LTC4008_15 Datasheet, PDF(13/24 Page) Linear Technology – 4A, High Effi ciency, Multi-Chemistry Battery Charger

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LTC4008_15 Datasheet, PDF (13/24 Pages) Linear Technology – 4A, High Effi ciency, Multi-Chemistry Battery Charger

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LTC4008

APPLICATIONS INFORMATION

Charger Current Programming

The basic formula for charging current is:

ICHARGE(MAX)

VREF

â¢

3.01kÎ© / RPROG

RSENSE

0.035V

VREF = 1.19V. This leaves two degrees of freedom: RSENSE

and RPROG. The 3.01k input resistors must not be altered

since internal currents and voltages are trimmed for this

value. Pick RSENSE by setting the average voltage between

CSP and BAT to be close to 100mV during maximum

charger current. Then RPROG can be determined by solving

the above equation for RPROG.

RPROG

RSENSE

â¢

VREF â¢ 3.01kÎ©

ICHARGE(MAX) +

0.035V

Table 2. Recommended RSNS and RPROG Resistor Values

IMAX (A)

RSENSE (Î©) 1% RSENSE (W)

RPROG (kÎ©) 1%

1.0

0.100

0.25

26.7

2.0

0.050

0.25

26.7

3.0

0.033

0.5

26.7

4.0

0.025

0.5

26.7

Charging current can be programmed by pulse width

modulating RPROG with a switch Q1 to RPROG at a frequency

higher than a few kHz (Figure 5). CPROG must be increased

to reduce the ripple caused by the RPROG switching. The

compensation capacitor at ITH will probably need to be

LTC4008

PROG

RPROG

CPROG

102k

2N7002

4008 F05

Figure 5. PWM Current Programming

increased also to improve stability and prevent large

overshoot currents during start-up conditions. Charging

current will be proportional to the duty cycle of the switch

with full current at 100% duty cycle and zero current when

Q1 is off.

Maintaining C/10 Accuracy

The C/10 comparator threshold that drives the FLAG pin

has a ï¬xed threshold of approximately VPROG = 400mV.

This threshold works well when RPROG is 26.7k, but will

not yield a 10% charging current indication if RPROG is

a different value. There are situations where a standard

value of RSENSE will not allow the desired value of charging

current when using the preferred RPROG value. In these

cases, where the full-scale voltage across RSENSE is within

Â±20mV of the 100mV full-scale target, the input resistors

connected to CSP and BAT can be adjusted to provide the

desired maximum programming current as well as the

correct FLAG trip point.

For example, the desired max charging current is 2.5A but

age across RSENSE at maximum charging current is only

82.5mV, normally RPROG would be 30.1k but the nominal

FLAG trip point is only 5% of maximum charging current.

If the input resistors are reduced by the same amount as

the full-scale voltage is reduced then, R4 = R5 = 2.49k

and RPROG = 26.7k, the maximum charging current is

still 2.5A but the FLAG trip point is maintained at 10%

of full scale.

There are other effects to consider. The voltage across the

current comparator is scaled to obtain the same values as

the 100mV sense voltage target, but the input referred sense

voltage is reduced, causing some careful consideration of

the ripple current. Input referred maximum comparator

threshold is 117mV, which is the same ratio of 1.4x the

DC target. Input referred IREV threshold is scaled back to

â24mV. The current at which the switcher starts will be

reduced as well so there is some risk of boost activity.

These concerns can be addressed by using a slightly larger

inductor to compensate for the reduction of tolerance to

ripple current.

4008fb

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