MIC3230 Datasheet, PDF(13/20 Page) Micrel Semiconductor – Constant Current Boost Controller for Driving High Power LEDs

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MIC3230 Datasheet, PDF (13/20 Pages) Micrel Semiconductor – Constant Current Boost Controller for Driving High Power LEDs

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Micrel, Inc.

MIC3230/1/2

VIN

CIN

4.7ÂµF/50v

ENABLE

PWMD

Synch to other MIC3230

100k

RFS

16.5k

CCOMP

10nF

10ÂµF

10V

Analog ground

47ÂµH

VIN

OVP

PWMD

SYNC

COMP

VDD

AGND

MIC3230/31

DRV

EPAD

RSLC

IADJ VFB = 0.25V

PGND

RADJ

1/4W

RCS

1/2W

Power ground

Figure 7. Design Example Schematic

100k

4.33k

VOUT

COUT

4.7ÂµF

100V

LED 1

LED X

ILED Return

Design Example

In this example, we will be designing a boost LED driver

operating off a 12V input. This design has been created

to drive six LEDs at 350mA with a ripple of about 12%.

We are designing for 80% efficiency at a switching

frequency of 500kHz.

Select RFS

To operate at a switching frequency of 500kHz, the RFS

resistor must be chosen using Equation 3.

RFS (kÎ©) =

(7526)1.035

500

= 16.6kÎ©

Use the closest standard value resistor of 16.5kâ¦.

Select RADJ

Having chosen the LED drive current to be 350mA in this

example, the current can be set by choosing the RADJ

resistor from Equation 1:

R ADJ

0.25V

0.35A

= 0.71Î©

The power dissipation in this resistor is:

P(RADJ ) = I 2 * RADJ = 87mW

Use a resistor rated at Â¼ watt or higher. Choose the

closest value from a resistor manufacture.

Operating Duty Cycle

The operating duty cycle can be calculated using

Equation 12 provided below:

Eq. (12)

D = (Vout â eff ÃVin + Vdiode )

Vout + Vdiode

These can be calculated for the nominal (typical)

operating conditions, but should also be understood for

the minimum and maximum system conditions as listed

below.

Dnom

(Voutnom â eff Ã Vinnom + Vschottky

Voutnom + Vschottky

)

Dmax

(Voutmax â eff Ã Vinmin + Vschottky )

Voutmax + Vschottky

Dmin

(Voutmin â eff ÃVinmax + Vschottky )

Voutmin + Vschottky

Therefore DNOM =56% DMAX = 78% and DMIN = 33%

Inductor Selection

First, it is necessary to calculate the RMS input current

(nominal, min and max) for the system given the

operating conditions listed in the design example table.

This minimum value of the RMS input current is

necessary to ensure proper operation. Using Equation

9, the following values have been calculated:

IIN _ RMS _ max

= VOUT _ max Ã IOUT _ max

eff ÃVIN _ min

= 1.64A _ rms

January 2009

M9999-011409-A

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