Texas Instruments SLVP089 User Manual

Page 23

Design Procedures

2-5

Design Procedure

The power dissipation (conduction + switching losses) can be approximated
as:

2
O

DS(ON)

)

0.5

)

Assuming total switching time, t

r+f

, = 100 ns, a 55

C maximum ambient tem-

perature, and r

DS(ON)

adjustment factor = 1.6, then:

(0.04

1.6)

0.64

)

0.5

5.5

0.1

–6

100

0.45 W

The thermal impedance for Q1 R

= 90

C/W for FR-4 with 2-oz. copper and

a one-inch-square pattern, thus:

)

(90

0.45)

2.3.4

Synchronous Switch and Rectifier

The synchronous switch calculations follow the same path as the power switch
except that the duty cycle is 1–D. Then r

DS(ON)

should be less than 0.012 V

3A = 40 m

. Selecting an IRF7201 with an r

DS(ON)

= 30 m

, then:

(0.03

1.6)

0.36

)

0.5

5.5

0.1

–6

100

0.238 W

)

(90

0.238)

The catch rectifier serves as a backup device for the synchronous switch and
conducts during the time interval when both devices are off. The 30BQ015 is
a 3-A, 15-V rectifier in an SMC power surface-mount package. If the synchro-
nous switch were not used, the power dissipation for the catch diode would be:

1 – D

Min

0.7

0.71

1.491 W

However, since the catch diode actually conducts only during the deadtime
and switching time, the power dissipation is:

)

0.7

0.1

–6

100

2.1 mW

2.3.5

Snubber Network

A snubber network is usually needed to suppress the ringing at the node where
the power switch drain, output inductor, and synchronous switch drain con-
nect. This is usually a trial-and-error sequence of steps to optimize the net-
work, but as a starting point, select a snubber capacitor with a value that is
4–10 times larger than the estimated capacitance of the synchronous switch
and catch rectifier. Then, measuring a ringing time constant of 3 ns, R is:

–

1000

–