LT1769CGN#TR Linear Technology, LT1769CGN#TR Datasheet - Page 13

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

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Part Number

Manufacturer

Quantity

Price

Company:

Part Number:

LT1769CGN#TRLT1769CGN

Manufacturer:

LT/凌特

Quantity:

20 000

Company:

Part Number:

LT1769CGN#TRLT1769CGN#PBF

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Quantity:

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Total Power in the IC is: 0.35 + 0.43 + 0.5 = 1.3W

Temperature rise will be (1.3W)(35 C/W) = 46 C. This

assumes that the LT1769 is properly heat sunk by con-

necting the eleven fused ground pins to expanded traces

and that the PC board has a backside or internal plane for

heat spreading.

The P

diode D2 (see Figure 7) to a lower system voltage (lower

than V

For example, V

The average I

The previous example shows the dramatic drop in driver

power dissipation when the boost diode (D2) is connected

to an external 3.3V source instead of the 12.6V battery.

approximately 12 C drop in junction temperature.

Fused-lead packages conduct most of their heat out the

leads. This makes it very important to provide as much PC

board copper around the leads as is practical. Total

APPLICATIONS

Example: V

DRIVER

Then P

DRIVER

BIAS

DRIVER

12.6

BAT

drops from 0.43W to 0.09W resulting in an

0.42 0.08 0.5W

) instead of V

DRIVER

3.5mA 19

term can be reduced by connecting the boost

= 19V, V

7.5mA

0 09

2 12.6

3 3

0.16 12.6

required is:

= 3.3V then:

12 6

55 19

BAT

55 19

0.012 2000mA

INFORMATION

3 3

= 12.6V, I

1.5mA 12.6

BAT

12 6

19 2 200kHz

3 3

BAT

0.43W

= 2A:

0 09

0.35W

thermal resistance of the package-board combination is

dominated by the characteristics of the board in the

immediate area of the package. This means both lateral

thermal resistance across the board and vertical thermal

resistance through the board to other copper layers. Each

layer acts as a thermal heat spreader that increases the

heat sinking effectiveness of extended areas of the board.

Total board area becomes an important factor when the

area of the board drops below about 20 square inches. The

graph in Figure 8 shows thermal resistance vs board area

for 2-layer and 4-layer boards with continuous copper

planes. Note that 4-layer boards have significantly lower

thermal resistance, but both types show a rapid increase

for reduced board areas. Figure 9 shows actual measured

lead temperatures for chargers operating at full current.

Battery voltage and input voltage will affect device power

dissipation, so the data sheet power calculations must be

used to extrapolate these readings to other situations.

Vias should be used to connect board layers together.

Planes under the charger area can be cut away from the

rest of the board and connected with vias to form both a

low thermal resistance system and to act as a ground plane

for reduced EMI.

Glue-on, chip-mounted heat sinks are effective only in

moderate power applications where the PC board copper

cannot be used, or where the board size is small. They offer

very little improvement in a properly laid out multilayer

board of reasonable size.

Higher Duty Cycle for the LT1769 Battery Charger

Maximum duty cycle for the LT1769 is typically 90%, but

this may be too low for some applications. For example, if

Figure 7. Lower V

10 F

BOOST

SPIN

LT1769

BOOST

1769 F07

LT1769

1769fa

LT1769CGN#TR Linear Technology, LT1769CGN#TR Datasheet - Page 13

LT1769CGN#TR

Specifications of LT1769CGN#TR

Available stocks

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