FAN5308 データシートの表示（PDF） - Fairchild Semiconductor

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FAN5308

800mA High-Efficiency Step-Down DC-DC Converter

Fairchild Semiconductor 

Applications Information

Setting the Output Voltage

The internal reference is 0.8V (typical). The output volt-

age is divided by a resistor divider, R1 and R2 to the FB

pin. The output voltage is given by:

VOUT

=

VR

E

F

×





1

+





RR-----12--





EQ. 3

where R1 + R2 < 800KΩ.

According to this equation, and assuming desired output

voltage of 1.5096V, and given R2 = 10kΩ, the calculated

value of R1 is 8.87kΩ. If quiescent current is a key

design parameter, a higher value feedback resistor can

be used (e.g. R2 = 100kΩ) and a small bypass capacitor

of 10pF is required in parallel with the upper resistor, as

shown in Figure 16.

CIN

10µF

VIN

1

PGND

2

EN

3

P1

(AGND)

SW

6

3.3µH

5 NC

R1

FB

4

Cf

5KΩ

R2 10KΩ

VOUT

1.2V (800mA)

COUT

2 x 10µF

Capacitors Selection

For best performances, a low-ESR input capacitor is

required. A ceramic capacitor of at least 10µF, placed

close to the VIN and AGND pins, is recommended. The

output capacitor determines the output ripple and the

transient response.

Capacitor

Value

10µF

Vendor

Taiyo

Yuden

TDK

Murata

Part Number

JMK212BJ106MG

JMK316BJ106KL

C2012X5ROJ106K

C3216X5ROJ106M

GRM32ER61C106K

Table 2: Recommended Capacitors

PCB Layout Recommendations

The recommended PCB layout is shown in Figure 17. The

inherently high peak currents and switching frequency of

power supplies require careful PCB layout design.

Figure 16. Setting the Output Voltage

Inductor Selection

The inductor parameters directly related to the device’s

performances are saturation current and DC resistance.

The FAN5308 operates with a typical inductor value of

3.3µH. The lower the DC resistance, the higher the effi-

ciency. For saturation current, the inductor should be

rated higher than the maximum load current plus half of

the inductor ripple current.

This is calculated as follows:

∆IL = VOUT × -1----–-----(--V-----O--L---U--×---T--f---⁄---V-----I--N-----)

where:

∆IL = Inductor Ripple Current

f = Switching Frequency

L = Inductor Value

EQ. 4

Inductor Value Vendor Part Number

3.3µH

3.3µH

Panasonic ELL6PM3R3N

Murata LQS66C3R3M04

Table 1: Recommended Inductors

Figure 17. Recommended PCB Layout

Use wide traces for high-current paths and place the

input capacitor, the inductor, and the output capacitor as

close as possible to the integrated circuit terminals. To

minimize voltage stress to the device resulting from ever-

present switching spikes, use an input bypass capacitor

with low ESR. Note that the peak amplitude of the

switching spikes depends upon the load current; the

higher the load current, the higher the switching spikes.

The resistor divider that sets the output voltage should

be routed away from the inductor to avoid RF coupling.

The ground plane at the bottom side of the PCB acts as

an electromagnetic shield to reduce EMI.

For more board layout recommendations, download the

Fairchild application note PCB Grounding System and

FAN2001/FAN2011 High-Performance DC-DC Converters

(AN-42036).

©2005 Fairchild Semiconductor Corporation

FAN5308 Rev. 1.0.2

9

www.fairchildsemi.com

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