MIC502 Datasheet, PDF(9/11 Page) Micrel Semiconductor – Fan Management IC Advance Information

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MIC502 Datasheet, PDF (9/11 Pages) Micrel Semiconductor – Fan Management IC Advance Information

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MIC502

Applications Information

The Typical Application drawing on page 1 illustrates a typical

application circuit for the MIC502. Interfacing the MIC502

with a system consists of the following steps:

1. Selecting a temperature sensor

2. Interfacing the temperature sensor to the VT1 input

3 Selecting a fan-drive transistor, and base-drive current

limit resistor

4. Deciding what to do with the Secondary

Fan-Control Input

5. Making use of the Overtemperature Fault Output.

Temperature Sensor Selection

Temperature sensor T1 is a negative temperature coefficient

(NTC) thermistor. The MIC502 can be interfaced with either

a negative or positive tempco thermistor; however, a nega-

tive temperature coefficient thermistor typically costs less

than its equivalent positive tempco counterpart. While a

variety of thermistors can be used in this application, the

following paragraphs reveal that those with an R25 rating

(resistance at 25Â°C) of from about 50kâ¦ to 100kâ¦ lend

themselves nicely to an interface network that requires only

a modest current drain. Keeping the thermistor bias current

low not only indicates prudent design; it also prevents self-

heating of the sensor from becoming an additional design

consideration. It is assumed that the thermistor will be located

within the system power supply, which most likely also

houses the speed-controlled fan.

Temperature Sensor Interface

As shown by the Electrical Characteristics table, the working

voltage for input VT1 is specified as a percentage of VDD. This

conveniently frees the designer from having to be concerned

with interactions resulting from variations in the supply volt-

age. By design, the operating range of VT1 is from about 30%

of VDD to about 70% of VDD.

VPWM(min) = VPWM(max) â VPWM(span)

When VT1 = VPWM(max) â 0.7VDD, a 100% duty-cycle motor

drive signal is generated. Conversely, when VT1 = VPWM(min)

â 0.3VDD, the motor-drive signal has a 0% duty cycle.

Resistor voltage divider R1 || T1, R2 in the Typical Application

diagram is designed to preset VT1 to a value of VPWM that

corresponds to the slowest desired fan speed when the

resistance of thermistor T1 is at its highest (cold) value. As

temperature rises the resistance of T1 decreases and VT1

increases because of the parallel connection of R1 and T1.

Since VT1 = VPWM(min) represents a stopped fan (0% duty-

cycle drive), and since it is foreseen that at least some cooling

will almost always be required, the lowest voltage applied to

the VT1 input will normally be somewhat higher than 0.3VDD

(or >VPWM(min)). It is assumed that the system will be in sleep

mode rather than operate the fan at a very low duty cycle

(<< 25%). Operation at very low duty cycle results in relatively

little airflow. Sleep mode should be used to reduce acoustic

noise when the system is cool. For a given minimum desired

fan speed, a corresponding VT1(min) can be determined via

the following observation:

Micrel

since

VPWM(max) = 70% of VDD â 100% RPM

and

VPWM(min) = 30% of VDD â 0% RPM

then

VPWM(span) = 40% of VDD â 100% RPM range.

Figure 6 shows the following linear relationship between the

voltage applied to the VT1 input, motor drive duty cycle, and

approximate motor speed.

since

VT1 = 0.7VDD â 100% PWM

then

VT1 = 0.6VDD â 75% PWM

and

VT1 = 0.5VDD â 50% PWM

and

VT1 = 0.4VDD â 25% PWM.

In addition to the R25 thermistor rating, sometimes a data

sheet will provide the ratio of R25/R50 (resistance at 25Â°C

divided by resistance at 50Â°C) is given. Sometimes this is

given as an R0/R50 ratio. Other data sheet contents either

specify or help the user determine device resistance at

arbitrary temperatures. The thermistor interface to the MIC502

usually consists of the thermistor and two resistors.

100

0 20 40 60 80 100

VT1/SUPPLY VOLTAGE (%)

Figure 6. Control Voltage vs. Fan Speed

Design Example

The thermistor-resistor interface network is shown in the

Typical Application drawing. The following example describes

the design process: A thermistor data sheet specifies a

thermistor that is a candidate for this design as having an R25

resistance of 100kâ¦. The data sheet also supports calcula-

tion of resistance at arbitrary temperatures, and it was discov-

ered the candidate thermistor has a resistance of 13.6k at

70Â°C (R70). Accuracy is more important at the higher tem-

perature end of the operating range (70Â°C) than the lower end

because we wish the overtemperature fault output (/OTF) to

be reasonably accurateâit may be critical to operating a

power supply crowbar or other shutdown mechanism, for

example. The lower temperature end of the range is less

important because it simply establishes minimum fan speed,

which is when less cooling is required.

May 1999

171

MIC502

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