KR100431266B1 - Inverter for back-light of LCD - Google Patents

Abstract

The present invention relates to an backlight inverter of an LCD, in particular, a switching element connected to an input of a transformer for driving a lamp using an input power to determine the supply of input power; A first error amplifier receiving a feedback signal F / B of a feedback portion connected to the lamp through an inverting (−) terminal, receiving a reference voltage signal through a non-inverting (+) terminal, comparing the reference voltage signal, and outputting a comparison value; The output signal of the first error amplifier is input through the non-inverting (+) terminal, and the oscillation signal of a certain period is input to the inverting (-) terminal. The two signals are compared and the on / off of the switching element is controlled according to the result. A first comparator; Receives a dimming signal having a linear rising voltage input from the outside, compares it with a conventional dimming signal, and performs PWM dimming and analog dimming control accordingly. In the analog dimming mode, the inverting (-) terminal of the first error amplifier The feedback signal F / B is gradually attenuated, and the output signal of the first error amplifier is not changed. In the PWM mode, the feedback signal F / B is input to the inverting terminal of the first error amplifier. It provides a backlight inverter of the LCD characterized in that it comprises a mixed signal control means for varying the output signal of the first error amplifier in a pulse period without changing, thereby improving the response characteristics when switching from analog dimming to PWM dimming state In order to achieve this, a unique circuit can be implemented by a control method different from the existing complex control method.

Description

LCD Inverter for backlight {Inverter for back-light of LCD}

The present invention relates to an LCD backlight inverter. In particular, in order to improve response characteristics when switching from analog dimming to PWM dimming state, an LCD backlight inverter that implements a unique circuit in a control method different from the conventional complex control method is implemented. It is about.

In general, an inverter is a reverse conversion device that converts DC power into AC power, and combines a DC motor with an alternator, uses a vibrator, uses a discharge tube, and nowadays uses a transistor or a thyristor. This is widely used.

Such an inverter is generally used as an alternating current power source for mobile use, a fluorescent lamp power source for an automobile, an emergency power source in case of a power failure, or a backlight power source for an LCD or other display device.

Dimming methods of the controller for the backlight inverter currently in use include analog dimming, PWM dimming, and complex dimming. The circuit configuration is varied according to each operation.

FIG. 1 is a circuit diagram illustrating a conventional backlight inverter controller to which the PWM dimming method is applied, and FIG. 2 is a timing diagram of FIG. 1.

In general, when the IC power is continuously turned on / off in the LCD backlight inverter, a load variation may occur continuously, thereby causing a problem of power fluctuation. In addition, in a circuit for amplifying a weak signal such as an OP amplifier, the fluctuation of the power supply causes a problem that the fluctuation of the power supply voltage is superimposed on the signal and thus acts as a fluctuation of the signal or noise.

Referring to FIG. 1 and FIG. 2 attached to this problem, the input voltage Vin is rectified while passing through the first diode D1 through the first transistor Q1 and then smoothed by the first inductor L1. Then, the rectified and smoothed voltage is transmitted to the transformer and the driver 1 to be converted to the driving voltage necessary for driving the lamp (Lamp) and transmitted to the lamp (Lamp).

Thereafter, the feedback signal F / B is input to the inverting (-) terminal of the error amplifier ERROR AMP by a feedback part composed of a plurality of resistors and diodes. The error amplifier ERROR AMP compares the feedback signal F / B with the reference voltage and outputs the result to the comparator COMP. The comparator COMP compares the input signal with the reference value again and outputs the output signal. Through the on / off of the first transistor (Q1) is determined through.

At this time, while the above operation is performed, the error amplifier ERROR AMP is turned on or off according to the signal output from the PWM oscillator 2.

As a result, the error amplifier (ERROR AMP) and the comparator (COMP) power is repeatedly turned on and off according to the PWM dimming cycle during the PWM dimming, thereby exhibiting an unstable factor in the overall operating characteristics of the IC and the inverter.

In particular, in the conventional case as described above, as shown in the timing diagram of the lamp current shown in FIG. 1, a delay occurs when the initial power is turned on, and the lamp flickers due to a sudden change in the lamp current when switching to the pulse width modulation operation region. Will occur.

In addition, in the conventional case, the delay function is intended to solve the peak noise current in the PWM operation region as well as the delay function when the initial power is turned on, but when the excessive delay function is implemented, the delay function is delayed by the delay function just before switching to the PWM in the analog region. This causes a problem that the lamp current is suddenly changed and the lamp flickers.

However, unlike the PWM dimming method described above, analog dimming has a problem in operation. Therefore, it is difficult to fully control the dimming by either PWM dimming or analog dimming. It is a problem.

In addition, there is a problem that even in the complex method, the proposed techniques have limitations.

An object of the present invention for solving the problems of the prior art as described above is to implement an independent circuit in a separate control method different from the conventional complex control method to improve the response characteristics when switching from analog dimming to PWM dimming state To provide an inverter for backlight.

1 is a circuit diagram showing a configuration of a backlight inverter according to the prior art.

2 is a timing diagram according to the prior art.

3 is a circuit diagram showing a configuration of an inverter for backlight according to the present invention.

4 is a timing diagram according to the present invention.

5 is an exemplary configuration diagram of another embodiment of the composite signal controller shown in FIG.

Features of the backlight inverter of the LCD according to the present invention for achieving the above object, the switching element is connected to the input terminal of the transformer for driving the lamp using the input power to determine the supply of the input power; A first error amplifier receiving a feedback signal (F / B) of a feedback portion connected to the lamp through an inverting (-) terminal, receiving a reference voltage signal through a non-inverting (+) terminal, and comparing the reference voltage signal to output a comparison value; The output signal of the first error amplifier is input through the non-inverting (+) terminal and the oscillation signal of a certain period is input to the inverting (-) terminal, and the two signals are compared. A first comparator for controlling; After receiving a dimming signal having a linear rising voltage input from the outside and comparing it with a conventional dimming signal, PWM dimming and analog dimming control are performed accordingly. In the analog dimming mode, the first error amplifier is inverted (-). The feedback signal F / B inputted to the terminal is gradually attenuated and the output signal of the first error amplifier is not changed. In the PWM mode, the feedback signal F / B inputted to the inverting terminal of the first error amplifier is applied. B) includes a combined signal control means for varying the output signal of the first error amplifier at a pulse period without changing it.

An additional feature of the backlight inverter of the LCD according to the present invention for achieving the above object, the composite signal control means is connected between the output terminal and the ground terminal of the first error amplifier to perform the function of a switching element A second transistor; The second transistor is turned on / off by inputting a triangular wave having a predetermined period to the inverting (-) terminal and comparing the signal input to the non-inverting (+) terminal to the base terminal of the second transistor. A second comparator for controlling an output signal of the first error amplifier to be changed; The dimming signal input from the outside is input to the non-inverting (+) terminal, and its output signal is previously input to the inverting (-) terminal, and compared to the previous state and the current state. A second error amplifier provided to the non-inverting (+) terminal; And a voltage divided by the second and third resistors for dividing the output signal of the second error amplifier into the base terminal and turning on and off, and entering the inverting terminal of the first error amplifier during the on operation. And a third transistor for attenuating the feedback signal through the first resistor.

The above object and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram showing the configuration of an inverter for backlight according to the present invention.

The accompanying FIG. 3 does not show the PWM oscillator referred to by reference numeral 2 in the configuration of FIG. 1 showing the prior art, and focuses on the configuration of the main parts related to the present invention. The configuration of the first transistor Q1, which is a switching element connected between the input power and the input terminal of the transformer for driving the power supply and the driving power, determines the supply of the driving power.

In FIG. 3, the complex signal controller denoted by reference numeral 100 is a portion for performing PWM dimming control and analog dimming control according to the present invention, and the first error amplifier referred to by reference numeral ERR1 is connected to a lamp LAMP. The feedback signal (F / B) of the part is input to the inverting (-) terminal, the reference voltage signal is input to the non-inverting (+) terminal, and compared and output the comparison value, the output signal of which is the composite signal controller 100. It is applied to the point A of PA.

In this case, reference numeral C1 denotes a capacitor connected between the output terminal of the first error amplifier ERR1 and the inverting (−) terminal, and reference numeral COM1 denotes a non-inverting (+) output signal of the first error amplifier ERR1. ) And the oscillation signal, which is oscillated through the first inductor referred to as L1 and the capacitor and diode to which the reference number is not indicated, is compared to the inverted (-) terminal and the two signals are compared according to the result. A first comparator for controlling on / off of the first transistor Q1 is shown.

In addition, reference numeral Q2 denotes a second transistor connected between the output terminal of the first error amplifier ERR1 and the ground terminal to perform a function of a switching element, and the reference numeral COM2 has a constant period at an inverting (-) terminal. The first error amplifier is turned on and off by supplying a comparison wave to a signal input to a non-inverting (+) terminal and supplying a comparison value to the base terminal of the second transistor Q2. A second comparator for controlling the output signal of ERR1 to be turned on / off.

In addition, reference numeral ERR2 inputs a dimming signal requested from the outside to the non-inverting (+) terminal and receives its output signal before to the inverting (-) terminal and compares the previous state and the current state. And a second error amplifier provided to the non-inverting (+) terminal of the second comparator COM2, and to the second and third resistors R2 and R3 that divide the output signal of the second error amplifier ERR2. The voltage divided by the input voltage is input to the base terminal, and the on-off operation is performed, and the on-off operation converts the voltage applied to the collector terminal to the ground potential.

The operation of the present invention having the configuration as described above will be briefly described.

In the PWM operation in the complex dimming, the organic signal is performed by the composite signal controller 10 to control the generation of delay during noise or motion conversion.

Looking at the detailed operation, when the dimming signal is applied to the high state from the ground potential (0V-> 5V), the output signal of the second error amplifier (ERR2) was previously low and the current high state signal is Since it is input, the output signal is turned high.

Therefore, after the output signal of the second error amplifier ERR2 is input to the non-inverting terminal + of the second comparator and simultaneously divided by the second resistor R2 and the third resistor R3, the third transistor ( It is input to the base terminal of Q3).

Therefore, the third transistor Q3 is turned on so that the voltage state of the portion referred to by the reference number PB of the collector terminal of the third transistor Q3 is close to the ground potential and through the first resistor R1. The voltage state of the connected reference number PC is clearly higher than that of the collector terminal of the third transistor Q3.

Therefore, as the path through which the current flows in parallel in the process of returning the current through the lamp, the amount of current of the feedback signal F / B flowing into the inverting (-) terminal of the first error amplifier ERR1 is determined. The current control in the analog area is performed by decreasing.

Then, switching to PWM is performed when the voltage difference between the point referred to as PB and the point referred to as PC is eliminated, that is, the output signal of the second error amplifier ERR2 is turned low and the third When transistor Q3 remains off, there is no current flowing through the first resistor R1, so that the output signal of the second comparator COM2 is caused by a triangular wave referred to as PWM-OSC. The second transistor Q2 moves to an operation (on / off) area and performs a PWM operation by an on / off duty ratio applied to the reference PA point.

At this time, when the voltage state of the reference number PC is larger than the voltage state of the reference number PB, the situation where the voltages of the two points are the same is the point of time of conversion from the analog dimming area to the PWM dimming area. The peak-to-peak voltage is determined in the triangular wave so that an organic operating region conversion is achieved.

At this time, the attached Figure 4 shows the PWM operation region and the analog operating region as a time when the dimming signal is varied, the attached Figure 5 shows another embodiment of the composite signal controller, a plurality of without using the second error amplifier An embodiment in which a transistor and a variable resistance element are used.

As a result, in the present invention, as shown in FIG. 4, the comparison value, which is an output signal of the first comparator COM1, in which the dimming signal in the linear state is compared with the triangular wave in a certain period, is in the form of a pulse in the state of the ground potential. The analog dimming control is performed until the switching point and the PWM dimming control method is followed from the moment when the output signal of the first comparator COMP1 has a pulse shape.

That is, in practice, the point of time when PWM dimming is required based on the dimming signal and the triangular wave in the linear state is detected, and the corresponding point in time is the potential of the signal output from the first output terminal A of the composite signal controller 100 is changed. Therefore, it operates as a PWM dimming area.

While the invention has been shown and described in connection with specific embodiments thereof, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who owns it can easily find out.

As described above, the LCD backlight inverter of the present invention implements PWM dimming and analog dimming by turning on / off the output of the error amplifier without turning on / off the IC power, and stabilizes the circuit by reducing the power fluctuation. There is an effect that can improve the reliability of the IC.

Claims (2)

A switching element connected to an input terminal of a transformer for driving a lamp by using an input power source to determine supply of input power; A first error amplifier receiving a feedback signal (F / B) of a feedback portion connected to the lamp through an inverting (-) terminal, receiving a reference voltage signal through a non-inverting (+) terminal, and comparing the reference voltage signal to output a comparison value; The output signal of the first error amplifier is input through the non-inverting (+) terminal and the oscillation signal of a certain period is input to the inverting (-) terminal, and the two signals are compared. A first comparator for controlling; After receiving a dimming signal having a linear rising voltage input from the outside and comparing it with a conventional dimming signal, PWM dimming and analog dimming control are performed accordingly. In the analog dimming mode, the first error amplifier is inverted (-). The feedback signal F / B inputted to the terminal is gradually attenuated and the output signal of the first error amplifier is not changed. In the PWM mode, the feedback signal F / B inputted to the inverting terminal of the first error amplifier is applied. B) includes an integrated signal control means for varying the output signal of the first error amplifier in a pulse period without changing. The method of claim 1, The composite signal control means includes a second transistor connected between an output terminal of the first error amplifier and a ground terminal to perform a function of a switching element; The second transistor is turned on / off by inputting a triangular wave having a predetermined period to the inverting (-) terminal and comparing the signal input to the non-inverting (+) terminal to the base terminal of the second transistor. A second comparator for controlling an output signal of the first error amplifier to be changed; The dimming signal input from the outside is input to the non-inverting (+) terminal, and its output signal is previously input to the inverting (-) terminal, and compared to the previous state and the current state. A second error amplifier provided to the non-inverting (+) terminal; And A feedback input to the inverting (-) terminal of the first error amplifier during the on operation by receiving a voltage divided by the second and third resistors for dividing the output signal of the second error amplifier into the base terminal And a third transistor for attenuating the signal through the first resistor.