LT1769CGN#TR Linear Technology, LT1769CGN#TR Datasheet - Page 9

LT1769CGN#TR

Manufacturer Part Number

LT1769CGN#TR

Description

IC CHARGER BATT CONST V/I 28SSOP

Manufacturer

Linear Technology

Datasheet

1.LT1769CGNPBF.pdf (16 pages)

Specifications of LT1769CGN#TR

Function

Charge Management

Battery Type

Lead Acid, Li-Ion, NiCd, NiMH

Voltage - Supply

8 V ~ 25 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

28-SSOP (0.150", 3.95mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Part Number:

LT1769CGN#TRLT1769CGN

Manufacturer:

LT/凌特

Quantity:

20 000

Company:

Part Number:

LT1769CGN#TRLT1769CGN#PBF

Manufacturer:

LINEAR/凌特

Quantity:

20 000

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APPLICATIONS

Input and Output Capacitors

In the 2A Lithium-Ion Battery Charger (Figure 1), the input

capacitor (C

ripple current in the converter, so it must have adequate

ripple current rating. Worst-case RMS ripple current will

be equal to one half of the output charge current. Actual

capacitance value is not critical. Solid tantalum capacitors

such as the AVX TPS and Sprague 593D series have high

ripple current rating in a relatively small surface mount

package, but caution must be used when tantalum capaci-

tors are used for input bypass . High input surge currents

are possible when the adapter is hot-plugged to the

charger and solid tantalum capacitors have a known

failure mechanism when subjected to very high turn-on

surge currents. Selecting a high voltage rating on the

capacitor will minimize problems. Consult with the manu-

facturer before use. Alternatives include new high capacity

ceramic (5 F to 20 F) from Tokin or United Chemi-Con/

Marcon, et al. Sanyo OS-CON can also be used.

The output capacitor (C

output switching ripple current. The general formula for

capacitor ripple current is:

For example, V

and f = 200kHz, I

EMI considerations usually make it desirable to minimize

ripple current in the battery leads. Beads or inductors can

be added to increase battery impedance at the 200kHz

switching frequency. Switching ripple current splits be-

tween the battery and the output capacitor depending on

the ESR of the output capacitor and the battery imped-

ance. If the ESR of C

is raised to 4 with a bead or inductor, only 5% of the

ripple current will flow into the battery.

Soft-Start and Undervoltage Lockout

The LT1769 is soft-started by the 0.33 F capacitor on the

0.5V, then ramp at a rate set by the internal 45 A pull-up

current and the external capacitor. Charge current starts

pin. On start-up, the V

RMS

0.29 (V

) is assumed to absorb all input switching

RMS

(L1)(f)

OUT

BAT

= 16V, V

= 0.3A.

) 1 –

is 0.2 and the battery impedance

OUT

INFORMATION

pin voltage will quickly rise to

) is also assumed to absorb

BAT

= 8.4V, L1 = 20 H,

ramping up when V

current is achieved with V

tor, the time to reach full charge current is about 10ms and

it is assumed that input voltage to the charger will reach full

value in less than 10ms. The capacitor can be

increased up to 1 F if longer input start-up times are needed.

starting can be defeated if the input voltage rises much

slower than the time out period. This happens because the

switching regulators in the battery charger and the com-

puter power supply are typically supplying a fixed amount

of power to the load. If the input voltage comes up slowly

compared to the soft-start time, the regulators will try to

deliver full power to the load when the input voltage is still

well below its final value. If the adapter is current limited,

it cannot deliver full power at reduced output voltages and

the possibility exists for a quasi “latch” state where the

adapter output stays in a current limited state at reduced

output voltage. For instance, if maximum charger plus

computer load power is 25W, a 15V adapter might be

current limited at 2A. If adapter voltage is less than

(25W/2A = 12.5V) when full power is drawn, the adapter

voltage will be pulled down by the constant 25W load until

it reaches a lower stable state where the switching regu-

lators can no longer supply full load. This situation can be

prevented by utilizing undervoltage lockout , set higher than

the minimum adapter voltage where full power can be

achieved.

A fixed undervoltage lockout of 7V is built into the LT1769.

This 7V threshold can be increased by adding a resistive

divider to the UV pin as shown in Figure 2. Internal lockout

is performed by clamping the V

released from its clamped state when the UV pin rises

above 7V and is pulled low when the UV pin drops below

6.5V (0.5V hysteresis). At the same time UV

with an external pull-up resistor. This signal can be used

to alert the system that charging is about to start. The

charger will start delivering current about 4ms after V

released, as set by the 0.33 F capacitor. A resistor divider

is used to set the desired V

Figure 2. A typical value for R6 is 5k and R5 is found from:

In any switching regulator, conventional time-based soft-

R5 =

R6(V – V )

pin voltage reaches 0.7V and full

at 1.1V. With a 0.33 F capaci-

lockout voltage as shown in

pin low. The V

OUT

LT1769

goes high

pin is

1769fa

LT1769CGN#TR Linear Technology, LT1769CGN#TR Datasheet - Page 9

LT1769CGN#TR

Specifications of LT1769CGN#TR

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