MIC284-3BM TR Micrel Inc, MIC284-3BM TR Datasheet - Page 18

MIC284-3BM TR

Manufacturer Part Number

MIC284-3BM TR

Description

IC SUPERVISOR THERM 2ZONE 8-SOIC

Manufacturer

Micrel Inc

Series

SilentSense™r

Datasheet

1.MIC284-0YM.pdf (20 pages)

Specifications of MIC284-3BM TR

Function

Temp Monitoring System (Sensor)

Topology

ADC (Sigma Delta), Comparator, Register Bank

Sensor Type

External & Internal

Sensing Temperature

-55°C ~ 125°C, External Sensor

Output Type

I²C™/SMBus™

Output Alarm

Yes

Output Fan

Yes

Voltage - Supply

2.7 V ~ 5.5 V

Operating Temperature

-55°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

MIC284-3BMTR
MIC284-3BMTR

Current page: 18 of 20
Download datasheet (905Kb)

MIC284

Applications

Remote Diode Selection

Most small-signal PNP transistors with characteristics similar

to the JEDEC 2N3906 will perform well as remote temperature

sensors. Table 6 lists several examples of such parts that

Micrel has tested for use with the MIC284. Other transistors

equivalent to these should also work well.

Minimizing Errors

Self-Heating

One concern when using a part with the temperature accuracy

and resolution of the MIC284 is to avoid errors induced by

self-heating (V

what level of error this might represent, and how to reduce

that error, the dissipation in the MIC284 must be calculated

and its effects reduced to a temperature offset.

The worst-case operating condition for the MIC284 is when

sipated in the part is given in Equation 1 below.

In most applications, the /INT output will be low for at most

a few milliseconds before the host resets it back to the high

state, making its duty cycle low enough that its contribution to

self-heating of the MIC284 is negligible. Similarly, the DATA

pin will in all likelihood have a duty cycle of substantially below

25% in the low state. These considerations, combined with

more typical device and application parameters, give a better

system-level view of device self-heating in interrupt-mode

usage. This is illustrated by Equation 2.

If the part is to be used in comparator mode, calculations

similar to those shown in Equation 2 (accounting for the

expected value and duty cycle of I

will give a good estimate of the device’s self-heating error.

In any application, the best test is to verify performance

against calculation in the ﬁnal application environment. This

is especially true when dealing with systems for which some

MIC284

[(0.35mA I

∆T

= 5.5V, MSOP-08 package. T he maximum power dis-

= (1.38mW x 206°C/W) = 0.29°C

DD(typ)

x 3.3V) + (25% x 1.5mA I

× I

Maximum ∆T

) + (V

θ(j-a)

= [(I

= [(0.75mA x 5.5V) + (6mA x 0.8V) + (6mA x 0.8V) + (6mA x 0.8V)]

= 18.53mW

Table 6. Transistors Suitable for Remote Temperature Sensing Use

Vendor

Fairchild

On Semiconductor

Phillips Semiconductor

Samsung

of MSOP - 08 package is 206°C/W

× I

x V

OL(/INT)

relative to T

). In order to understand

) + (I

Equation 2. Real-world self-heating example

OL(DATA)

and I

Equation 1. Worst-case self-heating

) x 0.3V) + (1% x 1.5mA I

due to self heating is 18.53mW x 206°C/W = 3.82°C

OL(/CRIT)

) x V

OL(DATA)

)

Part Number

MMBT3906

MMBT3906L

PMBT3906

KST3906-TF

+ (I

OL(/INT)

of the thermal data (e.g., PC board thermal conductivity and

ambient temperature) may be poorly deﬁned or unobtainable

except by empirical means.

Series Resistance

The operation of the MIC284 depends upon sensing the

ΔV

two different current levels. For remote temperature mea-

surements, this is done using an external diode connected

between T1 and ground.

Since this technique relies upon measuring the relatively

small voltage difference resulting from two levels of current

through the external diode, any resistance in series with the

external diode will cause an error in the temperature reading

from the MIC284. A good rule of thumb is this: for each ohm

in series with the external transistor, there will be a 0.9°C error

in the MIC284’s temperature measurement. It isn’t difﬁcult

to keep the series resistance well below an ohm (typically <

0.1Ω), so this will rarely be an issue.

Filter Capacitor Selection

It is sometimes desirable to use a ﬁlter capacitor between the

T1 and GND pins of the MIC284. The use of this capacitor

is recommended in environments with a lot of high frequency

noise (such as digital switching noise), or if long wires are used

to attach to the remote diode. The maximum recommended

total capacitance from the T1 pin to GND is 2700pF. This

typically suggests the use of a 2200pF NP0 or C0G ceramic

capacitor with a 10% tolerance.

If the remote diode is to be at a distance of more than ≈ 6"

— 12" from the MIC284, using twisted pair wiring or shielded

microphone cable for the connections to the diode can signiﬁ-

cantly help reduce noise pickup. If using a long run of shielded

cable, remember to subtract the cable’s conductor-to-shield

capacitance from the 2700pF maximum total capacitance.

Layout Considerations

The following guidelines should be kept in mind when design-

ing and laying out circuits using the MIC284:

CB-E

OL(/INT)

x V

OL(/INT)

of a diode-connected PNP transistor (“diode”) at

x 0.3V) + (25% x 1.5mA I

) + (I

Package

OL(/CRIT)

SOT-23

x V

OL(/CRIT)

)]

x 0.3V) = 1.38mW

September 2005

Micrel, Inc

MIC284-3BM TR Micrel Inc, MIC284-3BM TR Datasheet - Page 18

MIC284-3BM TR

Specifications of MIC284-3BM TR

Related parts for MIC284-3BM TR