LM96163CISD/NOPB National Semiconductor, LM96163CISD/NOPB Datasheet - Page 36

LM96163CISD/NOPB

Manufacturer Part Number

LM96163CISD/NOPB

Description

IC TEMP SENSOR DGTL REMOTE 10LLP

Manufacturer

National Semiconductor

Series

PowerWise®, TruTherm®r

Datasheet

1.LM96163CISDNOPB.pdf (42 pages)

Specifications of LM96163CISD/NOPB

Function

Fan Control, Temp Monitor

Topology

ADC (Sigma Delta), Comparator, Register Bank, Tach

Sensor Type

External & Internal

Sensing Temperature

-40°C ~ 85°C, External Sensor

Output Type

SMBus™

Output Alarm

Yes

Output Fan

Yes

Voltage - Supply

3 V ~ 3.6 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

10-LLP

Temperature Sensor Function

Temp Sensor

Interface Type

Serial (2-Wire)

Resolution

10+SignBit

Package Type

LLP EP

Operating Temperature (min)

-40C

Operating Temperature (max)

85C

Operating Supply Voltage (min)

Operating Supply Voltage (typ)

3.3V

Operating Supply Voltage (max)

3.6V

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

LM96163CISDTR

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Also included is programmable hysteresis that is not de-

scribed by the curves of

as temperature is decreasing and moves all the temperature

set-points down by the programmed amount. For the example

shown here if the hysteresis is set to 1°C and if the tempera-

ture is decreasing from 96.5°C the duty cycle will remain at

68.75% and will not transition to 62.5% until the temperature

drops below 95.5°C.

If at any time the TCRIT output were to activate the PWM duty

cycle will be instantaneously forced to 100% thus forcing the

fans to full on.

The

grammable time interval preventing abrupt changes in the

PWM output duty cycle and thus preventing abrupt acoustical

noise changes as well. The threshold of acoustically detecting

fan noise transition is at about a 2% duty cycle change. The

table describes the time intervals that can be programmed

and the total amount of time it will take for the PWM output to

change from 0% to 100% for each time interval. For example

if the time interval for each step is set to 0.091 seconds the

time it will take to make a 0 to 100% duty cycle change will be

21.6 seconds when the duty cycle resolution is set to 0.39%

or 1.46 seconds when the resolution is 6.25%. One setting

will apply to all LUT transitions.

3.3 COMPUTING RPM OF THE FAN FROM THE TACH

COUNT

The Tach Count Registers 46

of periods of the 90 kHz tachometer clock in the LM96163 for

the tachometer input from the fan assuming a 2 pulse per

revolution fan tachometer, such as the fans supplied with the

Intel boxed processors. The RPM of the fan can be computed

from the Tach Count Registers 46

best be shown through an example.

Example:

Given: the fan used has a tachometer output with 2 per rev-

olution.

Let:

and

The total Tach Count, in decimal, is 191 + 1792 = 1983.

The RPM is computed using the formula

Time Interval

PWM Smoothing Time Intervals

(seconds)

0.182

0.091

0.046

0.023

PWM Smoothing Time Intervals

HEX

Figure

HEX

resolution

(seconds)

w/ 6.25%

= Decimal (7 x 256) = 1792.

2.913

1.456

0.728

0.364

= Decimal (11 x 16) + 15 = 191

HEX

7. The hysteresis takes effect

0-100% DC Time

and 47

HEX

table describes the pro-

HEX

and 47

count the number

resolution

w/ 0.39%

Seconds

HEX

43.7

21.6

10.9

5.45

. This can

where

f = 1 for 2 pulses/rev fan tachometer output;

f = 2 for 1 pulse/rev fan tachometer output, and

f = 2 / 3 for 3 pulses/rev fan tachometer output

For our example

3.4 DIODE NON-IDEALITY

The LM96163 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 cir-

cuit board lands and traces soldered to the LM96163'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 LM96163 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 con-

tribute to the die temperature much more strongly than will the

air temperature.

The LM96163 incorporates remote diode temperature sens-

ing technology allowing the measurement of remote temper-

atures. This diode can be located on the die of a target IC,

allowing measurement of the IC's temperature, independent

of the LM96163's die temperature. A discrete diode can also

be used to sense the temperature of external objects or am-

bient 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 an MMBT3904 transistor

base emitter junction be used with the collector tied to the

base.

The LM96163’s TruTherm BJT beta compensation technolo-

gy allows accurate sensing of integrated thermal diodes, such

as those found on most processors. With TruTherm technol-

ogy turned off, the LM96163 can measure a diode-connected

transistor such as the MMBT3904 or the thermal diode found

in an AMD processor.

The LM96163 has been optimized to measure the remote

thermal diode integrated in a typical Intel processor on 45nm,

65 nm or 90 nm process or an MMBT3904 transistor. Using

the Remote Diode TruTherm Enable register the remote input

can be optimized for a typical Intel processor on 45nm, 65 nm

or 90 nm process or an MMBT3904.

LM96163CISD/NOPB National Semiconductor, LM96163CISD/NOPB Datasheet - Page 36

LM96163CISD/NOPB

Specifications of LM96163CISD/NOPB

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