MIC79050_05 Datasheet, PDF(9/14 Page) Micrel Semiconductor

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MIC79050_05 Datasheet, PDF (9/14 Pages) Micrel Semiconductor – Simple Lithium-Ion Battery Charger

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MIC79050

Protected Constant-Current Charger

Another form of charging is using a simple wall adapter that

offers a ï¬xed voltage at a controlled, maximum current rating.

The output of a typical charger will source a ï¬xed voltage at a

maximum current unless that maximum current is exceeded. In

the event that the maximum current is exceeded, the voltage

will drop while maintaining that maximum current. Using an

MIC79050 after this type of charger is ideal for lithium-ion bat-

tery charging. The only obstacle is end of charger termination.

Using a simple differential ampliï¬er and a similar comparator

and reference circuit, similar to Figure 1, completes a single

cell lithium-ion battery charger solution.

Figure 2 shows this solution in completion. The source is a

ï¬xed 5V source capable of a maximum of 400mA of current.

When the battery demands full current (fast charge), the

source will provide only 400mA and the input will be pulled

down. The output of the MIC79050 will follow the input mi-

nus a small voltage drop. When the battery approaches full

charge, the current will taper off. As the current across RS

approaches 50mA, the output of the differential ampliï¬er

(MIC7300) will approach 1.225V, the reference voltage set

by the LM4041. When it drops below the reference voltage,

the output of the comparator (MIC6270) will allow the base

of Q1 to be pulled high through R2.

Zero-Output Impedance Source Charging

Input voltage sources that have very low output impedances

can be a challenge due to the nature of the source. Using

the circuit in Figure 3 will provide a constant-current and

constant voltage charging algorithm with the appropriate

end-of-charge termination. The main loop consists of an

op-amp controlling the feedback pin through the schottky

diode, D1. The charge current through RS is held constant

by the op-amp circuit until the output draws less than the set

charge-current. At this point, the output goes constant-volt-

age. When the current through RS gets to less than 50mA,

the difference amp output becomes less than the reference

voltage of the MIC834 and the output pulls low. This sets the

output of the MIC79050 less than nominal, stopping current

ï¬ow and terminating charge.

Micrel, Inc.

Lithium-Ion Battery Charging

Single lithium-ion cells are typically charged by providing a

constant current and terminating the charge with constant

voltage. The charge cycle must be initiated by ensuring that

the battery is not in deep discharge. If the battery voltage is

below 2.5V, it is commonly recommended to trickle charge the

battery with 5mA to 10mA of current until the output is above

2.5V. At this point the battery can be charged with constant

current until it reaches its top off voltage (4.2V for a typical

single lithium-ion cell) or a time out occurs.

For the constant-voltage portion of the charging circuit, an ex-

tremely accurate termination voltage is highly recommended.

The higher the accuracy of the termination circuit, the more

energy the battery will store. Since lithium-ion cells do not

exhibit a memory effect, less accurate termination does not

harm the cell but simply stores less usable energy in the bat-

tery. The charge cycle is completed by disabling the charge

circuit after the termination current drops below a minimum

recommended level, typically 50mA or less, depending on the

manufacturerâs recommendation, or if the circuit times out.

Time Out

The time-out aspect of lithium-ion battery charging can be

added as a safety feature of the circuit. Often times this func-

tion is incorporated in the software portion of an application

using a real-time clock to count out the maximum amount

of time allowed in the charging cycle. When the maximum

recommended charge time for the speciï¬c cell has been

exceeded, the enable pin of the MIC79050 can be pulled

low, and the output will ï¬oat to the battery voltage, no longer

providing current to the output.

As a second option, the feedback pin of the MIC79050 can

be modulated as in Figure 4. Figure 4. shows a simple circuit

where the MIC834, an integrated comparator and reference,

monitors the battery voltage and disables the MIC79050 output

after the voltage on the battery exceeds a set vaue. When the

voltage decays below this set threshold, the MIC834 drives

Q1 low allowing the MIC79050 to turn on again and provide

current to the battery until it is fully charged. This form of

pulse charging is an acceptable way of maintaining the full

charge on a cell until it is ready to be used.

RS=0.200â¦

16k

16.2k

221k

10k

August 2005

1/2 MIC7122

0.01ÂµF

R2=124k

R1=1k

MIC79050-4.2BM

IN BAT

EN FB

GND

SD101

MIC834

VDD OUT

R3=1k

R4=124k

INP GND

1/2 MIC7122

80mV

ICC= RS

1.24V Ã R1

IEOC= R2 Ã RS

Figure 3.

4.7ÂµF

8.06M

MIC79050

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