MIC2177 Datasheet, PDF(11/16 Page) Micrel Semiconductor

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MIC2177 Datasheet, PDF (11/16 Pages) Micrel Semiconductor – 2.5A Synchronous Buck Regulator

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MIC2177

Application Information

Feedback Resistor Selection (Adjustable Version)

The output voltage is configured by connecting an external

resistive divider to the FB pin as shown in âMIC2177 Block

Diagram.â The ratio of R1 to R2 determines the output

voltage. To optimize efficiency during low output current

operation, R2 should not be less than 20kâ¦. However, to

prevent feedback error due to input bias current at the FB pin,

R2 should not be greater than 100kâ¦. After selecting R2,

calculate R1 using the following formula:

ï£®ï£«

ï£°ï£¯ï£ï£¬

VOUT

1.245V

ï£¶

ï£¸ï£·

ï£¹

1ï£º

ï£»

Input Capacitor Selection

The input capacitor is selected for its RMS current and

voltage rating and should be a low ESR (equivalent series

resistance) electrolytic or tantalum capacitor. As a rule-of-

thumb, the voltage rating for a tantalum capacitor should be

twice the value of VIN, and the voltage rating for an electrolytic

should be 40% higher than VIN. The RMS current rating must

be equal or greater than the maximum RMS input ripple

current. A simple, worst-case formula for calculating this

RMS current is:

IRMS(max)

ILOAD(max)

Tantalum capacitors are a better choice for applications that

require the most compact layout or operation below 0Â°C. The

input capacitor must be located very close to the VIN pin

(within 0.2 inches, 5mm). Also place a 0.1ÂµF ceramic bypass

capacitor as close as possible to VIN.

Inductor Selection

The inductor must be at least a minimum value in order for the

MIC2177 to change from PWM to skip mode at the correct

value of output current. This minimum value ensures the

inductor ripple current never exceeds 600mA, and is calcu-

lated using the following formula:

ï£«

LMIN = VOUT ï£¬1 â

ï£

VOUT

VIN(max)

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ï£·

ï£¸

Ã 8.3ÂµH/V

Where:

VIN(max) = maximum input voltage

In general, a value at least 20% greater than LMIN should be

selected because inductor values have a tolerance of Â±20%.

Two other parameters to consider in selecting an inductor are

winding resistance and peak current rating. The inductor

must have a peak current rating equal or greater than the

peak inductor current. Otherwise, the inductor may saturate,

causing excessive current in the output switch. Also, the

inductorâs core loss may increase significantly. Both of these

effects will degrade efficiency. The formula for peak inductor

current is:

IL(peak) = ILOAD(max) + 300mA

Micrel

To maximize efficiency, the inductorâs resistance must be

less than the output switch on-resistance (preferably 50mâ¦

or less).

Output Capacitor Selection

Select an output capacitor that has a low value of ESR. This

parameter determines a regulatorâs output ripple voltage

(VRIPPLE) which is generated by âIL Ã ESR. As mentioned in

âInductor Selection,â the maximum value for âIL is 600mA.

Therefore, the maximum value of ESR is:

ESRMAX

600mA

VRIPPLE

Where:

VRIPPLE < 1% of VOUT

Typically, capacitors in the range of 100ÂµF to 220ÂµF have

ESR less than this maximum value. The output capacitor can

be either a low ESR electrolytic or tantalum capacitor, but

tantalum is a better choice for compact layout and operation

at temperatures below 0Â°C. The voltage rating of a tantalum

capacitor must be 2 Ã VOUT, and the voltage rating of an

electrolytic must be 1.4 Ã VOUT.

Output Diode Selection

In PWM operation, inductor current flows through the output

diode approximately 50ns during the dead time when one

output MOSFET turns off and the other turns on. In skip

mode, the inductor current flows through the diode during the

entire P-channel off time. The correct diode for both of these

conditions is a 1A diode with a reverse voltage rating greater

than VIN. It must be a Schottky or ultrafast-recovery diode

(tR < 100ns) to minimize power dissipation from the diodeâs

reverse-recovery charge.

Compensation

Compensation is provided by connecting a series RC load to

the COMP pin. This creates a pole-zero pair in the regulator

control loop, allowing the regulator to remain stable with

enough low frequency loop-gain for good load and line

regulation. At higher frequencies, pole-zero reduces loop-

gain to a level referred to as the mid-band gain. The mid-band

gain is low enough so that the loop gain crosses 0dB with

sufficient phase margin. Typical values for the RC load are

4.7nF â 10nF for the capacitor and 5kâ¦ â 20kâ¦ for the

resistor.

Printed Circuit Board Layout

A well designed PC board will prevent switching noise and

ground bounce from interfering with the operation of the

MIC2177. A good design takes into consideration component

placement and routing of power traces.

The first thing to consider is the locations of the input

capacitor, inductor, output diode, and output capacitor. The

input capacitor must be placed very close to the VIN pin, the

inductor and output diode very close to the SW pin, and the

output capacitor near the inductor. These components pass

large high-frequency current pulses, so they must use short,

wide power traces. In addition, their ground pins and PGND

are connected to a ground plane that is nearest the power

supply ground bus.

April 1999

MIC2177

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