ADM1022_技术文档

Low-Cost PC Temperature

Monitor and Fan Control ASIC

a

ADM1022

GENERAL DESCRIPTION

FEATURES

The ADM1022 is a low cost temperature monitor and fan con-

troller for microprocessor-based systems. The temperature of

one or two remote sensor diodes may be measured, allowing

monitoring of processor temperature in single- or dual-pro-

cessor systems.

External Temperature Measurement with Remote

Diode (Two Channels)

On-Chip Temperature Sensor

Interrupt and Over-Temperature Outputs

Fault Tolerant Fan Control

Brownout Detection

LDCM Support

System Management Bus (SMBus)

Standby Mode to Minimize Power Consumption

Limit Comparison of all Monitored Values

Measured values can be read out via a serial System Manage-

ment Bus, and values for limit comparisons can be programmed

in over the same serial bus.

The ADM1022 also contains a DAC for fan speed control.

Automatic hardware temperature trip points are provided and

the fan will be driven to full speed if they are exceeded.

APPLICATIONS

Network Servers and Personal Computers

Microprocessor-Based Ofﬁce Equipment

Test Equipment and Measuring Instruments

Finally, the chip has two supply voltage monitors for brownout

detection.

The ADM1022’s 3.0 V to 5.5 V supply voltage range, low supply

current, and SMBus interface make it ideal for a wide range of

applications. These include hardware monitoring and protection

applications in personal computers, electronic test equipment

and ofﬁce electronics.

FUNCTIONAL BLOCK DIAGRAM

V

MON

CC

ADD/NTEST_OUT

SERIAL BUS

INTERFACE

SDA

RESET

GENERATOR 1

RST1

ADM1022

SCL

ANALOG

OUTPUT

REGISTER

AND 8-BIT DAC

FAN_SPD/NTEST_IN

RESET

GENERATOR 2

RST2

MR

V

CC

ADDRESS

POINTER

REGISTER

VALUE AND

LIMIT

REGISTERS

20k⍀

BANDGAP

TEMPERATURE

SENSOR

LIMIT

COMPARATORS

ADC

INTERRUPT

STATUS

REGISTERS

ANALOG

MULTIPLEXER

D1+

D1–

2.5V

BANDGAP

REFERENCE

INT MASK

REGISTER

D2+/GPI

INT

D2–/THERM

MASK

GATING

CONFIGURATION

REGISTER

FAN_OFF

GND

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

which may result from its use. No license is granted by implication or

otherwise under any patent or patent rights of Analog Devices.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781/329-4700

Fax: 781/326-8703

World Wide Web Site: http://www.analog.com

ADM1022–SPECIFICATIONS ^(T_A^{= T}_MINto T_MAX, V_CC= V_MINto V_MAX, unless otherwise noted.)

Parameter

Min

Typ¹

Max

Unit

Test Conditions

POWER SUPPLY

Supply Voltage, V_CC

Supply Current, I_CC

3.0

3.30

1.4

5.5

2.6

V

mA

Interface Inactive, ADC Active

TEMPERATURE-TO-DIGITAL CONVERTER

Internal Sensor Accuracy

3

2

°C

µA

ms

1

T_A= 85°C, Tested at Wafer Sort

Resolution

External Diode Sensor Accuracy

5

3

Resolution

Remote Sensor Source Current

1

90

5.5

60

3.5

130

7.5

200

High Level (D+ = D– +0.65 V)

Low Level (D+ = D– +0.65 V)

Total Monitoring Cycle Time, t_C

ANALOG OUTPUT

Output Voltage Range

Total Unadjusted Error, TUE

Full-Scale Error

0

2.5

5

3

V

%

LSB

mA

I_L= 2 mA

1

2

Zero Error

No Load

Monotonic by Design

Differential Nonlinearity, DNL

Integral Nonlinearity

Output Source Current

Output Sink Current

1

2

1

VOLTAGE MONITOR THRESHOLDS

Reset Threshold, V_MON, V_CC

Hysteresis

2.85

2.925

50

3.00

V

mV

Measured with V_CCFalling

MR INPUT

MR Minimum Pulsewidth, t_MR

MR Glitch Immunity

MR to RST2 Propagation Delay, t_MD

MR Pull-Up Resistance

10

µs

100

0.5

20

ns

µs

30

kΩ

RESET OUTPUTS, RST1, RST2

Reset Output Voltage, V_OL

0.3

V

I_SINK= 1.2 mA

_CC= V_TH(MAX)

V

Reset Active Timeout Period, t_RP

V_CCto Reset Delay, t_D

DIGITAL OUTPUT ADD/NTEST_OUT²

Output High Voltage, V_OH

140

2.4

180

20

560

ms

µs

V

I_OUT= 3.0 mA

Output Low Voltage, V_OL

0.4

OPEN-DRAIN DIGITAL OUTPUTS

(INT, THERM, RST2, RST1)

Output Low Voltage, V_OL

0.4

1

V

µA

I_OUT= –3.0 mA

V_OUT= V_CC

High Level Output Leakage Current, I_OH

0.1

OPEN-DRAIN SERIAL DATA

BUS OUTPUT (SDA)

Output Low Voltage, V_OL

High Level Output Leakage Current, I_OH

0.4

1

V

µA

I_OUT= –3.0 mA

V_OUT= V_CC

SERIAL BUS DIGITAL INPUTS

(SCL, SDA)

Input High Voltage, V_IH

Input Low Voltage, V_IL

Input Leakage Current

Hysteresis

2.1

V (min)

V (max)

µA

0.8

5

500

mV

–2–

REV. 0

ADM1022

Parameter

Min

2.2

–1

Typ

Max

Unit

Test Conditions

DIGITAL INPUT LOGIC LEVELS

(FAN_SPD/NTEST_IN,

ADD/NTEST_OUT, MR, GPI)

Input High Voltage, V_IH

Input Low Voltage, V_IL

V

0.8

DIGITAL INPUT LEAKAGE CURRENT

(ALL DIGITAL INPUTS)

Input High Current, I_IH

–0.005

+0.005 +1

5

µA

pF

V_IN= V_CC

V_IN= 0

Input Low Current, I_IL

Input Capacitance, C_IN

SERIAL BUS TIMING³

Clock Frequency, f_SCLK

Glitch Immunity, t_SW

400

kHz

ns

µs

See Figure 1

50

Bus Free Time, t_BUF

1.3

600

1.3

0.6

Start Setup Time, t_SU:STA

Start Hold Time, t_HD:STA

Stop Condition Setup Time, t_SU:STO

SCL Low Time, t_LOW

SCL High Time, t_HIGH

SCL, SDA Rise Time, t_R

SCL, SDA Fall Time, t_F

Data Setup Time, t_SU:DAT

Data Hold Time, t_HD:DAT

ns

µs

300

ns

100

300

NOTES

¹Typicals are at T_A= 25°C and represent most likely parametric norm. Standby current typ is measured with V_CC= 3.3 V.

²ADD is a three-state input that may be pulled high, low or left open-circuit.

³Timing speciﬁcations are tested at logic levels of V_IL= 0.8 V for a falling edge and V_IH= 2.2 V for a rising edge.

Speciﬁcations subject to change without notice.

t_HD;STA

t_R

t_LOW

t_F

SCL

SDA

t_HD;DAT

t_SU;STA

t_SU;STO

t_HIGH

t_HD;STA

t_SU;DAT

t_BUF

S

P

S

Figure 1. Diagram for Serial Bus Timing

REV. 0

–3–

ADM1022

*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.

ABSOLUTE MAXIMUM RATINGS*

Positive Supply Voltage (V_CC) . . . . . . . . . . . . . . . . . . . . .6.5 V

Voltage On Digital Inputs Except Therm . . . –0.3 V to +6.5 V

Voltage On Therm Pin . . . . . . . . . . . . .–0.3 V to V_CC+ 0.3 V

Voltage on Any Other Input

or Output Pin . . . . . . . . . . . . . . . . . . .–0.3 V to V_CC+ 0.3 V

Input Current at Any Pin . . . . . . . . . . . . . . . . . . . . . . . 5 mA

Package Input Current . . . . . . . . . . . . . . . . . . . . . . . 20 mA

Maximum Junction Temperature (T_Jmax) . . . . . . . . . . 150°C

Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C

Lead Temperature, Soldering

THERMAL CHARACTERISTICS

16-Lead QSOP Package

θ

_JA= 105°C/W

_JA= 39°C/W

ORDERING GUIDE

Vapor Phase 60 sec . . . . . . . . . . . . . . . . . . . . . . . . . . . 215°C

Infrared 15 sec . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200°C

ESD Rating (Human Body Model) . . . . . . . . . . . . . . . 4000 V

Temperature

Range

Package

Description

Package

Option

Model

ADM1022ARQ 0°C to 85°C

16-Lead QSOP RQ-16

PIN CONFIGURATION

1

2

3

4

5

6

7

8

16

SDA

FAN_OFF

MR

15

14

13

12

11

10

9

SCL

INT

RST1

GND

ADM1022

TOP VIEW

(Not to Scale)

ADD/NTEST_OUT

D2+/GPI

D2–/THERM

D1+

V

CC

V

MON

RST2

D1–

FAN_SPD/NTEST_IN

–4–

REV. 0

ADM1022

PIN FUNCTION DESCRIPTION

No. Mnemonic

Description

1

2

3

FAN_OFF

Digital Output (Open-Drain) Fan Off Request. When asserted low this indicates a request to shut

off the fan independent of the FAN_SPD output. When negated (output FET off) it indicates that

the fan may be turned on.

Digital Input, Manual Reset. A logic low on this input causes RST2 to be asserted. Once this input

is negated that output will remain asserted for t_RP. This input has an internal 20 kΩ pull-up resistor.

Leave unconnected if not used.

Digital I/O (Open-Drain). This pin is asserted low while V_CCremains below the reset threshold. It

remains asserted for t_RPafter the reset condition is terminated. It is bidirectional so the ADM1022 can

be optionally reset; external logic must be used to prevent system auxiliary reset from occurring

when used as an input.

MR

RST1

4

5

6

7

GND

V_CC

V_MON

RST2

GROUND. Power and Signal Ground.

POWER 3.3 V. Power source and voltage monitor input for ﬁrst reset generator.

Analog Input. Voltage monitor input for second reset generator.

Digital Output (Open-Drain). This pin is asserted low under any of the following conditions:

– V_MONor V_CCremains below the reset threshold

– while MR is held low

– while RST1 is asserted.

It remains asserted for t_RPafter the reset conditions are terminated.

8

FAN_SPD/NTEST_IN

Analog Output/Test Input. An active-high input that enables NAND board-level connectivity testing.

Refer to section on NAND testing. Used as an analog output for fan speed control when NAND

test is not selected.

9

D1–

Remote Thermal Diode Negative Input. This is the negative input (current sink) from the remote

thermal diode. This also serves as the negative input into the A/D.

10

11

D1+

Remote Thermal Diode Positive Input. This is the positive input (current source) from the remote

thermal diode. This serves as the positive input into the A/D.

D2–/THERM

Analog Input/Digital I/O (Open-Drain). Can be programmed as negative input for a second diode

temperature sensor, or as a digital I/O pin. In this case it is an active low thermal overload output

that indicates a violation of a temperature set point (over-temperature). Also acts as an input to

provide external fan control. When this pin is pulled low by an external signal, a status bit is set and

the fan speed is set to full on.

12

D2+/GPI

Analog/Digital Input. Can be programmed as the positive input for a second diode sensor, or as a

general-purpose logic input. In this case it can be programmed as an active high or active low input

that sets Bit 4 of the Status Registers. This bit can only be reset by reading the status registers, pro-

vided GPI is in the inactive state.

13

14

ADD/NTEST_OUT

Digital I/O. The lowest order programmable bit of the SMBus Address. ADD is sampled at power-

up and changing it while powered on will have no immediate effect. This pin also functions as an

output when doing a NAND test.

Digital Output (Open Drain), System Interrupt Output. This signal indicates a violation of a set

trip point. The output is enabled when Bit 1 of the Conﬁguration Register is set to 1. The default

state is disabled.

INT

15

16

SCL

SDA

Digital Input SMBus Clock.

Digital I/O (Open-Drain) SMBus Bidirectional Data.

REV. 0

–5–

ADM1022–Typical Performance Characteristics

120

100

90

80

70

60

50

40

30

20

10

0

30

20

10

DXP TO GND

0

–10

DXP TO V (5V)

CC

–20

–30

–40

–50

–60

0

10

20

30

40

50

60

70

80

90 100 110

1

3.3

10

30

100

MEASURED TEMPERATURE

LEAKAGE RESISTANCE – M⍀

Figure 5. Pentium^®III Temperature Measurement vs.

ADM1022 Reading

Figure 2. Temperature Error vs. PC Leakage Resistance

6

5

30

25

20

4

250mV p-p REMOTE

3

15

ERROR

2

10

1

5

0

100mV p-p REMOTE

0

–5

1.0

–1

50

500

5k

500k

FREQUENCY – Hz

5M

50M

50k

2.2

3.2

4.7

10.0

14.0

22.0

29.0

7.0

DXP-DXN CAPACITANCE – nF

Figure 3. Temperature Error vs. Power Supply Noise

Frequency

Figure 6. Temperature Error vs. Capacitance Between D+

and D–

25

80

70

60

50

40

20

100mV p-p

15

10

50mV p-p

V

= 5V

CC

30

20

10

0

5

25mV p-p

5M

0

V

= 3V

CC

–5

50

500

5k

50k

500k

50M

0

1k

5k 10k 25k 50k 75k 100k 250k 500k 750k 1M

FREQUENCY – Hz

SCLK FREQUENCY – Hz

Figure 4. Temperature Error vs. Common-Mode Noise

Frequency

Figure 7. Standby Current vs. Clock Frequency

Pentium is a registered trademark of Intel Corporation.

–6–

REV. 0

ADM1022

GENERAL DESCRIPTION

10

9

The ADM1022 is a low-cost temperature monitor and fan con-

troller for microprocessor-based systems. The temperature of

one or two remote sensor diodes may be measured, allowing

monitoring of processor temperature in single- or dual-processor

systems. The chip also contains an on-chip sensor to allow

ambient temperature to be monitored.

8

7

10mV SQ. WAVE

6

5

4

Measured values can be read out via a serial System Manage-

ment Bus, and values for limit comparisons can be programmed

in over the same serial bus.

3

2

1

0

The ADM1022 also contains a DAC for fan speed control.

Automatic hardware temperature trip points are provided for

fault tolerant fan control and the fan will be driven to full speed

if they are exceeded. Two interrupt outputs are provided, which

will be asserted if the software or hardware limits are exceeded.

50

500

5k

50k

100k 500k

FREQUENCY – Hz

5M

25M 50M

Figure 8. Temperature Error vs. Differential-Mode Noise

Frequency

Finally, the chip has two supply voltage monitors for brownout

detection. These drive two reset pins, one of which is bidirec-

tional. A manual reset input is also provided.

INTERNAL REGISTERS OF THE ADM1022

2.3

2.2

A brief description of the ADM1022’s principal internal regis-

ters is given below. More detailed information on the function

of each register is given in Tables IV to IX.

V

= 5.5V

DD

Conﬁguration Register: Provides control and conﬁguration.

2.1

2.0

1.9

Address Pointer Register: This register contains the address that

selects one of the other internal registers. When writing to the

ADM1022, the ﬁrst byte of data is always a register address, which

is written to the Address Pointer Register.

V

= 3.3V

Interrupt (INT) Status Register: This register provides status

of each Interrupt event. It is also mirrored by a second register

at address 4Ch.

DD

1.8

1.7

V

= 3.0V

DD

Interrupt (INT) Mask Register: Allows masking of individual

interrupt sources.

–40 –30–20–10

0

10 20 30 40 50 60 70 80 90 100110120130

TEMPERATURE – ؇C

Figure 9. Standby Supply Current vs. Supply Voltage

Value and Limit Registers: The results of temperature measure-

ments are stored in these registers, along with their limit values.

Analog Output Register: The code controlling the analog out-

put DAC is stored in this register.

400

SERIAL BUS INTERFACE

350

Control of the ADM1022 is carried out via the serial bus. The

ADM1022 is connected to this bus as a slave device, under the

control of a master device, e.g., the PIIX4.

RST2

300

250

200

The ADM1022 has a 7-bit serial bus address. When the device is

powered up, it will do so with a default serial bus address. The ﬁve

MSBs of the address are set to 01011, the two LSBs are deter-

mined by the logical states of Pin 13 (ADD/NTEST_OUT).

This is a three-state input that can be grounded, connected to V_CC

or left open-circuit to give three different addresses. The state of

the ADD pin is only sampled at power-up, so changing ADD

with power-on will have no effect until the device is powered

off then on again.

150

RST1

100

–40 –30–20–10

0

10 20 30 40 50 60 70 80 90 100110120130

TEMPERATURE – ؇C

Figure 10. Power-up Reset vs. Temperature

Table I. ADD Pin Truth Table

ADD Pin

A1

A0

GND

No Connect

V_CC

1

0

1

REV. 0

–7–

ADM1022

If ADD is left open-circuit the default address will be 0101100.

In the case of the ADM1022, write operations contain either

one or two bytes, and read operations contain one byte, and

perform the following functions:

The facility to make hardwired changes to A1 and A0 allows the

user to avoid conflicts with other devices sharing the same serial

bus; for example, if more than one ADM1022 is used in a system.

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 reg-

ister selected by the address pointer register.

The serial bus protocol operates as follows:

1. The master initiates data transfer by establishing a START

condition, deﬁned as a high-to-low transition on the serial

data line SDA while the serial clock line SCL remains high.

This indicates that an address/data stream 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 an R/W bit, which deter-

mines the direction of the data transfer, i.e., whether data

will be written to or read from the slave device.

This is illustrated in Figure 11a. The device address is sent over

the bus followed by R/W 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.

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, the master will write to the slave

device. If the R/W bit is a one, the master will read from the

slave device.

When reading data from a register there are two possibilities:

1. If the ADM1022’s Address Pointer Register value is unknown

or not the desired value, it is ﬁrst necessary to set it to the cor-

rect value before data can be read from the desired data register.

This is done by performing a write to the ADM1022 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 11b.

2. 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.

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 11c.

2. 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 Reg-

ister, so Figure 11b can be omitted.

3. 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 acknowledge bit by pulling the data line high during the

low period before the 9th 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 10th clock pulse to assert a STOP condition.

NOTES

1. Although 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, 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.

2. In Figures 11a to 11c, the serial bus address is shown as the

default value 01011(A1)(A0), where A1 and A0 are set by

the three-state ADD pin.

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.

3. The ADM1022 also supports the Read Byte protocol, as

described in the System Management Bus speciﬁcation.

–8–

REV. 0

ADM1022

1

0

9

1

SCL

SDA

D6

D2

1

0

1

A1

A0

D7

D5

D4

D3

D1

D0

R/W

ACK. BY

ADM1022

START BY

MASTER

ACK. BY

ADM1022

FRAME 1

SERIAL BUS ADDRESS BYTE

FRAME 2

ADDRESS POINTER REGISTER BYTE

1

9

SCL (CONTINUED)

SDA (CONTINUED)

D2

D5

D4

D3

D1

D0

D7

D6

ACK. BY STOP BY

ADM1022 MASTER

FRAME 3

DATA BYTE

Figure 11a. Writing a Register Address to the Address Pointer Register, then Writing Data to the Selected Register

1

9

1

SCL

D6

D2

0

1

0

1

A1

A0

D7

D5

D4

D3

D1

SDA

D0

R/W

ACK. BY

STOP BY

ACK. BY

ADM1022

START BY

MASTER

ADM1022 MASTER

FRAME 1

SERIAL BUS ADDRESS BYTE

FRAME 2

ADDRESS POINTER REGISTER BYTE

Figure 11b. Writing to the Address Pointer Register Only

1

9

1

9

SCL

0

D6

D4

D2

SDA

START BY

1

0

1

A1

A0

D7

D5

D3

D1

D0

R/W

NO ACK.

STOP BY

ACK. BY

ADM1022

BY MASTER MASTER

MASTER

FRAME 1

SERIAL BUS ADDRESS BYTE

FRAME 2

DATA BYTE FROM ADM1022

Figure 11c. Reading Data from a Previously Selected Register

TEMPERATURE MEASUREMENT SYSTEM

Internal Temperature Measurement

of V_BE, varies from device to device, and individual calibra-

tion is required to null this out, so the technique is unsuitable

for mass-production.

The ADM1022 contains an on-chip bandgap temperature sen-

sor. The on-chip ADC performs conversions on the output of

this sensor and outputs the temperature data in 8-bit twos comple-

ment format. The format of the temperature data is shown in

Table II.

The technique used in the ADM1022 is to measure the change

in V_BEwhen the device is operated at two different currents.

This is given by:

∆V_BE= KT/q × ln(N)

where:

External Temperature Measurement

The ADM1022 can measure the temperature of two external

diode sensors or diode-connected transistors, connected to Pins

9 and 10 or 11 and 12.

K is Boltzmann’s constant

q is charge on the carrier

T is absolute temperature in Kelvins

N is ratio of the two currents

Pins 9 and 10 are a dedicated temperature input channel. The

default function of Pins 11 and 12 is the THERM input/output

and a general purpose logic input (GPI), but they can be conﬁg-

ured to measure a diode sensor by setting Bit 7 of the Conﬁgu-

ration Register to 1.

Figure 12 shows the input signal conditioning used to mea-

sure the output of an external temperature sensor. This ﬁgure

shows the external sensor as a substrate transistor, provided

for temperature monitoring on some microprocessors, but it

could equally well be a discrete transistor.

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

REV. 0

–9–

ADM1022

LAYOUT CONSIDERATIONS

V

DD

Digital boards can be electrically noisy environments, and care

must be taken to protect the analog inputs from noise, particu-

larly when measuring the very small voltages from a remote

diode sensor. The following precautions should be taken:

I

N

؋

I

BIAS

V

D+

OUT+

TO

ADC

OUT–

1. Place the ADM1022 as close as possible to the remote sens-

ing diode. Provided that the worst noise sources such as

clock generators, data/address buses and CRTs are avoided,

this distance can be four to eight inches.

REMOTE

SENSING

BIAS

DIODE

D–

TRANSISTOR

LOW-PASS

FILTER

C

2. Route the D+ and D– tracks close together, in parallel, with

grounded guard tracks on each side. Provide a ground plane

under the tracks if possible.

f

= 65kHz

Figure 12. Signal Conditioning

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.

3. Use wide tracks to minimize inductance and reduce noise

pickup. 10 mil track minimum width and spacing is recom-

mended.

10MIL

GND

D+

Table II. Temperature Data Format

Temperature

Digital Output

D–

–128°C

–125°C

–100°C

–75°C

–50°C

–25°C

–1°C

1000 0000

1000 0011

1001 1100

1011 0101

1100 1110

1110 0111

1111 1111

0000 0000

0000 0001

0000 1010

0001 1001

0011 0010

0100 1011

0110 0100

0111 1101

0111 1111

GND

Figure 13. Arrangement of Signal Tracks

4. Try to minimize the number of copper/solder joints, which

can cause thermocouple effects. Where copper/solder joints

are used, make sure that they are in both the D+ and D–

path and at the same temperature.

0°C

+1°C

+10°C

+25°C

+50°C

+75°C

+100°C

+125°C

+127°C

Thermocouple effects should not be a major problem as 1°C

corresponds to about 200 µV, and thermocouple voltages are

about 3 µV/^oC of temperature difference. Unless there are

two thermocouples with a big temperature differential between

them, thermocouple voltages should be much less than 200 µV.

5. Place 0.1 µF bypass and 1000 pF input ﬁlter capacitors close

to the ADM1022.

To prevent ground noise 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.

If the sensor is used in a very noisy environment, a capacitor of

value up to 1000 pF may be placed between the D+ and D–

inputs to ﬁlter the noise.

6. If the distance to the remote sensor is more than eight inches,

the use of twisted pair cable is recommended. This will work

up to about 6 to 12 feet.

7. For really long distances (up to 100 feet) use a shielded

twisted pair such as Belden #8451 microphone cable. Con-

nect the twisted pair to D+ and D– and the shield to GND

close to the ADM1022. Leave the remote end of the shield

unconnected to avoid ground loops.

To measure ∆V_BE, the sensor is switched between operating

currents of I and N × I. The resulting waveform is passed through

a 65 kHz low-pass ﬁlter to remove noise, thence to a chopper-

stabilized ampliﬁer that performs the functions of ampliﬁcation

and rectiﬁcation of the waveform to produce a dc voltage pro-

portional to ∆V_BE. This voltage is measured by the ADC to give

a temperature output in 8-bit twos complement format. To fur-

ther reduce the effects of noise, digital ﬁltering is performed by

averaging the results of 16 measurement cycles. An external

temperature measurement takes nominally 9.6 ms.

Because the measurement technique uses switched current

sources, excessive cable and/or ﬁlter capacitance can affect the

measurement. When using long cables, the ﬁlter capacitor C1

may be reduced or removed. In any case, the total shunt capaci-

tance should not exceed 1000 pF.

Cable resistance can also introduce errors. 1 Ω series resistance

introduces about 0.5°C error.

–10–

REV. 0

ADM1022

ANALOG OUTPUT

12V

The ADM1022 has a single analog output (FAN_SPD) from an

unsigned 8-bit DAC that produces 0 V–2.5 V. The analog out-

put register defaults to 00 during power-on reset, which produces

minimum fan speed. The analog output may be ampliﬁed and

buffered with external circuitry such as an op amp and transistor

to provide fan speed control.

R4

1k⍀

FAN_SPD

Q1

BD136

2SA968

AD8519

+

R3

1k⍀

R2

39k⍀

Suitable fan drive circuits are given in Figures 14a to 14e. When

using any of these circuits, the following points should be noted:

R1

10k⍀

1. All of these circuits will provide an output range from zero to

almost +V_FAN

.

Figure 14b. 12 V Fan Circuit with Op Amp and PNP

Transistor

2. To amplify the 2.5 V range of the analog output up to +V_FAN

the gain of these circuits needs to be set as shown.

,

12V

3. Care must be taken when choosing the op amp to ensure that

its input common-mode range and output voltage swing are

suitable.

R3

100k⍀

FAN_SPD

Q1

4. The op amp may be powered from the +V rail alone. If it

is powered from +V then the input common-mode range

should include ground to accommodate the minimum output

voltage of the DAC, and the output voltage should swing below

0.6 V to ensure that the transistor can be turned fully off.

AD8519

+

NDT452 P

R2

39k⍀

3.3V

R1

10k⍀

R4

1k⍀

5. In all these circuits, the output transistor must have an I_CMAX

greater than the maximum fan current, and be capable of dis-

sipating power due to the voltage dropped across it when the

fan is not operating at full speed.

Q2

NDT3055L

FAN_OFF

6. If the fan motor produces a large back ElectroMotive Force

(EMF) when switched off, it may be necessary to add clamp

diodes to protect the output transistors in the event that the

output goes from full-scale to zero very quickly.

Figure 14c. 12 V Fan Circuit with Op Amp and P-Channel

MOSFET

12V

7. Pulling FAN_SPD/NTEST_IN high externally on power-up

causes NAND Test Mode to be invoked on the ADM1022.

Therefore, a 4.7 kΩ pull-down resistor should be added

externally to the FAN_SPD pin to prevent ADM1022 inad-

vertently entering the NAND Tree Test Mode.

R3

100k⍀

R4

100k⍀

Q3

NDT452 P

R2

Figure 14c shows how the FAN_OFF signal may be used (with

any of the control circuits) to gate the fan on and off indepen-

dent of the value on the FAN_SPD/NTEST_IN pin.

3.9k⍀

Q1/Q2

MBT3904

DUAL

FAN_SPD

R5

5k⍀

R1

1k⍀

5V

Figure 14d. Discrete 12 V Fan Drive Circuit with

P-Channel MOSFET, Single Supply

FAN_SPD

Q1

AD8541

+

NDT452 P

12V

R5

100k⍀

R4

100k⍀

R2

15k⍀

Q4

BD132

TIP32A

5V

FAN

R1

10k⍀

Q3

BC556

2N3906

R2

Figure 14a. 5 V Fan Circuit with Op Amp

3.9k⍀

Q1/Q2

MBT3904

DUAL

FAN_SPD

R6

5k⍀

R3

100⍀

R1

1k⍀

Figure 14e. Discrete 12 V Fan Drive Circuit with Bipolar

Output Single Supply

REV. 0

–11–

ADM1022

FAULT TOLERANT FAN CONTROL

Operation of the INT output is illustrated in Figure 15. Assum-

ing that the temperature starts off within the programmed limits

and that temperature interrupt sources are not masked, INT

will go low if the temperature measured by any of the internal or

external sensors goes outside the programmed high or low

temperature limit for that sensor. INT also goes low whenever

THERM is low.

The ADM1022 incorporates a fault tolerant fan control capabil-

ity that is tied to operation of the THERM output. It can over-

ride the setting of the analog output and force it to maximum to

give full fan speed in the event of a critical over-temperature

problem, even if, for some reason, this has not been handled by

the system software.

There are four temperature set point registers that will activate

the fault tolerant fan control. Two of these limits are program-

mable by the user and two are hardware (read-only) registers

that will operate if the user does not program any limits. The

fault tolerant fan control is activated if a limit is exceeded for

three or more consecutive readings. These limits are separate

from the normal high and low temperature limits for the INT

output, which do not affect the fault tolerant fan control or

THERM output.

100؇C

90؇C

*

80؇C

HIGH LIMIT

*

70؇C

TEMP

*

60؇C

LOW LIMIT

*

50؇C

40؇C

A hardware limit of 70°C for the on-chip temperature sensor is

programmed into the register at address 13h. For the remote

sensors, a hardware limit of 100°C is programmed in to the

register at address 17h. These are the default limits and the ana-

log output will be forced to full-scale if the on-chip sensor reads

more than 70°C or either of the remote sensors reads more than

100°C. This makes the fault tolerant fan control fail-safe in that it

will operate at these temperatures even if the user has programmed

no other limits, or in the event of a software malfunction.

INT

ACPI CONTROL

METHODS

CLEAR EVENT

*ACPI AND DEFAULT CONTROL METHODS

ADJUST TEMPERATURE LIMIT VALUES

Figure 15. Operation of INT Output

Once the interrupt has been cleared, it will not be reasserted

even if the temperature remains outside the limit previously

exceeded. However, INT will be reasserted if:

The user may override these default limits by programming new

limits into registers at address 14h for the on-chip sensor and

18h for the remote sensors. The default values in these registers

are the same as for the read-only registers (70°C and 100°C),

but they may be programmed with higher or lower values.

a) the temperature goes outside the other limit for the sensor

or

b) the previously exceeded limit is reprogrammed and the tem-

perature is then outside the new limit on the next conversion

cycle

Once registers 13h and 14h have been programmed, or if the

default is acceptable, Bit 1 of the conﬁguration register must be

set to “1.” This bit is a write-once bit that can only be written to

“1” and it has two effects:

or

c) an interrupt is generated by another source.

1. It makes the values in registers 13h and 14h the active limits,

and disables read-only registers 17h and 18h.

INTERRUPT MASKING

2. It locks the data into registers 13h and 14h, so they cannot

be changed until the lock bit is reset, which is when RST2 is

asserted or a Power-On Reset occurs.

Any of the bits in the Interrupt Status Register can be masked

out by setting the corresponding mask bit in the Interrupt Mask

Register. That interrupt source will then no longer generate an

interrupt. However, the bits in the status register will be set as

normal.

Once the hardware override of the analog output is triggered, it

will only return to normal operation after three consecutive

measurements that are ﬁve degrees lower than each of the above

limits.

INTERRUPT CLEARING

Reading the Interrupt Status Register will output the contents of

the Register, then clear it. It will remain cleared until the moni-

toring cycle updates it, so the next read operation should not be

performed on the register until this has happened, or the result

will be invalid.

The analog output can also be forced to full-scale by pulling the

THERM pin (Pin 11) low. Bit 6 of the Status Register is also set.

Whenever FAN_SPD output is forced to full-scale, the FAN_OFF

output is negated.

The INT output is cleared with the INT_Clear bit, which is Bit

2 of the Conﬁguration Register, without affecting the contents

of the Interrupt (INT) Status Registers.

THE ADM1022 INTERRUPT SYSTEM

The ADM1022 has two interrupt outputs, INT and THERM.

These have different functions. INT responds to violations of

software programmed temperature limits and its interrupt sources

are maskable, as described in more detail later. THERM is

intended as a “fail-safe” interrupt output that cannot be masked.

Interrupts and status bits are only set if a limit is exceeded for at

least three consecutive conversions.

INTERRUPT STATUS MIRROR REGISTER

Whenever a bit in the Interrupt Status Register is set, the corre-

sponding bit is also set in the mirror register at address 4Ch.

This register allows a second management system to access the

status data without worrying about clearing the data. The data

in this register is for reading only and has no effect on the inter-

rupt output. The contents of this register are cleared when read.

–12–

REV. 0

ADM1022

THERM INPUT/OUTPUT

temperature falls ﬁve degrees below the limit for three con-

secutive measurements. While THERM is low, the analog

output will go to FFh to boost a controlled fan to full speed

and FAN_OFF will be negated.

Pin 11 may be conﬁgured as an input for a second temperature

sensor by setting Bit 7 of the Conﬁguration Register, or it may

be used as an interrupt output by clearing Bit 7 of the Conﬁgu-

ration Register, which is its default condition. The Thermal

Management Input/Output (THERM) is a logic input/open-

drain output. It can also function as a logic input. If THERM is

taken low by an external source, the analog output will be forced

to FFh to switch a controlled fan to maximum speed and

FAN_OFF will be negated.

When the Fault Tolerant Fan Control state is exited, the analog

FAN_SPD output returns to its previously programmed value,

which may have been changed during the time that the FAN_SPD

output was forced to FFh.

INTERRUPT STRUCTURE

The Interrupt Structure of the ADM1022 is shown in more

detail in Figure 17. As each measurement value is obtained and

stored in the appropriate value register, the value and the limits

from the corresponding limit registers are fed to the high and

low limit comparators. The result of each comparison (1 = out

of limit, 0 = in limit) is routed to the corresponding bit input of

the Interrupt Status Register via a data demultiplexer, and used

to set that bit high or low as appropriate.

THERM OPERATING MODE

THERM responds only to the “hardware” temperature limits

at addresses 13h, 14h, 17h and 18h, not to the software pro-

grammed limits. The function of these registers was described

earlier with regard to fault tolerant fan speed control.

HARDWARE

TRIP POINT

The Interrupt Mask Register has bits corresponding to each of

the Interrupt Status Register Bits. Setting an Interrupt Mask Bit

high forces the corresponding Status Bit output low, while set-

ting an Interrupt Mask Bit low allows the corresponding Status

Bit to be asserted. After masking, the status bits are all OR’d

together to produce the INT output, which will pull low if any

unmasked status bit goes high, i.e., when any measured value

goes out of limit.

5؇

TEMP

THERM

PROGRAMMED

EXT

VALUE

FF

H

FF

ANALOG

OUTPUT

H

THERM

INPUT

The INT output is enabled when Bit 1 of the Conﬁguration Register

(INT_Enable) is high, and Bit 2 (INT_Clear) is low.

Figure 16. Operation of THERM Output

The THERM output cannot be cleared nor its interrupt sources

masked.

THERM will go low if the hardware temperature limit is exceeded

for three consecutive measurements. It will remain low until the

GPI

INT. TEMP

0

EXT. TEMP2

HIGH

LIMIT

1

1 = OUT

OF

LIMIT

DIODE 2 FAULT

RESERVED

GPI

2

3

4

5

6

7

DATA

DEMULTI-

PLEXER

INTERRUPT

HIGH

AND

STATUS

REGISTER

FROM

VALUE

LOW

EXT. TEMP1

THERM

VALUE

LIMIT

COMPARA-

TORS

AND LIMIT

REGISTERS

MASK GATING

؋

8

DIODE 1 FAULT

STATUS

BIT

MASK

BIT

LOW

LIMIT

INT

INTERRUPT

MASK

REGISTER

MASKING

DATA

FROM BUS

INT_ENABLE

INT_CLEAR

8 MASK BITS

(SAME BIT

ORDER AS

STATUS

CONFIGURATION

REGISTER

REGISTER)

THIS CONNECTION ONLY RELEVANT IF

THERM IS PULLED LOW EXTERNALLY.

D2–/THERM

Figure 17. Interrupt Register Structure

REV. 0

–13–

ADM1022

GENERAL PURPOSE LOGIC INPUT (GPI)

Operation of the reset outputs at power-up, and for a manual

reset input, is shown in Figure 18. It should be noted that the

resets will only be asserted once V_CCrises above 1 V. Below this

voltage there is insufﬁcient gate drive voltage to turn on the out-

put FETs. If the device being reset and its pull-up resistor is

supplied from V_CC, the reset voltage will rise with V_CCto 1 V

before being pulled low. If the device being reset and its pull-up

resistor use a separate supply voltage, the reset output will fol-

low that voltage until reset is asserted.

Pin 12 may be conﬁgured as an input for a second temperature

sensor input by setting Bit 7 of the Conﬁguration Register, or it

may be used as a general purpose logic input by clearing Bit 7 of

the Conﬁguration Register, which is its default condition. The

GPI input may be programmed to be active high or active low by

clearing or setting Bit 6 of the Conﬁguration Register. The default

value is active high. Bit 4 of the Interrupt Status Register follows

the state (or inverted state) of GPI and will generate an interrupt

when it is set to one, like any other input to the Interrupt Status

Register. However, the GPI bit is not latched in the Status Register

and always reflects the current state (or inverted state) of the

GPI input. If it is one it will not be cleared by reading the

Status Register.

The ADM1022 can also be reset by taking RST1 low as an input.

The above-mentioned registers will be reset to their default

values and the ADC will remain inactive as long as RST1 is

below the reset threshold.

V

CC

RESETS

–1V

The ADM1022 has a manual reset input, (Pin 2 – MR), a bidi-

rectional reset pin, (Pin 3 – RST1) and a reset output (Pin 7 –

RST2). These operate as follows:

RST1

RST2

Taking MR low forces a system reset and takes the RST2 output

low. It will remain low for t_RPafter MR goes high again. The

MR input has a 20 kΩ pull-up resistor, and may be left uncon-

nected if not used. MR is typically used to generate a system

reset from a front-panel push-button.

t_RP

POWER-ON RESET

The RST1 pin is a bidirectional I/O. It is asserted low as an out-

put if V_CCfalls below the reset threshold. It can also operate as a

reset input to the ADM1022 in the same way as MR. At power-

up, RST2 will remain asserted for t_RPafter RST1 goes high.

MR

RST2

t_RP

t

The RST2 output is asserted low under any of the following

conditions:

MANUAL RESET (FOR EXAMPLE)

≤ the MR input is low, as previously described,

– RST1 is asserted low as an output or pulled low as an input,

≤ V_MONis below the reset threshold.

Figure 18. Operation of Reset Outputs

RST1 AS I/O

If RST1 is used as a reset input to the ADM1022 while also

being used as a system reset output, it will be necessary to sepa-

rate the two functions so that a reset from the system to the

ADM1022 does not also reset the system.

POWER-ON RESET

When the ADM1022 is powered up, it will initiate a power-on

reset sequence when the supply voltage V_CCrises above the

power-on reset threshold, with registers being reset to their

power-on values. Normal operation will begin when the supply

voltage rises above the reset threshold. Registers whose power-

on values are not shown have power on conditions that are

indeterminate (this includes the Value and Limit Registers). In

most applications, usually the ﬁrst action after power-on would

be to write limits into the Limit Registers.

This can be achieved using the circuit of Figure 19. If ALT_RST

is high, then reset outputs from the ADM1022 can pass through

N2 to reset the system.

If, however, ALT_RST is low, the ADM1022 will be reset, but

SYS_RST will be held high by the high input from N1 to N2.

Power-on reset clears or initializes the following registers (the ini-

tialized values are shown in Table IV):

V

CC

ADM1022

– Conﬁguration Register

– Interrupt Status Register

– Interrupt Status Mirror Register

– Interrupt Mask Register

– Test Register

– Analog Output Register

– Programmable Trip Point Registers

100k⍀

RST1

N2

SYS_RST

N1

ALT_RST

Figure 19. Separation of RST1 Input from RST1 Output

–14–

REV. 0

ADM1022

5 V OPERATION

The structure of the NAND Tree is shown in Figure 21. To

perform a NAND Tree test, all pins are initially driven low. The

test vectors set all inputs low, then one-by-one toggles them

high (keeping them high). Exercising the test circuit with this

“walking one” pattern, starting with the input closest to the out-

put of the tree, cycling towards the farthest, causes the output of

the tree to toggle with each input change. Allow for a typical

propagation delay of 500 ns.

The ADM1022 may be operated with V_CCand/or V_MONcon-

nected to any supply voltage between 3.0 V and 5.5 V, but it

should be noted that the reset threshold voltages are ﬁxed and

optimized for 3.3 V operation. If the V_CCsupply voltage is 5 V,

for example, the V_MONinput can still be used to monitor another

3.3 V supply without problems. However, the reset threshold for

the 5 V, V_CCsupply, may be below that at which 5 V logic will

operate reliably and may not give a reliable indication of brown-

out on the 5 V supply.

POWER-ON

RESET

Alternatively, V_MONmay be conﬁgured to monitor a supply volt-

age higher than 3.3 V by adding an input attenuator.

CLK

D

Q

FAN_SPD/

NTEST_IN

LATCH

ENABLE

The ratio of R1 to R2 is given by:

R1/R2 = (V_R– 2.93)/2.93

GPI

Where V_Ris the desired reset voltage and 2.93 V is the nominal

reset voltage of the V_MONinput.

SCL

SDA

MR

ADD/NTEST_OUT

Figure 21. NAND Tree

V

MON

R1

V

IN

Table III. Test Vectors

R2

GPI

SCL

SDA

MR

ADD/NTEST_OUT

0

1

0

1

0

1

0

1

0

1

0

1

Figure 20. Scaling V_MONto a Higher Reset Voltage

The input resistance of the V_MONinput is approximately 100 kΩ,

with a tolerance of around 30%, so the parallel combination of

R1 and R2 should be much lower than 100 kΩ to minimize

errors due to variations in this input resistance.

CONFIGURING THE INTERRUPT

INITIALIZATION (SOFT RESET)

On power-up, the Interrupt functionality of the device is disabled.

The Conﬁguration Register (0x40) must be written to, in order

to enable the Interrupt output. The INT_Clear bit (Bit 2) should

be cleared to 0 and the INT_Enable bit (Bit 1) of the Register

should be set to 1.

Soft reset performs a similar, but not identical, function to

power-on reset. The Test Register and Analog Output register

are not initialized.

Soft reset is accomplished by setting Bit 4 of the Conﬁguration

Register high. This bit automatically clears after being set.

If the INT_Enable bit is set, and the INT_Clear bit is not

cleared to 0, then any interrupts generated will be reflected in

the Interrupt Status Register, but will not toggle the Interrupt

pin externally.

NAND TREE TEST

A NAND tree is provided in the ADM1022 for Automated Test

Equipment (ATE) board level connectivity testing. The device

is placed into NAND tree test mode by powering up with pin

FAN_SPD/NTEST_IN (Pin 8) held high. This pin is sampled

and its state at power-up is latched. If it is connected high, the

NAND tree test mode is invoked. NAND tree test mode will

only be exited once the ADM1022 is powered down.

In NAND tree test mode, all digital inputs may be tested as illus-

trated in Table III. ADD/NTEST_OUT will become the NAND

tree output pin.

REV. 0

–15–

ADM1022

Table IV. Registers

Address A7–A0

in Hex

Register Name

Comments

Value Registers

Company ID

0x13–0x3A

0x3E

See Table V.

This location will contain the company identiﬁcation number. This

register is read only.

Revision

0x3F

This location will contain the revision number of the part in the lower

four bits of the register [3:0]. The upper four bits reflect the ADM1022

Version Number [7:4]. The ﬁrst version is 1100. The next version of

ADM1022 would be 1101, etc. For instance, if the stepping were A0

and this part is an ADM1022, this register would read 1100 0000.

This register is read only.

Conﬁguration Register

0x40

0x41

0x42

0x43

0x44

0x47

0x4A

0x4C

See Table VI. Power-On Value = 0010 0101.

See Table VII. Power-On Value = 0000 0000.

Interrupt Status Register

Reserved for Future Use

Interrupt Mask Register

Reserved for Future Use

Interrupt Status Register Mirror

See Table VIII. Power-On Value = 0000 0000.

See Table IX. Power-On Value = 0000 0000.

Table V. Registers 0x13–0x3A Value Registers

Description

Address

Read/Write

0x13

Read/Write

Programmable Local Temp Sensor Automatic Trip Point—Default 70°C. This register can only

be written to if the write once bit in the conﬁguration register (0x40, Bit 3) has not been set.

Programmable Remote Thermal Diode Automatic Trip Point—Default 100°C. This register

can only be written to if the write once bit in the conﬁguration register (0x40, Bit 3) has not

been set.

0x14

Read/Write

0x15

0x17

Read/Write

Read Only

Test Register for manufacturer’s use only. Do not write to this register.

Default Local Temp Sensor Automatic Trip Point—Default 70°C. Cannot be changed. Dis-

abled when Bit 3 of Conﬁguration Register is set.

0x18

Read Only

Default Remote Thermal Diode Automatic Trip Point—Default 100°C. Cannot be changed.

Disabled when Bit 3 of Conﬁguration Register is set.

Analog Output, FAN_SPD (Defaults to 0x00h).

External Temperature Value Diode 2.

External Temperature Value Diode 1.

Internal Temperature.

External Temperature Diode 2 High Limit.

External Temperature Diode 2 Low Limit.

External Temperature Diode 1 High Limit.

0x19

0x20

0x26

0x27

0x2B

0x2C

0x37

0x38

0x39

0x3A

Read/Write

Read Only

Read/Write

External Temperature Diode 1 Low Limit.

Internal Temperature High Limit.

Internal Temperature Low Limit.

–16–

REV. 0

ADM1022

Table VI. Register 0x40 Conﬁguration Register

Description

Bit

Name

Read/Write

0

START

Read/Write

Setting this bit to a “1” enables startup of ADM1022; clearing this bit to a “0” places

ADM1022 in standby mode. Caution: The INT output will not be cleared if the user

clears this bit after an interrupt has occurred (see “INT Clear” bit). At startup tempera-

ture monitoring and limit checking functions begin. Note, all limit values should be pro-

grammed into ADM1022 prior to using the standard thermal interrupt mechanism based

upon high and low limits. (Power-Up Default = 1.)

1

2

3

INT Enable

INT Clear

Read/Write

Setting this bit to a “1” enables the INT output. 1 = Enabled 0 = Disabled

(Power-Up Default = 0).

This bit clears the INT output when set (1) without affecting the contents of the Interrupt

Status Register. (Power-Up Default = 1.)

Programmable

Automatic Trip

Point Lock Bit

Read/Write

Once

Setting this bit to a “1” will lock in the value set into the Programmable Local and Remote

Automatic Trip Point Registers (Value Register locations 0x13 and 0x14). Furthermore,

when this bit is set, the values in the Default Local and Remote Automatic Trip Point

Registers (Value Register locations 0x17 and 0x18) will no longer have an effect on the

THERM, FAN_SPD or FAN-OFF outputs. This bit cannot be written again until after

RST2 has been asserted or Power-On Reset occurs. (Power-Up Default = 0.)

Setting this bit to a “1” will restore power-up default values to the Conﬁguration Regis-

ter, Interrupt Status Register, Interrupt Status Register Mirror, Interrupt Mask Register.

This bit automatically clears itself since the power-on default is zero.

Setting this bit to a “1” will cause the FAN OFF pin to be floated. Clearing this bit to “0”

will cause the FAN OFF pin to be driven low, which requests that the fan be turned off.

This bit will be unconditionally set if the THERM pin is ever asserted. Reading this bit

reflects the state of the FAN-OFF output buffer. Due to the open-drain nature of this pin

the value read does not represent the actual state of the external circuit connected to it.

(Power-Up Default = 1.)

4

5

Soft Reset

Read/Write

FAN OFF

6

7

GPI Invert

D2

Read/Write

Setting this bit to a “1” will invert the GPI input for the purpose of level detection and

interrupt generation. Clearing this bit to a “0” leaves the GPI input unmodiﬁed. (Power-

Up Default = 0.)

Setting this bit conﬁgures Pins 11 and 12 as inputs for a second diode temperature sen-

sor. Clearing this bit conﬁgures Pin 11 as THERM output and Pin 12 as general purpose

logic input (GPI). (Power-Up Default = 0.)

Table VII. Register 0x41 Interrupt Status Register. Power-On Default <7:0> = 00h

Bit Name

Read/Write

Description

0

1

Int. Temp Error

Ext. Temp2 Error

Read Only

A one indicates that one of the internal temperature sensor limits has been exceeded.

A one indicates that one of the limits for the second external temperature sensor has

been exceeded.

2

3

4

Diode 2 Fault

Reserved

GPI Input

Read Only

A one indicates either a short- or open-circuit fault on remote sensor diode 2.

Undeﬁned.

A “1” indicates that the GPI pin is asserted. The polarity of the GPI pin is determined

by GPI Invert (Bit 6) in the Conﬁguration Register. For example, if GPI Invert is cleared,

this bit will be “1” when the GPI pin is high (“1”); this bit will be “0” when the GPI

pin is low (“0”). If GPI Invert is set, this bit will be “1” when the GPI pin is low (“0”);

this bit will be “0” when the GPI pin is high (“1”). Note that the state of GPI is not

latched; this bit simply reflects the state or inverted state of the GPI pin. Note: if this

bit is “1” reading this register will NOT clear it to “0.”

5

Ext. Temp1 Error

Read Only

A one indicates that one of the limits for the ﬁrst external temperature sensor has been

exceeded.

6

7

THERM Input

Diode 1 Fault

Read Only

A one indicates that the thermal overload (THERM) line has been asserted externally.

A one indicates either a short- or open-circuit fault on remote sensor diode 1.

NOTE: An error that causes continuous interrupts to be generated may be masked in its respective mask register until the error can be alleviated.

REV. 0

–17–

ADM1022

Table VIII. 0x43 Interrupt Mask Register. Power-On Default <7:0> = 00h

Bit

Name

Read/Write

Description

0

1

2

3

4

5

6

7

Int. Temp Error

Ext. Temp2 Error

Diode 2 Fault

Reserved

Read Only

Read/Write

A one disables the corresponding interrupt status bit for the INT output.

Undeﬁned.

A one disables the corresponding interrupt status bit for the INT output.

GPI Input

Ext. Temp1 Error

THERM Input

Diode 1 Fault

Table IX. Register 0x4C Interrupt Status Register Mirror. Power-On Default <7:0> = 00h

Bit

Name

Read/Write

Description

0

Int. Temp Error

Read Only

A one indicates that one of the internal temperature sensor limits has been

exceeded.

1

Ext. Temp2 Error

Read Only

A one indicates that one of the limits for the second external temperature

sensor has been exceeded.

2

3

4

Diode 2 Fault

Reserved

GPI Input

Read Only

A one indicates either a short- or open-circuit fault on remote sensor diode 2.

Undeﬁned

A “1” indicates that the GPI pin is asserted. The polarity of the GPI pin is

determined by GPI Invert (Bit 6) in the Conﬁguration Register. For example,

if GPI Invert is cleared, this bit will be “1” when the GPI pin is high (“1”);

this bit will be “0” when the GPI pin is low (“0.”) If GPI Invert is set, this bit

will be “1” when the GPI pin is low (“0”); this bit will be “0” when the GPI

pin is high (“1”). Note that the state of GPI is not latched; this bit simply

reflects the state or inverted state of the GPI pin. Note: if this bit is “1”

reading this register will NOT clear it to “0.”

5

6

7

Ext. Temp1 Error

THERM Input

Diode 1 Fault

Read Only

A one indicates that one of the limits for the ﬁrst external temperature sensor

has been exceeded.

A one indicates that the thermal overload (THERM) line has been asserted

externally.

A one indicates either a short- or open-circuit fault on remote sensor diode 1.

–18–

REV. 0

ADM1022

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

16-Lead QSOP

(RQ-16)

0.197 (5.00)

0.189 (4.80)

9

16

1

0.244 (6.20)

0.228 (5.79)

0.157 (3.99)

0.150 (3.81)

8

PIN 1

0.069 (1.75)

0.053 (1.35)

0.059 (1.50)

MAX

8؇

0؇

0.010 (0.25)

0.004 (0.10)

0.012 (0.30)

0.008 (0.20)

0.025

(0.64)

BSC

0.050 (1.27)

0.016 (0.41)

SEATING 0.010 (0.20)

PLANE

0.007 (0.18)

REF: JEDEC 0.150" SSOP – DRAWING NUMBER MO-137

REV. 0

–19–


型号：	ADM1022
厂家：	ADI
描述：	Low-Cost PC Temperature Monitor and Fan Control ASIC 低价电脑温度监控和风扇控制ASIC 风扇电脑监控 PC
文件：	总19页 (文件大小：190K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ADM1022 [ADI]

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