Fairchild SEMICONDUCTOR RC5040 User Manual

APPLICATION NOTE

AN42

15

Table 10. Schottky Diode Selection Table

Output Filter Capacitors

Output ripple performance and transient response are
functions of the filter capacitors. Since the 5V supply of a PC
motherboard may be located several inches away from the
DC-DC converter, the input capacitance can play an impor-
tant role in the load transient response of the RC5040.
The higher the input capacitance, the more charge storage is
available for improving the current transfer through the
FET(s). Capacitors with low Equivalent Series Resistance
(ESR) are best for this type of application and can influence
the converter's efficiency if not chosen carefully. The input
capacitor should be placed as close to the drain of the FET as
possible to reduce the effect of ringing caused by long trace
lengths.

ESR is the resonant impedance of the capacitor, and it is dif-
ficult to quantify. Since the capacitor is actually a complex
impedance device having resistance, inductance, and capaci-
tance, it is natural for it to have a resonant frequency. As a
rule, the lower the ESR, the better suited the capacitor is for
use in switching power supply applications. Many manufac-
turers do not supply ESR data, but a useful estimate can be
obtained using the following equation:

where DF is the dissipation factor of the capacitor, f is the
operating frequency, and C is the capacitance in farads.

With this in mind, correct calculation of the output capaci-
tance is crucial to the performance of the DC-DC converter.
The output capacitor determines the overall loop stability,
output voltage ripple, and load transient response. The calcu-
lation is as follows:

where

∆

V is the maximum voltage deviation due to load

transients

, ∆

T is the reaction time of the power source, and

I

O

is the output load current.

∆

V is the loop response time of

the RC5040 and RC5042, approximately 8

µ

s.

For I

O

= 10A and

∆

V = 165mV, the bulk capacitance

required can be approximated as follows:

Input filter

The DC-DC converter design should include an input induc-
tor between the system +5V supply and the converter input
as described below. This inductor will serve to isolate the
+5V supply from noise occurring in the switching portion of
the DC-DC converter and also to limit the inrush current into
the input capacitors during power up. An inductor value of
around 2.5

µ

H is recommended, as illustrated in Figure 15.

Bill of Materials

The Bill of Materials for the application circuits of Figures 2
through 4 is presented in Table 11.

Manufacturer

Model #

Conditions

Forward Voltage

V

F

Philips
PBYR1035

I

F

= 20A; T

j

=25

°

C

I

F

= 20A; T

j

=125

°

C

< 0.84v
< 0.72v

Motorola
MBR2035CT

I

F

= 20A; T

j

=25

°

C

I

F

= 20A; T

j

=125

°

C

< 0.84v
< 0.72v

Motorola
MBR1545CT

I

F

= 15A; T

j

=25

°

C

I

F

= 15A; T

j

=125

°

C

< 0.84v
< 0.72v

Motorola
MBR2015CTL

I

F

= 20A; T

j

=25

°

C

I

F

= 20A; T

j

=150

°

C

< 0.58v
< 0.48v

ESR

DF

2

π

fC

-------------

=

C

µ

F

( )

I

O

∆

T

×

∆

V

I

O

ESR

×

–

--------------------------------------

=

C

µ

F

( )

I

O

∆

T

×

∆

V

I

O

ESR

×

–

--------------------------------------

10A

8

µ

s

×

165mV

10A

11m

Ω

×

–

---------------------------------------------------------

1454

µ

F

=

=

=

1000

µ

F, 10V

Electrolytic

0.1

µ

F

65-AP42-17

2.5

µ

H

5V

Vin

Figure 15. Input Filter

Table 11. Bill of Materials for a 14.5A Pentium Pro Motherboard Application

C4, C5, C7, C8, C9,
C10

Panasonic
ECU-V1H104ZFX

0.1

µ

F 50V capacitor

C6

Panasonic
ECSH1CY475R

4.7

µ

F 16V capacitor

Cext

Panasonic
ECU-V1H121JCG

39pF capacitor

C12

C1, C2, C3

United Chemicon
LXF16VB102M

1000

µ

F 6.3V electrolytic

capacitor 10mm x 20mm

ESR<0.047

Ω

C11

Panasonic
ECU-V1H224ZFX

0.22

µ

F 50V capacitor