4 design example, 1 flyback design steps, An364 – Cirrus Logic AN364 User Manual

AN364

20

AN364REV3

4 Design Example

The Cirrus Logic CRD1611-8W reference design is used for the design example. The required operating parameters
for the analytical process are outlined in the table below.

4.1 Flyback Design Steps

Step 1) Select a Value for Boost Output Voltage
The CRD1611-8W is a 230V reference design. Boost output voltage V

BST

is 405V nominal.

Step 2) Select an Appropriate FET
Use Equation 3

to calculate maximum boost output voltage V

BST(max)

. The CS1611 limits the boost output

voltage to +10%. V

BST(max)

is calculated using Equation 27:

Using a 300V zener as a clamp device sets the maximum clamp voltage V

CLAMP

to 315V (+5% tolerance),

leaving 40V of V

Margin

to an 800V FET. Using an analytical approach to partition V

CLAMP

into V

Reflected

and

(V

Reflected

- V

CLAMP

) requires assumptions on the switching details.

It is recommended to choose V

Reflected

to equal 70% of V

CLAMP

. Voltage V

Reflected

is set to 220V, leaving 80V

of overshoot to dissipate as leakage inductance energy. The actual overshoot range is from 65V to 95V,
depending on the clamp zener tolerance. See Equation 28:

Step 3) Determine the Flyback Transformer Turns Ratio
Select a turns ratio for the flyback transformer T1 based on the desired output voltage, V

OUT

, and V

Reflected

.

Output voltage V

OUT

is the maximum LED string forward voltage at full current, plus rectifying diode forward

voltage V

F

. Using Equation 4, calculate turns ratio N:

Step 4) Select the Full Brightness Switching Frequency
At full power, the flyback stage operates in valley-switching mode. The addition of a small transition time T3
results in extending time TT and slightly reducing the design frequency. The frequency reduction has a
negligible effect on the design, but requires that time T1, T2 and TT be correctly calculated at full brightness.
An optimal compromise between transformer size and efficiency is reached at a switching frequency of
~85kHz.
To accommodate valley switching, T3 is set to approximately one-half of the resonant period of the flyback
inductor resonance, taking into account all capacitances associated with the FET drain node. Setting T3 to 1



s

is an acceptable starting value. Once a system is built and validated, the design can be refined. Using
Equation 5, solve for (T1 + T2):

Parameters

Symbol

Value

Output Power

P

OUT

6.6W

AC Line Input Voltage

V

IN

230V

Output Voltage

V

OUT

15V

Load Current

I

OUT

440mA

Maximum Switching Frequency

*

F

sw(max)

85kHz

* Increasing F

sw

reduces the size of the magnetics but increases switching losses in the FET.

V

BST max





405V

=

1.1 V 445V

=



[Eq. 27]

V

Breakdown

V

BST max





V

CLAMP

V

M

in

arg

+

+

445V 315V 40V

+

+

800V

=

=

=

[Eq. 28]

N

V

Reflected

V

OUT

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

220V

15V 0.4V

+

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

14.3

=

=

=

[Eq. 29]

T1 T2

+

1

F

sw

-----------







 T3

–

1

85kHz

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







 1s

–

11.76

s

=

=

=

[Eq. 30]