LTC4012CUF-3-PBF LINER [Linear Technology], LTC4012CUF-3-PBF Datasheet - Page 21

LTC4012CUF-3-PBF

Manufacturer Part Number

LTC4012CUF-3-PBF

Description

High Efficiency, Multi-Chemistry Battery Charger with PowerPath Control

Manufacturer

LINER [Linear Technology]

Datasheet

1.LTC4012CUF-3-PBF.pdf (28 pages)

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applicaTions inForMaTion

The output capacitor shown across the battery and ground

must also absorb PWM output ripple current. The general

formula for this capacitor current is:

For example, I

High capacity ceramic capacitors (20µF or more) available

from a variety of manufacturers can be used for input/out-

put capacitors. Other alternatives include OS-CON and

POSCAP capacitors from Sanyo.

Low ESR solid tantalum capacitors have high ripple cur-

rent rating in a relatively small surface mount package,

but exercise caution when using tantalum for input or

output bulk capacitors. High input surge current can be

created when the adapter is hot-plugged to the charger

or when a battery is connected to the charger. Solid tan-

talum capacitors have a known failure mechanism when

subjected to very high surge currents. Select tantalum

capacitors that have high surge current ratings or have

been surge tested.

EMI considerations usually make it desirable to minimize

ripple current in battery leads. Adding Ferrite beads or

inductors can increase battery impedance at the nominal

550kHz switching frequency. Switching ripple current splits

between the battery and the output capacitor in inverse

relation to capacitor ESR and the battery impedance. If

the ESR of the output capacitor is 0.2Ω and the battery

impedance is raised to 4Ω with a ferrite bead, only 5%

of the current ripple will flow to the battery.

L1 = 10µH

PWM

RMS

BAT

CLP

= 12.6V

= 19V

= 550kHz

0 29

RMS

•

BAT

= 0.22A with:

•

PWM



 

–

CLP

BAT



 

Inductor Selection

Higher switching frequency generally results in lower ef-

ficiency because of MOSFET gate charge losses, but it allows

smaller inductor and capacitor values to be used. A primary

effect of the inductor value L1 is the amplitude of ripple

current created. The inductor ripple current ∆I

with higher inductance and PWM operating frequency:

Accepting larger values of ∆I

ductance, but results in higher output voltage ripple and

greater core losses. Lower charge currents generally call

for larger inductor values.

The LTC4012-3 limits maximum instantaneous peak in-

ductor current during every PWM cycle. To avoid unstable

switch waveforms, the ripple current must satisfy:

so choose:

For C-grade parts, a reasonable starting point for setting

ripple current is ∆I

∆I

batteries over the wider I-grade temperature range. The

voltage compliance of internal LTC4012-3 circuits also

imposes limits on ripple current. Select R

to avoid average current errors in high ripple designs. The

following equation can be used for guidance:

∆I

= 0.2 • I

SENSE

PWM

µA

BAT

•

MAX

•







∆

150

0 125

•

• –

SENSE



 

only if the IC will actually be used to charge

•







150

≤

SENSE

PWM

•

= 0.4 • I

–

BAT

CLP

≤

MAX

–







SENSE

MAX







MAX



 

allows the use of low in-

µA

. For I-grade parts, use

•

∆

LTC4012-3

(in Figure 1)

decreases

40123fb

LTC4012CUF-3-PBF LINER [Linear Technology], LTC4012CUF-3-PBF Datasheet - Page 21

LTC4012CUF-3-PBF

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