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ADT7460ARQ-REEL |ADT7460ARQREELAD ?N/a13400avaidBCOOL™ Thermal Management Controller and Voltage Monitor
ADT7460ARQZ-REEL |ADT7460ARQZREELADN/a2927avaidBCOOL™ Thermal Management Controller and Voltage Monitor
ADT7460ARQZ-REEL |ADT7460ARQZREELANALOGN/a2704avaidBCOOL™ Thermal Management Controller and Voltage Monitor


ADT7460ARQ-REEL ,dBCOOL™ Thermal Management Controller and Voltage MonitorSPECIFICATIONS A MIN MAX CC MIN MAXParameter Min Typ Max Unit Test Conditions/CommentsPOWER SUPPLYS ..
ADT7460ARQZ ,dBCOOL™ Thermal Management Controller and Voltage Monitoroverview of the automatic fancontrol circuitry on the ADT7460/ADT7463. From a sys- • PWM2 or SMBALE ..
ADT7460ARQZ ,dBCOOL™ Thermal Management Controller and Voltage MonitorAN-613aAPPLICATION NOTE • P.O. Box 9106 • Norwood, MA 02062-9106 • • • www.analog.comProgramming ..
ADT7460ARQZ-REEL ,dBCOOL™ Thermal Management Controller and Voltage MonitorAPPLICATIONSLow Acoustic Noise PCsNetworking and Telecommunications EquipmentFUNCTIONAL BLOCK DIAGR ..
ADT7460ARQZ-REEL ,dBCOOL™ Thermal Management Controller and Voltage Monitorspecifications are tested at logic levels of V = 0.8 V for a falling edge and V = 2.0 V for a risin ..
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AM26LS32PC ,Quad Differential Line Receivers 16-PDIP 0 to 70Maximum RatingsSupply Voltage 7VCommon-Mode Range ±25VDifferential Input Voltage ±25VEnable Voltage ..
AM26LS33AC , QUADRUPLE DIFFERENTIAL LINE RECEIVERS
AM26LS33ACD ,Quadruple Differential Line ReceiverFeatures 3 DescriptionThe AM26LS32Ax and AM26LS33Ax devices are1• AM26LS32A Devices Meet or Exceed ..
AM26LS33ACDR ,Quadruple Differential Line Receiver SLLS115F–OCTOBER 1980–REVISED SEPTEMBER 20165 Pin Configuration and FunctionsD, J, N, NS, and PW P ..
AM26LS33ACDR ,Quadruple Differential Line ReceiverLogic Diagram (Positive Logic)4G12G21A31Y11B62A52Y72B103A119 3Y3B144A134Y154BCopyright 2016, Texas ..
AM26LS33ACDRG4 ,Quadruple Differential Line Receiver 16-SOIC 0 to 70Maximum Ratings(1)over operating free-air temperature range (unless otherwise noted)MIN MAX UNIT(2) ..


ADT7460ARQ-REEL-ADT7460ARQZ-REEL
dBCOOL™ Thermal Management Controller and Voltage Monitor
REV.BCOOL™ Remote Thermal
Controller and Fan Controller
FEATURES
Controls and Monitors up to 4 Fan Speeds
1 On-Chip and 2 Remote Temperature Sensors
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 and 3-Wire Fan Speed Measurement
Limit Comparison of All Monitored Values
Meets SMBus 2.0 Electrical Specifications
(Fully SMBus 1.1 Compliant)
APPLICATIONS
Low Acoustic Noise PCs
Networking and Telecommunications Equipment
FUNCTIONAL BLOCK DIAGRAM
GENERAL DESCRIPTION

The ADT7460 dBCOOL controller is a thermal monitor and
multiple PWM fan controller for noise-sensitive applications
requiring active system cooling. It can monitor the temperature
of up to two remote sensor diodes, plus its own internal tempera-
ture. It can 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 ADT7460 also
provides critical thermal protection to the system using the
bidirectional THERM pin as an output to prevent system or
component overheating.
*. Patent Nos. 6,188,189; 6,169,442; 6,097,239; 5,982,221; and 5,867,012. Other patents pending.
ADT7460–SPECIFICATIONS1, 2, 3, 4
ANALOG-TO-DIGITAL CONVERTER
(INCLUDING MUX AND ATTENUATORS)
(TA = TMIN to TMAX, VCC = VMIN to VMAX, unless otherwise noted.)
ADT7460
SERIAL BUS TIMING
NOTESAll voltages are measured with respect to GND, unless otherwise specified.Typicals are at TA = 25°C and represent the most likely parametric norm.Logic inputs will accept input high voltages up to VMAX even when the 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.The delay is the time between the round robin finishing one set of measurements and starting the next.Guaranteed by design, not production tested.
Specifications subject to change without notice.
Figure 1. Diagram for Serial Bus Timing
ADT7460
ABSOLUTE MAXIMUM RATINGS*

Positive Supply Voltage (VCC) . . . . . . . . . . . . . . . . . . . . . 6.5 V
Voltage on Any Other Input or Output Pin . . . . –0.3 V to +6.5 V
Input Current at Any Pin . . . . . . . . . . . . . . . . . . . . . . . ±5 mA
Package Input Current . . . . . . . . . . . . . . . . . . . . . . . ±20 mA
Maximum Junction Temperature (TJ max) . . . . . . . . . . 150°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature, Soldering
IR Reflow Peak Temperature . . . . . . . . . . . . . . . . . . . 220°C
Lead Temperature (soldering 10 sec) . . . . . . . . . . . . . 300°C
ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1500 V
*Stresses above those listed under Absolute Maximum Ratings may cause perma-
nent 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.
CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000V readily
accumulate on the human body and test equipment and can discharge without detection. Although the
ADT7460 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.
THERMAL CHARACTERISTICS

16-Lead QSOP Package:
θJA = 150°C/W, θJC = 39°C/W
ORDERING GUIDE
PIN FUNCTION DESCRIPTIONS
PIN CONFIGURATION
ADT7460
FUNCTIONAL DESCRIPTION
General Description

The ADT7460 is a thermal monitor and multiple fan controller
for any system requiring monitoring and cooling. The device
communicates with the system via a serial System Management
Bus (SMBus). The serial bus controller has an optional address
line for device selection (Pin 9), 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 of
the ADT7460 are performed over the serial bus. In addition, two of
the pins can be reconfigured as an SMBALERT output to indicate
out-of-limit conditions.
Measurement Inputs

The device has three measurement inputs, one for voltage and
two for temperature. It can also measure its own supply voltage
and can measure ambient temperature with its on-chip tem-
perature sensor.
Pin 14 is an analog input with an on-chip attenuator and is
configured to monitor 2.5 V.
Power is supplied to the chip via Pin 3, and the system also
monitors VCC through this pin. In PCs, this pin is normally
connected to a 3.3 V standby supply. This pin can, however, be
connected to a 5 V supply and monitor it without overranging.
Remote temperature sensing is provided by the D1� and D2�
inputs, to which diode-connected, external temperature-sensing
transistors, such as a 2N3904 or CPU thermal diode, may be
connected.
The ADC also accepts input from an on-chip band gap tem-
perature sensor that monitors system ambient temperature.
Sequential Measurement

When the ADT7460 monitoring sequence is started, it cycles
sequentially through the measurement of 2.5 V input and the
temperature sensors. Measured values from these inputs are
stored in value registers. These can be read out over the serial
bus, or can be compared with programmed limits stored in the
limit registers. The results of out-of-limit comparisons are stored
in the Status registers, which can be read over the serial bus to
flag out-of-limit conditions.
ADT7460 Address Selection

Pin 8 is the dual function PWM3/ADDRESS ENABLE pin. IfPin
8 is pulled low on power-up, the ADT7460 will read the state of
Pin 9 (TACH4/ADDRESS SELECT/THERM) to determine the
ADT7460’s slave address. If Pin 8 is high on power-up, then
the ADT7460 will default to SMBus slave address 0x2E. This
function is described in more detail later.
INTERNAL REGISTERS OF THE ADT7460

A brief description of the ADT7460’s principal internal registers
is given below. More detailed information on the function of
each register is given in Tables IV to XLI.
Configuration Registers

The configuration registers provide control and configuration of
the ADT7460, including alternate pinout functionality.
Address Pointer Register

This register contains the address that selects one of the other
internal registers. When writing to the ADT7460, the first byte
of data is always a register address, which is written to the
address pointer register.
Status Registers

These registers provide the status of each limit comparison and
are used to signal out-of-limit conditions on the temperature,
voltage, or fan speed channels. If Pin 14 is configured as
SMBALERT, then this pin will assert low whenever an unmasked
status bit gets set.
Interrupt Mask Registers

These registers allow each interrupt status event to be masked
when Pin 14 is configured as an SMBALERT output.
Value and Limit Registers

The results of analog voltage input, temperature, and fan
speed measurements are stored in these registers, along with
their limit values.
Offset Registers

These registers allow each temperature channel reading to be
offset by a twos complement value written to these registers.
TMIN Registers

These registers program the starting temperature for each fan
under automatic fan speed control.
TRANGE Registers

These registers program the temperature-to-fan speed control
slope in automatic fan speed control mode for each PWM output.
Operating Point Registers

These registers define the target operating temperatures for each
thermal zone when running under dynamic TMIN control. This
function allows the cooling solution to adjust dynamically in
response to measured temperature and system performance.
Enhance Acoustics Registers

These registers allow each PWM output controlling fan to be
tweaked to enhance the system’s acoustics.
TPC 1.Remote Temperature
Error vs. Leakage Resistance
TPC 4.Local Temperature Error vs.
Actual Temperature
TPC 7.Supply Current vs.
Supply Voltage
TPC 2.Remote Temperature Error
vs. Capacitance between D+ and D–
TPC 5.Remote Temperature Error
vs. Power Supply Noise Frequency
TPC 8.Remote Temperature Error
vs. Differential Mode Noise
Frequency
TPC 3.Remote Temperature Error
vs. Actual Temperature
TPC 6.Local Temperature Error vs.
Power Supply Noise Frequency
TPC 9.Remote Temperature Error
vs. Common-Mode Noise
Frequency
ADT7460
FRONT
CHASSIS
FAN
REAR
CHASSIS
FAN

Figure 2. Recommended Implementation
RECOMMENDED IMPLEMENTATION

Configuring the ADT7460 as in Figure 2 allows the systems
designer the following features: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.VCC measured internally through Pin 3.CPU temperature measured using Remote 1 temperature
channel.Ambient temperature measured through Remote 2
temperature channel.Bidirectional THERM pin. Allows Intel Pentium 4
PROCHOT monitoring and can function as an
overtemperature THERM output.SMBALERT system interrupt output.
SERIAL BUS INTERFACE
Control of the ADT7460 is carried out using the serial System
Management Bus (SMBus). The ADT7460 is connected to this
bus as a slave device, under the control of a master controller.
The ADT7460 has a 7-bit serial bus address. When the device
is powered up with Pin 8 (PWM3/ADDRESS ENABLE) high,
the ADT7460 will have a default SMBus address of 0101110 or
0x2E. If more than one ADT7460 is to be used in a system,
then each ADT7460 should be placed in address select mode by
strapping Pin 8 low on power-up. The logic state of Pin 9 then
determines the device’s SMBus address. The logic state of these
pins is sampled upon power-up.
The device address is sampled and latched on the first valid
SMBus transaction, more precisely, on the low-to-high transition
at the beginning of the eighth SCL pulse, when the serial address
byte matches the selected slave address. The selected slave
address is chosen using the ADDRESS ENABLE/ADDRESS
SELECT pins. Any attempted changes in the address will have
no effect after this.
Table I. Address Select Mode

Figure 3. Default SMBus Address = 0x2E
Figure 4. SMBus Address = 0x2C (Pin 9 = 0)
The facility to make hardwired changes to the SMBus slave
address allows the user to avoid conflicts with other devices shar-
ing the same serial bus, for example, if more than one ADT7460
is used in a system.
The serial bus protocol operates as follows:The master initiates data transfer by establishing a start condi-
tion, defined as a high-to-low transition on the serial data
line SDA while the serial clock line SCL remains high. This
indicates that an address/data stream will follow. All slave
peripherals connected to the serial bus respond to the start
condition and shift in the next eight bits, consisting of a 7-bit
address (MSB first) plus a R/W bit, which determines the
direction of the data transfer, i.e., whether data will be written
to or read from the slave device.
Figure 5. SMBus Address = 0x2D (Pin 9 = 1)
Figure 6. Unpredictable SMBus Address if Pin 8 Is
Unconnected
The peripheral whose address corresponds to the transmitted
address responds by pulling the data line low during the low
period before the ninth clock pulse, known as the Acknowl-
edge Bit. All other devices on the bus now remain idle while
the selected device waits for data to be read from or written
to it. If the R/W bit is a 0, then the master will write to the
slave device. If the R/W bit is a 1, the master will read from
the slave device.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, as a low-to-high transition when the
clock is high may 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.When all data bytes have been read or written, stop conditions
are established. In write mode, the master will pull the data
line high during the 10th clock pulse to assert a stop condition.
In read mode, the master device will override the acknowl-
edge bit by pulling the data line high during the low period
before the ninth clock pulse. This is known as No Acknowledge.
The master will then take the data line low during the low
period before the 10th clock pulse, then high during the
ADT7460
Figure 7. Writing a Register Address to the Address Pointer Register, Then Writing Data to the Selected Register
Any number of bytes of data may 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.
In the case of the ADT7460, 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.
This is illustrated in Figure 7. The device address is sent over
the bus followed by R/W being set to 0. This is followed by two
data bytes. The first data byte is the address of the internal data
register to be written to, which is stored in the address pointer
register. The second data byte is the data to be written to the
internal data register.
When reading data from a register, there are two possibilities:If the ADT7460’s address pointer register value is unknown
or not the desired value, it is first necessary to set it to the
correct value before data can be read from the desireddata
register. This is done by performing a write to the ADT7460
as before, but only the data byte containing the register address
is sent as data is not to be written to the register. This is
shown in Figure 8.
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 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, so Figure 8 can be omitted.
Notes
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.In Figures 7 to 9, the serial bus address is shown as the
default value 01011(A1)(A0), where A1 and A0 are set by
the address select mode function previously defined.In addition to supporting the Send Byte and Receive Byte
protocols, the ADT7460 also supports the Read Byte protocol
(see System Management Bus specifications Rev. 2.0 for
more information).If it is required to perform several read or write operations in
succession, the master can send a repeat start condition
instead of a stop condition to begin a new operation.
Figure 8. Writing to the Address Pointer Register Only
SCL
SDA
NO ACK. BY
MASTER
STOP BY
MASTER
START BY
MASTERFRAME 1
SERIAL BUS ADDRESS
BYTE
FRAME 2
DATA BYTE FROM ADT7460 1
ACK. BY
ADT7460

Figure 9. Reading Data from a Previously Selected Register
ADT7460
ADT7460 WRITE OPERATIONS

The SMBus specification defines several protocols for different
types of read and write operations. The ones used in the
ADT7460 are discussed below. The following abbreviations are
used in the diagrams:
S – STARTSTOPREAD
W –WRITEACKNOWLEDGE–NO ACKNOWLEDGE
The ADT7460 uses the following SMBus write protocols:
Send Byte

In this operation, the master device sends a single command
byte to a slave device as follows:The master device asserts a start condition on SDA.The master sends the 7-bit slave address followed by the
write bit (low).The addressed slave device asserts ACK on SDA.The master sends a command code.The slave asserts ACK on SDA.The master asserts a stop condition on SDA and the
transaction ends.
For the ADT7460, the send byte protocol is used to write a
register address to RAM for a subsequent single byte read from
the same address. This is illustrated in Figure 10.
Figure 10. Setting a Register Address for
Subsequent Read
If it is required to read data from the register immediately after
setting up the address, the master can assert a repeat start con-
dition 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:The master device asserts a start condition on SDA.The master sends the 7-bit slave address followed by the
write bit (low).The addressed slave device asserts ACK on SDA.The master sends a command code.The slave asserts ACK on SDA.The master sends a data byte.The slave asserts ACK on SDA.The master asserts a stop condition on SDA to end the
transaction.
This is illustrated in Figure 11.
Figure 11. Single Byte Write to a Register
ADT7460 READ OPERATIONS

The ADT7460 uses the following SMBus read protocols:
Receive Byte

This is useful when repeatedly reading a single register. The
register address needs to have been set up previously. In this
operation, the master device receives a single byte from a slave
device as follows:The master device asserts a start condition on SDA.The master sends the 7-bit slave address followed by the
read bit (high).The addressed slave device asserts ACK on SDA.The master receives a data byte.The master asserts NO ACK on SDA.The master asserts a stop condition on SDA and the trans-
action ends.
In the ADT7460, 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.
Figure 12. 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 an interrupt output or
can be used as an SMBALERT. One or more outputs can be
connected to a common SMBALERT line connected to the
master. If a device’s SMBALERT line goes low, the following
procedure occurs:SMBALERT is pulled low.Master initiates a read operation and sends the alert response
address (ARA = 0001 100). This is a general calladdress
that must not be used as a specific device address.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 it can
be interrogated in the usual way.If more than one device’s SMBALERT output is low, the
one with the lowest device address will have priority in
accordance with normal SMBus arbitration.Once the ADT7460 has responded to the alert response
address, the master must read the status registers and the
SMBALERT will be cleared only if the error condition has
gone away.
SMBus Timeout
The ADT7460 includes an SMBus timeout feature. If there is
no SMBus activity for 35 ms, the ADT7460 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.
CONFIGURATION REGISTER 1 (REG. 0x40)
<6> TODIS = 0; SMBus Timeout Enabled (Default)
<6> TODIS = 1; SMBus Timeout Disabled
VOLTAGE MEASUREMENT INPUT

The ADT7460 has one external voltage measurement channel.
It can also measure its own supply voltage, VCC.
Pin 14 may be configured to measure a 2.5 V supply. 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 ADT7460 and be measured
without overranging the VCC measurement channel. The 2.5 V
input can be used to monitor a chipset supply voltage in
computer systems.
ANALOG-TO-DIGITAL CONVERTER

All analog inputs are multiplexed into the on-chip, successive
approximation, analog-to-digital converter. This has a resolu-
tion 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 2.5 V
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.
INPUT CIRCUITRY

The internal structure for the 2.5 V analog input is shown in
Figure 13. The input circuit consists of an input protection diode,
an attenuator, plus a capacitor to form a first order low-pass
filter that gives the input immunity to high frequency noise.
VOLTAGE MEASUREMENT REGISTERS

Reg. 0x20 2.5 V Reading = 0x00 Default
2.5 V LIMIT REGISTERS

Associated with the 2.5 V measurement channel 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. 0x44 2.5 V Low Limit = 0x00 Default
Reg. 0x45 2.5 V High Limit = 0xFF Default
Figure 13. Structure of Analog Inputs
Table II 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 711 µs and averages 16 conversions to reduce noise;measurement takes nominally 11.38 ms.
ADT7460
Table II.10-Bit A/D Output Code vs. VIN

<0.0065
•••••
•••••
•••••
•••••
•••••
•••••
•••••
•••••
•••••
•••••
•••••
•••••
*The VCC output codes listed assume that VCC is 3.3 V. If VCC input is reconfigured for 5 V operation (by setting Bit 7 of Configuration Register 1), then the VCC
output codes are the same as for the 5 VIN column.
ADDITIONAL ADC FUNCTIONS FOR VOLTAGE
MEASUREMENTS

A number of other functions are available on the ADT7460 to
offer the systems 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. There may
be an instance where you would like to speed up conversions.
Setting Bit 4 of Configuration Register 2 (Reg. 0x73) turns aver-
aging off. This effectively gives a reading 16 times faster (711 µs),
but the reading may be noisier.
Bypass Voltage Input Attenuator

Setting Bit 5 of Configuration Register 2 (Reg. 0x73) removes
the attenuation circuitry from the 2.5 V input. This allows the
user to directly connect external sensors or 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.
Single-Channel ADC Conversion

Setting Bit 6 of Configuration Register 2 (Reg. 0x73) places the
ADT7460 into single-channel ADC conversion mode. In this
mode, the ADT7460 can be made to read a single voltage chan-
nel only. If the internal ADT7460 clock is used, the selected
input will be read every 711 µs. The appropriate ADC channel
is selected by writing to Bits <7:5> of the TACH1 Minimum
High Byte Register (0x55).
Bits <7:5> Reg. 0x55Channel Selected

0002.5 V
010VCC
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
TEMPERATURE MEASUREMENT SYSTEM
Local Temperature Measurement

The ADT7460 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 0x26). As both positive and negative temperatures can be
measured, the temperature data is stored in twos complement
format, as shown in Table III. Theoretically, the temperature sensor
and ADC can measure temperatures from –128�C to +127�C
with a resolution of 0.25�C. However, this exceeds the operating
temperature range of the device, so local temperature measure-
ments outside this range are not possible.
Remote Temperature Measurement

The ADT7460 can measure the temperature of two remote diode
sensors or diode-connected transistors connected to Pins 12 and
13, or Pins 10 and 11.
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 calibra-
tion is required to null this out, so the technique is unsuitable
for mass production. The technique used in the ADT7460 is to
measure the change in VBE when the device is operated at two
different currents.
This is given by
where:
K is Boltzmann’s constant.
q is the charge on the carrier.
T is the absolute temperature in Kelvins.
N is the ratio of the two currents.
Figure 14 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 equally well be a
discrete transistor, such as a 2N3904.
Figure 14. Signal Conditioning for Remote Diode Temperature Sensors
ADT7460
If a discrete transistor is used, the collector will not be 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. Figures 15a and 15b
show how to connect the ADT7460 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.
To measure ∆VBE, the sensor is switched between operating cur-
rents of I and N � I. The resulting waveform is passed through
a 65kHz low-pass filter to remove noise and to a chopper-
stabilized amplifier that performs the functions of amplification
and rectification of the waveform to produce a dc voltage
proportional to ∆VBE. This voltage is measured by the ADC to
give a temperature output in 10-bit, twos complement format. To
further reduce the effects of noise, digital filtering is performed
by averaging the results of 16 measurement cycles. A remote
temperature measurement takes nominally 25.5 ms. The results
of remote temperature measurements are stored in 10-bit, twos
complement format, as illustrated in Table III. The extra resolu-
tion 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.
Table III.Temperature Data Format

*Bold denotes 2 LSBs of measurement in Extended
Resolution Register 2 (Reg. 0x77) with 0.25�C resolution.
Figure 15a. Measuring Temperature Using an
NPN Transistor
Figure 15b. Measuring Temperature Using a
PNP Transistor
Nulling Out Temperature Errors

As CPUs run faster, it is getting more difficult to avoid high fre-
quency clocks when routing the D+, D– traces around a system
board. Even when recommended layout guidelines are followed,
there may still be temperature errors attributed to noise being
coupled onto the D+/D– lines. High frequency noise generally has
the effect of giving temperature measurements that are too high
by a constant amount. The ADT7460 has temperature offset reg-
isters at Addresses 0x70, 0x72 for the Remote 1 and Remote2
temperature channels. By doing a one-time calibration of the system,
one can determine the offset caused by system board noise and
null it out using the offset registers. The offset registers automati-
cally add a twos complement 8-bit reading to every temperature
measurement. The LSB adds 0.25°C offset to the temperature
reading so the 8-bit register effectively allows temperature offsets
of up to �32�C with a resolution of 0.25�C. This ensures that
the readings in the temperature measurement registers are as
accurate as possible.
Temperature Offset Registers

Reg. 0x70 Remote 1 Temp Offset = 0x00 (0°C Default)
Reg. 0x71 Local Temp Offset = 0x00 (0°C Default)
Reg. 0x72 Remote 2 Temp Offset = 0x00 (0°C Default)
TEMPERATURE MEASUREMENT REGISTERS
Reg. 0x25 Remote 1 Temperature = 0x80 Default
Reg. 0x26 Local Temperature = 0x80 Default
Reg. 0x27 Remote 2 Temperature = 0x80 Default
Reg. 0x77 Extended Resolution 2 = 0x00 Default
<7:6> TDM2 = Remote 2 Temperature LSBs
<5:4> LTMP = Local Temperature LSBs
<3:2> TDM1 = Remote 1 Temperature LSBs
Temperature Measurement Limit Registers

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.
Reg. 0x4E Remote 1 Temp Low Limit = 0x81 Default
Reg. 0x4F Remote 1 Temp High Limit = 0x7F Default
Reg. 0x50 Local Temp Low Limit = 0x81 Default
Reg. 0x51 Local Temp High Limit = 0x7F Default
Reg. 0x52 Remote 2 Temp Low Limit = 0x81 Default
Reg. 0x53 Remote 2 Temp High Limit = 0x7F Default
Reading Temperature from the ADT7460

It is important to note that temperature can be read from the
ADT7460 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.
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 regis-
ters have been read from. This prevents an MSB reading from
being updated while its 2 LSBs are being read, and vice versa.
ADDITIONAL ADC FUNCTIONS FOR TEMPERATURE
MEASUREMENT

A number of other functions are available on the ADT7460 to
offer the systems 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 may be necessary to take a very fast measurement, e.g., of
CPU temperature. Setting Bit 4 of Configuration Register2
(Reg. 0x73) turns averaging off. This takes a reading every
15.5ms. Each remote temperature measurement takes 4ms and
the local temperature measurement takes 1.4 ms.
SINGLE-CHANNEL ADC CONVERSIONS

Setting Bit 6 of Configuration Register 2 (Reg. 0x73) places the
ADT7460 into single-channel ADC conversion mode. In this
mode, the ADT7460 can be made to read a single temperature
channel only. The appropriate ADC channel is selected by writing
to Bits <7:5> of TACH1 Minimum High Byte Register (0x55).
Bits <7:5> Reg. 0x55Channel Selected

101Remote 1 Temp
110Local Temp
111Remote 2 Temp
Configuration Register 2 (Reg. 0x73)
<4> = 1 Averaging Off
<6> = 1 Single-Channel Convert Mode
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. Registers 0x6A–0x6C are the THERM limits.
When a temperature exceeds its THERM limit, all fans will run
at 100% duty cycle. The fans will stay running at 100% until the
temperature drops below THERM – Hysteresis (this can be
disabled by setting the BOOST bit in Configuration Register3,
Bit 2, Register 0x78). The hysteresis value for that THERM
limit is the value programmed into Registers 0x6D, 0x6E
(hysteresis registers). The default hysteresis value is 4°C.
Figure 16. THERM Limit Operation
ADT7460
LIMITS, STATUS REGISTERS, AND INTERRUPTS
Limit Values

Associated with each measurement channel on the ADT7460
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.
8-Bit Limits

The following is a list of 8-bit limits on the ADT7460:
Voltage Limit Registers

Reg. 0x44 2.5 V Low Limit = 0x00 Default
Reg. 0x45 2.5 V High Limit = 0xFF Default
Reg. 0x48 VCC Low Limit = 0x00 Default
Reg. 0x49 VCC High Limit = 0xFF Default
Temperature Limit Registers

Reg. 0x4E Remote 1 Temp Low Limit = 0x81 Default
Reg. 0x4F Remote 1 Temp High Limit = 0x7F Default
Reg. 0x6A Remote 1 THERMTHERMTHERMTHERMTHERM Limit = 0x64 Default
Reg. 0x50 Local Temp Low Limit = 0x81 Default
Reg. 0x51 Local Temp High Limit = 0x7F Default
Reg. 0x6B Local THERMTHERMTHERMTHERMTHERM Limit = 0x64 Default
Reg. 0x52 Remote 2 Temp Low Limit = 0x81 Default
Reg. 0x53 Remote 2 Temp High Limit = 0x7F Default
Reg. 0x6C Remote 2 THERMTHERMTHERMTHERMTHERM Limit = 0x64 Default
THERM Limit Register

Reg. 0x7A THERM Timer 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.
Since fans running under speed or stalled are normally the only
conditions of interest, only high limits exist for fan TACHs.
Since fan TACH period is actually being measured, exceeding
the limit indicates a slow or stalled fan.
Fan Limit Registers

Reg. 0x54 TACH1 Minimum Low Byte = 0xFF Default
Reg. 0x55 TACH1 Minimum High Byte = 0xFF Default
Reg. 0x56 TACH2 Minimum Low Byte = 0xFF Default
Reg. 0x57 TACH2 Minimum High Byte = 0xFF Default
Reg. 0x58 TACH3 Minimum Low Byte = 0xFF Default
Reg. 0x59 TACH3 Minimum High Byte = 0xFF Default
Reg. 0x5A TACH4 Minimum Low Byte = 0xFF Default
Reg. 0x5B TACH4 Minimum High Byte = 0xFF Default
Out-of-Limit Comparisons

Once all limits have been programmed, the ADT7460 can be
enabled for monitoring. The ADT7460 will measure all param-
eters in round-robin format and set the appropriate status bit for
out-of-limit conditions. Comparisons are done differently depending
on whether the measured value is being compared to a high or
low limit.
NO INT
LOW LIMIT
TEMP >
LOW LIMIT

Figure 17. Temperature > Low Limit: No INT
Figure 18. Temperature = Low Limit: INT Occurs
Figure 19. Temperature = High Limit: No INT
HIGH LIMIT

Figure 20. Temperature > High Limit: INT Occurs
Analog Monitoring Cycle Time

The analog monitoring cycle begins when a 1 is written to the
start bit (Bit 0) of Configuration Register 1 (Reg 0x40). The ADC
measures each analog input in turn and as each measurement is
completed, the result is automatically stored in the appropri-
ate value register. This round-robin monitoring cycle continues
unless disabled by writing a 0 to Bit 0 of Configuration Register1.
As the ADC will normally be left to free-run in this manner, the
time taken to monitor all the analog inputs will normally not be
of interest, as the most recently measured value of any input can
be read out at any time.
For applications where the monitoring cycle time is important,
it can easily be calculated.
The total number of channels measured isTwo supply voltage inputs (2.5 V and VCC)Local temperatureTwo remote temperatures
As mentioned previously, the ADC performs round-robin conver-
sions and takes 11.38 ms for each voltage measurement, 12ms
for a local temperature reading, and 25.5 ms for each remote
temperature reading.
The total monitoring cycle time for averaged voltage and tempera-
ture monitoring is, therefore, nominally
The round robin starts again 35 ms later. Therefore, all channels
are measured approximately every 120 ms.
Fan TACH measurements are made in parallel and are not
synchronized with the analog measurements in any way.
Status Registers

The results of limit comparisons are stored in Status Registers1
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 will be cleared to 0. If the measurement is out-of-limits, the
corresponding status register bit will be set to 1.
The state of the various measurement channels may 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 you
need only read Status Register 2 when this bit is set. Alternatively,
Pin 5 or Pin 14 can be configured as an SMBALERT output. This
will automatically notify the system supervisor of an out-of-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 gets set, indicating an out-of-limit condition, it will remain
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-of-limit, its associated status bit will
get set in the interrupt status registers.
ADT7460
Figure 21. Status Register 1
Status Register 1 (Reg. 0x41)
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 temp high or low limit has been

exceeded.
Bit 5 (LT) = 1, Local temp high or low limit has been exceeded.
Bit 4 (R1T) = 1, Remote 1 temp high or low limit has been

exceeded.
Bit 3 = Unused
Bit 2 (VCC) = 1, VCC high or low limit has been exceeded.
Bit 1 = Unused
Bit 0 (2.5 V) = 1, 2.5 V high or low limit has been exceeded.

Figure 22. Status Register 2
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 D2+/D2– inputs.
Bit 5 (F4P) = 1, indicates Fan 4 has dropped below minimum

speed. Alternatively, indicates that THERM timer limit has
been exceeded if the THERM timer 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.
Bit 2 (FAN1) = 1, indicates Fan 1 has dropped below minimum

speed.
Bit 1 (OVT) = 1, indicates that a THERM overtemperature

limit has been exceeded.
Bit 0 = Unused
SMBALERT Interrupt Behavior

The ADT7460 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.
Figure 23. SMBALERT and Status Bit Behavior
Figure 23 shows how the SMBALERT output and sticky status
bits behave. Once a limit is exceeded, the corresponding status
bit gets set to 1. The status bit remains set until the error condi-
tion subsides and the status register gets read. The status bits
are referred to as sticky since they remain set until read by soft-
ware. 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.
HANDLING SMBALERT INTERRUPTS

To prevent the system from being tied up servicing interrupts, it
is recommend to handle the SMBALERT interrupt as follows:Detect the SMBALERT assertion.Enter the interrupt handler.Read the status registers to identify the interrupt source.Mask the interrupt source by setting the appropriate mask bit
in the interrupt mask registers (Reg. 0x74, 0x75).Take the appropriate action for a given interrupt source.Exit the interrupt handler.Periodically poll the status registers. If the interrupt status bit
has cleared, reset the corresponding interrupt mask bit to 0.
This will cause the SMBALERT output and status bits to
behave as shown in Figure 24.
Figure 24. 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 only prevents the SMBALERT output from
being asserted; the appropriate status bit will get set as normal.
Interrupt Mask Register 1 (Reg. 0x74)
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.
Bit 4 (R1T) = 1, masks SMBALERT for Remote 1 temperature.
Bit 3 = Unused
Bit 2 (VCC) = 1, masks SMBALERT for VCC channel.
Bit 1 = Unused
Bit 0 (2.5 V) = 1, masks SMBALERT for 2.5 V channel.
Interrupt Mask Register 2 (Reg. 0x75)
Bit 7 (D2) = 1, masks SMBALERT for Diode 2 errors.
Bit 6 (D1) = 1, masks SMBALERT for Diode 1 errors.
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 limits).
Bit 0 = Unused
Enabling the SMBALERT Interrupt Output

The SMBALERT interrupt function is disabled by default. Pin5
or Pin 14 can be reconfigured as an SMBALERT output to
signal out-of-limit conditions.
Configuring Pin 5 as SMBALERT Output
RegisterBit Setting

Config Reg 4 (Reg. 0x7D)<0> AL2.5V = 1
Configuring Pin 14 as SMBALERT Output
RegisterBit Setting

Config Reg 4 (Reg. 0x7D)<0> AL2.5V = 1
To Assign THERM Functionality to Pin 9

Pin 9 can be configured as the THERM pin on the ADT7460.
To configure Pin 9 as the THERM pin, set the THERM ENABLE
Bit (Bit 1) in Configuration Register 3 (Address = 0x78) = 1.
THERM as an Input

When configured as an input, the THERM pin allows the user to
time assertions on the pin. This can be useful for connecting to
the PROCHOT output of a CPU to gauge system performance.
See this data sheet for more information on timing THERM
assertions and generating SMBALERTs based on THERM.
The user can also set up the ADT7460 so when the THERM pin
is driven low externally the fans will run at 100%. The fans will
run at 100% for the duration of the THERM pin being 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 will have no effect. See
Figure 25 for more information.
Figure 25. Asserting THERM Low as an Input in
Automatic Fan Speed Control Mode
THERM Timer

The ADT7460 has an internal timer to measure THERM
assertion time. For example, the THERM input may be connected
to the PROCHOT output of a Pentium 4 CPU and measure
system performance. The THERM input may also be connected
to the output of a trip point temperature sensor.
The timer is started on the assertion of the ADT7460’s THERM
input and stopped on the negation of the pin. The timer counts
THERM times cumulatively, i.e., the timer resumes counting
on the next THERM assertion. The THERM timer will continue
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 will stop at that reading until cleared.
The 8-bit THERM timer register (Reg. 0x79) is designed such
that Bit 0 will get 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 gets set and Bit 0 becomes the LSB
of the timer with a resolution of 22.76 ms.
Figure 26 illustrates how the THERM timer behaves as the
THERM input is asserted and negated. Bit 0 gets set on the first
ADT7460
Figure 26. Understanding the THERM Timer
When using the THERM timer, be aware of the following:After a THERM timer read (Reg. 0x79)The contents of the timer get cleared on read.The F4P bit (Bit 5) of Status Register 2 needs to be
cleared (assuming the THERM limit has been exceeded).If the THERM timer is read during a THERM assertion
a) The contents of the timer are cleared.
b) Bit 0 of the THERM timer is set to 1 (since a THERM
assertion is occurring).
c) The THERM timer increments from zero.
d) If the THERM limit (Reg. 0x7A) = 0x00, then the
F4P bit gets set.
Generating SMBALERT Interrupts from THERM Events

The ADT7460 can generate SMBALERTs when a program-
mable THERM limit has been exceeded. This allows the
systems designer to ignore brief, infrequent THERM assertions
while capturing longer THERM events. Register 0x7A is the
THERM limit register. This 8-bit register allows a limit from 0
seconds (first THERM assertion) to 5.825 seconds to be set
before an SMBALERT is generated. The THERM timer value is
compared with the contents of the THERM limit register. If the
THERM timer value exceeds the THERM limit value, then the
F4P bit (Bit 5) of Status Register 2 gets set and an SMBALERT
is generated. Note that the F4P bit (Bit 5) of Mask Register 2
(Reg. 0x75) will mask out SMBALERTs if this bit is set to 1,
although the F4P bit of Interrupt Status Register 2 will still get set
if the THERM limit is exceeded.
Figure 27 is a Functional Block Diagram of the THERM timer,
limit, and associated circuitry. Writing a value of 0x00 to the
THERM limit register (Reg. 0x7A) causes SMBALERT to
be generated on the first THERM assertion. A THERM limit
value of 0x01 generates an SMBALERT once cumulative THERM
assertions exceed 45.52 ms.
Configuring the Desired THERM BehaviorConfigure the THERM input.
Setting Bit 1 (THERM ENABLE) of Configuration Register 3
(Reg. 0x78) enables the THERM monitoring function.Select the desired fan behavior for THERM events.
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 = 0, the fans will run at their current settings and
will not be affected by THERM events.Select whether THERM events should generate
SMBALERT interrupts.

Bit 5 (F4P) of Mask Register 2 (Reg. 0x75), when set,
masks out SMBALERTs when the THERM limit value gets
exceeded. This bit should be cleared if SMBALERTs based
on THERM events are required.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.Select a THERM monitoring time.
This is 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 perfor-
mance is degrading significantly since THERM is asserting
more frequently on an hourly basis.
Alternatively, OS or BIOS level software can time-stamp when
the system is powered on. If an SMBALERT is generated
due to the THERM limit being exceeded, another time-stamp
can be taken. The difference in time can be calculated for a
fixed THERM limit time. For example, if it takes one week
for a THERM limit of 2.914 s to be exceeded and the next
time it takes only one hour, then this is an indication of a
serious degradation in system performance.
Configuring the ADT7460 THERM Pin as an Output

In addition to the ADT7460 being able to monitor THERM as
an input, the ADT7460 can optionally drive THERM low as an
output. The user can preprogram system critical thermal limits.
If the temperature exceeds a thermal limit by 0.25°C, THERM
will assert low. If the temperature is still above the thermal limit
on the next monitoring cycle, THERM will stay low. THERM
will remain asserted low until the temperature is equal to or
below the thermal limit. Since the temperature for that channel
is only measured every monitoring cycle, once 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 temperature THERM limits get exceeded by
0.25°C. The THERM limit registers are at Locations 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 28. Asserting THERM as an Output, Based on
Tripping THERM Limits
FAN DRIVE USING PWM CONTROL

The ADT7460 uses pulsewidth 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. A single NMOSFET 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–300 mA each. If you drive several fans
in parallel from a single PWM output or drive larger server fans,
the MOSFET will need to 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. This would reduce the voltage
applied across the fan and therefore the maximum operating
speed of the fan.
Figure 29 shows how a 3-wire fan may be driven using PWM
control.
Figure 29. Driving a 3-Wire Fan Using an
N-Channel MOSFET
Figure 29 uses a 10 kΩ pull-up resistor for the TACH signal. This
assumes that the TACH signal is open-collector from the fan. In
all cases, the TACH signal from the fan must be kept below 5V
maximum to prevent damaging the ADT7460. If in doubt as to
ADT7460
Figure 31. Interfacing Two Fans in Parallel to the PWM3 Output Using Low Cost NPN Transistors
Figure 32. Interfacing Two Fans in Parallel to the PWM3 Output Using a Single N-Channel MOSFET
Figure 30 shows a fan drive circuit using an NPN transistor such
as a general-purpose MMBT2222. While these devices are inexpen-
sive, 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.
Figure 30. Driving a 3-Wire Fan Using an NPN Transistor
Driving Two Fans from PWM3

Note that the ADT7460 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 31 shows how to drive
two fans in parallel using low cost NPN transistors. Figure32
is the equivalent circuit using the NDT3055L MOSFET. Note
that since the MOSFET can handle up to 3.5 A, it is simply a
matter of connecting another fan directly in parallel with the first.
Care should be taken in designing drive circuits with transistors
and FETs to ensure that the PWM pins are not required to
source current and that they sink less than the 8 mA maximum
current specified on the data sheet.
Driving Up to Three Fans from PWM2

TACH measurements for fans are synchronized to particular
PWM channels, e.g., TACH1 is synchronized to PWM1. TACH3
and TACH4 are both synchronized to PWM3, so PWM3 can
drive two fans. Alternatively, PWM2 can be programmed to
synchronize TACH2, TACH3, and TACH4 to the PWM2
output. This allows PWM2 to drive two or three fans. In this
case, the drive circuitry looks the same as shown in Figures30, 31,
and 32. The SYNC bit in Register 0x62 enables this function.
ENHANCE ACOUSTICS REGISTER 1 (REG. 0x62)
<4> SYNC = 1, Synchronizes TACH2, TACH3, and TACH4
PWM2.
Driving 2-Wire Fans

Figure 33 shows how a 2-wire fan may be connected to the
ADT7460. 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 commu-
tation pulses into a voltage. This is ac-coupled into the ADT7460
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 200mA, a 2Ω
RSENSE value is suitable when the threshold is programmed asmV. For fans that draw more current, such as larger desktop
or server fans, RSENSE may be reduced for the same programmed
threshold. The smaller the threshold programmed the better, since
more voltage will be developed across the fan and the fan will spin
faster. Figure 34 shows a typical plot of the sensing waveform at a
TACH/AIN pin. The most important thing is that the voltage spikes
(either negative going or positive going) are more than 40mV
in amplitude. This allows fan speed to be reliably determined.
Figure 33. Driving a 2-Wire Fan
LAYING OUT 2-WIRE AND 3-WIRE FANS

Figure 35 shows how to lay out a common circuit arrangement for
2-wire and 3-wire fans. Some components will not be populated,
depending on whether a 2-wire or 3-wire fan is being used.
3.3V OR 5V
TACH/AIN
PWM
12V OR 5V
MMBT2222
FOR 3-WIRE FANS:
POPULATE R1, R2, R3
R4 = 0�
C1 = UNPOPULATED
FOR 2-WIRE FANS:
POPULATE R4, C1
R1, R2, R3 UNPOPULATED

Figure 35. Planning for 2-Wire or 3-Wire Fans on a PCB
TACH Inputs

Pins 4, 6, 7, and 9 are open-drain TACH inputs intended for
fan speed measurement.
Signal conditioning in the ADT7460 accommodates the slow rise
and fall times typical of fan tachometer outputs. The maximum
input signal range is 0 V to 5 V, even where VCC is less than 5V.
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.
Figures 36a to 36d show circuits for most common fan TACH
outputs.
If the fan TACH output has a resistive pull-up to VCC, it can be
connected directly to the fan input, as shown in Figure36a.
Figure 36a. Fan with TACH Pull-Up to VCC
If the fan output has a resistive pull-up to 12 V (or other voltage
greater than 5 V), the fan output can be clamped with a Zener
diode, as shown in Figure 36b. 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.value of between 3 V and 5 V is suitable.
ADT7460
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 (Figure37),
so the accumulated count is actually proportional to the fan
tachometer period and inversely proportional to the fan speed.
Figure 37. Fan Speed Measurement
N, the number of pulses counted, is determined by the settings
of Register 0x7B (fan pulses per revolution register). This
register contains two bits for each fan, allowing one, two
(default), three, or four TACH pulses to be counted.
Fan Speed Measurement Registers

The fan tachometer readings are 16-bit values consisting of a
2-byte read from the ADT7460.
Reg. 0x28 TACH1 Low Byte = 0x00 Default
Reg. 0x29 TACH1 High Byte = 0x00 Default
Reg. 0x2A TACH2 Low Byte = 0x00 Default
Reg. 0x2B TACH2 High Byte = 0x00 Default
Reg. 0x2C TACH3 Low Byte = 0x00 Default
Reg. 0x2D TACH3 High Byte = 0x00 Default
Reg. 0x2E TACH4 Low Byte = 0x00 Default
Reg. 0x2F TACH4 High Byte = 0x00 Default
Reading Fan Speed from the ADT7460

If fan speeds are being measured, this 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 from. This prevents 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). Since 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).
Since the actual fan TACH period is being measured, exceeding
a fan TACH limit by 1 will set the appropriate status bit and
can be used to generate an SMBALERT.
Figure 36b. Fan with TACH Pull-Up to Voltage
> 5 V, e.g., 12 V, Clamped with Zener Diode
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 36c. Alternatively, a resistive
attenuator may be used, as shown in Figure 36d.
R1 and R2 should be chosen such that:
The fan inputs have an input resistance of nominally 160 kΩ to
ground, so this should be taken into account when calculating
resistor values.
With a pull-up voltage of 12 V and pull-up resistor less than 1kΩ,
suitable values for R1 and R2 would be 100 kΩ and 47kΩ. This
will give a high input voltage of 3.83 V.
Figure 36c. Fan with Strong TACH Pull-Up to > VCC or
Totem-Pole Output, Clamped with Zener and Resistor
Figure 36d. 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 may be less than 1000RPM and
it would take several seconds to accumulate a reasonably large
and accurate count. Instead, the period of the fan revolution is
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