MAX1610 Datasheet, PDF(8/20 Page) Maxim Integrated Products – Digitally Controlled CCFL Backlight Power Supplies

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MAX1610 Datasheet, PDF (8/20 Pages) Maxim Integrated Products – Digitally Controlled CCFL Backlight Power Supplies

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Digitally Controlled CCFL Backlight

Power Supplies

RW BIT

CLOCKED

INTO SLAVE

ACKNOWLEDGED

BIT CLOCK

INTO MASTER

MOST SIGNIFICANT

BIT CLOCKED

SCL â¢ â¢ â¢

SDA â¢ â¢ â¢

SLAVE PULLING

SDA LOW

tDV

Figure 3. MAX1611 SMB Serial-Interface TimingâAcknowledge

_______________Detailed Description

Getting Started

A cold-cathode fluorescent lamp (CCFL) has two termi-

nals. For the CCFL to emit light, the two lamp terminals

must be driven with a high-voltage (approximately

550V AC RMS) and high-frequency (approximately

45kHz) sine wave. The MAX1610/MAX1611 use a vary-

ing DC input voltage to create this high-voltage, high-

frequency sine-wave drive. To select the correct

component values for the MAX1610/MAX1611 circuit,

several CCFL parameters and the minimum DC input

voltage must be specified; these are listed in Table 1.

Table 3 shows the recommended component values to

use with the circuit of Figure 4, depending on the par-

ticular CCFL parameters. The C2 values in Table 3

have been selected such that the normal operating

voltage on the secondary of T1 is as close as possible

to the CCFL strike voltage (where the strike voltage

(VS) is assumed to be approximately 1.8 times the

CCFL operating voltage (VL)).

Components T1, C1, R2, Q1, and Q2 form a Royer

oscillator. A Royer oscillator is a resonant tank circuit

that oscillates at a frequency dependent on C1, the pri-

mary magnetizing inductance of T1 (LP), and the

impedance seen by the T1 secondary. The

MAX1610/MAX1611 regulate the current fed into the

Royer oscillator by sensing the voltage on R1. For a

given current through the Royer oscillator (IR1), the

power delivered to the CCFL depends on the Royer

oscillator frequency. The R1 values in Table 3 have

been selected to ensure that the power into the CCFL

does not exceed its maximum rating, despite T1, C1, and

C2 component-value variations. The Royer oscillator

waveforms for the circuit of Figure 4 are shown in Figures

5 and 6.

Analog Circuitry

The MAX1610/MAX1611 maintain fixed CCFL bright-

ness with varying input voltages on BATT by regulating

the current fed into the Royer oscillator. This current is

sensed via resistor R1 between CSAV and GND. An

internal switch from BATT-to-LX pulse-width modulates

at a fixed frequency to servo the CSAV pin to its regula-

tion voltage. The CSAV regulation voltage can be

adjusted via the digital interface to set CCFL bright-

ness. The MAX1610 and MAX1611 differ only in the

digital interface they use to adjust the internal 5-bit digi-

tal-to-analog converter (DAC) that sets the CSAV regu-

lation voltage. The minimum-scale (min-scale) CSAV

regulation voltage is resistor adjustable using the MIN-

DAC pin, setting the minimum CCFL brightness. The

D/A setting at MAX1610/MAX1611 power-up is preset

to mid-scale (10000 binary) (Figure 7).

MINDAC Sets the Minimum Scale

The MINDAC pin sets the lowest CCFL brightness

level. The voltage at MINDAC is divided by eight, and

sets the minimum CSAV regulation voltage. For exam-

ple, in the circuit of Figure 4, R5 (150kâ¦) and R6

(51kâ¦) form a resistor divider from REF, which sets

MINDAC to 507mV (REF = 2.0V). This sets a minimum

CSAV regulation voltage of 63mV with a full-scale

CSAV regulation voltage of 247mV.

8 _______________________________________________________________________________________

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