4 design example, 1 buck design steps, Step 1) select a value for boost output voltage – Cirrus Logic AN379 User Manual

AN379

AN379REV2

21

4 Design Example

The required operating parameters for the analytical process are outlined in the table below.

Notes:

1. It is desirable to use a power FET that does not exceed 50V breakdown.
2. System efficiency estimate is 77%

3. Rectifying Schottky diode voltage V

F

is equal to 0.5V

4.1 Buck Design Steps

The example design is a 12VAC application. A maximum buck switching frequency of 150kHz is selected,
which corresponds to a switching period TT

BUCK

of 6.67µs.

Step 1) Select a Value for Boost Output Voltage
Full-scale boost output voltage V

BST(full)

is determined by sense resistor R

BST

which is set to 604k

. Use

Equation 7 on page 10 to calculate the full scale boost output voltage V

BST(full)

. Solve Equation 40 for boost

voltage V

BST(full)

:

For a 12VAC system, full-scale voltage V

BST(full)

is approximately 40V. The nominal boost output voltage V

BST

is 28V and droops to its lowest value towards the end of each half line-cycle until the boosting process starts
again in the next half line-cycle. The CS1680 limits the boost output voltage to ±15%. Therefore, minimum
boost output voltage V

BST(min)

and maximum boost output voltage V

BST(max)

are calculated using Equation 41

and 42, respectively:

Step 2) Select an Appropriate FET
Buck converters have an optimal operating range above 50% duty cycle, although any duty cycle above 30%
is close to optimal. When FET Q

BUCK

is turned off, the maximum drain voltage V

Drain(max)

occurs and is

calculated from Equation 43:

Use Equation 9 on page 11 to determine FET breakdown voltage V

Breakdown

. Solve Equation 44 for

voltage V

Breakdown

:

Parameters

Symbol

Value

Output Power

P

OUT

5.15W

AC Input Voltage

V

IN

12 VAC



10%

Output Voltage

V

OUT

12V



10%

Load Current

I

OUT

430 mA

Maximum Buck Switching Frequency

*

F

BUCKSW(max)

150 kHz

* Increasing the switching frequency may reduce the size of the magnetics but increase switching losses in the FET

and inductor.

V

BST full





I

ref

R

BST

20k



+







64

A

604k

 20k

+







39.9V

=

=

=

[Eq. 40]

V

BST min





28V

=

0.85



24V

=

[Eq. 41]

V

BST max





28V

=

1.15

32V

=



[Eq. 42]

V

Drain max





V

BST BOP





V

Diode

+

40V 0.9375





 0.5V

+

38V

=

=

=

[Eq. 43]

V

Breakdown

V

BST BOP





V

Diode

V

M

in

arg

+

+

37.5V 0.5V V

M

in

arg

+

+

=

=

[Eq. 44]