MIC2755BMM(2000) Просмотр технического описания (PDF) - Micrel

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производитель

MIC2755BMM
(Rev.:2000)

Battery System Supervisor

Micrel 

MIC2755

Applications Information

Outputs

Since the MIC2755 outputs are open-drain MOSFETs, most

applications will require pull-up resistors. The value of the

resistors should not be too large or leakage effects may

dominate.

Programming Thresholds

There are separate resistive-divider configurations for cir-

cuits that require or do not require manual reset capability.

Configuration Without Manual Reset

See Figure 1. The battery-OK threshold is calculated using:

VBAT(OK)

=

VREF



R1+

R2 + R3

R4

+

R4 

The low-battery threshold is calculated using:

VBAT(low)

=

VREF

 R1+

R2 + R3 +

R3 + R4

R4 

The dead-battery threshold is calculated using:

VBAT(dead)

=

VREF



R1+ R2 + R3 + R4

R2 + R3 + R4



where, for all equations:

VREF = 1.24V

In order to provide the additional criteria needed to solve for

the resistor values, the resistors can be selected such that

they have a given total value, that is, R1 + R2 + R3 + R4 =

Rtotal. A value such as 1MΩ for Rtotal is a reasonable value

because it draws minimum battery current per resistor ladder

but has no significant effect on system accuracy.

When working with large resistors, a small amount of leakage

current can cause voltage offsets that degrade system accu-

racy. The maximum recommended total resistance from

VBAT to ground is 3MΩ.

VBAT

VBAT

R1

572k

R2

28k

R3

55.6k

R4

344k

100k 100k 100k

MIC2755

VDD

/POF

PTH

/NMI

NTH

/RST

RTH(/MR) GND

POF

NMI

RST

Figure 1. Example Circuit without Manual Reset

Once the desired trip points are determined, set the VBAT(OK)

threshold first.

For a typical single-cell lithium ion battery, 3.6V is a reason-

able “OK threshold” because at 3.6V the battery is moder-

ately charged. Solving for R4:

VBAT(OK)

=

3.6V

=

1.24V

 1MΩ

 R4 

R4 = 344kΩ

Micrel

To determine the resistor values for VBAT(low) threshold, set

R4 = 344kΩ and solve for R3.

VBAT(low)

=

3.1V

=

1.24V





1MΩ 

R3 + R4

R3 = 56k

Once R3 and R4 are determined, the equation for VBAT(dead)

can be used to determine R2. A single lithium-ion cell should

not be discharged below 2.5V. Many applications limit the

drain to 2.9V. Using 2.9V for the VBAT(dead) threshold allows

calculating the following resistor values.

VBAT(dead)

=

2.9V

=

1.24V





R2

+

1MΩ

55.6k +

344k





R2 = 27.4k

R1 = 1MΩ – R2 – R3 – R4 = 572k

Configuration With Manual Reset

See Figure 2. To use manual reset, the MIC2755 requires a

separate resistor ladder for the switch and fresh-battery

threshold. The remaining two thresholds are set by the three-

resistor ladder.

VBAT

VBAT

R6

656k

R7

344k

R8

573k

R9

26.7k

SW

R10

400k

100k 100k 100k

MIC2755

VDD

/POF

PTH

/NMI

NTH

/RST

RTH(/MR) GND

POF

NMI

RST

Figure 2. Example Circuit with Manual Reset

VBAT(OK)

=

VREF



R6 + R7

R7



VBAT(low)

=

VREF

 R8

+

R9 +

R10

R10 

VBAT(dead)

=

VREF



R8 + R9 + R10

R9 + R10



where, for all equations:

VREF = 1.24V

Once the desired trip points are determined, set R6 + R7 =

1MΩ and solve for R7.

VBAT(fresh)

=

3.6V

=

1.24V





1MΩ

R7





R7 = 344k

R6 = 1MΩ – 344k = 656k

The remaining resistor values are solved in a similar manner

as the above.

1MΩ = R8 + R9 + R10

MIC2755

6

February 2000

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