OZ964 Datasheet, PDF(8/14 Page) List of Unclassifed Manufacturers

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OZ964 Datasheet, PDF (8/14 Pages) List of Unclassifed Manufacturers – Change Summary

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FUNCTIONAL INFORMATION

1. Steady-State Operation

Referring to the example schematic shown in

Figure 2, page 9, OZ964 drives a full-bridge

power train where the transformer couples the

energy from the power supply source to the

CCFL. The switches in the bridge denoted as

QA, QB, QC and QD are configured such that the

transistors in each pair, QA/QB and QC/QD, are

turned-on complementarily. The turn-on duration

of the diagonal switches, QA/QD and QB/QC,

simultaneously determines the amount of energy

delivered to the transformer and subsequently to

the CCFL. The current in the CCFL is sensed

and regulated by adjusting the turn-on time

(overlap) for both diagonal switches. This is

accomplished through an error amplifier in the

current feedback loop.

A voltage loop is used to regulate the output

voltage for CCFL ignition and is programmable

by using a capacitor divider (C8/C13).

Over Voltage Protection (OVP) limits the

transformer voltage under an open-lamp

condition. A soft-start circuit ensures a gradual

increase in power to the CCFL. The soft-start

capacitor (C9) determines the rate of rise of the

voltage on the SST pin. Meanwhile, the voltage

level determines the turn-on time of the diagonal

switches QA/QD and QB/QC.

The output drives for the power MOSFET gates

include PDR_A, NDR_B, PDR_C and NDR_D

that output a complementary square pulse. The

operation of the four switches is implemented

with zero-voltage switching that provides a high-

efficiency power conversion.

2. Enable

OZ964 is enabled when the voltage on ENA (pin

3) is greater than 2V. A voltage of less than 1V

disables the IC. When the inverter controller is

disabled, it draws approximately 200uA. An

under-voltage lockout protection feature is

provided that will disable the IC if VDDA voltage

drops below an ~3.4V threshold. The IC will

resume normal operation once VDDA reaches a

threshold voltage of greater than ~4.3V.

3. Soft-Start

To avoid component stresses and in-rush current

to the CCFLs during ignition, a soft start function

is implemented to provide reliable CCFL

operation. The soft-start function is initiated when

OZ964

the voltage at ENA (pin 3) is greater than 2V. The

soft-start time is determined by an external

capacitor (C9) connected to the SST (pin 4). At

start-up, as C9 charges via a charging current,

the voltage level at the capacitor controls the

gradual increase in power delivered to the

transformer T1.

4. Ignition

The OZ964 provides an option of selecting a

different frequency for striking the CCFLs. The

striking time is user-defined and determined by

an external capacitor CCTIMR (C6) and external

resistor RCTIMR (R5) connected to CTIMR (pin 1).

The approximate striking time is determined by

the following equation.

CCTIMR[ÂµF] x (3-(RCTIMR[kâ¦] x 0.0026))

T[second] =

2.6

The approximate striking frequency is determined

by the following equation.

fstriking[kHz] =

65â¢104

CCT[pF]â¢(RRT // RRT1) [kâ¦]

Note: RRT // RRT1 means RRT is in parallel with RRT.1.

5. Normal Operation

Once the IC is enabled, the voltage at SST (pin

4) controls the rate of power delivered to the

load. SST voltage increases to a level such that

the CCFLs are ignited. The striking frequency is

determined by external components R10, R9 and

C5 connected to RT1 (pin 8), RT (pin 17) and CT

(pin 18) respectively.

Once the external resistor R16 senses sufficient

current, the control loop takes control and

regulates the CCFL current. The normal

operating frequency is determined by the

combination of external resistor R9 and external

capacitor C5. The operating frequency is

approximated by the following equation.

fop[kHz] =

65â¢104

CCT[pF]â¢RRT[kâ¦]

CONFIDENTIAL

OZ964-DS-1.2

Page 7

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