An379 – Cirrus Logic AN379 User Manual

AN379

AN379REV2

9

The CS1680 maximum switching frequency is 312.5kHz. Test results indicate that optimal performance is
obtained in the range of 75kHz to 225kHz. Higher frequencies allow the use of smaller magnetics, but
switching losses increase. Selecting too low a full brightness switching frequency risks allowing the minimum
frequency to drop into the audible range. Equation 1 defines the buck stage switching frequency TT

BUCK(fb)

at

full brightness:

Using the full brightness frequency, determine the value of critical period (T1

BUCK

+T2

BUCK

) using Equation 2:

where

T3

BUCK

= the idle time added at the end of time (T1

BUCK

+T2

BUCK

)

The resonant frequency is defined by the magnetizing inductance and the parasitic capacitance at the drain of
power FET Q

BUCK

, which includes the parasitic capacitance across the buck inductor winding, power FET

Q

BUCK

drain to source, and the reflected capacitance due to catch diode D

BUCK

. The buck inductance

resonates with the total parasitic capacitance of the drain node and is calculated using Equation 3:

where

L

BUCK

= buck inductance

C

P

= total parasitic capacitance at the drain of power FET Q

BUCK

During full brightness circuit operation, the circuit is delivering full nominal power to the LED string. When
power FET Q

BUCK

turns on, current flows through the LED string, inductor L

BUCK

winding, FET Q

BUCK

, and

resistor R

BUCK(Sense)

. The current rises linearly from zero to a preset maximum peak current I

BUCKPK

defined

by sense resistor R

BUCK(Sense)

and the internal IC threshold. The gate is driven high for as long as is required

to reach peak current I

BUCKPK

. The controller has a maximum turn-on time T1

BUCK

limit set to 6.5

s, after

which the gate is turned off.
During period T2

BUCK

, the buck inductor current decays linearly, transferring the energy stored in the inductor

to the load. At the end of period T2

BUCK

, the current in the inductor is zero. However, some energy is stored

in parasitic capacitance C

P

charged to voltage V

OUT

. Capacitance C

P

and inductance L

BUCK

oscillate until the

losses exhaust the energy stored in capacitor C

P

.

The zero-current detection circuit looks for the first zero-crossing of the oscillation after period T2

BUCK

, and

starts a timer that determines the duration of idle time T3

BUCK

. Once the idle time is depleted the control loop

turns on power FET Q

BUCK

to start a new cycle. Extending idle time T3

BUCK

, when no current flows in the load

circuit, dilutes the energy delivered during time T1

BUCK

and T2

BUCK

resulting in lower average power to the

load.

TT

BUCK fb

 

1

F

BUCKSW

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

=

[Eq. 1]

T1

BUCK

T2

BUCK

+

1

F

BUCKSW

-------------------------- T3

BUCK

–

TT

BUCK

T3

BUCK

–

=

=

[Eq. 2]

T3

BUCK

 L

BUCK

C

P



=

[Eq. 3]