LT1082_1 Datasheet, PDF(9/12 Page) Linear Integrated Systems – 1A High Voltage, Efficiency Switching Voltage Regulator

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

LT1082_1 Datasheet, PDF (9/12 Pages) Linear Integrated Systems – 1A High Voltage, Efficiency Switching Voltage Regulator

◁

LT1082

OPERATIO

Total power dissipation is the sum of supply current times

input voltage plus switch power:

PTOT = (IIN)(VIN) + PSW

In a typical example, using negative-to-positive converter

to generate 5V at 0.5A from a â 45V input, duty cycle is

approximately 12%, and switch current is about 0.5A,

yielding:

IIN = 4.5mA + 0.5(0.004 + DC/28) = 8.7mA

PSW = (0.5)2 â¢ 1.2â¦ â¢ (0.12) = 0.036W

PTOT = (45V)(8.7mA) + 0.036 = 0.43W

Temperature rise in a plastic miniDIP would be 90Â°C/W

times 0.43W, or approximately 39Â°C. The maximum am-

bient temperature would be limited to 100Â°C (commercial

temperature limit) minus 39Â°C, or 61Â°C.

In most applications, full load current is used to calculate

die temperature. However, if overload conditions must

also be accounted for, four approaches are possible. First,

if loss of regulated output is acceptable under overload

conditions, the internal thermal limit of the LT1082 will

protect the die in most applications by shutting off switch

current. Thermal limit is not a tested parameter, however,

and should be considered only for noncritical applications

with temporary overloads. A second approach is to use the

larger TO-220 (T) package which, even without a heat sink,

may limit die temperatures to safe levels under overload

conditions. In critical situations, heat sinking of these

packages is required; especially if overload conditions

must be tolerated for extended periods of time.

The third approach for lower current applications is to

leave the second switch emitter (miniDIP only) open. This

increases switch âonâ resistance by 2:1, but reduces

switch current limit by 2:1 also, resulting in a net 2:1

reduction in I2R switch dissipation under current limit

conditions.

The fourth approach is to clamp the VC pin to a voltage less

than its internal clamp level of 2V. The LT1082 switch

current limit is zero at approximately 1V on the VC pin and

1.6A at 2V on the VC pin. Peak switch current can be

externally clamped between these two levels with a diode.

See AN19 for details.

LT1082 Synchronizing

The LT1082 can be externally synchronized in the fre-

quency range of 75kHz to 90kHz. This is accomplished as

shown in the accompanying figures. Synchronizing oc-

curs when the VC pin is pulled to ground with an external

transistor. To avoid disturbing the DC characteristics of

the internal error amplifier, the width of the synchronizing

pulse should be under 1Âµs. C2 sets the pulse width at â

0.6Âµs. The effect of a synchronizing pulse on the LT1082

amplifier offset can be calculated from:

( )( ) âVOS

ï£« KT ï£¶

ï£ï£¬ q ï£¸ï£·

ï£«

ï£ï£¬IC

VC ï£¶

R3ï£¸ï£·

KT/q = 26mV at 25Â°C

tS = pulse width

fS = pulse frequency

IC = LT1082 VC source current (â 200ÂµA)

VC = LT1082 operating VC voltage (1V to 2V)

R3 = resistor used to set mid-frequency âzeroâ in LT1082

frequency compensation network.

With tS = 0.6Âµs, fS = 80kHz, VC = 1.5V, and R3 = 2k, offset

voltage shift is â 5mV. This is not particularly bothersome,

but note that high offset could result if R3 were reduced to

a much lower value. Also, the synchronizing transistor

must sink higher currents with low values of R3, so larger

drives may have to be used. The transistor must be

capable of pulling the VC pin to within 100mV of ground to

ensure synchronizing.

Synchronizing the LT1082

VIN

LT1082

GND

VN2222*

1N4148

350pF

2.2k

1N4148

FROM 5V

LOGIC

*SILICONIX OR EQUIVALENT

1082 OP01

sn1082 1082fas

▷