adm9240 Analog Devices, Inc., adm9240 Datasheet - Page 11

adm9240

Manufacturer Part Number

adm9240

Description

Low Cost Microprocessor System Hardware Monitor

Manufacturer

Analog Devices, Inc.

Datasheet

1.ADM9240.pdf (22 pages)

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MONITORING CYCLE TIME

The monitoring cycle begins when a one is written to the Start

Bit (Bit 0), and a zero to the INT_Clear Bit (Bit 3) of the Con-

figuration Register. INT_Enable (Bit 1) should be set to one to

enable the INT output. The ADC measures each analog input

in turn, starting with V

perature sensor. As each measurement is completed the result

is automatically stored in the appropriate value register. This

“round-robin” monitoring cycle continues until it is disabled by

writing a 0 to Bit 0 of the Configuration Register.

The counter controlling the multiplexer is driven by an on-chip

clock of nominally 22.5 kHz, so the entire measurement sequence

takes (nominally):

This rapid sampling of the analog inputs ensures a quick re-

sponse in the event of any input going out of limits, unlike other

monitoring chips that employ slower ADCs.

When a monitoring cycle is started, monitoring of the fan speed

inputs begins at the same time as monitoring of the analog in-

puts. However, the two monitoring cycles are not synchronized

in any way, and the monitoring cycle time for the fan inputs is

dependent on fan speed and much slower than for the analog

inputs. For more details see the Fan Speed Measurement section.

INPUT SAFETY

Scaling of the analog inputs is performed on-chip, so external

attenuators are normally not required. However, since the

power supply voltages will appear directly at the pins, it is advis-

able to add small external resistors in series with the supply

traces to the chip to prevent damaging the traces or power sup-

plies should an accidental short such as a probe connect two

power supplies together.

As the resistors will form part of the input attenuators, they will

affect the accuracy of the analog measurement if their value is

too high. The analog input channels are calibrated assuming an

external series resistor of 500 , and the accuracy will remain

within specification for any value from zero to 1 k , so a stan-

dard 510

The worst such accident would be connecting –12 V to +12 V—

a total of 24 V difference, with the series resistors this would

draw a maximum current of approximately 24 mA.

ANALOG OUTPUT

The ADM9240 has a single analog output from an unsigned

8-bit DAC which produces 0 V–1.25 V. The analog output

maximum 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.

A suitable drive circuit is given in Figure 5.

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

input common-mode range and output voltage swing are suitable.

The op amp may be powered from the +12 V rail alone or from

mode range should include ground to accommodate the mini-

mum 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.

REV. 0

12 V. If it is powered from +12 V then the input common-

resistor is suitable.

44.4 s

CCP2

and finishing with the on-chip tem-

7 = 310.8 s

–11–

If the op amp is powered from –12 V, precautions such as a

clamp diode to ground may be needed to prevent the base-

emitter junction of the transistor being reverse-biased in the

unlikely event that the output of the op amp should swing nega-

tive for any reason.

The positive output swing of the op amp should be as close to

+12 V as possible so that the maximum voltage can be obtained

from the transistor. Even if the op amp swings to the rail, the

maximum voltage from the emitter of the transistor will be

about 11.4 V. typical values for this condition would be:

giving an actual gain of 9.2.

The transistor should have a reasonably high h

base current pulling down the output of the op amp, it must

have an I

capable of dissipating power due to the voltage dropped across it

when the fan is not operating at full speed. Depending on the

fan parameters, some suitable devices would be 2N2219A,

2N3019 or ZTX450.

LAYOUT AND GROUNDING

Analog inputs will provide best accuracy when referred to the

GNDA pin. A separate, low impedance ground plane for analog

ground, which provides a ground point for the voltage dividers

and analog components, will provide best performance but is

not mandatory.

The power supply bypass, the parallel combination of 10 F

(electrolytic or tantalum) and 0.1 F (ceramic) bypass capaci-

tors connected between Pin 9 and ground, should also be lo-

cated as close as possible to the ADM9240.

R1 = 82 k , R2 = 10 k (nearest preferred value)

CMAX

Figure 5. Analog Output Driving Fan

NTEST_IN/AOUT

Gain = 11.4/1.25 = 9.12 = 1 + R1/R2

greater than the maximum fan current and be

ADM9240

+12V

to avoid its

adm9240 Analog Devices, Inc., adm9240 Datasheet - Page 11

adm9240

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