KR19980020086A - Lamp driving circuit for backlight of liquid crystal display panel - Google Patents

Abstract

The present invention discloses a lamp driving circuit for a backlight of a liquid crystal display panel. The circuit comprises amplifying means having a negative input terminal for inputting a signal from a feedback signal input pin, a positive input terminal to which a reference voltage is applied, and an output terminal connected to a comparison signal input pin, and inputting an output signal of the amplifying means to a minimum; A voltage controlled oscillation means for oscillating between a maximum frequency at a frequency, a dead time control means for generating a signal for controlling a dead time by inputting an output signal of the voltage controlled oscillation means, and inverting an output signal of the dead time control means Inverting driving means for outputting to the first output pin, non-inverting driving means for non-inverting the output signal of the dead time control means to output to the second output pin, a power supply voltage applying pin for applying a power supply voltage, applying a ground voltage A ground voltage applying pin, an on / off pin for turning on / off an operation, and a compensation pin are integrated. Therefore, the number of pins can be reduced, and the application circuit can be simplified accordingly.

Description

Lamp driving circuit for backlight of liquid crystal display panel

The present invention relates to a liquid crystal display panel, and more particularly, to a lamp driving circuit for a backlight of a liquid crystal display panel.

Since the liquid crystal display panel does not emit light by itself, a discharge lamp called a cold cathode fluorescent lamp (CCFL) and an inverter module for driving the lamp always display liquid crystals in order to view information on the screen of the liquid crystal display panel. It is attached to the display panel.

The lamp driving circuits for backlights for liquid crystal display panels up to now have two independent circuits, a buck converter for maintaining a constant output current in an input voltage fluctuation range and a rotor converter for converting direct current to alternating current. By combining the circuit method, the lamp was driven in a two-step method. However, future trends will evolve into single-stage circuitry, which is a 32-pin and 14-pin package with dedicated integrated circuits for driving cold cathode fluorescent lamps with these single-stage circuits, but fewer to make the external application easier for users. The number of pins must be able to drive a cold cathode fluorescent lamp, which is a backlight lamp of a liquid crystal display panel.

1 illustrates an application circuit of a driving integrated circuit for driving a backlight lamp of a conventional liquid crystal display panel. In the conventional 14-pin integrated circuit package, a ground voltage (GND, PGND) is used as one and a protection function is minimized. The number of pins was reduced by the method, and the 32-pin package was formed by adding various protection circuits. Looking at the function of each pin, it consists of a resistor (RT), a capacitor (CT) for setting the frequency, a gate signal for turning on and off the up and down switches, a power supply voltage (VCC), and a ground voltage (GND) have.

By the way, the integrated circuit for driving the conventional cold cathode fluorescent lamp is rarely sold as an integrated circuit operation, the unit integrated with the drive integrated circuit and the inverter module is sold. In addition, the LCC of the power stage has already been determined experimentally the most optimized value and applied to the inverter module, the minimum and maximum frequency is already determined.

Therefore, it is not reasonable to separately create two pins for frequency selection outside the integrated circuit, with the experimentally optimized LCC value determined. The shortcoming was that the circuit became complicated with 32 pins and 14 pins without the need for application circuits.

SUMMARY OF THE INVENTION An object of the present invention is to provide a lamp driving circuit for a backlight of a liquid crystal display panel that enables users to more easily make external applications by reducing the number of pins of the driving integrated circuit for backlight of a liquid crystal display panel.

In order to achieve the above object, a backlight lamp driving circuit of a liquid crystal display panel of the present invention is connected to a negative input terminal for inputting a signal from a feedback signal input pin, a positive input terminal to which a reference voltage is applied, and a comparison signal input pin. Amplifying means having an output terminal, a voltage controlled oscillating means for oscillating between the maximum frequencies at a minimum frequency by inputting the output signal of the amplifying means, and generating a signal for controlling a dead time by inputting an output signal of the voltage controlled oscillating means; Non-inverting driving means for inverting the output signal of the dead time control means, inverting the output signal to the first output pin, and non-inverting the output signal of the dead time control means to output to the second output pin. Means, a power supply voltage applying pin for applying a power supply voltage, a ground voltage application pin for applying a ground voltage, and An on / off pin for turning on / off, and a compensation pin, characterized in that integrated.

1 shows an application circuit using a backlight lamp driving integrated circuit of a conventional liquid crystal display panel.

2 is a block diagram of a driving integrated circuit for a liquid crystal display panel of the present invention.

FIG. 3 shows an application circuit using the integrated circuit shown in FIG. 2.

Hereinafter, a lamp driving circuit for a backlight of the liquid crystal display panel of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of a backlight lamp driving integrated circuit of a liquid crystal display panel according to an embodiment of the present invention, in which an integrated circuit includes an amplifier 10, a voltage controlled oscillator 20, a dead time control circuit 30, and a driving circuit 40. 50), pin 1 of the integrated circuit power supply voltage terminal (Vcc) and pin 4 of the ground terminal (GND), and pins 8 and 7 are the gate signal generation terminals for turning on and off the external switching transistors ( G1, G2), Pin 5 is the feedback terminal (FEEDBACK), Pin 3 is the compensation terminal (PROTECTION), and pin 2 is the on / off terminal (ON / OFF), and pin 6 is a comparison terminal (COMP). The amplifier 10 has a negative input terminal connected to pin 5, a positive input terminal to which a reference voltage Vref is applied, and an output terminal connected to pin 6. The voltage controlled oscillator 20 oscillates in response to the output signal of the amplifier 10. The dead time control circuit 30 generates a dead time control signal in response to the output signal of the voltage controlled oscillator 20. The driving circuit 40 inverts the dead time control signal and outputs it to pin 8, and the driving circuit 50 non-inverts the dead time control signal and outputs it to pin 7.

The integrated circuit shown in Fig. 2 has no pin for the user to set the frequency arbitrarily, and the minimum and maximum frequencies are set in the voltage controlled oscillator 20 itself.

3 illustrates an application circuit using the integrated circuit of FIG. 2, and includes a driving integrated circuit 100 for backlight, capacitors C1, C2, and C3, a PMOS transistor Q1, an NMOS transistor Q2, and an inductor L. ), A transformer, diodes D1 and D2, a resistor R, and a lamp.

FIG. 3 simplifies the external application circuit by removing the terminals RT and CT of the conventional integrated circuit pins and allowing the voltage controlled oscillator to oscillate between the minimum frequency and the maximum frequency by itself. .

Therefore, the number of pins in the backlight lamp driving circuit of the liquid crystal display panel of the present invention can be reduced at the time of integration, and the application circuit can be simplified accordingly.

In addition, it is possible to satisfy all three conditions of cost competitiveness, module efficiency, and light weight reduction of the module, which are most important for the backlight inverter module of the liquid crystal display panel.

A pulse having a constant pulse width may be generated in response to changes in power supply voltage and temperature change.

Claims (1)

Amplifying means having a negative input terminal for inputting a signal from the feedback signal input pin, a positive input terminal to which a reference voltage is applied, and an output terminal connected to the comparison signal input pin; Voltage controlled oscillation means for inputting the output signal of the amplifying means to oscillate between the maximum frequency at the minimum frequency; Dead time control means for inputting an output signal of the voltage controlled oscillation means to generate a signal for controlling the dead time; Inversion driving means for inverting the output signal of the dead time control means and outputting it to a first output pin; Non-inverting driving means for non-inverting the output signal of the dead time control means and outputting it to a second output pin; A power supply voltage applying pin for applying a power supply voltage; A ground voltage applying pin for applying a ground voltage; An on / off pin for turning on / off an operation; And a compensation pin to integrate the lamp driving circuit for the backlight of the liquid crystal display panel.