ADM1030ARQ-REEL ON Semiconductor, ADM1030ARQ-REEL Datasheet - Page 20

ADM1030ARQ-REEL

Manufacturer Part Number

ADM1030ARQ-REEL

Description

IC SNSR TEMP/FAN PWM CTRL 16QSOP

Manufacturer

ON Semiconductor

Datasheet

1.ADM1030ARQ.pdf (29 pages)

Specifications of ADM1030ARQ-REEL

Rohs Status

RoHS non-compliant

Function

Fan Control, Temp Monitor

Topology

ADC, Comparator, Multiplexer, Register Bank

Sensor Type

External & Internal

Sensing Temperature

0°C ~ 100°C, External Sensor

Output Type

SMBus™

Output Alarm

Yes

Output Fan

Yes

Voltage - Supply

3 V ~ 5.5 V

Operating Temperature

0°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

16-QSOP

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ADM1030ARQ-REEL

Manufacturer:

ADI/亚德诺

Quantity:

20 000

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ADM1030

1. Run the fan at 53% PWM duty cycle in Software Mode. Clear

2. Measure the fan RPM. This represents the fan RPM below

3. Ensure that Speed Range, N, = 2 when using RPM Feed-

Fans come in a variety of different options. One distinguishing

feature of fans is the number of poles that a fan has internally.

The most common fans available have four, six, or eight poles.

The number of poles the fan has generally affects the number of

pulses per revolution the fan outputs.

If the ADM1030 is used to drive fans other than 4-pole fans that

output 2 tach pulses/revolution, then the fan speed measurement

equation needs to be adjusted to calculate and display the cor-

rect fan speed, and also to program the correct count value in

RPM Feedback Mode.

FAN SPEED MEASUREMENT EQUATIONS

For a 4-pole fan (2 tach pulses/rev):

For a 6-pole fan (3 tach pulses/rev):

For an 8-pole fan (4 tach pulses/rev):

If in doubt as to the number of poles the fans used have, or the

number of tach output pulses/rev, consult the fan manufacturer’s

data sheet, or contact the fan vendor for more information.

FAN DRIVE USING PWM CONTROL

The external circuitry required to drive a fan using PWM con-

trol is extremely simple. A single NMOS FET is the only drive

transistor required. The specifications of the MOSFET depend

on the maximum current required by the fan being driven. Typi-

cal notebook fans draw a nominal 170 mA, and so SOT devices

can be used where board space is a constraint. If driving several

fans in parallel from a single PWM output, or driving larger

server fans, the MOSFET will need to handle the higher current

requirements. The only other stipulation is that the MOSFET

should have a gate voltage drive, V

facing to the PWM_OUT pin. The MOSFET should also have

a low on-resistance to ensure that there is not significant volt-

age drop across the FET. This would reduce the maximum

operating speed of the fan.

Figure 18 shows how a 3-wire fan may be driven using

PWM control.

Bits 5 and 7 of Configuration Register 1 (Reg 0x00) to enter

PWM duty cycle mode. Write 0x08 to the Fan Speed Config

which the RPM mode will fail to operate. Do NOT program a

lower RPM than this value when using RPM Feedback mode.

back mode.

Fan RPM = (f ¥ 60)/(Count ¥ N ¥ 1.5)

Fan RPM = (f ¥ 60)/(Count ¥ N ¥ 2)

Fan RPM = (f ¥ 60)/Count ¥ N

< 3.3 V, for direct inter-

Rev. 2 | Page 20 of 29 | www.onsemi.com

–20–

The NDT3055L n-type MOSFET was chosen since it has 3.3 V

gate drive, low on-resistance, and can handle 3.5 A of current.

Other MOSFETs may be substituted based on the system’s fan

drive requirements.

Figure 19 shows how a 2-wire fan may be connected to the

ADM1030. This circuit allows the speed of the 2-wire fan to

be measured even though the fan has no dedicated Tach sig-

nal. A series R

commutation pulses into a voltage. This is ac-coupled into

the ADM1030 through the 0.01 mF capacitor. On-chip signal

conditioning allows accurate monitoring of fan speed. For typical

notebook fans drawing approximately 170 mA, a 2 W R

value is suitable. For fans such as desktop or server fans, that

draw more current, R

is the better, since more voltage will be developed across the

fan, and the fan will spin faster. Figure 20 shows a typical plot

of the sensing waveform at the TACH/AIN pin. The most

important thing is that the negative-going spikes are more than

250 mV in amplitude. This will be the case for most fans when

the voltage spikes at the TACH/AIN pin are greater than 250 mV.

This allows fan speed to be reliably determined.

SENSE

Figure 18. Interfacing the ADM1030 to a 3-Wire Fan

Figure 19. Interfacing the ADM1030 to a 2-Wire Fan

= 2 W. The value of R

ADM1030

PWM_OUT

TACH/AIN

SENSE

resistor in the fan circuit converts the fan

SENSE

3.3V

10k�

TYPICAL

10k�

TYPICAL

10k�

TYPICAL

may be reduced. The smaller R

SENSE

0.01�F

can be reduced as long as

TACH

NDT3055L

(2� TYPICAL)

NDT3055L

SENSE

5V OR 12V

FAN

5V OR 12V

FAN

REV. A

SENSE

ADM1030ARQ-REEL ON Semiconductor, ADM1030ARQ-REEL Datasheet - Page 20

ADM1030ARQ-REEL

Specifications of ADM1030ARQ-REEL

Available stocks

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