adjusted. When the temperature drops below the low temperature limit, TMIN can increase in the long cycle. Increasing TMIN has the effect of running the fan slower and, therefore, quieter. The long cycle diagram in Figure 25 shows the conditions that need to be true for TMIN to increase. Here is a quick summary of those conditions and the reasons they need to be true. HIGH TEMP LIMIT HYSTERESIS ACTUAL TEMP TMIN TMIN can increase, if 04498-0-079 LOW TEMP LIMIT Once the temperature has fallen 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 ≤0.25°C per cycle. Example: Increase TMIN Cycle THERM LIMIT OPERATING POINT Once 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 74, because the temperature is increasing at a rate ≤0.25°C per short cycle, no reduction in TMIN takes place during the short cycle. 1. 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. 2. 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. 3. TMIN is below the operating point temperature. TMIN should never be allowed to increase above the operating point temperature, because the fans would not switch on until the temperature rose above the operating point. 4. The temperature is above TMIN. The dynamic TMIN control is turned off below TMIN. Figure 73. Temperature between Operating Point and 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: 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. This occurs during the short cycle (see Figure 71). The rate at which TMIN decreases depends on the programmed value of n. It also Rev. 0 | Page 52 of 80 ADT7467 THERM LIMIT HIGH TEMP LIMIT OPERATING POINT HYSTERESIS ACTUAL TEMP NO CHANGE IN TMIN HERE DUE TO ANY CYCLE, BECAUSE T1(n) – T1 (n – 1) ≤ 0.25°C AND T1(n) < OP = > TMIN STAYS THE SAME TMIN LOW TEMP LIMIT DECREASE HERE DUE TO LONG CYCLE ONLY T1(n) – T1 (n – 1) ≤ 0.25°C AND T1(n) > OP = > TMIN DECREASES BY 1°C EVERY LONG CYCLE 04498-0-080 DECREASE HERE DUE TO SHORT CYCLE ONLY T1(n) – T1 (n – 1) = 0.5°C OR 0.75°C = > TMIN DECREASES BY 1°C EVERY SHORT CYCLE Figure 74. Effect of Exceeding Operating Point Minus Hysteresis Temperature OPERATING POINT LOW TEMP LIMIT THERM LIMIT HYSTERESIS ACTUAL TEMP HIGH TEMP LIMIT HIGH TEMP LIMIT OPERATING POINT THERM LIMIT TMIN TMIN PREVENTED FROM INCREASING 04498-0-082 Figure 75 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. Once the temperature rises above the low temperature limit, TMIN stays the same. HYSTERESIS Figure 76. TMIN Adjustments Limited by the High Temperature Limit STEP 11: MONITORING THERM 04498-0-081 LOW TEMP LIMIT ACTUAL TEMP TMIN Figure 75. Increasing TMIN for Quieter Operation Example: Preventing TMIN from Reaching Full Scale Because TMIN is dynamically adjusted, it is undesirable for TMIN to reach full scale (127°C), because the fan would never switch on. As a result, TMIN is allowed to vary only within a specified range: 1. The lowest possible value for TMIN is –127°C (twos complement mode) or −64°C (Offset 64 mode). 2. TMIN cannot exceed the high temperature limit. 3. If the temperature is below TMIN, the fan is switched off or is running at minimum speed and dynamic TMIN control is disabled. 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 ADT7467. 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 ADT7467. This gives the maximum temperature at which the Pentium 4 can run before clock modulation occurs. Rev. 0| Page 53 of 80 ADT7467 Enabling the THERM Trip Point as the Operating Point Bits <4:2> of dynamic TMIN control Register 1 (Reg. 0x36) enable/disable THERM monitoring to program the operating point. Dynamic TMIN Control Register 1 (0x36) <2> PHTR2 = 1, copies the Remote 2 current temperature to the Remote 2 operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted. This allows the system to run as quietly as possible without affecting system performance. PHTR2 = 0, ignores any THERM assertions. The Remote 2 operating point register reflects its programmed value. <3> PHTL = 1, copies the local current temperature to the local temperature operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted. This allows the system to run as quietly as possible without affecting system performance. PHTL = 0, ignores any THERM assertions. The local temperature operating point register reflects its programmed value. <4> PHTR1 = 1, copies the Remote 1 current temperature to the Remote 1 operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted. This allows the system to run as quietly as possible without affecting system performance. PHTR1 = 0, ignores any THERM assertions. The Remote 1 operating point register reflects its programmed value. R2T = 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. <6> LT = 1, enables dynamic TMIN control on the local temperature channel. The chosen TMIN value is dynamically adjusted based on the current temperature, operating point, and high and low limits for this zone. LT = 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. <7> R1T = 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. R1T = 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. ENHANCING SYSTEM ACOUSTICS 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 psychoacoustic reasons, the ADT7467 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. Acoustic Enhancement Mode Overview Enabling Dynamic TMIN Control Mode Bits <7:5> of dynamic TMIN control Register 1 (Reg. 0x36) enable/disable dynamic TMIN control on the temperature channels. Dynamic TMIN Control Register 1 (0x36) <5> R2T = 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. Figure 77 gives a top-level overview of the automatic fan control circuitry on the ADT7467 and shows where acoustic enhancement fits in. Acoustic enhancement is intended as a postdesign 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. Rev. 0 | Page 54 of 80 ADT7467 ACOUSTIC ENHANCEMENT PWM MIN 100% PWM CONFIG RAMP CONTROL (ACOUSTIC ENHANCEMENT) TMIN REMOTE 2 = CPU TEMP TRANGE THERMAL CALIBRATION PWM MIN 100% LOCAL = VRM TEMP TRANGE THERMAL CALIBRATION TMIN TACHOMETER 1 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) 0% PWM MIN 100% TRANGE PWM1 0% MUX TMIN PWM GENERATOR TACHOMETER 2 MEASUREMENT RAMP CONTROL (ACOUSTIC ENHANCEMENT) TACHOMETER 3 AND 4 MEASUREMENT 0% TACH1 PWM CONFIG PWM GENERATOR CPU FAN SINK PWM2 TACH2 PWM CONFIG FRONT CHASSIS PWM GENERATOR PWM3 TACH3 REMOTE 1 = AMBIENT TEMP REAR CHASSIS 04498-0-083 THERMAL CALIBRATION Figure 77. Acoustic Enhancement Smoothes Fan Speed Variations under Automatic Fan Speed Control Approaches to System Acoustic Enhancement 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) use 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. Now 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 ADT7467. Enabling Acoustic Enhancement for Each PWM Output Enhance Acoustics Register 1 (Reg. 0x62) <3> = 1, enables acoustic enhancement on PWM1 output. Enhance Acoustics Register 2 (Reg. 0x63) <7> = 1, enables acoustic enhancement on PWM2 output. <3> = 1, enables acoustic enhancement on PWM3 output. Effect of Ramp Rate on Enhanced Acoustics Mode 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 Rev. 0| Page 55 of 80 ADT7467 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. 85 TIME SLOTS 170 TIME SLOTS 04498-0-084 PWM_OUT 33% DUTY CYCLE PWM OUTPUT (ONE PERIOD) = 255 TIME SLOTS STEP 12: 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 (Reg. 0x62) <2:0> ACOU, selects the ramp rate for PWM1. 000 = 1 time slot = 35 s 001 = 2 time slots = 17.6 s 010 = 3 time slots = 11.8 s 011 = 5 time slots = 7 s 100 = 8 time slots = 4.4 s 101 = 12 time slots =3 s 110 = 24 time slots = 1.6 s 111 = 48 time slots = 0.8 s Figure 78. 33% PWM Duty Cycle Represented in Time Slots The ramp rates in the enhanced acoustics mode are selectable from the values 1, 2, 3, 5, 8, 12, 24, and 48. 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 79 shows how the enhanced acoustics mode algorithm operates. Enhance Acoustics Register 2 (Reg. 0x63) <2:0> ACOU3, selects the ramp rate for PWM3. READ TEMPERATURE 000 = 1 time slot = 35 s 001 = 2 time slots = 17.6 s 010 = 3 time slots = 11.8 s 011 = 5 time slots = 7 s 100 = 8 time slots = 4.4 s 101 = 12 time slots = 3 s 110 = 24 time slots = 1.6 s 111 = 48 time slots = 0.8 s CALCULATE NEW PWM DUTY CYCLE IS NEW PWM VALUE > PREVIOUS VALUE? NO DECREMENT PREVIOUS PWM VALUE BY RAMP RATE YES <6:4> ACOU2, selects the ramp rate for PWM2. 04498-0-085 INCREMENT PREVIOUS PWM VALUE BY RAMP RATE 000 = 1 time slot = 35 s 001 = 2 time slots = 17.6 s 010 = 3 time slots = 11.8 s 011 = 5 time slots = 7 s 100 = 8 time slots = 4.4 s 101 = 12 time slots = 3 s 110 = 24 time slots = 1.6 s 111 = 48 time slots = 0.8 s Figure 79. Enhanced Acoustics 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, then 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 enhance acoustics registers. If the new PWM duty cycle value is less than the previous PWM value, then 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. 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%. 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 ADT7467 into manual mode and changing the PWM output from 0% to 100% PWM duty cycle. The PWM output takes 35 s to reach 100%, when a ramp rate of 1 time slot is selected. Rev. 0 | Page 56 of 80 ADT7467 140 Figure 80 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 s 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. 120 RTEMP (°C) 120 100 100 80 80 PWM DUTY CYCLE (%) 60 60 40 40 120 RTEMP (°C) 20 20 120 100 0 100 0 80 80 TIME (s) 0 17.6 04498-0-088 140 Figure 82. Enhanced Acoustics Mode with Ramp Rate = 2 60 Figure 83 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 s for the fan to reach full speed. 60 40 40 0 0 0 0.76 TIME (s) 04498-0-086 20 20 RTEMP (°C) 120 100 Figure 80. Enhanced Acoustics Mode with Ramp Rate = 48 100 Figure 81 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 s for the fan to reach full speed. 120 140 120 80 80 60 60 PWM DUTY CYCLE (%) 40 40 140 20 20 RTEMP (°C) 120 100 0 0 0 TIME (s) 35 04498-0-089 PWM CYCLE (%) 100 80 Figure 83. Enhanced Acoustics Mode with Ramp Rate = 1 PWM DUTY CYCLE (%) 80 As Figure 80 to Figure 83 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. 60 60 40 40 20 0 0 TIME (s) 4.4 0 04498-0-087 20 Figure 81. Enhanced Acoustics Mode with Ramp Rate = 8 Figure 82 shows the PWM output response for a ramp rate of 2. In this instance, the fan took about 17.6 s to reach full running speed. Figure 84 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. Rev. 0| Page 57 of 80 ADT7467 Enhanced Acoustics Register 1 (Reg. 0x62) 90 80 <2:0> ACOU, selects the ramp rate for PWM1. 70 PWM DUTY CYCLE (%) 000 = 140 s 001 = 70.4 s 010 = 47.2 s 011 = 28 s 100 = 17.6 s 101 = 12 s 110 = 6.4 s 111 = 3.2 s 60 50 RTEMP (°C) 40 30 04498-0-090 20 10 0 Enhance Acoustics Register 2 (Reg. 0x63) Figure 84. How Fan Reacts to Temperature Variation in Enhanced Acoustics Mode <2:0> ACOU3, selects the ramp rate for PWM3. Slower Ramp Rates 000 = 140 s 001 = 70.4 s 010 = 47.2 s 011 = 28 s 100 = 17.6 s 101 = 12 s 110 = 6.4 s 111 = 3.2 s The ADT7467 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 (Reg. 0x5C) <3> SLOW, 1 slows the ramp rate for PWM1 by 4. PWM2 Configuration Register (Reg. 0x5D) <3> SLOW, 1 slows the ramp rate for PWM2 by 4. PWM3 Configuration Register (Reg. 0x5E) <6:4> ACOU2, selects the ramp rate for PWM2. <3> SLOW, 1 slows the ramp rate for PWM3 by 4. The following sections list the ramp-up times when the SLOW bit is set for each PWM output. Rev. 0 | Page 58 of 80 000 = 140 s 001 = 70.4 s 010 = 47.2 s 011 = 28 s 100 = 17.6 s 101 = 12 s 110 = 6.4 s 111 = 3.2 s ADT7467 REGISTER TABLES Table 16. ADT7467 Registers Address 0x21 0x22 0x25 R/W R R R 0x26 R 0x27 R 0x28 R 0x29 R 0x2A R 0x2B R 0x2C R 0x2D R 0x2E R 0x2F R 0x30 R/W 0x31 R/W 0x32 R/W 0x33 R/W 0x34 R/W 0x35 R/W 0x36 R/W 0x37 R/W 0x38 R/W 0x39 R/W 0x3A R/W 0x3D R 0x3E R 0x3F R 0x40 R/W Description Vccp Reading VCC Reading Remote 1 Temperature Local Temperature Remote 2 Temperature TACH1 Low Byte TACH1 High Byte TACH2 Low Byte TACH2 High Byte TACH3 Low Byte TACH3 High Byte TACH4 Low Byte TACH4 High Byte PWM1 Current Duty Cycle PWM2 Current Duty Cycle PWM3 Current Duty Cycle Remote 1 Operating Point Local Temp Operating Point Remote 2 Operating Point Dynamic TMIN Control Reg. 1 Dynamic TMIN Control Reg. 2 Max PWM 1 Duty Cycle Max PWM 2 Duty Cycle Max PWM 3 Duty Cycle Device ID Register Company ID Number Revision Number Configuration Register 1 Bit 7 9 9 9 Bit 6 8 8 8 Bit 5 7 7 7 Bit 4 6 6 6 Bit 3 5 5 5 Bit 2 4 4 4 Bit 1 3 3 3 Bit 0 2 2 2 Default 0x00 0x00 0x01 9 8 7 6 5 4 3 2 0x01 9 8 7 6 5 4 3 2 0x01 7 6 5 4 3 2 1 0 0x00 15 14 13 12 11 10 9 8 0x00 7 6 5 4 3 2 1 0 0x00 15 14 13 12 11 10 9 8 0x00 7 6 5 4 3 2 1 0 0x00 15 14 13 12 11 10 9 8 0x00 7 6 5 4 3 2 1 0 0x00 15 14 13 12 11 10 9 8 0x00 7 6 5 4 3 2 1 0 0x00 7 6 5 4 3 2 1 0 0x00 7 6 5 4 3 2 1 0 0x00 7 6 5 4 3 2 1 0 0xA4 Yes 7 6 5 4 3 2 1 0 0xA4 Yes 7 6 5 4 3 2 1 0 0xA4 Yes R2T LT R1T PHTR2 PHTL PHTR1 VCCPLO CYR2 0x00 Yes CYR2 CYR2 CYL CYL CYL CYR1 CYR1 CYR1 0x00 Yes 7 6 5 4 3 2 1 0 0xFF 7 6 5 4 3 2 1 0 0xFF 7 6 5 4 3 2 1 0 0xFF 7 6 5 4 3 2 1 0 0x68 7 6 5 4 3 2 1 0 0x41 VER VER VER VER STP STP STP STP 0x70 VCC TODIS FSPDIS VxI FSPD RDY LOCK STRT 0x01 Rev. 0| Page 59 of 80 Lockable? Yes ADT7467 Address 0x41 R/W R 0x42 R 0x46 0x47 0x48 0x49 0x4E R/W R/W R/W R/W R/W 0x4F R/W 0x50 R/W 0x51 R/W 0x52 R/W 0x53 R/W 0x54 R/W 0x55 R/W 0x56 R/W 0x57 R/W 0x58 R/W 0x59 R/W 0x5A R/W 0x5B R/W 0x5C R/W 0x5D R/W 0x5E R/W 0x5F R/W 0x60 R/W Description Interrupt Status Register 1 Interrupt Status Register 2 VCCP Low Limit VCCP High Limit VCC Low Limit VCC High Limit Remote 1 Temp Low Limit Remote 1 Temp High Limit Local Temp Low Limit Local Temp High Limit Remote 2 Temp Low Limit Remote 2 Temp High Limit TACH1 Minimum Low Byte TACH1 Minimum High Byte TACH2 Minimum Low Byte TACH2 Minimum High Byte TACH3 Minimum Low Byte TACH3 Minimum High Byte TACH4 Minimum Low Byte TACH4 Minimum High Byte PWM1 Configuration Register PWM2 Configuration Register PWM3 Configuration Register Remote 1 TRANGE/PWM1 Frequency Local TRANGE/PWM2 Frequency Bit 7 OOL Bit 6 R2T Bit 5 LT Bit 4 R1T Bit 3 RES Bit 2 VCC Bit 1 VCCP Bit 0 RES Default 0x00 D2 D1 F4P FAN3 FAN2 FAN1 OVT RES 0x00 7 7 7 7 7 6 6 6 6 6 5 5 5 5 5 4 4 4 4 4 3 3 3 3 3 2 2 2 2 2 1 1 1 1 1 0 0 0 0 0 0x00 0xFF 0x00 0xFF 0x01 7 6 5 4 3 2 1 0 0x7F 7 6 5 4 3 2 1 0 0x01 7 6 5 4 3 2 1 0 0x7F 7 6 5 4 3 2 1 0 0x01 7 6 5 4 3 2 1 0 0x7F 7 6 5 4 3 2 1 0 0xFF 15 14 13 12 11 10 9 8 0xFF 7 6 5 4 3 2 1 0 0xFF 15 14 13 12 11 10 9 8 0xFF 7 6 5 4 3 2 1 0 0xFF 15 14 13 12 11 10 9 8 0xFF 7 6 5 4 3 2 1 0 0xFF 15 14 13 12 11 10 9 8 0xFF BHVR BHVR BHVR INV SLOW SPIN SPIN SPIN 0x82 Yes BHVR BHVR BHVR INV SLOW SPIN SPIN SPIN 0x82 Yes BHVR BHVR BHVR INV SLOW SPIN SPIN SPIN 0x82 Yes RANGE RANGE RANGE RANGE THRM FREQ FREQ FREQ 0XC4 Yes RANGE RANGE RANGE RANGE THRM FREQ FREQ FREQ 0XC4 Yes Rev. 0 | Page 60 of 80 Lockable? ADT7467 Address 0x61 R/W R/W 0x62 R/W 0x63 R/W 0x64 R/W 0x65 R/W 0x66 R/W 0x67 R/W 0x68 R/W 0x69 R/W 0x6A R/W 0x6B R/W 0x6C R/W 0x6D R/W 0x6E R/W 0x6F R/W 0x70 R/W 0x71 R/W 0x72 R/W 0x73 R/W 0x74 R/W 0x75 R/W 0x76 R/W 0x77 R/W 0x78 R/W 0x79 R 0x7A R/W 0x7B R/W Description Remote 2 TRANGE/PWM3 Frequency Enhance Acoustics Reg 1 Enhance Acoustics Reg 2 PWM1 Min Duty Cycle PWM2 Min Duty Cycle PWM3 Min Duty Cycle Remote 1 Temp TMIN Local Temp TMIN Remote 2 Temp TMIN Remote 1 THERM Temp Limit Local THERM Temp Limit Remote 2 THERM Temp Limit Remote 1 and Local Temp/TMIN Hysteresis Remote 2 Temp/TMIN Hysteresis XNOR Tree Test Enable Remote 1 Temperature Offset Local Temperature Offset Remote 2 Temperature Offset Configuration Register 2 Interrupt Mask 1 Register Interrupt Mask 2 Register Extended Resolution 1 Extended Resolution 2 Configuration Register 3 THERM Timer Status Register THERM Timer Limit Register TACH Pulses per Revolution Bit 7 RANGE Bit 6 RANGE Bit 5 RANGE Bit 4 RANGE Bit 3 THRM Bit 2 FREQ Bit 1 FREQ Bit 0 FREQ Default 0XC4 Lockable? Yes MIN3 MIN2 MIN1 SYNC EN1 ACOU ACOU ACOU 0X00 Yes EN2 ACOU2 ACOU2 ACOU2 EN3 ACOU3 ACOU3 ACOU3 0X00 Yes 7 6 5 4 3 2 1 0 0X80 Yes 7 6 5 4 3 2 1 0 0X80 Yes 7 6 5 4 3 2 1 0 0X80 Yes 7 6 5 4 3 2 1 0 0X9A Yes 7 6 5 4 3 2 1 0 0X9A Yes 7 6 5 4 3 2 1 0 0X9A Yes 7 6 5 4 3 2 1 0 0XA4 Yes 7 6 5 4 3 2 1 0 0XA4 Yes 7 6 5 4 3 2 1 0 0XA4 Yes HYSR1 HYSR1 HYSR1 HYSR1 HYSL HYSL HYSL HYSL 0X44 Yes HYSR2 HYSR2 HYSR2 HYRS RES RES RES RES 0X40 Yes RES RES RES RES RES RES RES XEN 0X00 Yes 7 6 5 4 3 2 1 0 0X00 Yes 7 6 5 4 3 2 1 0 0X00 Yes 7 6 5 4 3 2 1 0 0X00 Yes SHDN CONV ATTN AVG AIN4 AIN3 AIN2 AIN1 0X00 Yes OOL R2T LT RIT RES VCC VCCP RES 0X00 D2 D1 F4P FAN3 FAN2 FAN1 OVT RES 0X00 RES RES VCC VCC VCCP VCCP RES RES 0X00 TDM2 TDM2 LTMP LTMP TDM1 TDM1 RES RES 0X00 DC4 DC3 DC2 DC1 FAST BOOST THERM 0X00 TMR TMR TMR TMR TMR TMR TMR ALERT Enable ASRT/T MRO LIMT LIMT LIMT LIMT LIMT LIMT LIMT LIMT 0X00 FAN4 FAN4 FAN3 FAN3 FAN2 FAN2 FAN1 FAN1 0X55 Rev. 0| Page 61 of 80 0X00 Yes ADT7467 Address 0x7C RW R/W 0x7D R/W 0x7E 0x7F R R Description Configuration Register 5 Configuration Register 4 Test Register 1 Test Register 2 Bit 7 RES Bit 6 RES Bit 5 RES Bit 4 RES Bit 3 GPIOP Bit 2 GPIOD RES RES BpAtt RES AINL AINL VCCP DO NOT WRITE TO THESE REGISTERS DO NOT WRITE TO THESE REGISTERS Bit 1 LF/HF Pin 9 Func Bit 0 Twos Compl Pin 9 Func Default 0X00 Lockable? Yes 0X00 Yes 0X00 0X00 Yes Yes Table 17. Voltage Reading Registers (Power-On Default = 0x00)1 Register Address 0x21 0x22 R/W Read-only Read-only Description Reflects the voltage measurement2 at the VCCP input on Pin 14 (8 MSBs of reading). Reflects the voltage measurement3 at the VCC input on Pin 3 (8 MSBs of reading). 1 If the extended resolution bits of these readings are also being read, the extended resolution registers (Reg. 0x76, 0x77) must be read first. Once the extended resolution registers have been read, the associated MSB reading registers are frozen until read. Both the extended resolution registers and the MSB registers are frozen. 2 If VCCPLow (Bit 1 of the Dynamic TMIN Control Register 1, 0x36) is set, VCCP can control the sleep state of the ADT7467. 3 VCC (Pin 3) is the supply voltage for the ADT7467. Table 18. Temperature Reading Registers (Power-On Default = 0x01)1, 2 Register Address 0x25 0x26 0x27 R/W Read-only Read-only Read-only Description Remote 1 temperature reading3, 4 (8 MSB of reading). Local temperature reading (8 MSB of reading). Remote 2 temperature reading (8 MSB of reading). 1 These temperature readings can be in twos complement or Offset 64 format; this interpretation is determined by Bit 0 of Configuration Register 5 (0x7C). If the extended resolution bits of these readings are also being read, the extended resolution registers (Reg. 0x76, 0x77) must be read first. Once the extended resolution registers have been read, all associated MSB reading registers get frozen until read. Both the extended resolution registers and the MSB registers are frozen. 3 In twos complement mode, a temperature reading of −128°C (0x80) indicates a diode fault (open or short) on that channel. 4 In Offset 64 mode, a temperature reading of −64°C (0x00) indicates a diode fault (open or short) on that channel. 2 Table 19. Fan Tachometer Reading Registers (Power-On Default = 0x00)1 Register Address 0x28 0x29 0x2A 0x2B 0x2C 0x2D 0x2E 0x2F R/W Read-only Read-only Read-only Read-only Read-only Read-only Read-only Read-only Description TACH1 low byte. TACH1 high byte. TACH2 low byte. TACH2 high byte. TACH3 low byte. TACH3 high byte. TACH4 low byte. TACH4 high byte. 1 These registers count the number of 11.11 µs periods (based on an internal 90 kHz clock) that occur between a number of consecutive fan TACH pulses (default = 2). The number of TACH pulses used to count can be changed using the fan pulses per revolution register (Reg. 0x7B). This allows the fan speed to be accurately measured. Because a valid fan tachometer reading requires that two bytes are read, the low byte must be read first. Both the low and high bytes are then frozen until read. At power-on, these registers contain 0x0000 until such time as the first valid fan TACH measurement is read into these registers. This prevents false interrupts from occurring while the fans are spinning up. A count of 0xFFFF indicates that a fan is one of the following: • Stalled or blocked (object jamming the fan). • Failed (internal circuitry destroyed). • Not populated. (The ADT7467 expects to see a fan connected to each TACH. If a fan is not connected to that TACH, its TACH minimum high and low bytes should be set to 0xFFFF.) • Alternate function, for example, TACH4 reconfigured as THERM pin. • 2-wire instead of 3-wire fan. Table 20. Current PWM Duty Cycle Registers (Power-On Default = 0x00)1 Register Address 0x30 0x31 0x32 1 R/W Read/write Read/write Read/write Description PWM1 current duty cycle (0% to 100% duty cycle = 0x00 to 0xFF). PWM2 current duty cycle (0% to 100% duty cycle = 0x00 to 0xFF). PWM3 current duty cycle (0% to 100% duty cycle = 0x00 to 0xFF). These registers reflect the PWM duty cycle driving each fan at any given time. When in automatic fan speed control mode, the ADT7467 reports the PWM duty cycles back through these registers. The PWM duty cycle values vary according to temperature in automatic fan speed control mode. During fan startup, these registers report back 0x00. In software mode, the PWM duty cycle outputs can be set to any duty cycle value by writing to these registers. Rev. 0 | Page 62 of 80 ADT7467 Table 21. Operating Point Registers (Power-On Default = 0x64)1, 2, 3 Register Address 0x33 0x34 0x35 R/W3 Read/write Read/write Read/write Description Remote 1 operating point register (default = 100°C). Local temperature operating point register (default = 100°C). Remote 2 operating point register (default = 100°C). 1 These registers set the target operating point for each temperature channel when the dynamic TMIN control feature is enabled. The fans being controlled are adjusted to maintain temperature about an operating point. 3 These registers become read-only when the Configuration Register 1 lock bit is set to 1. Any subsequent attempts to write to these registers fail. 2 Table 22. Register 0x36—Dynamic TMIN Control Register 1 (Power-On Default = 0x00)1 Bit <0> Name CYR2 R/W Read/write <1> VCCPLO Read/write <2> PHTR1 Read/write <3> PHTL Read/write <4> PHTR2 Read/write <5> R1T Read/write <6> LT Read/write <7> R2T Read/write 1 Description MSB of 3-Bit Remote 2 Cycle Value. The other two bits of the code reside in Dynamic TMIN Control Register 2 (Reg. 0x37). These three bits define the delay time between making subsequent TMIN adjustments in the control loop, in terms of the number of monitoring cycles. The system has associated thermal time constants that need to be found to optimize the response of fans and the control loop. VCCPLO = 1. When the power is supplied from 3.3 V STANDBY and the core voltage (VCCP) drops below its VCCP low limit value (Reg. 0x46), the following occurs: • Status Bit 1 in Status Register 1 is set. • SMBALERT is generated, if enabled. • PROCHOT monitoring is disabled. • Dynamic TMIN control is disabled. • The device is prevented from entering shutdown. • Everything is re-enabled once VCCP increases above the VCCP low limit. PHTR1 = 1 copies the Remote 1 current temperature to the Remote 1 operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted, allowing the system to run as quietly as possible without affecting system performance. PHTR1 = 0 ignores any THERM assertions on the THERM pin. The Remote 1 operating point register reflects its programmed value. PHTL = 1 copies the local channel’s current temperature to the local operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted. This allows the system to run as quietly as possible without affecting system performance. PHTL = 0 ignores any THERM assertions on the THERM pin. The local temperature operating point register reflects its programmed value. PHTR2 = 1 copies the Remote 2 current temperature to the Remote 2 operating point register, if THERM is asserted. The operating point contains the temperature at which THERM is asserted, allowing the system to run as quietly as possible without affecting system performance. PHTR2 = 0 ignores any THERM assertions on the THERM pin. The Remote 2 operating point register reflects its programmed value. R1T = 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. R1T = 0 disables dynamic TMIN control. The TMIN value chosen is not adjusted, and the channel behaves as described in the Fan Speed Control section. LT=1 enables dynamic TMIN control on the local temperature channel. The chosen TMIN value is dynamically adjusted based on the current temperature, operating point, and high and low limits for this zone. LT = 0 disables dynamic TMIN control. The TMIN value chosen is not adjusted, and the channel behaves as described in the Fan Speed Control section. R2T = 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. R2T = 0 disables dynamic TMIN control. The TMIN value chosen is not adjusted and the channel behaves as described in the Fan Speed Control section. This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any subsequent attempts to write to this register fail. Rev. 0| Page 63 of 80 ADT7467 Table 23. Register 0x37—Dynamic TMIN Control Register 2 (Power-On Default = 0x00)1 Bit <2:0> <5:3> <7:6> Name CYR1 R/W Read/write CYL Bits 000 001 010 011 100 101 110 111 Read/write CYR2 Bits 000 001 010 011 100 101 110 111 Read/write Bits 000 001 010 011 100 101 110 111 1 Description 3-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 channel, in terms of number of monitoring cycles. The system has associated thermal time constants that need to be found to optimize the response of fans and the control loop. Decrease Cycle Increase Cycle 8 cycles (1 s) 16 cycles (2 s) 16 cycles (2 s) 32 cycles (4 s) 32 cycles (4 s) 64 cycles (8 s) 64 cycles (8 s) 128 cycles (16 s) 128 cycles (16 s) 256 cycles (32 s) 256 cycles (32 s) 512 cycles (64 s) 512 cycles (64 s) 1024 cycles (128 s) 1024 cycles (128 s) 2048 cycles (256 s) 3-Bit Local Temperature Cycle Value. These three bits define the delay time between making subsequent TMIN adjustments in the control loop for the local temperature channel, in terms of number of monitoring cycles. The system has associated thermal time constants that need to be found to optimize the response of fans and the control loop. Decrease Cycle Increase Cycle 8 cycles (1 s) 16 cycles (2 s) 16 cycles (2 s) 32 cycles (4 s) 32 cycles (4 s) 64 cycles (8 s) 64 cycles (8 s) 128 cycles (16 s) 128 cycles (16 s) 256 cycles (32 s) 256 cycles (32 s) 512 cycles (64 s) 512 cycles (64 s) 1024 cycles (128 s) 1024 cycles (128 s) 2048 cycles (256 s) 2 LSBs of 3-Bit Remote 2 Cycle Value. The MSB of the 3-bit code resides in Dynamic TMIN Control Register 1 (Reg. 0x36). These three bits define the delay time between making subsequent TMIN adjustments in the control loop for the Remote 2 channel, in terms of number of monitoring cycles. The system has associated thermal time constants that need to be found to optimize the response of fans and the control loop. Decrease Cycle 8 cycles (1 s) 16 cycles (2 s) 32 cycles (4 s) 64 cycles (8 s) 128 cycles (16 s) 256 cycles (32 s s) 512 cycles (64 s) 1024 cycles (128 s) Increase Cycle 16 cycles (2 s) 32 cycles (4 s) 64 cycles (8 s) 128 cycles (16 s) 256 cycles (32 s) 512 cycles (64 s) 1024 cycles (128 s) 2048 cycles (256 s) This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any subsequent attempts to write to this register fail. Table 24. Maximim PWM Duty Cycle (Power-On Default = 0xFF)1, 2 Register Address 0x38 0x39 0x3A 1 2 R/W2 Read/write Read/write Read/write Description Maximum duty cycle for PWM1 output, default = 100% (0xFF). Maximum duty cycle for PWM2 output, default = 100% (0xFF). Maximum duty cycle for PWM3 output, default = 100% (0xFF). These registers set the maximum PWM duty cycle of the PWM output . This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any subsequent attempts to write to this register fail. Rev. 0 | Page 64 of 80 ADT7467 Table 25. Register 0x40—Configuration Register 1 (Power-On Default = 0x01) Bit <0> Name STRT R/W Read/write <1> LOCK Write once <2> RDY Read-only <3> FSPD Read/write <4> VxI Read/write <5> FSPDIS Read/write <6> TODIS Read/write <7> VCC Read/write Description Logic 1 enables monitoring and PWM control outputs based on the limit settings programmed. Logic 0 disables monitoring and PWM control based on the default power-up limit settings. Note that the limit values programmed are preserved even if a Logic 0 is written to this bit and the default settings are enabled. This bit becomes read-only and cannot be changed once Bit 1 (LOCK bit) has been written. All limit registers should be programmed by BIOS before setting this bit to 1. (Lockable.) Logic 1 locks all limit values to their current settings. Once this bit is set, all lockable registers become readonly and cannot be modified until the ADT7467 is powered down and powered up again. This prevents rogue programs such as viruses from modifying critical system limit settings. (Lockable.) This bit is set to 1 by the ADT7467 to indicate only that the device is fully powered up and ready to begin system monitoring. When set to 1, this bit runs all fans at full speed. Power-on default = 0. This bit does not get locked at any time. BIOS should set this bit to a 1 when the ADT7467 is configured to measure current from an ADI ADOPT™ VRM controller and to measure the CPU’s core voltage. This bit allows monitoring software to display CPU watts usage. (Lockable.) Logic 1 disables fan spin-up for two TACH pulses. Instead, the PWM outputs go high for the entire fan spinup timeout selected. When this bit is set to 1, the SMBus timeout feature is enabled. This allows the ADT7467 to be used with SMBus controllers that cannot handle SMBus timeouts. (Lockable.) When this bit is set to 1, the ADT7467 rescales its VCC pin to measure 5 V supply. If this bit is 0, the ADT7467 measures VCC as a 3.3 V supply. (Lockable.) Table 26. Register 0x41—Interrupt Status Register 1 (Power-On Default = 0x00) Bit <1> Name VCCP R/W Read-only <2> VCC Read-only <4> R1T Read-only <5> LT Read-only <6> R2T Read-only <7> OOL Read-only Description VCCP = 1 indicates that the VCCP high or low limit has been exceeded. This bit is cleared on a read of the status register only if the error condition has subsided. VCC = 1 indicates that the VCC high or low limit has been exceeded. This bit is cleared on a read of the status register only if the error condition has subsided. R1T = 1 indicates that the Remote 1 low or high temperature has been exceeded. This bit is cleared on a read of the status register only if the error condition has subsided. LT = 1 indicates that the local low or high temperature has been exceeded. This bit is cleared on a read of the status register only if the error condition has subsided. R2T = 1 indicates that the Remote 2 low or high temperature has been exceeded. This bit is cleared on a read of the status register only if the error condition has subsided. OOL = 1 indicates that an out-of-limit event has been latched in Status Register 2. This bit is a logical OR of all status bits in Status Register 2. Software can test this bit in isolation to determine whether any of the voltage, temperature, or fan speed readings represented by Status Register 2 are out-of-limit, which saves the need to read Status Register 2 every interrupt or polling cycle. Rev. 0| Page 65 of 80 ADT7467 Table 27. Register 0x42—Interrupt Status Register 2 (Power-On Default = 0x00) Bit <1> Name OVT R/W Read-only <2> FAN1 Read-only <3> FAN2 Read-only <4> FAN3 Read-only <5> F4P Read-only Read/write Read-only <6> <7> D1 D2 Read-only Read-only Description OVT = 1 indicates that one of the THERM overtemperature limits has been exceeded. This bit is cleared on a read of the status register when the temperature drops below THERM –THYST. FAN1 = 1 indicates that Fan 1 has dropped below minimum speed or has stalled. This bit is not set when the PWM1 output is off. FAN2 = 1 indicates that Fan 2 has dropped below minimum speed or has stalled. This bit is not set when the PWM2 output is off. FAN3 = 1 indicates that Fan 3 has dropped below minimum speed or has stalled. This bit is not set when the PWM3 output is off. F4P = 1 indicates that Fan 4 has dropped below minimum speed or has stalled. This bit is not set when the PWM3 output is off. When Pin 9 is programmed as a GPIO output, writing to this bit determines the logic output of the GPIO. If Pin 9 is configured as the THERM timer input for THERM monitoring, then this bit is set when the THERM assertion time exceeds the limit programmed in the THERM limit register (Reg. 0x7A). D1 = 1 indicates either an open or short circuit on the Thermal Diode 1 inputs. D2 = 1 indicates either an open or short circuit on the Thermal Diode 2 inputs. Table 28. Voltage Limit Registers1 Register Address 0x46 0x47 0x48 0x49 1 2 R/W Read/write Read/write Read/write Read/write Description2 VCCP low limit. VCCP high limit. VCC low limit. VCC high limit. Power-On Default 0x00 0xFF 0x00 0xFF Setting the Configuration Register 1 lock bit has no effect on these registers. High Limits: An interrupt is generated when a value exceeds its high limit (> comparison). Low Limits: An interrupt is generated when a value is equal to or below its low limit (≤ comparison). Table 29. Temperature Limit Registers1 Register Address 0x4E 0x4F 0x50 0x51 0x52 0x53 R/W Read/write Read/write Read/write Read/write Read/write Read/write Description2 Remote 1 temperature low limit. Remote 1 temperature high limit. Local temperature low limit. Local temperature high limit. Remote 2 temperature low limit. Remote 2 temperature high limit. Power-On Default 0x81 0x7F 0x81 0x7F 0x81 0x7F 1 Exceeding any of these temperature limits by 1°C causes the appropriate status bit to be set in the interrupt status register. Setting the Configuration Register 1 lock bit has no effect on these registers. 2 High Limits: An interrupt is generated when a value exceeds its high limit (> comparison). Low Limits: An interrupt is generated when a value is equal to or below its low limit (≤ comparison). Table 30. Fan Tachometer Limit Registers1 Register Address 0x54 0x55 R/W Read/write Read/write 0x56 0x57 0x58 0x59 0x5A 0x5B Read/write Read/write Read/write Read/write Read/write Read/write 1 Description TACH1 minimum low byte. TACH1 minimum high byte/single channel ADC channel select. TACH2 minimum low byte. TACH2 minimum high byte. TACH3 minimum low byte. TACH3 minimum high byte. TACH4 minimum low byte. TACH4 minimum high byte. Power-On Default 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF Exceeding any of the TACH limit registers by 1 indicates that the fan is running too slowly or has stalled. The appropriate status bit is set in Interrupt Status Register 2 to indicate the fan failure. Setting the Configuration Register 1 lock bit has no effect on these registers. Rev. 0 | Page 66 of 80 ADT7467 Table 31. Register 0x55—TACH 1 Minimum High Byte (Power-On Default = 0xFF) Bit <4:0> Name Reserved R/W Read-only <7:5> SCADC Read/write Description These bits are reserved when Bit 6 of Config 2 Register (0x73) is set (single-channel ADC mode). Otherwise, these bits represent Bits <4:0> of the TACH1 minimum high byte. When Bit 6 of Config 2 Register (0x73) is set (single-channel ADC mode), these bits are used to select the only channel from which the ADC makes measurements. Otherwise, these bits represent Bits <7:5> of the TACH1 minimum high byte. Table 32. PWM Configuration Registers Register Address 0x5C 0x5D 0x5E Bit Name <2:0> SPIN R/W1 Read/write Read/write Read/write R/W Read/write <3> <4> SLOW INV Read/write Read/write <7:5> BHVR Read/write 1 Description Power-On Default PWM1 configuration. 0x82 PWM2 configuration. 0x82 PWM3 configuration. 0x82 Description These bits control the startup timeout for PWMx. The PWM output stays high until two valid TACH rising edges are seen from the fan. If there is not a valid TACH signal during the fan TACH measurement directly after the fan startup timeout period, then the TACH measurement reads 0xFFFF and Status Register 2 reflects the fan fault. If the TACH minimum high and low bytes contain 0xFFFF or 0x0000, then the status register 2 bit is not set, even if the fan has not started. 000 = No startup timeout 001 = 100 ms 010 = 250 ms (default) 011 = 400 ms 100 = 667 ms 101 = 1 s 110 = 2 s 111 = 4 s SLOW = 1 makes the ramp rates for acoustic enhancement four times longer. This bit inverts the PWM output. The default is 0, which corresponds to a logic high output for 100% duty cycle. Setting this bit to 1 inverts the PWM output, so 100% duty cycle corresponds to a logic low output. These bits assign each fan to a particular temperature sensor for localized cooling. 000 = Remote 1 temperature controls PWMx (automatic fan control mode). 001 = local temperature controls PWMx (automatic fan control mode). 010 = Remote 2 temperature controls PWMx (automatic fan control mode). 011 = PWMx runs full speed. 100 = PWMx disabled (default). 101 = fastest speed calculated by local and Remote 2 temperature controls PWMx. 110 = fastest speed calculated by all three temperature channel controls PWMx. 111 = manual mode. PWM duty cycle registers (Reg. 0x30 to Reg. 0x32) become writable. These registers become read-only when the Configuration Register 1 lock bit is set to 1. Any subsequent attempts to write to these registers fail. Rev. 0| Page 67 of 80 ADT7467 Table 33. TEMP TRANGE/PWM Frequency Registers Register Address 0x5F 0x60 0x61 Bit Name <2:0> FREQ R/W1 Read/write Read/write Read/write R/W Read/write <3> THRM Read/write <7:4> RANGE Read/write 1 Description Power-On Default Remote 1 TRANGE/PWM1 frequency. 0xC4 Local temperature TRANGE/PWM2 frequency. 0xC4 Remote 2 TRANGE/PWM3 frequency. 0xC4 Description These bits control the PWMx frequency. 000 = 11.0 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 THRM = 1 causes the THERM pin (Pin 9) to assert low as an output when this temperature channel’s THERM limit has been exceeded by 0.25°C. The THERM pin remains asserted until the temperature is equal to or below the THERM limit. The minimum time that THERM asserts is one monitoring cycle. This allows clock modulation of devices that incorporate this feature. THRM = 0 makes the THERM pin act as an input only, for example, for Pentium 4 PROCHOT monitoring, when Pin 9 is configured as THERM. These bits determine the PWM duty cycle vs. the temperature slope for automatic fan control. 0000 = 2°C 0001 = 2.5°C 0010 = 3.33°C 0011 = 4°C 0100 = 5°C 0101 = 6.67°C 0110 = 8°C 0111 = 10°C 1000 = 13.33°C 1001 = 16°C 1010 = 20°C 1011 = 26.67°C 1100 = 32°C (default) 1101 = 40°C 1110 = 53.33°C 1111 = 80°C These registers become read-only when the Configuration Register 1 lock bit is set. Any further attempts to write to these registers have no effect. Rev. 0 | Page 68 of 80 ADT7467 Table 34. Register 0x62—Enhanced Acoustics Register 1 (Power-On Default = 0x00) Bit <2:0> Name ACOU R/W1 Read/write <3> <4> EN1 SYNC Read/write Read/write <5> MIN1 Read/write <6> MIN2 Read/write <7> MIN3 Read/write 1 Description These bits select the ramp rate applied to the PWM1 output. Instead of PWM1 jumping instantaneously to its newly calculated speed, PWM1 ramps gracefully at the rate determined by these bits. This feature enhances the acoustics of the fan being driven by the PWM1 output. Time Slot Increase Time for 33% to 100% 000 = 1 35 s 001 = 2 17.6 s 010 = 3 11.8 s 011 = 4 7s 100 = 8 4.4 s 101 = 12 3s 110 = 24 1.6 s 111 = 48 0.8 s When this bit is 1, acoustic enhancement is enabled on PWM1 output. SYNC = 1 synchronizes fan speed measurements on TACH2, TACH3, and TACH4 to PWM3. This allows up to three fans to be driven from PWM3 output and their speeds to be measured. SYNC = 0 synchronizes only TACH3 and TACH4 to PWM3 output. When the ADT7467 is in automatic fan control mode, this bit defines whether PWM1 is off (0% duty cycle) or at PWM1 minimum duty cycle when the controlling temperature is below its TMIN – hysteresis value. 0 = 0% duty cycle below TMIN – hysteresis. 1 = PWM1 minimum duty cycle below TMIN – hysteresis. When the ADT7467 is in automatic fan speed control mode, this bit defines whether PWM2 is off (0% duty cycle) or at PWM2 minimum duty cycle when the controlling temperature is below its TMIN – hysteresis value. 0 = 0% duty cycle below TMIN – hysteresis. 1 = PWM 2 minimum duty cycle below TMIN – hysteresis. When the ADT7467 is in automatic fan speed control mode, this bit defines whether PWM3 is off (0% duty cycle) or at PWM3 minimum duty cycle when the controlling temperature is below its TMIN – hysteresis value. 0 = 0% duty cycle below TMIN – hysteresis. 1 = PWM3 minimum duty cycle below TMIN – hysteresis. This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Rev. 0| Page 69 of 80 ADT7467 Table 35. Register 0x63—Enhanced Acoustics Register 2 (Power-On Default = 0x00) Bit <2:0> Name ACOU3 R/W1 Read/write <3> <6:4> EN3 ACOU2 Read/write Read/write <7> EN2 Read/write Description These bits select the ramp rate applied to the PWM3 output. Instead of PWM3 jumping instantaneously to its newly calculated speed, PWM3 ramps gracefully at the rate determined by these bits. This effect enhances the acoustics of the fan being driven by the PWM3 output. Time Slot Increase Time for 33% to 100% 000 = 1 35 s 001 = 2 17.6 s 010 = 3 11.8 s 011 = 5 7s 100 = 8 4.4 s 101 = 12 3s 110 = 24 1.6 s 111 = 48 0.8 s When this bit is 1, acoustic enhancement is enabled on PWM3 output. These bits select the ramp rate applied to the PWM2 output. Instead of PWM2 jumping instantaneously to its newly calculated speed, PWM2 ramps gracefully at the rate determined by these bits. This effect enhances the acoustics of the fans being driven by the PWM2 output. Time Slot Increase Time for 33% to 100% 000 = 1 35 s 001 = 2 17.6 s 010 = 3 11.8 s 011 = 5 7s 100 = 8 4.4 s 101 = 12 3s 110 = 24 1.6 s When this bit is 1, acoustic enhancement is enabled on PWM2 output. 1 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 36. PWM Minimum Duty Cycle Registers Register Address 0x64 0x65 0x66 Bit Name <7:0> PWM duty cycle 1 R/W1 Read/write Read/write Read/write R/W1 Read/write Description PWM1 minimum duty cycle. PWM2 minimum duty cycle. PWM3 minimum duty cycle. Description These bits define the PWMMIN duty cycle for PWMx. 0x00 = 0% duty cycle (fan off). 0x40 = 25% duty cycle. 0x80 = 50% duty cycle. 0xFF = 100% duty cycle (fan full speed). Power-On Default 0x80 (50% duty cycle) 0x80 (50% duty cycle) 0x80 (50% duty cycle) These registers become read-only when the ADT7467 is in automatic fan control mode. Table 37. TMIN Registers1 Register Address 0x67 0x68 0x69 R/W2 Read/write Read/write Read/write Description Remote 1 temperature TMIN. Local temperatue TMIN. Remote 2 temperature TMIN. 1 Power-On Default 0x5A (90°C) 0x5A (90°C) 0x5A (90°C) These are the TMIN registers for each temperature channel. When the temperature measured exceeds TMIN, the appropriate fan runs at minimum speed and increases with temperature according to TRANGE. 2 These registers become read-only when the Configuration Register 1 lock bit is set. Any further attempts to write to these registers have no effect. Rev. 0 | Page 70 of 80 ADT7467 Table 38. THERM Limit Registers1 Register Address 0x6A 0x6B 0x6C R/W2 Read/write Read/write Read/write Description Remote 1 THERM limit. Local THERM limit. Remote 2 THERM limit. Power-On Default 0x64 (100°C) 0x64 (100°C) 0x64 (100°C) If any temperature measured exceeds its THERM limit, all PWM outputs drive their fans at 100% duty cycle. This is a fail-safe mechanism incorporated to cool the system in the event of a critical overtemperature. It also ensures some level of cooling in the event that software or hardware locks up. If set to 0x80, this feature is disabled. The PWM output remains at 100% until the temperature drops below THERM Limit – Hysteresis. If the THERM pin is programmed as an output, then exceeding these limits by 0.25°C can cause the THERM pin to assert low as an output. 2 These registers become read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to these registers have no effect. 1 Table 39. Temperature/TMIN Hysteresis Registers1 Register Address 0x6D <3:0> R/W2 Read/write HYSL <7:4> HYSR1 0x6E <7:4> Read/write HYSR2 Description Remote 1 and local temperature hysteresis. Local temperature hyseresis. 0°C to 15°C of hysteresis can be applied to the local temperature AFC and dynamic TMIN control loops. Remote 1 temperature hyseresis. 0°C to 15°C of hysteresis can be applied to the Remote 1 temperature AFC and dynamic TMIN control loops. Remote 2 temperature hysteresis. Local temperature hyseresis. 0°C to 15°C of hysteresis can be applied to the local temperature AFC and dynamic TMIN control loops. Power-On Default 0x44 0x40 1 Each 4-bit value controls the amount of temperature hysteresis applied to a particular temperature channel. Once the temperature for that channel falls below its TMIN value, the fan remains running at PWMMIN duty cycle until the temperature = TMIN – hysteresis. Up to 15°C of hysteresis can be assigned to any temperature channel. The hysteresis value chosen also applies to that temperature channel, if its THERM limit is exceeded. The PWM output being controlled goes to 100%, if the THERM limit is exceeded and remains at 100% until the temperature drops below THERM – hysteresis. For acoustic reasons, it is recommended that the hysteresis value not be programmed less than 4°C. Setting the hysteresis value lower than 4°C causes the fan to switch on and off regularly when the temperature is close to TMIN. 2 These registers become read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to these registers have no effect. Table 40. XNOR Tree Test Enable Register Address 0x6F <0> R/W1 Read/write XEN <7:1> Reserved 1 Description XNOR tree test enable register. If the XEN bit is set to 1, the device enters the XNOR tree test mode. Clearing the bit removes the device from the XNOR tree test mode. Unused. Do not write to these bits. Power-On Default 0x00 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 41. Remote 1 Temperature Offset Register Address 0x70 <7:0> 1 R/W1 Read/write Read/write Description Remote 1 temperature offset. Allows a twos complement offset value to be automatically added to or subtracted from the Remote 1 temperature reading. This is to compensate for any inherent system offsets such as PCB trace resistance. LSB value = 0.5°C. Power-On Default 0x00 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Rev. 0| Page 71 of 80 ADT7467 Table 42. Local Temperature Offset Register Address 0x71 <7:0> 1 R/W1 Read/write Read/write Description Local temperature offset. Allows a twos complement offset value to be automatically added to or subtracted from the local temperature reading. LSB value = 0.5°C. Power-On Default 0x00 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 43. Remote 2 Temperature Offset Register Address 0x72 <7:0> 1 R/W1 Read/write Read/write Description Remote 2 temperature offset. Allows a twos complement offset value to be automatically added to or subtracted from the Remote 2 temperature reading. This is to compensate for any inherent system offsets such as PCB trace resistance. LSB value = 0.5°C. Power-On Default 0x00 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 44. Register 0x73—Configuration Register 2 (Power-On Default = 0x00) Bit 0 Name AIN1 R/W1 Read/write 1 AIN2 Read/write 2 AIN3 Read/write 3 AIN4 Read/write 4 AVG Read/write 5 ATTN Read/write 6 CONV Read/write 7 SHDN Read/write 1 Description AIN1 = 0, speed of 3-wire fans measured using the TACH output from the fan. AIN1 = 1, Pin 6 is reconfigured to measure the speed of 2-wire fans using an external sensing resistor and coupling capacitor. AIN voltage threshold is set via Configuration Register 4 (Reg. 0x7D). Only relevant in low frequency mode. AIN2 = 0, speed of 3-wire fans measured using the TACH output from the fan. AIN2 = 1, Pin 7 is reconfigured to measure the speed of 2-wire fans using an external sensing resistor and coupling capacitor. AIN voltage threshold is set via Configuration Register 4 (Reg. 0x7D). Only relevant in low frequency mode. AIN3 = 0, speed of 3-wire fans measured using the TACH output from the fan. AIN3 = 1, Pin 4 is reconfigured to measure the speed of 2-wire fans using an external sensing resistor and coupling capacitor. AIN voltage threshold is set via Configuration Register 4 (Reg. 0x7D). Only relevant in low frequency mode. AIN4 = 0, speed of 3-wire fans measured using the TACH output from the fan. AIN4 = 1, Pin 9 is reconfigured to measure the speed of 2-wire fans using an external sensing resistor and coupling capacitor. AIN voltage threshold is set via Configuration Register 4 (Reg. 0x7D). Only relevant in low frequency mode. AVG = 1, averaging on the temperature and voltage measurements is turned off. This allows measurements on each channel to be made much faster. ATTN = 1, the ADT7467 removes the attenuators from the VCCP input. The VCCP input can be used for other functions such as connecting up external sensors. CONV = 1, the ADT7467 is put into a single-channel ADC conversion mode. In this mode, the ADT7467 can be made to read continuously from one input only, for example, Remote 1 temperature. The appropriate ADC channel is selected by writing to bits <7:5> of TACH1 minimum high byte register (0x55). Bits <7:5> Reg. 0x55 000 Reserved 001 VCCP 010 VCC (3.3 V) 011 Reserved 100 Reserved 101 Remote 1 temperature 110 Local temperature 111 Remote 2 temperature SHDN = 1, ADT7467 goes into shutdown mode. All PWM outputs assert low (or high depending on state of INV bit) to switch off all fans. The PWM current duty cycle registers read 0x00 to indicate that the fans are not being driven. This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Rev. 0 | Page 72 of 80 ADT7467 Table 45. Register 0x74—Interrupt Mask Register 1 (Power-On Default <7:0> = 0x00) Bit 1 2 4 5 6 7 Name VCCP VCC R1T LT R2T OOL R/W Read/write Read/write Read/write Read/write Read/write Read/write Description VCCP = 1, masks SMBALERT for out-of-limit conditions on the VCCP channel. VCC = 1, masks SMBALERT for out-of-limit conditions on the VCC channel. R1T = 1, masks SMBALERT for out-of-limit conditions on the Remote 1 temperature channel. LT = 1, masks SMBALERT for out-of-limit conditions on the local temperature channel. R2T = 1, masks SMBALERT for out-of-limit conditions on the Remote 2 temperature channel. OOL = 1, masks SMBALERT for any out-of-limit condition in Status Register 2. Table 46. Register 0x75—Interrupt Mask Register 2 (Power-On Default <7:0> = 0x00) Bit 1 2 3 4 5. Name OVT FAN1 FAN2 FAN3 F4P R/W Read only Read/write Read/write Read/write Read/write 6 7 D1 D2 Read/write Read/write Description OVT = 1, masks SMBALERT for overtemperature THERM conditions. FAN1 = 1, masks SMBALERT for a Fan 1 fault. FAN2 = 1, masks SMBALERT for a Fan 2 fault. FAN3 = 1, masks SMBALERT for a Fan 3 fault. F4P = 1, masks SMBALERT for a Fan 4 fault. If the TACH4 pin is being used as the THERM input, this bit masks SMBALERT for a THERM timer event. D1 = 1, masks SMBALERT for a diode open or short on a Remote 1 channel. D2 = 1, masks SMBALERT for a diode open or short on a Remote 2 channel. Table 47. Register 0x76—Extended Resolution Register 11 Bit <3:2> <5:4> 1 Name VCCP VCC R/W Read-only Read-only Description VCCP LSBs. Holds the 2 LSBs of the 10-bit VCCP measurement. VCC LSBs. Holds the 2 LSBs of the 10-bit VCC measurement. If this register is read, this register and the registers holding the MSB of each reading are frozen until read. Table 48. Register 0x77—Extended Resolution Register 21 Bit <3:2> <5:4> <7:6> 1 Name TDM1 LTMP TDM2 R/W Read-only Read-only Read-only Description Remote 1 temperature LSBs. Holds the 2 LSBs of the 10-bit Remote 1 temperature measurement. Local temperature LSBs. Holds the 2 LSBs of the 10-bit local temperature measurement. Remote 2 temperature LSBs. Holds the 2 LSBs of the 10-bit Remote 2 temperature measurement. If this register is read, this register and the registers holding the MSB of each reading are frozen until read. Rev. 0| Page 73 of 80 ADT7467 Table 49. Register 0x78—Configuration Register 3 (Power-On Default = 0x00) Bit <0> Name ALERT R/W1 Read/write <1> THERM Read/write <2> BOOST Read/write <3> FAST Read/write <4> DC1 Read/write <5> DC2 Read/write <6> DC3 Read/write <7> DC4 Read/write Description ALERT = 1, Pin 5 (PWM2/SMBALERT) is configured as an SMBALERT interrupt output to indicate outof-limit error conditions. THERM Enable = 1 enables THERM timer monitoring functionality on Pin 9. Also determined by Bits 0 and 1 (PIN9FUNC) of Configuration Register 4. When THERM is asserted, if the fans are running and the boost bit is set, the fans run at full speed. Alternatively, THERM can be programmed so that a timer is triggered to time how long THERM has been asserted. When THERM is an input and BOOST = 1, assertion of THERM causes all fans to run at the maximum programmed duty cycle for fail-safe cooling. FAST = 1, enables fast TACH measurements on all channels. This increases the TACH measurement rate from once per second to once every 250 ms (4 ×). DC1 = 1, enables TACH measurements to be continuously made on TACH1. Fans must be driven by dc. Setting this bit prevents pulse stretching, because it is not required for DC-driven motors. DC2 = ,1 enables TACH measurements to be continuously made on TACH2. Fans must be driven by dc. Setting this bit prevents pulse stretching, because it is not required for DC-driven motors. DC3 = 1, enables TACH measurements to be continuously made on TACH3. Fans must be driven by dc. Setting this bit prevents pulse stretching, because it is not required for DC-driven motors. DC4 = 1, enables TACH measurements to be continuously made on TACH4. Fans must be driven by dc. Setting this bit prevents pulse stretching, because it is not required for DC-driven motors. 1 This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 50. Register 0x79—THERM Timer Status Register (Power-On Default = 0x00) Bit <7:1> Name TMR R/W Read-only <0> ASRT/ TMR0 Read-only Description Times how long THERM input is asserted. These seven bits read zero until the THERM assertion time exceeds 45.52 ms. This bit is set high on the assertion of the THERM input, and is cleared on read. If the THERM assertion time exceeds 45.52 ms, this bit is set and becomes the LSB of the 8-bit TMR reading. This allows THERM assertion times from 45.52 ms to 5.82 s to be reported back with a resolution of 22.76 ms. Table 51. Register 0x7A—THERM Timer Limit Register (Power-On Default = 0x00) Bit <7:0> Name LIMT R/W Read/write Description Sets maximum THERM assertion length allowed before an interrupt is generated. This is an 8-bit limit with a resolution of 22.76 ms allowing THERM assertion limits of 45.52 ms to 5.82 s to be programmed. If the THERM assertion time exceeds this limit, Bit 5 (F4P) of Interrupt Status Register 2 (Reg. 0x42) is set. If the limit value is 0x00, then an interrupt is generated immediately on the assertion of the THERM input. Rev. 0 | Page 74 of 80 ADT7467 Table 52. Register 0x7B—TACH Pulses per Revolution Register (Power-On Default = 0x55) Bit <1:0> Name FAN1 R/W Read/write <3:2> FAN2 Read/write <5:4> FAN3 Read/write <7:6> FAN4 Read/write Description Sets number of pulses to be counted when measuring Fan 1 speed. Can be used to determine fan pulses per revolution for unknown fan type. Pulses Counted 00 = 1 01 = 2 (default) 10 = 3 11 = 4 Sets number of pulses to be counted when measuring Fan 2 speed. Can be used to determine fan pulses per revolution for unknown fan type. Pulses Counted 00 = 1 01 = 2 (default) 10 = 3 11 = 4 Sets number of pulses to be counted when measuring Fan 3 speed. Can be used to determine fan pulses per revolution for unknown fan type. Pulses Counted 00 = 1 01 = 2 (default) 10 = 3 11 = 4 Sets number of pulses to be counted when measuring Fan 4 speed. Can be used to determine fan pulses per revolution for unknown fan type. Pulses Counted 00 = 1 01 = 2 (default) 10 = 3 11 = 4 Table 53. Register 0x7C—Configuration Register 5 (Power-On Default = 0x00) Bit <0> Name 2sC <1> <2> HF/LF GPIOD <3> GPIOP <4:7> RES 1 R/W1 Read/write Description 2sC = 1, sets the temperature range to twos complement temperature range. 2sC = 0, changes the temperature range to Offset 64. When this bit is changed, the ADT7467 interprets all relevant temperature register values as defined by this bit. Sets the PWM drive frequency to high frequency mode (0) or low frequency mode (1). GPIO direction. When GPIO function is enabled, this determines whether the GPIO is an input (0) or an output (1). GPIO polarity. When the GPIO function is enabled and is programmed as an output, this bit determines whether the GPIO is active low (0) or high (1). Unused. This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Rev. 0| Page 75 of 80 ADT7467 Table 54. Register 0x7D—Configuration Register 4 (Power-On Default = 0x00) Bit <1:0> Name Pin9FUNC R/W1 Read/write <3:2> AINL Read/write <4:7> <5> RES BpAttVCCP <6:7> RES 1 Description These bits set the functionality of Pin 9: 00 = TACH4 (default) 01 = Bidirectional THERM 10 = SMBALERT 11 = GPIO These two bits define the input threshold for 2-wire fan speed measurements (low frequency mode only): 00 = ±20 mV 01 = ±40 mV 10 = ±80 mV 11 = ±130 mV Unused. Bypass VCCP attenuator. When set, the measurement scale for this channel changes from 0 V (0x00) to 2.2965V (0xFF) . Unused. This register becomes read-only when the Configuration Register 1 lock bit is set to 1. Any further attempts to write to this register have no effect. Table 55. Register 0x7E—Manufacturer’s Test Register 1 (Power-On Default = 0x00) Bit <7:0> Name Reserved R/W Read-only Description Manufacturer’s test register. These bits are reserved for manufacturer’s test purposes and should not be written to under normal operation. Table 56. Register 0x7F—Manufacturer’s Test Register 2 (Power-On Default = 0x00) Bit <7:0> Name Reserved R/W Read-only Description Manufacturer’s test register. These bits are reserved for manufacturer’s test purposes and should not be written to under normal operation. Rev. 0 | Page 76 of 80 Figure 85. Rev. 0| Page 77 of 80 ALLOW SELECTED PWM TO TURN OFF WHEN TEMP IS BELOW TMIN–HYST SYNC FAN SPEED MEASUREMENTS ENABLE SELECTED PWM RAMP-UP SPEED SELECTED PWM RAMP-UP SPEED TEMPERATURE HYSTERESIS (THYST) (0x6D, 0x6E) 04498-0-044 16°C 88.2Hz 80°C 53.33°C 40°C 32°C 26.67°C 20°C 10°C 13.33°C 35.3Hz 58.8Hz 8°C 29.4Hz 44.1Hz 5°C 6.67°C 22.1Hz 4°C 14.7Hz THERM AS OVERTEMP OUTPUT THERM AS (TIMER) INPUT 667ms 1s 2s 4s 1 PULSE PER REV 2 PULSE PER REV 3 PULSE PER REV 4 PULSE PER REV XNOR Test (0x6F) THERM TEMP LIMITS (0x6A, 0x6B, 0x6C) AVERAGE TEMP AND VOLTAGE MEASUREMENTS (SEE CONFIGURATION 2, 0x73) VCCP HIGH LIMIT (0x47) VCCP LOW LIMIT (0x46) VCCP LOW (SLEEP) CYXX TMIN ADJUSTMENT CYCLE TIME ENABLE DYNAMIC TMIN CONTROL ON INDIVIDUAL CHANNEL FASTEST SPEED CALCULATED BY ALL 3 TEMPERATURE CHANNEL CONTROLS THERM GENERAL INTERRUPT FANS VOLTAGES TEMPERATURE 2048 CYCLES (256s) 1024 CYCLES (128s) 512 CYCLES (64s) 256 CYCLES (32s) 128 CYCLES (16s) 64 CYCLES (8s) 32 CYCLES (4s) 16 CYCLES (2s) DECREASE CYCLE TIME 1024 CYCLES (128s) 512 CYCLES (64s) 256 CYCLES (32s) 128 CYCLES (16s) 64 CYCLES (8s) 32 CYCLES (4s) 16 CYCLES (2s) 8 CYCLES (1s) BYPASS VCCP ATTENUATOR TMIN THYST COOLING TRANGE = SLOPE THYST MIN PWM 0% DUTY CYCLE TWOS COMPLEMENT OFFSET 64 F4P DRIVE PWM OUTPUTS HIGH/LOW T THERM HEATING AUTOMATIC FAN CONTROL TEMPERATURE GPIO POLARITY GPIO DIRECTION FAN DRIVE HIGH/LOW FREQUENCY MODE 100% DUTY CYCLE MAX PWM ±130mV ±80mV ±20mV ±40mV INPUT THRESHOLD FOR 2-WIRE FANS (AINL) GPIO SMBALERT THERM TACH 4 SMBALERT MASK INTERRUPT? (0x74,0x75) TEMPERATURE RANGE CONFIGURATION 5 (0X7C) (ONLY USED WHEN FANS ARE POWERED BY DC AND NOT PWM) SMBALERT PWM 2 SET PIN 14/20 FUNCTIONALITY THERM INTERRUPTS ON STATUS REGISTER 2 SHUTDOWN SINGLE CHANNEL ADC MODE RESCALE VCCP INPUT (5V/3.3V) AVERAGE TEMP AND VOLTAGE MEASUREMENTS MEASURE FROM 2- OR 3WIRE FANS INTERRUPT STATUS (0x41, 0x42) HARDWARE INTERRUPTS FAN FAULT DIODE FAULT. FOR REMOTE CHANNELS ONLY TEMPERATURE MEASURED IS OUT OF LIMITS THERM TIMER LIMIT HAS BEEN EXCEEDED ENABLE CONTINUOUS FAN SPEED MEASUREMENT CONFIGURE PIN 10 FAST TACH MEASUREMENTS CONFIGURATION 4 (0x7D) RESCALE VCC (5V/3.3V) RUN FANS AT FULLSPEED READY LOCK SETTINGS TEMPERATURE MEASUREMENT HIGH LIMIT LOW LIMIT (0X4E-0X53) TEMPERATURE OFFSET (0x70-0x72) SOFTWARE INTERRUPTS TEMPERATURE MEASUREMENT (0X25, 0X26,0X27) START MONITORING CONFIGURATION 1 (0X40) THERM BOOST (FAN MUST BE RUNNING) ENABLE THERM MANUAL MODE. PWM DUTY CYCLE REGISTERS (0x30-0x32) BECOME WRITABLE CHANGE CYCLE TIME INCREASE CYCLE TIME MEASUREMENT LSBs (0X77) IF THESE REGISTERS ARE USED, ALL TEMPERATURE MEASUREMENT MSB REGISTERS ARE FROZEN UNTIL ALL TEMPERATURE MEASUREMENT MSB REGISTERS ARE READ. FASTEST SPEED CALCULATED BY LOCAL AND REMOTE 2 TEMP CONTROLS SELECTED PWM DRIVE SELECTED PWM DRIVE DISABLED (DEFAULT) SELECTED PWM DRIVE RUNS FULL SPEED REMOTE 2 TEMP CONTROLS SELECTED PWM DRIVE (AFC MODE) LOCAL TEMP CONTROLS SELECTED PWM DRIVE (AFC MODE) VCC HIGH LIMIT (0x49) VCC LOW LIMIT (0x48) MEASUREMENT MSBs (0x25-0x27) VCC MEASUREMENT (0x22) REMOTE 1 TEMP CONTROLS SELECTED PWM DRIVE (AFC MODE) CONFIGURATION 3 (0x78) PHTXX CURRENT TEMPERATURE OF SELECTED CHANNEL IS COPIED TO RELEVANT OPERATING POINT REGISTER ON ASSERTION OF THERM VCCP MEASUREMENT (0x47) THERM TIMER STATUS (0x79) THERM TIMER LIMIT (0x7A) DYNAMIC TMIN CONTROL (0x36, 0x37) PWMMIN DUTY CYCLE (AUTOMATIC MODE ONLY) (0X64-0X66) PWM DUTY CYCLE (MANUAL MODE ONLY) (0x30-0x32) MAX FAN SPEED (MAX PWM DUTY CYCLE) (0x38-0x3A) ADT7467/ADT7468 PROGRAMMING BLOCK DIAGRAM PWM FREQUENCY 2.5°C 3.33°C 11.0Hz 2°C THERM IS INPUT/OUTPUT AUTOMATIC FAN CONTROL 0.8s (33%-100%) 1.6s (33%-100%) 3s (33%-100%) 400ms 100ms NO TIMEOUT 4.4s (33%-100%) FAN SPINUP TIMEOUT FAN BEHAVIOR SLOW IMPROVED ACOUSTIC RAMP-UP INVERT PWM OUTPUT 250ms (DEFAULT) FAN TACH PULSES PER REV (0x7B) PWM CONFIGURATION (0x5C-0x5E) FANTACH 16-BIT MINIMUM LIMIT (0X54-0X5B) 7s (33%-100%) 18s (33%-100%) 17.6s (33%-100%) 35s (33%-100%) TRANGE TEMP TRANGE,PWM FREQ,THERMENABLE (0x5F, 0x60, 0x61) OPERATING POINT (0x33-0x35) FAN 16-BIT MEASUREMENT (0x28-0x2F) LOW BYTE MUST BE READ FIRST. WHEN THE LOW BYTE IS READ, REGISTERS ARE LOCKED UNTIL THE ASSOCIATED HIGH BYTE IS READ. TMIN. MIN TEMP THAT CAUSES SELECTED FANS TO RUN (0x67-0x69) ENHANCE ACOUSTICS (0x62,0x63) LOCAL TEMP REMOTE TEMP2 REMOTE TEMP1 VCC PWM DUTY CYCLE/RELATIVE FAN SPEED VCCP CONFIGURATION 2 (0X73) ADT7467 ADT7467 PROGRAMMING BLOCK DIAGRAM ADT7467 OUTLINE DIMENSIONS 0.193 BSC 9 16 0.154 BSC 1 0.236 BSC 8 PIN 1 0.069 0.053 0.065 0.049 0.010 0.025 0.004 BSC COPLANARITY 0.004 0.012 0.008 SEATING PLANE 0.010 0.006 8° 0° 0.050 0.016 COMPLIANT TO JEDEC STANDARDS MO-137AB Figure 86. 16-Lead Shrink Small Outline Package [QSOP] (RQ-16) Dimensions shown in inches ORDERING GUIDE Model ADT7467ARQ ADT7467ARQ-REEL ADT7467ARQ-REEL7 Temperature Range –40°C to +120°C –40°C to +120°C –40°C to +120°C Package Description 16-Lead QSOP 16-Lead QSOP 16-Lead QSOP Rev. 0 | Page 78 of 80 Package Option RQ-16 RQ-16 RQ-16 ADT7467 NOTES Rev. 0| Page 79 of 80 ADT7467 NOTES © 2004 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D04498–0–4/04(0) Rev. 0 | Page 80 of 80