MIC4574 Datasheet, PDF(5/6 Page) Micrel Semiconductor – 200kHz Simple 0.5A Buck Voltage Regulator

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MIC4574 Datasheet, PDF (5/6 Pages) Micrel Semiconductor – 200kHz Simple 0.5A Buck Voltage Regulator

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MIC4574

Functional Description

The MIC4574 is a variable duty cycle switch-mode regulator

with an internal power switch. Refer to the block diagrams.

Supply Voltage

The MIC4574 operates from a +4V to +24V unregulated

input. Highest efficiency operation is from a supply voltage

below +15V.

Enable/Shutdown

The shutdown (SHDN) input is TTL compatible. Ground the

input if unused. A logic-low enables the regulator. A logic-

high shuts down the internal regulator which reduces the

current to typically 50ÂµA.

Feedback

Fixed versions of the regulator have an internal resistive

divider from the feedback (FB) pin. Connect FB directly to the

output line.

Adjustable versions require an external resistive voltage

divider from the output voltage to ground, connected from the

1.23V tap to FB.

Duty Cycle Control

A fixed-gain error amplifier compares the feedback signal

with a 1.23V bandgap voltage reference. The resulting error

amplifier output voltage is compared to a 200kHz sawtooth

waveform to produce a voltage controlled variable duty cycle

output.

Applications Information

The applications circuits that follow have been constructed

and tested. Refer to Application Note 15 for additional

information, including efficiency graphs and manufacturerâs

addresses and telephone numbers for most circuits.

Micrel

A higher feedback voltage increases the error amplifier

output voltage. A higher error amplifier voltage (comparator

inverting input) causes the comparator to detect only the

peaks of the sawtooth, reducing the duty cycle of the com-

parator output. A lower feedback voltage increases the duty

cycle.

Output Switching

When the internal switch is on, an increasing current flows

from the supply VIN, through external storage inductor L1, to

output capacitor COUT and the load. Energy is stored in the

inductor as the current increases with time.

When the internal switch is turned off, the collapse of the

magnetic field in L1 forces current to flow through fast

recovery diode D1, charging COUT.

Output Capacitor

External output capacitor COUT provides stabilization and

reduces ripple.

Return Paths

During the on portion of the cycle, the output capacitor and

load currents return to the supply ground. During the off

portion of the cycle, current is being supplied to the output

capacitor and load by storage inductor L1, which means that

D1 is part of the high-current return path.

For a mathematical approach to component selection and

circuit design, refer to Application Note 14.

6V to 24V

47ÂµF

35V

3 SHDN

SW 7

MIC4574-3.3BN

5 VIN

FB 1

SGND PGND

L1 3.3V/0.5A

100ÂµH

1N5819

220ÂµF

16V

8V to 24V

47ÂµF

35V

3 SHDN

SW 7

MIC4574-5.0BN

5 VIN

FB 1

SGND PGND

L1 5.0V/0.5A

100ÂµH

1N5819

220ÂµF

16V

C1 Nichicon

C2 Nichicon

D1 Motorola

L1 Sumida

UPL1V470MEH, ESR = 0.34â¦

UPL1C221MPH, ESR = 0.16â¦

1N5819

RCH875-101K, DCR = 0.28â¦

Figure 1. 6Vâ24V to 3.3V/0.5A Buck Converter

Through Hole

16V to 24V

33ÂµF

63V

SHDN

MIC4574BN

VIN

SGND PGND

C1 Nichicon

C2 Nichicon

D1 Motorola

L1 Sumida

UPL1J470MEH, ESR = 0.34â¦

UPL1C221MPH, ESR = 0.16â¦

1N5819

RCH875-101K, DCR = 0.28â¦

Figure 2. 8Vâ24V to 5V/0.5A Buck Converter

Through Hole

220ÂµH

MBR160

12V/0.5A

13.0k

1.50k

220ÂµF

16V

C1 Nichicon

C2 Nichicon

D1 Motorola

L1 Sumida

UPL1J330MEH, ESR = 0.35â¦

UPL1C221MPH, ESR = 0.16â¦

MBR160

RCH106-221K, DCR = 0.78â¦

Figure 3. 16Vâ24V to 12V/0.5A Buck Converter

Through Hole

4-96

April 1998â¢

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