LT1507 Просмотр технического описания (PDF) - Linear Technology

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LT1507

500kHz Monolithic Buck Mode Switching Regulator

Linear Technology 

LT1507

APPLICATIONS INFORMATION

works by prematurely tripping the oscillator before it

reaches its normal peak value. For instance, if the oscilla-

tor is synchronized at twice its nominal frequency, oscil-

lator amplitude will drop by half. A ramp which previously

started at the 40% point now starts at the 80% point! This

effectively blocks slope compensation and the regulator

may respond with fluctuating pulse widths, a “phase

oscillation” if you will. The regulator output stays in

regulation but subharmonic frequencies are generated at

the switch node.

The solution to this problem is to generate an external

ramp that replaces the missing internal ramp. As it turns

out, this is not difficult if the sync signal can be arranged

to have a fairly low duty cycle (< 35%). The ramp is created

by AC coupling a resistor from the sync signal to the

compensation capacitor as shown in Figure 7. This gener-

ates a negative ramp on the VC pin during switch ON time

that emulates the missing internally generated ramp.

Amplitude of the ramp should be about 100mV to 200mV

peak-to-peak. The formulas for calculating the values of

RS and CS are shown below. Note that the CS value is

unimportant as long as it exceeds the value given. The

formula assures that the impedance of CS will be small

compared to RS.

RS

=

VSYNC(DCS)(1− DCS)

VP-P(CC)(f)

CS

>

20

2π(f)(RS)

VSYNC = Peak-to-peak value of sync signal

DCS = Duty cycle of incoming sync signal

VP-P = Desired amplitude of ramp

f = Sync frequency

Theoretical minimum amplitude for the ramp, assuming

no internal ramp, is:

VP-P

≥

(2VOUT − VIN)(1− DCS)

2(f)(L)(gmP )

gmP = Transconductance from VC pin to switch current

(1.8A/V for the LT1507).

For VIN = 4.7, VOUT = 3.3V, f = 1MHz, L = 5µH and DCS = 25%:

VP-P

≥

2

(6.6 − 4.7)(1− 0.25)

1106510−6 1.8

=

71mV

To avoid small values of RS, the compensation capacitor (CC)

should be made as small as possible. 2000pF will work in

most situations. If we increase VPP to 90mV for a little

cushion, RS will be:

( ) ( ) RS

=

(5)(0.25)(0.75)

0.09 2

10−9





1

106

=



5.2k

( ) C ≥

20

= 612pF

2π 1

106





(5200)

THERMAL CALCULATIONS

Power dissipation in the LT1507 chip comes from four

sources: switch DC loss, switch AC loss, boost circuit

current and input quiescent current. The formulas below

show how to calculate each of these losses. These formu-

las assume continuous mode operation, so they should

not be used for calculating efficiency at light load currents.

Switch loss:

PSW

=

RSW(IOUT )2(VOUT)+

VIN

16ns(IOUT )(VIN)(f)

Boost current loss:

PBOOST

=

VOUT2

VIN

 0.008

+

IOUT

75



Quiescent current loss:

PQ = VIN(0.003) + VOUT (0.005)

RSW = Switch resistance (≈ 0.4Ω)

16ns = Equivalent switch current/voltage overlap time

f = Switching frequency

17

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