LM89-1DIMM/NOPB [TI]

具有 SMBus 接口和 2 个地址用于总线共享的 ±0.75°C 远程和本地温度传感器 | DGK | 8 | 0 to 125;


型号：	LM89-1DIMM/NOPB
厂家：	TEXAS INSTRUMENTS
描述：	具有 SMBus 接口和 2 个地址用于总线共享的 ±0.75°C 远程和本地温度传感器 \| DGK \| 8 \| 0 to 125 温度传感传感器温度传感器
文件：	总39页 (文件大小：1060K)
中文：	中文翻译
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LM89

SNIS128D –AUGUST 2002–REVISED JUNE 2014

LM89 ±0.75°C Accurate, Remote Diode And Local Digital Temperature Sensor

With Two-Wire Interface

1 Features

3 Description

The LM89 is an 11-bit digital temperature sensor with

a 2-wire System Management Bus (SMBus) serial

interface. The LM89 accurately measures its own

temperature as well as the temperature of an external

device, such as processor thermal diode or diode-

connected transistor such as the 2N3904. The

temperature of any ASIC, GPU, FPGA or MCU can

be accurately determined using the LM89 as long as

•

Accurately Senses Die Temperature of Remote

ICs or Diode Junctions

•

Offset Register Allows Accurate Sensing of a

Variety of Thermal Diodes

•

On-Board Local Temperature Sensing

10-Bit Plus Sign Remote Diode Temperature Data

Format, 0.125°C Resolution

dedicated diode (semiconductor junction) is

•

T_CRIT_A Output Useful for System Shutdown

ALERT Output Supports SMBus 2.0 Protocol

available on the target die. The LM89 has an Offset

factors without requiring software management.

SMBus 2.0 Compatible Interface, Supports

TIMEOUT

Activation of the ALERT occurs when any

temperature goes outside a preprogrammed window

set by the HIGH and LOW limit registers or exceeds

the T_CRIT limit. Activation of the T_CRIT_A occurs

when any temperature exceeds the T_CRIT

programmed limit.

•

8-Pin VSSOP and SOIC Packages

Key Specifications:

–

Supply Voltage: 3.0 V to 3.6 V

Local Temp Accuracy (includes quantization

error)

The LM89 is pin and register compatible with the

LM86, LM90, LM99, On Semiconductor ADM1032

and Maxim MAX6657/8.

–

T_A= 25°C to 125°C ±3.0 °C (max)

–

Remote Diode Temp Accuracy (includes

quantization error)

The LM89C and the LM89-1C have the same

functions but different SMBus slave addresses,

allowing multiple LM89's on a bus. LM89-1D's default

local T_CRIT temperature limit is 105°C; all other

versions are 85°C. (See Device Comparison Table.)

–

T_A= 30°C, T_D= 80°C ±0.75 °C (max)

2 Applications

•

Processor/Computer System Thermal

Management

Device Information⁽¹⁾

(For Example, Laptop, Desktop, Workstations,

Server)

PART NUMBER

LM89-1D

PACKAGE

VSSOP (8)

SOIC (8)

BODY SIZE (NOM)

3.0 mm x 3.0 mm

4.9 mm x 3.9 mm

•

Electronic Test Equipment

Office Electronics

LM89C

(1) For all available packages, see the orderable addendum at

the end of the datasheet.

4 Remote Diode Temperature Sensor System Diagram

Main Power Supply

T_CRIT_A Temperature Response Diagram

Core Voltage

Shutdown Control

3.3V derived

from Aux.

Supply

T_CRIT_A

D+

MCU/

GPU/

ASIC/

FPGA

LM89

SMBus

Master

2.2nF*

D-

SMBData

SMBCLK

ALERT

*Note: 2.2nF capacitor must be placed as close as possible to D+ and D- pins of the LM89.

An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,

intellectual property matters and other important disclaimers. UNLESS OTHERWISE NOTED, this document contains ADVANCE

INFORMATION for pre-production products; subject to change without notice.

LM89

SNIS128D –AUGUST 2002–REVISED JUNE 2014

www.ti.com

Table of Contents

9.1 Overview ................................................................... 9

9.2 Functional Block Diagram ......................................... 9

9.3 Feature Description................................................... 9

9.4 Device Functional Modes........................................ 18

9.5 Programming .......................................................... 19

9.6 Register Maps ........................................................ 19

10 Application and Implementation........................ 24

10.1 Application Information.......................................... 24

10.2 Typical Application ............................................... 24

10.3 Do's and Don'ts .................................................... 26

11 Power Supply Recommendations ..................... 27

12 Layout................................................................... 28

12.1 Layout Guidelines ................................................. 28

12.2 Layout Example .................................................... 28

13 Device and Documentation Support ................. 29

13.1 Trademarks........................................................... 29

13.2 Electrostatic Discharge Caution............................ 29

13.3 Glossary................................................................ 29

Features.................................................................. 1

Applications ........................................................... 1

Description ............................................................. 1

Remote Diode Temperature Sensor System

Diagram................................................................... 1

Revision History..................................................... 2

Device Comparison Table..................................... 3

Pin Configuration And Functions ........................ 3

Specifications......................................................... 4

8.1 Absolute Maximum Ratings ...................................... 4

8.2 Handling Ratings....................................................... 5

8.3 Recommended Operating Conditions....................... 5

8.4 Thermal Information.................................................. 5

8.5 Temperature-To-Digital Converter Characteristics ... 5

8.6 Digital DC Characteristics ......................................... 6

8.7 Timing Requirements................................................ 6

8.8 SMBus Digital Switching Characteristics .................. 7

8.9 Typical Characteristics.............................................. 8

Detailed Description .............................................. 9

14 Mechanical, Packaging, and Orderable

Information ........................................................... 29

5 Revision History

Changes from Revision C (March 2013) to Revision D

Page

•

Changed data sheet flow and layout to conform with new Texas Instruments standards. Added the following

sections: Application and Implementation, Power Supply Recommendations, Layout, Device and Documentation

Support, Mechanical, Packaging, and Orderable Information................................................................................................ 1

Added information for LM89-1DIMM throughout document. .................................................................................................. 1

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SNIS128D –AUGUST 2002–REVISED JUNE 2014

6 Device Comparison Table

Order Number

LM89CIM

Local T_CRIT Threshold

Slave Address [A6:A0]

100 1100

85°C

105°C

LM89CIMM

LM89-1CIMM

LM89-1DIMM

100 1100

100 1101

7 Pin Configuration And Functions

8-Pin VSSOP or SOIC

DGK or D Packages

(TOP VIEW)

Pin Functions

DESCRIPTION

NAME

DGK or D

NUMBER

FUNCTION

TYPICAL CONNECTION

V_DD

Positive Supply Voltage Input

DC Voltage from 3.0 V to 3.6 V. V_DDshould be bypassed with a 0.1µF

capacitor in parallel with 100pF. The 100pF capacitor should be

placed as close as possible to the power supply pin. A bulk

capacitance of approximately 10µF needs to be in the near vicinity to

the LM89 V_DD

D+

Diode Current Source

To Diode Anode. Connected to remote discrete diode-connected

transistor junction or to the diode-connected transistor junction on a

remote IC whose die temperature is being sensed. A 2.2 nF diode

bypass capacitor is required to filter high frequency noise. Place the

2.2 nF capacitor between and as close as possible to the LM89's D+

and D− pins. Make sure the traces to the 2.2 nF capacitor are

matched.

D−

Diode Return Current Sink

To Diode Cathode.

T_CRIT_A

T_CRIT Alarm Output, Open-Drain, Pull-Up Resistor, Controller Interrupt or Power Supply Shutdown

Active-Low

Control

GND

Power Supply Ground

Ground

ALERT

Interrupt Output, Open-Drain,

Active-Low

Pull-Up Resistor, Controller Interrupt or Alert Line

SMBData

SMBCLK

SMBus Bi-Directional Data Line,

Open-Drain Output

From and to Controller, Pull-Up Resistor

From Controller, Pull-Up Resistor

SMBus Input

Table 1. ESD Protection⁽¹⁾

Pin Name

NO.

SNP

ESD

CLAMP

V_DD

D+

D−

T_CRIT_A

(1) An “x” indicates that the component exists.

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Table 1. ESD Protection⁽¹⁾(continued)

Pin Name

NO.

SNP

ESD

CLAMP

ALERT

SMBData

SMBCLK

V+

I/O

ESD

Clamp

SNP

GND

Figure 1. ESD Protection Input Structure

8 Specifications

8.1 Absolute Maximum Ratings⁽¹⁾⁽²⁾

MIN

−0.3

−0.5

−0.3

-1

MAX

UNIT

Supply Voltage

6.0

Voltage at SMBData, SMBCLK, ALERT, T_CRIT_A

Voltage at Other Pins

(V_DD+ 0.3 V)

D− Input Current

°C

Input Current at All Other Pins⁽³⁾

Package Input Current⁽³⁾

-5

SMBData, ALERT, T_CRIT_A Output Sink Current

Junction Temperature

150

Soldering Information, Lead Temperature

SOIC or VSSOP Packages⁽⁴⁾

Vapor Phase (60

seconds)

215

220

°C

Infrared (15 seconds)

(1) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not

apply when operating the device beyond its rated operating conditions.

(2) Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings

only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating

conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(3) When the input voltage (V_I) at any pin exceeds the power supplies (V_I< GND or V_I> V_DD), the current at that pin should be limited to 5

mA. Parasitic components and or ESD protection circuitry are shown in Table 1 and Figure 1 for the LM89's pins. The nominal

breakdown voltage of D3 is 6.5 V. Care should be taken not to forward bias the parasitic diode, D1, present on pins: D+, D−. Forward

biasing the parasitic diode by more than 50 mV may corrupt a temperature measurements.

(4) Visit www.ti.com/packaging for other recommendations and methods of soldering surface mount devices.

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SNIS128D –AUGUST 2002–REVISED JUNE 2014

8.2 Handling Ratings

MIN

-65

MAX

150

UNIT

T_stg

Storage temperature range

°C

Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all

pins⁽¹⁾

-2000

2000

Charged device model (CDM), per JEDEC specification

JESD22-C101, all pins; Applies only to LM89-1DiMM⁽²⁾

-1000

-200

1000

200

V_(ESD)

Electrostatic discharge

Machine model ESD stress voltage, per JEDEC specification

JESD22-A115.⁽³⁾

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

(3) The machine model is a 200pF capacitor discharged directly into each pin.

8.3 Recommended Operating Conditions

MIN

MAX

UNIT

Operating Temperature Range

Electrical Characteristics Temperature Range

LM89

125

°C

_MIN≤ T_A≤ T_MAX

0°C ≤ T_A≤ +85°C

Supply Voltage Range (V_DD

)

3.0

3.6

8.4 Thermal Information

LM89

VSSOP

8 PINS

158

LM89

SOIC

8 PINS

116

THERMAL METRIC⁽¹⁾

UNIT

R_θJA

R_θJC(top)

R_θJB

ψ_JT

Junction-to-ambient thermal resistance

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

°C/W

Junction-to-top characterization parameter

Junction-to-board characterization parameter

ψ_JB

(1) For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.

8.5 Temperature-To-Digital Converter Characteristics

Unless otherwise noted, these specifications apply for V_DD= +3.0Vdc to 3.6Vdc. Unless otherwise noted, MIN and MAX limits

apply for T_A= T_J= T_MINto T_MAXand typical limits T_A= T_J= +25°C.

PARAMETER

TEST CONDITIONS

MIN⁽¹⁾

TYP⁽²⁾

MAX⁽¹⁾

UNIT

°C

(3)

Temperature Error Using Local Diode

T_A= +25°C to +125°C,

-3

±1

0.75

Temperature Error Using Remote Diode of 0.13 T_A= +30°C

micron Pentium 4 or other devices with typical

nonideality of 1.0021 and series R= 3.64Ω.

to +50°C

T_Diode= +80°C

-0.75

-1

°C

T_A= +30°C

T_Diode= +60°C to

+100°C

°C

T_A= +0°C to T_Diode= +25°C to

+85°C +125°C

-3

°C

Remote Diode Measurement Resolution

Local Diode Measurement Resolution

0.125

Bits

°C

Bits

°C

(1) Limits are ensured to AOQL (Average Outgoing Quality Level).

(2) Typical values are at T_A= 25°C and represent most likely parametric norm.

(3) Local temperature accuracy does not include the effects of self-heating. The rise in temperature due to self-heating is the product of the

internal power dissipation of the LM89 and the thermal resistance. See Thermal Information for the thermal resistance to be used in the

self-heating calculation.

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Temperature-To-Digital Converter Characteristics (continued)

Unless otherwise noted, these specifications apply for V_DD= +3.0Vdc to 3.6Vdc. Unless otherwise noted, MIN and MAX limits

apply for T_A= T_J= T_MINto T_MAXand typical limits T_A= T_J= +25°C.

PARAMETER

TEST CONDITIONS

MIN⁽¹⁾

TYP⁽²⁾

MAX⁽¹⁾

UNIT

(4)

Quiescent Current

SMBus Inactive, 16Hz conversion

rate

0.8

1.7

Shutdown

315

0.7

160

µA

D− Source Voltage

Diode Source Current

(D+ − D−) = +0.65V; high level

Low level

110

315

µA

ALERT and T_CRIT_A Output Saturation

Voltage

I_OUT= 6.0 mA

0.4

Power-On Reset Threshold

Measure on V_DDinput, falling

1.8

2.4

edge

(5)

Local and Remote HIGH Default Temperature

settings

°C

(5)

Local and Remote LOW Default Temperature

settings

Local T_CRIT Default Temperature Setting for

LM89-1C and LM89C

(5)

Local T_CRIT Default Temperature Setting for

LM89-1D

105

110

(5)

Remote T_CRIT Default Temperature Setting

(4) Limits are specific to TI's AOQL (Average Outgoing Quality Level).

(5) Default values set at power up.

8.6 Digital DC Characteristics

Unless otherwise noted, these specifications apply for V_DD= +3.0Vdc to 3.6Vdc. Unless otherwise noted, MIN and MAX limits

apply for T_A= T_J= T_MINto T_MAXand typical limits T_A= T_J= +25°C.

SYMBOL

PARAMETER

TEST CONDITIONS

MIN⁽¹⁾

TYP⁽²⁾

MAX⁽¹⁾

UNIT

SMBData, SMBCLK INPUTS

V_IN(1)

Logical “1” Input Voltage

Logical “0”Input Voltage

2.1

V_IN(0)

0.8

V_IN(HYST)

SMBData and SMBCLK Digital Input

Hysteresis

400

I_IN(1)

I_IN(0)

C_IN

Logical “1” Input Current

Logical “0” Input Current

Input Capacitance

V_IN= V_DD

V_IN= 0 V

0.005

−0.005

µA

-10

ALL DIGITAL OUTPUTS

I_OH

High Level Output Current

SMBus Low Level Output Voltage

V_OH= V_DD

µA

V_OL

I_OL= 4mA

I_OL= 6mA

0.4

0.6

(1) Limits are specific to TI's AOQL (Average Outgoing Quality Level).

(2) Typical values are at T_A= 25°C and represent most likely parametric norm.

8.7 Timing Requirements

Unless otherwise noted, these specifications apply for V_DD= +3.0Vdc to +3.6Vdc. Unless otherwise noted, MIN and MAX

limits apply for T_A= T_J= T_MINto T_MAXand typical limits T_A= T_J= +25°C.

PARAMETER

MIN⁽¹⁾

TYP⁽²⁾

MAX⁽¹⁾

UNIT

(3)

Conversion Time of All Temperatures at the Fastest Setting

31.25

34.4

(1) Limits are specific to TI's AOQL (Average Outgoing Quality Level).

(2) Typical values are at T_A= 25°C and represent most likely parametric norm.

(3) This specification is provided only to indicate how often temperature data is updated. The LM89 can be read at any time without regard

to conversion state (and will yield last conversion result)

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8.8 SMBus Digital Switching Characteristics

Unless otherwise noted, these specifications apply for V_DD= +3.0Vdc to +3.6Vdc, C_L(load capacitance) on output lines = 80

pF. Unless otherwise noted, MIN and MAX limits apply for T_A= T_J= T_MINto T_MAXand typical limits T_A= T_J= +25°C.

The switching characteristics of the LM89 fully meet or exceed the published specifications of the SMBus version 2.0. The

following parameters are the timing relationships between SMBCLK and SMBData signals related to the LM89. They adhere

to but are not necessarily the SMBus bus specifications.

SYMBOL

f_SMB

PARAMETER

SMBus Clock Frequency

TEST CONDITIONS

MIN⁽¹⁾

TYP⁽²⁾

MAX⁽¹⁾

Unit

kHz

µs

100

t_LOW

SMBus Clock Low Time

SMBus Clock High Time

SMBus Rise Time

from V_IN(0)max to V_IN(0)max

4.7

4.0

25,000

t_HIGH

from V_IN(1)min to V_IN(1)min

µs

(3)

t_R,SMB

t_F,SMB

t_OF

µs

(4)

SMBus Fall Time

0.3

µs

Output Fall Time

C_L= 400pF,

250

(4)

I_O= 3mA,

t_TIMEOUTSMBData and SMBCLK Time Low for Reset

(5)

of Serial Interface

t_SU;DAT

t_HD;DAT

t_HD;STA

Data In Setup Time to SMBCLK High

Data Out Stable after SMBCLK Low

250

300

100

900

Start Condition SMBData Low to SMBCLK

Low (Start condition hold before the first

clock falling edge)

t_SU;STO

t_SU;STA

t_BUF

Stop Condition SMBCLK High to SMBData

Low (Stop Condition Setup)

100

0.6

1.3

µs

SMBus Repeated Start-Condition Setup

Time, SMBCLK High to SMBData Low

SMBus Free Time Between Stop and Start

Conditions

(1) Limits are specific to TI's AOQL (Average Outgoing Quality Level).

(2) Typical values are at T_A= 25°C and represent most likely parametric norm.

(3) The output rise time is measured from (V_IN(0)max + 0.15V) to (V_IN(1)min − 0.15V).

(4) The output fall time is measured from (V_IN(1)min - 0.15V) to (V_IN(1)min + 0.15V).

(5) Holding the SMBData and/or SMBCLK lines Low for a time interval greater than t_TIMEOUTwill reset the LM89's SMBus state machine,

therefore setting SMBData and SMBCLK pins to a high impedance state.

t_LOW

t_R

t_F

V_IH

V_IL

SMBCLK

SMBDAT

t_HD;STA

t_SU;STA

t_HIGH

t_SU;STO

t_BUF

t_SU;DAT

t_HD;DAT

V_IH

V_I

Figure 2. SMBus Communication

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8.9 Typical Characteristics

2000

1800

1600

140

1200

1000

800

600

400

0.01

0.1

1.0

100

CONVERSION RATE (Hz)

Figure 3. Conversion Rate Effect On Power Supply Current

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Detailed Description

9.1 Overview

The LM89 temperature sensor incorporates a delta V_BEbased temperature sensor using a Local or Remote

diode and a 10-bit plus sign ADC (Delta-Sigma Analog-to-Digital Converter). The LM89 is compatible with the

serial SMBus version 2.0 two-wire interface. Digital comparators compare the measured Local Temperature (LT)

to the Local High (LHS), Local Low (LLS) and Local T_CRIT (LCS) user-programmable temperature limit

registers. The measured Remote Temperature (RT) is digitally compared to the Remote High (RHS), Remote

Low (RLS) and Remote T_CRIT (RCS) user-programmable temperature limit registers. Activation of the ALERT

output indicates that a comparison is greater than the limit preset in a T_CRIT or HIGH limit register or less than

the limit preset in a LOW limit register. The T_CRIT_A output responds as a true comparator with built in

hysteresis. The hysteresis is set by the value placed in the Hysteresis register (TH). Activation of T_CRIT_A

occurs when the temperature is above the T_CRIT setpoint. T_CRIT_A remains activated until the temperature

goes below the setpoint calculated by T_CRIT − TH. The hysteresis register impacts both the remote

temperature and local temperature readings.

The LM89 may be placed in a low power consumption (Shutdown) mode by setting the RUN/STOP bit found in

the Configuration register. In the Shutdown mode, the LM89's SMBus interface remains while all circuitry not

required is turned off.

The Local temperature reading and setpoint data registers are 8-bits wide. The format of the 11-bit remote

temperature data is a 16-bit left justified word. Two 8-bit registers, high and low bytes, are provided for each

setpoint as well as the temperature reading. Two offset registers (RTOLB and RTOHB) can be used to

compensate for nonideality error, discussed further in Diode Nonideality. The remote temperature reading

reported is adjusted by subtracting from or adding to the actual temperature reading the value placed in the

offset registers.

9.2 Functional Block Diagram

3.0V-3.6V

ALERT

Fault

Queue

10-Bit Plus Sign

'-6

Converter

Temperature

Sensor

Circuitry

Programable

Level

Filter

Fault

Queue

D+

D-

Local/Remote

Diode Selector

T_Crit_A

Fault

Queue

LOW

Limit

Registers

T_CRIT Limit

& Hysteresis

Registers

HIGH

Limit

Registers

Conversion

Rate

Registers

Local/Remote

Temperature

Registers

Configuration

and Status

Registers

Control Logic

One Shot

Remote Offset

Registers

SMBData

SMBClock

Two-Wire Serial

Interface

9.3 Feature Description

9.3.1 Conversion Sequence

The LM89 takes approximately 31.25 ms to convert the Local Temperature (LT), Remote Temperature (RT), and

to update all of its registers. Only during the conversion process the busy bit (D7) in the Status register (02h) is

high. These conversions are addressed in a round robin sequence. The conversion rate may be modified by the

Conversion Rate Register (04h). When the conversion rate is modified a delay is inserted between conversions,

the actual conversion time remains at 31.25 ms. Different conversion rates will cause the LM89 to draw different

amounts of supply current as shown in Figure 4.

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Feature Description (continued)

2000

1800

1600

140

1200

1000

800

600

400

0.01

0.1

1.0

100

CONVERSION RATE (Hz)

Figure 4. Conversion Rate Effect On Power Supply Current

9.3.2 The ALERT Output

The LM89's ALERT pin is an active-low open-drain output that is triggered by a temperature conversion that is

outside the limits defined by the temperature setpoint registers. Reset of the ALERT output is dependent upon

the selected method of use. The LM89's ALERT pin is versatile and will accommodate three different methods of

use to best serve the system designer: as a temperature comparator, as a temperature based interrupt flag, and

as part of an SMBus ALERT system. The three methods of use are further described below. The ALERT and

interrupt methods are different only in how the user interacts with the LM89.

Each temperature reading (LT and RT) is associated with a T_CRIT setpoint register (LCS, RCS), a HIGH

setpoint register (LHS and RHS) and a LOW setpoint register (LLS and RLS). At the end of every temperature

reading, a digital comparison determines whether that reading is above its HIGH or T_CRIT setpoint or below its

LOW setpoint. If so, the corresponding bit in the STATUS REGISTER is set. If the ALERT mask bit is not high,

any bit set in the STATUS REGISTER, with the exception of Busy (D7) and OPEN (D2), will cause the ALERT

output to be pulled low. Any temperature conversion that is out of the limits defined by the temperature setpoint

registers will trigger an ALERT. Additionally, the ALERT mask bit in the Configuration register must be cleared to

trigger an ALERT in all modes.

9.3.2.1 ALERT Output As A Temperature Comparator

When the LM89 is implemented in a system in which it is not serviced by an interrupt routine, the ALERT output

could be used as a temperature comparator. Under this method of use, once the condition that triggered the

ALERT to go low is no longer present, the ALERT is de-asserted (Figure 5). For example, if the ALERT output

was activated by the comparison of LT > LHS, when this condition is no longer true the ALERT will return HIGH.

This mode allows operation without software intervention, once all registers are configured during set-up. In order

for the ALERT to be used as a temperature comparator, bit D0 (the ALERT configure bit) in the FILTER and

ALERT CONFIGURE REGISTER (BFh) must be set high. This is not the power-on-default state.

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Feature Description (continued)

Remote High Limit

RDTS Measurement

LM89 ALERT Pin

Status Register: RTDS High

TIME

Figure 5. ALERT Comparator Temperature Response Diagram

9.3.2.2 ALERT Output As An Interrupt

The LM89's ALERT output can be implemented as a simple interrupt signal when it is used to trigger an interrupt

service routine. In such systems it is undesirable for the interrupt flag to repeatedly trigger during or before the

interrupt service routine has been completed. Under this method of operation, during a read of the STATUS

the master has reset the ALERT mask bit, at the end of the interrupt service routine. The STATUS REGISTER

bits are cleared only upon a read command from the master (see Figure 6) and will be re-asserted at the end of

the next conversion if the triggering condition(s) persist(s). In order for the ALERT to be used as a dedicated

interrupt signal, bit D0 (the ALERT configure bit) in the FILTER and ALERT CONFIGURE REGISTER (BFh)

must be set low. This is the power-on-default state.

The following sequence describes the response of a system that uses the ALERT output pin as a interrupt flag:

1. Master Senses ALERT low

2. Master reads the LM89 STATUS REGISTER to determine what caused the ALERT

3. LM89 clears STATUS REGISTER, resets the ALERT HIGH and sets the ALERT mask bit (D7 in the

Configuration register).

4. Master attends to conditions that caused the ALERT to be triggered. The fan is started, setpoint limits are

adjusted, etc.

5. Master resets the ALERT mask (D7 in the Configuration register).

RDTS Measurement

Remote High Limit

LM89 ALERT pin

ALERT mask set in

response to reading of

status register by

master

End of Temperature

conversion

Status Register: RTDS High

TIME

Figure 6. ALERT Output As An Interrupt Temperature Response Diagram

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Feature Description (continued)

9.3.2.3 ALERT Output As An SMBus Alert

When the ALERT output is connected to one or more ALERT outputs of other SMBus compatible devices and to

a master, an SMBus alert line is created. Under this implementation, the LM89's ALERT should be operated

using the ARA (Alert Response Address) protocol. The SMBus 2.0 ARA protocol, defined in the SMBus

specification 2.0, is a procedure designed to assist the master in resolving which part generated an interrupt and

service that interrupt while impeding system operation as little as possible.

The SMBus alert line is connected to the open-drain ports of all devices on the bus thereby AND'ing them

together. The ARA is a method by which with one command the SMBus master may identify which part is pulling

the SMBus alert line LOW and prevent it from pulling it LOW again for the same triggering condition. When an

ARA command is received by all devices on the bus, the devices pulling the SMBus alert line LOW, first, send

their address to the master and second, release the SMBus alert line after recognizing a successful transmission

of their address.

The SMBus 1.1 and 2.0 specification state that in response to an ARA (Alert Response Address) “after

acknowledging the slave address the device must disengage its SMBALERT pulldown”. Furthermore, “if the host

still sees SMBALERT low when the message transfer is complete, it knows to read the ARA again”. This SMBus

“disengaging of SMBALERT” requirement prevents locking up the SMBus alert line. Competitive parts may

address this “disengaging of SMBALERT” requirement differently than the LM89 or not at all. SMBus systems

that implement the ARA protocol as suggested for the LM89 will be fully compatible with all competitive parts.

The LM89 fulfills “disengaging of SMBALERT” by setting the ALERT mask bit (bit D7 in the Configuration

ALERT output pin. Once the ALERT mask bit is activated, the ALERT output pin will be disabled until enabled by

software. In order to enable the ALERT the master must read the STATUS REGISTER, at address 02h, during

the interrupt service routine and then reset the ALERT mask bit in the Configuration register to 0 at the end of

the interrupt service routine.

The following sequence describes the ARA response protocol.

1. Master Senses SMBus alert line low

2. Master sends a START followed by the Alert Response Address (ARA) with a Read Command.

3. Alerting Device(s) send ACK.

4. Alerting Device(s) send their Address. While transmitting their address, alerting devices sense whether their

address has been transmitted correctly. (The LM89 will reset its ALERT output and set the ALERT mask bit

once its complete address has been transmitted successfully.)

5. Master/slave NoACK

6. Master sends STOP

7. Master attends to conditions that caused the ALERT to be triggered. The STATUS REGISTER is read and

fan started, setpoint limits adjusted, etc.

8. Master resets the ALERT mask (D7 in the Configuration register).

The ARA, 000 1100, is a general call address. No device should ever be assigned this address.

Bit D0 (the ALERT configure bit) in the FILTER and ALERT CONFIGURE REGISTER (BFh) must be set low in

order for the LM89 to respond to the ARA command.

The ALERT output can be disabled by setting the ALERT mask bit, D7, of the Configuration register. The power-

on-default is to have the ALERT mask bit and the ALERT configure bit low.

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Feature Description (continued)

Remote High Limit

RDTS Measurement

LM89 ALERT pin

ALERT mask set in

response to ARA

from master

Status Register: RTDS High

TIME

Figure 7. ALERT Output As An Smbus Alert Temperature Response Diagram

9.3.3 T_CRIT_A Output And T_CRIT Limit

T_CRIT_A is activated when any temperature reading is greater than the limit preset in the critical temperature

setpoint register (T_CRIT), as shown in Figure 8. The Status Register can be read to determine which event

caused the alarm. A bit in the Status Register is set high to indicate which temperature reading exceeded the

T_CRIT setpoint temperature and caused the alarm, see Status Register (SR).

Local and remote temperature diodes are sampled in sequence by the A/D converter. The T_CRIT_A output and

the Status Register flags are updated after every Local and Remote temperature conversion. T_CRT_A follows

the state of the comparison, it is reset when the temperature falls below the setpoint RCS-TH. The Status

T_CRIT setpoint, as shown in Figure 8.

Figure 8. T_CRIT_A Temperature Response Diagram

9.3.4 Smbus Interface

The LM89 operates as a slave on the SMBus, so the SMBCLK line is an input and the SMBData line is bi-

directional. The LM89 never drives the SMBCLK line and it does not support clock stretching. According to

SMBus specifications, the LM89 has a 7-bit slave address. All bits A6 through A0 are internally programmed and

can not be changed by software or hardware. The LM89 and LM89-1 versions have the following SMBus slave

addresses:

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Version

LM89CIM, LM89CIMM

LM89-1CIMM, LM89-

1DIMM

9.3.5 Temperature Data Format

Temperature data can only be read from the Local and Remote Temperature registers; the setpoint registers

(T_CRIT, LOW, HIGH) are read/write.

Remote temperature data is represented by an 11-bit, two's complement word with an LSB (Least Significant Bit)

equal to 0.125°C. The data format is a left justified 16-bit word available in two 8-bit registers:

Temperature

Digital Output

Binary

Hex

+125°C

+25°C

+1°C

0111 1101 0000 0000

0001 1001 0000 0000

0000 0001 0000 0000

0000 0000 0010 0000

0000 0000 0000 0000

1111 1111 1110 0000

1111 1111 0000 0000

1110 0111 0000 0000

1100 1001 0000 0000

7D00h

1900h

0100h

0020h

0000h

FFE0h

FF00h

E700h

C900h

+0.125°C

0°C

−0.125°C

−1°C

−25°C

−55°C

Local Temperature data is represented by an 8-bit, two's complement byte with an LSB (Least Significant Bit)

equal to 1°C:

Temperature

Digital Output

Binary

Hex

7Dh

19h

01h

00h

FFh

E7h

C9h

+125°C

+25°C

+1°C

0111 1101

0001 1001

0000 0001

0000 0000

1111 1111

1110 0111

1100 1001

0°C

−1°C

−25°C

−55°C

9.3.6 Open-Drain Outputs

The SMBData, ALERT and T_CRIT_A outputs are open-drain outputs and do not have internal pull-ups. A “high”

level will not be observed on these pins until pull-up current is provided by some external source, typically a pull-

up resistor. Choice of resistor value depends on many system factors but, in general, the pull-up resistor should

be as large as possible. This will minimize any internal temperature reading errors due to internal heating of the

LM89. The maximum resistance of the pull-up to provide a 2.1V high level, based on LM89 specification for High

Level Output Current with the supply voltage at 3.0V, is 82kΩ(5%) or 88.7kΩ(1%).

9.3.7 Diode Fault Detection

The LM89 is equipped with operational circuitry designed to detect fault conditions concerning the remote diode.

In the event that the D+ pin is detected as shorted to V_DDor floating, the Remote Temperature High Byte (RTHB)

OPEN bit (D2) in the status register is set. As a result, if the Remote T_CRIT setpoint register (RCS) is set to a

value less than +127°C the ALERT and T_Crit output pins will be pulled low, if the Alert Mask and T_Crit Mask

are disabled. If the Remote HIGH Setpoint High Byte Register (RHSHB) is set to a value less than +127°C then

ALERT will be pulled low, if the Alert Mask is disabled. The OPEN bit itself will not trigger and ALERT.

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In the event that the D+ pin is shorted to ground or D−, the Remote Temperature High Byte (RTHB) register is

loaded with −128°C (1000 0000) and the OPEN bit (D2) in the status register will not be set. Since operating the

LM89 at −128°C is beyond it's operational limits, this temperature reading represents this shorted fault condition.

If the value in the Remote Low Setpoint High Byte Register (RLSHB) is more than −128°C and the Alert Mask is

disabled, ALERT will be pulled low.

Remote diode temperature sensors that have been previously released and are competitive with the LM89 output

a code of 0°C if the external diode is short-circuited. This change is an improvement that allows a reading of 0°C

to be truly interpreted as a genuine 0°C reading and not a fault condition.

9.3.8 Communicating With The LM89

The data registers in the LM89 are selected by the Command Register. At power-up the Command Register is

set to “00”, the location for the Read Local Temperature Register. The Command Register latches the last

location it was set to. Each data register in the LM89 falls into one of four types of user accessibility:

1. Read only

2. Write only

3. Read/Write same address

4. Read/Write different address

A Write to the LM89 will always include the address byte and the command byte. A write to any register requires

one data byte.

Reading the LM89 can take place either of two ways:

1. If the location latched in the Command Register is correct (most of the time it is expected that the Command

read from the LM89), then the read can simply consist of an address byte, followed by retrieving the data

byte.

2. If the Command Register needs to be set, then an address byte, command byte, repeat start, and another

address byte will accomplish a read.

The data byte has the most significant bit first. At the end of a read, the LM89 can accept either acknowledge or

No Acknowledge from the Master (No Acknowledge is typically used as a signal for the slave that the Master has

read its last byte). It takes the LM89 31.25 ms to measure the temperature of the remote diode and internal

diode. When retrieving all 11 bits from a previous remote diode temperature measurement, the master must

insure that all 11 bits are from the same temperature conversion. This may be achieved by reading the MSB

(most significant byte first) followed by the LSB (least significant byte). Reading the MSB first will lock the LSB,

thus synchronizing the two bytes. One-shot mode can also be used without any restrictions on the MSB and LSB

reading sequence.

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9.3.8.1 SMBus Timing Diagrams

Figure 9. LM89 Timing Diagram

(A) Serial Bus Write To The Internal Command Register Followed By A The Data Byte

Figure 10. LM89 Timing Diagram

(B) Serial Bus Write To The Internal Command Register

SMBCLK

SMBDat

R/W

Ack

LM89

No Ack

Master

Stop

Master

Start

Master

Address byte.

Frame 1

Serial Bus Address Byte

Frame 2

Data Byte from the LM89

Figure 11. LM89 Timing Diagram

9.3.9 Serial Interface Reset

In the event that the SMBus Master is RESET while the LM89 is transmitting on the SMBData line, the LM89

must be returned to a known state in the communication protocol. This may be done in one of two ways:

1. When SMBData is LOW, the LM89 SMBus state machine resets to the SMBus idle state if either SMBData

or SMBCLK are held low for more than 35 ms (t_TIMEOUT). Note that according to SMBus specification 2.0 all

devices are to timeout when either the SMBCLK or SMBData lines are held low for 25-35 ms. Therefore, to

insure a timeout of all devices on the bus the SMBCLK or SMBData lines must be held low for at least 35

ms.

2. When SMBData is HIGH, have the master initiate an SMBus start. The LM89 will respond properly to an

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SMBus start condition at any point during the communication. After the start the LM89 will expect an SMBus

address byte.

9.3.10 Digital Filter

In order to suppress erroneous remote temperature readings due to noise, the LM89 incorporates a user-

configured digital filter. The filter is accessed in the FILTER and ALERT CONFIGURE REGISTER at BFh. The

filter can be set according to the following table.

Filter

No Filter

Level 1

Level 2

Level 2 sets maximum filtering.

Figure 13 depicts the filter output in response to a step input and an impulse input. Figure 14 depicts the digital

filter in use in a Pentium 4 processor system. Note that the two curves, with filter and without, have been

purposely offset so that both responses can be clearly seen. Inserting the filter does not induce an offset as

shown.

Figure 12. Filter Output Response To A Step Input

A) Step Response

Figure 13. Filter Output Response To A Step Input

B) Impulse Response

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LM89

with

Filter Off

LM89

with

Filter On

100

150

200

SAMPLE NUMBER

A. The filter on and off curves were purposely offset to better show noise performance.

Figure 14. Digital Filter Response In A Pentium 4 Processor System

9.3.11 Fault Queue

In order to suppress erroneous ALERT or T_CRIT triggering the LM89 incorporates a Fault Queue. The Fault

Queue acts to insure a remote temperature measurement is genuinely beyond a HIGH, LOW or T_CRIT setpoint

by not triggering until three consecutive out of limit measurements have been made, see Figure 15. The fault

queue defaults off upon power-up and may be activated by setting bit D0 in the Configuration register (09h) to

“1”.

RDTS Measurement

Status Register: RTDS High

n+1 n+2 n+3 n+4 n+5

SAMPLE NUMBER

Figure 15. Fault Queue Temperature Response Diagram

9.3.12 One-Shot Register

The One-Shot register is used to initiate a single conversion and comparison cycle when the device is in standby

mode, after which the device returns to standby. This is not a data register and it is the write operation that

causes the one-shot conversion. The data written to this address is irrelevant and is not stored. A zero will

always be read from this register.

9.4 Device Functional Modes

9.4.1 Power-On-Default States

LM89 always powers up to these known default states. The LM89 remains in these states until after the first

conversion.

1. Command Register set to 00h

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Device Functional Modes (continued)

2. Local Temperature set to 0°C

3. Remote Diode Temperature set to 0°C until the end of the first conversion.

4. Status Register set to 00h.

5. Configuration register set to 00h; ALERT enabled, Remote T_CRIT alarm enabled and Local T_CRIT alarm

enabled

6. 85°C Local T_CRIT temperature setpoint for LM89C and LM89-1C; 105°C Local T_CRIT temperature

setpoint for LM89-1D

7. 110°C Remote T_CRIT temperature setpoint

8. 70°C Local and Remote HIGH temperature setpoints

9. 0°C Local and Remote LOW temperature setpoints

10. Filter and Alert Configure Register set to 00h; filter disabled, ALERT output set as an SMBus ALERT

11. Conversion Rate Register set to 8h; conversion rate set to 16 conv./sec.

9.5 Programming

9.6 Register Maps

9.6.1 Command Register

Selects which registers will be read from or written to. Data for this register should be transmitted during the

Command Byte of the SMBus write communication.

Command Select

P0-P7: Command Select

Command Select Address

Power-On-Default State

Name

Read Address

<P7:P0> hex

Write Address

<P7:P0> hex

<D7:D0> binary

<D7:D0>

decimal

00h

01h

02h

03h

04h

0000 0000

0000 1000

RTHB

Local Temperature

Remote Temperature High Byte

Status Register

09h

0Ah

Configuration

8 (16

Conversion Rate

conv./sec)

05h

06h

07h

08h

0Bh

0Ch

0Dh

0Eh

0Fh

0100 0110

0000 0000

0100 0110

0000 0000

LHS

LLS

Local HIGH Setpoint

Local LOW Setpoint

RHSHB

RLSHB

One Shot

Remote HIGH Setpoint High Byte

Remote LOW Setpoint High Byte

Writing to this register will initiate a

one shot conversion

10h

11h

0000 0000

RTLB

Remote Temperature Low Byte

11h

RTOHB

Remote Temperature Offset High

Byte

12h

0000 0000

RTOLB

Remote Temperature Offset Low

Byte

13h

14h

19h

20h

13h

14h

19h

20h

0000 0000

0110 1110

RHSLB

RLSLB

RCS

Remote HIGH Setpoint Low Byte

Remote LOW Setpoint Low Byte

Remote T_CRIT Setpoint

110

LM89C 0101 0101

LM89-1C 0101 0101

LM89-1D 0110 1001

105

LCS

Local T_CRIT Setpoint

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Command Select Address

Power-On-Default State

Name

Read Address

<P7:P0> hex

Write Address

<P7:P0> hex

<D7:D0> binary

<D7:D0>

decimal

21h

B0h-BEh

BFh

21h

B0h-BEh

BFh

0000 1010

T_CRIT Hysteresis

Manufacturers Test Registers

Remote Diode Temperature Filter

Read Manufacturer's ID

0000 0000

0000 0001

RDTF

RMID

RDR

FEh

FFh

LM89C 0011 0001

LM89-1C 0011 0100

LM89-1D 0011 0101

Read Stepping or Die Revision Code

9.6.2 Local And Remote Temperature Registers (LT, RTHB, RTLB)

Table 2. Local And Remote Temperature Registers (LT, RTHB) (Read Only Address 00h, 01h):

BIT

Value

SIGN

For LT and RTHB D7–D0: Temperature Data. LSB = 1°C. Two's complement format.

Table 3. Local And Remote Temperature Registers (RTLB) (Read Only Address 10h):

BIT

Value

0.5

0.25

0.125

For RTLB D7–D5: Temperature Data. LSB = 0.125°C. Two's complement format.

The maximum value available from the Local Temperature register is 127; the minimum value available from the

Local Temperature register is -128. The maximum value available from the Remote Temperature register is

127.875; the minimum value available from the Remote Temperature registers is −128.875.

9.6.3 Status Register (SR)

Table 4. Status Register (SR) (Read Only Address 02h):

Bit

Value

Busy

LHIGH

LLOW

RHIGH

RLOW

OPEN

RCRIT

LCRIT

Power up default is with all bits “0” (zero).

D7: Busy: When set to “1” ADC is busy converting.

D6: LHIGH: When set to “1” indicates a Local HIGH Temperature alarm.

D5: LLOW: When set to “1” indicates a Local LOW Temperature alarm.

D4: RHIGH: When set to “1” indicates a Remote Diode HIGH Temperature alarm.

D3: RLOW: When set to “1” indicates a Remote Diode LOW Temperature alarm

D2: OPEN: When set to “1” indicates a Remote Diode disconnect.

D1: RCRIT: When set to “1” indicates a Remote Diode Critical Temperature alarm.

D0: LCRIT: When set to “1” indicates a Local Critical Temperature alarm.

9.6.4 Configuration Register

Table 5. Configuration Register (Read Address 03h /Write Address 09h):

Bit

Value

ALERT mask

RUN/STOP

Remote

T_CRIT_A

mask

Local

T_CRIT_A

mask

Fault Queue

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Power up default is with all bits “0” (zero)

D7: ALERT mask: When set to “1” ALERT interrupts are masked.

D6: RUN/STOP: When set to “1” SHUTDOWN is enabled.

D5: is not defined and defaults to “0”.

D4: Remote T_CRIT mask: When set to “1” a diode temperature reading that exceeds T_CRIT setpoint will not

activate the T_CRIT_A pin.

D3: is not defined and defaults to “0”.

D2: Local T_CRIT mask: When set to “1” a Local temperature reading that exceeds T_CRIT setpoint will not

activate the T_CRIT_A pin.

D1: is not defined and defaults to “0”.

D0: Fault Queue: when set to “1” three consecutive remote temperature measurements outside the HIGH, LOW,

or T_CRIT setpoints will trigger an “Outside Limit” condition resulting in setting of status bits and associated

output pins..

9.6.5 Conversion Rate Register

Table 6. Conversion Rate Register (Read Address 04h

/Write Address 0Ah)

Value

Conversion Rate

62.5 mHz

125 mHz

250 mHz

500 mHz

1 Hz

2 Hz

4 Hz

8 Hz

16 Hz

32 Hz

10-255

Undefined

9.6.6 Local And Remote High Setpoint Registers (LHS, RHSHB, And RHSLB)

Table 7. Local And Remote High Setpoint Registers (LHS, RHSHB) (Read Address 05h, 07h /Write

Address 0Bh, 0Dh):

BIT

Value

SIGN

For LHS and RHSHB: HIGH setpoint temperature data. Power up default is LHIGH = RHIGH = 70°C. 1 LSB =

1°C. Two's complement format.

Table 8. Local And Remote High Setpoint Registers (RHSLB) (Read/Write Address 13h):

BIT

Value

0.5

0.25

0.125

For RHSLB: Remote HIGH Setpoint Low Byte temperature data. Power up default is 0°C. 1 LSB = 0.125°C.

Two's complement format.

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9.6.7 Local And Remote Low Setpoint Registers (LLS, RLSHB, And RLSLB)

Table 9. Local And Remote Low Setpoint Registers (LLS, RLSHB) (Read Address 06h, 08h, /Write

Address 0Ch, 0Eh):

BIT

Value

SIGN

For LLS and RLSHB: HIGH setpoint temperature data. Power up default is LHIGH = RHIGH = 0°C. 1 LSB = 1°C.

Two's complement format.

Table 10. Local And Remote Low Setpoint Registers (RLSLB) (Read/Write Address 14h):

BIT

Value

0.5

0.25

0.125

For RLSLB: Remote HIGH Setpoint Low Byte temperature data. Power up default is 0°C. 1 LSB = 0.125°C.

Two's complement format.

9.6.8 Remote Temperature Offset Registers (RTOHB And RTOLB)

Table 11. Remote Temperature Offset Registers (RTOHB)(Read/Write Address 11h):

BIT

Value

SIGN

For RTOHB: Remote Temperature Offset High Byte. Power up default is LHIGH = RHIGH = 0°C. 1 LSB = 1°C.

Two's complement format.

Table 12. Remote Temperature Offset Registers (RTOLB) (Read/Write Address 12h):

BIT

Value

0.5

0.25

0.125

For RTOLB: Remote Temperature Offset High Byte. Power up default is 0°C. 1 LSB = 0.125°C. Two's

complement format.

The offset value written to these registers will automatically be added to or subtracted from the remote

temperature measurement that will be reported in the Remote Temperature registers.

9.6.9 Local And Remote T_crit Registers (RCS And LCS)

Table 13. Local And Remote T_CRIT Registers (RCS And LCS) (Read/Write Address 20h, 19h):

BIT

Value

SIGN

D7–D0: T_CRIT setpoint temperature data. Power up default is Local T_CRIT = 85°C (LM89C and LM89-1C) or

105°C (LM89-1D), and Remote T_CRIT=110°C. 1 LSB = 1°C, two's complement format.

9.6.10 T_CRIT Hysteresis Register (TH)

Table 14. T_CRIT Hysteresis Register (TH) (Read And Write Address 21h):

BIT

Value

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D7–D0: T_CRIT Hysteresis temperature. Power up default is TH = 10°C. 1 LSB = 1°C, maximum value = 31.

9.6.11 Filter And Alert Configure Register

Table 15. Filter And Alert Configure Register (Read And Write Address BFh):

BIT

Value

Filter Level

ALERT Configure

D7-D3: is not defined defaults to "0".

D2-D1: input filter setting as defined the table below:

Filter Level

No Filter

Level 1

Level 2

Level 2 sets maximum filtering.

D0: when set to "1" comparator mode is enabled.

9.6.12 Manufacturers Id Register

(Read Address FEh) The default value is 01h.

9.6.13 Die Revision Code Register

(Read Address FFh) The LM89C version has a default value of 31h or 49 decimal. The LM89-1C version has a

default value of 34h or 52 decimal. The LM89-1D has a default value of 35h or 53 decimal. This register will

increment by 1 every time there is a revision to the die by Texas Instruments.

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10 Application and Implementation

10.1 Application Information

The LM89 can be applied easily in the same way as other integrated-circuit temperature sensors, and its remote

diode sensing capability allows it to be used in new ways as well. It can be soldered to a printed circuit board,

and because the path of best thermal conductivity is between the die and the pins, its temperature will effectively

be that of the printed circuit board lands and traces soldered to the LM89's pins. This presumes that the ambient

air temperature is almost the same as the surface temperature of the printed circuit board; if the air temperature

is much higher or lower than the surface temperature, the actual temperature of the LM89 die will be at an

intermediate temperature between the surface and air temperatures. Again, the primary thermal conduction path

is through the leads, so the circuit board temperature will contribute to the die temperature much more strongly

than will the air temperature.

To measure temperature external to the LM89's die, use a remote diode. This diode can be located on the die of

a target IC, allowing measurement of the IC's temperature, independent of the LM89's temperature.

10.2 Typical Application

The LM89 has been optimized to measure the remote thermal diode of a 0.13 micron Pentium 4, a Mobile

Pentium 4 Processor-M processor or other embedded thermal diodes that have similar characteristics. A discrete

diode can also be used to sense the temperature of external objects or ambient air. Remember that a discrete

diode's temperature will be affected, and often dominated, by the temperature of its leads. Most silicon diodes do

not lend themselves well to this application. It is recommended that a MMBT3904 transistor base emitter junction

be used with the collector tied to the base (diode-connected).

An LM89 with a diode-connected MMBT3904 will have a typical -1°C offset.

T_2N3904= T_LM89+1°C

Main Power Supply

Core Voltage

Shutdown Control

3.3V derived

from Aux.

Supply

T_CRIT_A

D+

MCU/

GPU/

ASIC/

FPGA

LM89

SMBus

Master

2.2nF*

D-

SMBData

SMBCLK

ALERT

*Note: 2.2nF capacitor must be placed as close as possible to D+ and D- pins of the LM89.

10.2.1 Design Requirements

10.2.1.1 Diode Nonideality

10.2.1.1.1 Diode Nonideality Factor Effect On Accuracy

When a transistor is connected as a diode, the following relationship holds for variables V_BE, T and I_f:

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Typical Application (continued)

V_be

I_F= I_Se^KV- 1

where

(1)

k T

V_t=

where

•

q = 1.6×10⁻¹⁹Coulombs (the electron charge),

T = Absolute Temperature in Kelvin

k = 1.38×10⁻²³joules/K (Boltzmann's constant),

η is the nonideality factor of the process the diode is manufactured on,

I_S= Saturation Current and is process dependent,

I_f= Forward Current through the base emitter junction

V_BE= Base Emitter Voltage drop

(2)

In the active region, the -1 term is negligible and may be eliminated, yielding the following equation

V_be

I_F= I_Se^KV

(3)

In the above equation, η and I_Sare dependant upon the process that was used in the fabrication of the particular

diode. By forcing two currents with a very controlled ratio (N) and measuring the resulting voltage difference, it is

possible to eliminate the I_Sterm. Solving for the forward voltage difference yields the relationship:

k T

V_be= K

ln (N)

(4)

The voltage seen by the LM89 also includes the I_FR_Svoltage drop of the series resistance. The nonideality

factor, η, is the only other parameter not accounted for and depends on the diode that is used for measurement.

Since ΔV_BEis proportional to both η and T, the variations in η cannot be distinguished from variations in

temperature. Since the nonideality factor is not controlled by the temperature sensor, it will directly add to the

inaccuracy of the sensor. For the Pentium 4 and Mobile Pentium Processor-M Intel specifies a ±0.1% variation in

η from part to part. As an example, assume a temperature sensor has an accuracy specification of ±1°C at room

temperature of 25 °C and the process used to manufacture the diode has a nonideality variation of ±0.1%. The

resulting accuracy of the temperature sensor at room temperature will be:

T_ACC= ± 1°C + (±0.1% of 298 °K) = ±1.4 °C

(5)

The additional inaccuracy in the temperature measurement caused by η, can be eliminated if each temperature

sensor is calibrated with the remote diode that it will be paired with.

Processor Family

η, nonideality

TYP

MIN

MAX

Pentium III CPUID 67h

Pentium III CPUID 68h/PGA370Socket/Celeron

Pentium 4, 423 pin

1.0065

1.008

1.0125

1.0368

1.0030

1.0057

0.9933

1.0011

1.0045

1.0021

1.003

Pentium 4, 478 pin

0.13 micron, Pentium 4

MMBT3904

AMD Athlon MP model 6

1.002

1.008

1.016

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10.2.2 Detailed Design Procedure

10.2.2.1 Compensating For Diode Nonideality

In order to compensate for the errors introduced by nonideality, the temperature sensor is calibrated for a

particular processor. The LM89 is calibrated for the nonideality of a 0.13 micron, Mobile Pentium 4, 1.0021.

When a temperature sensor calibrated for a particular processor type is used with a different processor type or a

given processor type has a nonideality that strays from the typical, errors are introduced.

Temperature errors associated with nonideality may be reduced in a specific temperature range of concern

through use of the offset registers (11h and 12h).

10.2.3 Application Curves

LM89 is connected to diode-connected MMBT3904.

2N3904 and LM89 junction temperatures are equivalent during

test.

Figure 17. Remote Temperature Accuracy

Figure 16. Local Temperature Accuracy

10.3 Do's and Don'ts

Noise coupling into the digital lines greater than 400mVp-p (typical hysteresis) and undershoot less than 500mV

below GND, may prevent successful SMBus communication with the LM89. SMBus no acknowledge is the most

common symptom, causing unnecessary traffic on the bus. Although the SMBus maximum frequency of

communication is rather low (100kHz max), care still needs to be taken to ensure proper termination within a

system with multiple parts on the bus and long printed circuit board traces. An RC lowpass filter with a 3db

corner frequency of about 40MHz is included on the LM89's SMBCLK input. Additional resistance can be added

in series with the SMBData and SMBCLK lines to further help filter noise and ringing. Minimize noise coupling by

keeping digital traces out of switching power supply areas as well as ensuring that digital lines containing high

speed data communications cross at right angles to the SMBData and SMBCLK lines.

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11 Power Supply Recommendations

V_DDshould be bypassed with a 0.1µF capacitor in parallel with 100pF. The 100pF capacitor should be placed as

close as possible to the power supply pin. A bulk capacitance of approximately 10µF needs to be in the near

vicinity of the LM89. The ideal place to connect the LM89's GND pin is as close as possible to the Processors

GND associated with the sense diode.

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12 Layout

12.1 Layout Guidelines

In a noisy environment, such as a processor mother board, layout considerations are very critical. Noise induced

on traces running between the remote temperature diode sensor and the LM89 can cause temperature

conversion errors. Keep in mind that the signal level the LM89 is trying to measure is in microvolts. The following

guidelines should be followed:

1. V_DDshould be bypassed with a 0.1µF capacitor in parallel with 100pF. The 100pF capacitor should be placed

as close as possible to the power supply pin. A bulk capacitance of approximately 10µF needs to be in the

near vicinity of the LM89.

2. A 2.2nF diode bypass capacitor is required to filter high frequency noise. Place the 2.2nF capacitor as close

as possible to the LM89's D+ and D− pins. Make sure the traces to the 2.2nF capacitor are matched.

3. Ideally, the LM89 should be placed within 10cm of the Processor diode pins with the traces being as straight,

short and identical as possible. Trace resistance of 1Ω can cause as much as 1°C of error. This error can be

compensated by using the Remote Temperature Offset Registers, since the value placed in these registers

will automatically be subtracted from or added to the remote temperature reading.

4. Diode traces should be surrounded by a GND guard ring to either side, above and below if possible. This

GND guard should not be between the D+ and D− lines. In the event that noise does couple to the diode

lines it would be ideal if it is coupled common mode. That is equally to the D+ and D− lines.

5. Avoid routing diode traces in close proximity to power supply switching or filtering inductors.

6. Avoid running diode traces close to or parallel to high speed digital and bus lines. Diode traces should be

kept at least 2cm apart from the high speed digital traces.

7. If it is necessary to cross high speed digital traces, the diode traces and the high speed digital traces should

cross at a 90 degree angle.

8. The ideal place to connect the LM89's GND pin is as close as possible to the Processors GND associated

with the sense diode.

9. Leakage current between D+ and GND should be kept to a minimum. One nanoampere of leakage can

cause as much as 1°C of error in the diode temperature reading. Keeping the printed circuit board as clean

as possible will minimize leakage current.

12.2 Layout Example

Figure 18. Ideal Diode Trace Layout

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13 Device and Documentation Support

13.1 Trademarks

All trademarks are the property of their respective owners.

13.2 Electrostatic Discharge Caution

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

13.3 Glossary

SLYZ022 — TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

14 Mechanical, Packaging, and Orderable Information

The following pages include mechanical, packaging, and orderable information. This information is the most

current data available for the designated devices. This data is subject to change without notice and revision of

this document. For browser-based versions of this data sheet, refer to the left-hand navigation.

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PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead finish/

Ball material

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

(1)

(2)

(3)

(4/5)

(6)

LM89-1CIMM/NOPB

LM89-1CIMMX/NOPB

LM89-1DIMM/NOPB

LM89-1DIMMX/NOPB

LM89CIMM/NOPB

LM89CIMMX/NOPB

LM89CIMX/NOPB

ACTIVE

VSSOP

SOIC

DGK

1000 RoHS & Green

3500 RoHS & Green

1000 RoHS & Green

3500 RoHS & Green

1000 RoHS & Green

3500 RoHS & Green

2500 RoHS & Green

Level-1-260C-UNLIM

0 to 125

T19C

T19D

T15C

LM89

CIM

⁽¹⁾The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

⁽²⁾RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance

do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may

reference these types of products as "Pb-Free".

RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.

Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based

flame retardants must also meet the <=1000ppm threshold requirement.

⁽³⁾MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

⁽⁴⁾There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

⁽⁵⁾Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

(6)

Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two

lines if the finish value exceeds the maximum column width.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 2

PACKAGE MATERIALS INFORMATION

www.ti.com

9-Aug-2022

TAPE AND REEL INFORMATION

REEL DIMENSIONS

TAPE DIMENSIONS

Reel

Diameter

Cavity

A0 Dimension designed to accommodate the component width

B0 Dimension designed to accommodate the component length

K0 Dimension designed to accommodate the component thickness

Overall width of the carrier tape

P1 Pitch between successive cavity centers

Reel Width (W1)

QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE

Sprocket Holes

Q1 Q2

Q3 Q4

Q1 Q2

Q3 Q4

User Direction of Feed

Pocket Quadrants

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

LM89-1CIMM/NOPB

LM89-1CIMMX/NOPB

LM89-1DIMM/NOPB

LM89-1DIMMX/NOPB

LM89CIMM/NOPB

LM89CIMMX/NOPB

LM89CIMX/NOPB

VSSOP

SOIC

DGK

1000

3500

1000

3500

1000

3500

2500

178.0

330.0

178.0

330.0

178.0

330.0

12.4

5.3

6.5

3.4

5.4

1.4

2.0

8.0

12.0

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

9-Aug-2022

TAPE AND REEL BOX DIMENSIONS

Width (mm)

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

LM89-1CIMM/NOPB

LM89-1CIMMX/NOPB

LM89-1DIMM/NOPB

LM89-1DIMMX/NOPB

LM89CIMM/NOPB

LM89CIMMX/NOPB

LM89CIMX/NOPB

VSSOP

SOIC

DGK

1000

3500

1000

3500

1000

3500

2500

208.0

367.0

208.0

367.0

208.0

367.0

191.0

367.0

191.0

367.0

191.0

367.0

35.0

Pack Materials-Page 2

PACKAGE OUTLINE

D0008A

SOIC - 1.75 mm max height

SCALE 2.800

SMALL OUTLINE INTEGRATED CIRCUIT

SEATING PLANE

.228-.244 TYP

[5.80-6.19]

.004 [0.1] C

PIN 1 ID AREA

6X .050

[1.27]

.189-.197

[4.81-5.00]

NOTE 3

.150

[3.81]

4X (0 -15 )

8X .012-.020

[0.31-0.51]

.150-.157

[3.81-3.98]

NOTE 4

.069 MAX

[1.75]

.010 [0.25]

C A B

.005-.010 TYP

[0.13-0.25]

4X (0 -15 )

SEE DETAIL A

.010

[0.25]

.004-.010

[0.11-0.25]

0 - 8

.016-.050

[0.41-1.27]

DETAIL A

TYPICAL

(.041)

[1.04]

4214825/C 02/2019

NOTES:

1. Linear dimensions are in inches [millimeters]. Dimensions in parenthesis are for reference only. Controlling dimensions are in inches.

Dimensioning and tolerancing per ASME Y14.5M.

2. This drawing is subject to change without notice.

3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not

exceed .006 [0.15] per side.

4. This dimension does not include interlead flash.

5. Reference JEDEC registration MS-012, variation AA.

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EXAMPLE BOARD LAYOUT

D0008A

SOIC - 1.75 mm max height

SMALL OUTLINE INTEGRATED CIRCUIT

8X (.061 )

[1.55]

SYMM

SEE

DETAILS

8X (.024)

[0.6]

SYMM

(R.002 ) TYP

[0.05]

6X (.050 )

[1.27]

(.213)

[5.4]

LAND PATTERN EXAMPLE

EXPOSED METAL SHOWN

SCALE:8X

SOLDER MASK

OPENING

SOLDER MASK

OPENING

METAL UNDER

SOLDER MASK

METAL

EXPOSED

METAL

EXPOSED

METAL

.0028 MAX

[0.07]

.0028 MIN

[0.07]

ALL AROUND

SOLDER MASK

DEFINED

NON SOLDER MASK

DEFINED

SOLDER MASK DETAILS

4214825/C 02/2019

NOTES: (continued)

6. Publication IPC-7351 may have alternate designs.

7. Solder mask tolerances between and around signal pads can vary based on board fabrication site.

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EXAMPLE STENCIL DESIGN

D0008A

SOIC - 1.75 mm max height

SMALL OUTLINE INTEGRATED CIRCUIT

8X (.061 )

[1.55]

SYMM

8X (.024)

[0.6]

SYMM

(R.002 ) TYP

[0.05]

6X (.050 )

[1.27]

(.213)

[5.4]

SOLDER PASTE EXAMPLE

BASED ON .005 INCH [0.125 MM] THICK STENCIL

SCALE:8X

4214825/C 02/2019

NOTES: (continued)

8. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate

design recommendations.

9. Board assembly site may have different recommendations for stencil design.

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IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD

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These resources are intended for skilled developers designing with TI products. You are solely responsible for (1) selecting the appropriate

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These resources are subject to change without notice. TI grants you permission to use these resources only for development of an

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TI objects to and rejects any additional or different terms you may have proposed. IMPORTANT NOTICE

Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265

LM89-1DIMM/NOPB [TI]

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