KR19990003572U - Brightness equalization circuit of the monitor - Google Patents

Abstract

The present invention is a video preamplifier (10) for amplifying the RGB image signal; A video power amplifier 20 which inverts and amplifies the RGB video signal amplified by the video preamplifier 10 again; A dynamic focus signal generator 30 for outputting a dynamic focus signal supplied to the dynamic focus grid G4 of the water pipe CRT; The AC parabola component obtained by filtering the DC component of the predetermined dynamic focus signal output from the dynamic focus signal generator 30 is inverted, and the inverted parabola signal is buffered and mixed into the output signal of the video preamplifier 10. It relates to a brightness equalization circuit of the monitor, characterized in that it comprises an inverting portion 40 to make. This circuit is output from the dynamic focus signal generator 30 to prevent the focus of the screen appearing on the water tube CRT from being blurred from the center portion of the water tube CRT to the edge portion of the dynamic focus grid G4. When the AC parabola component of the dynamic focus signal supplied to the RGB image signal output from the video preamplifier 10 is applied, the video power amplifier 20 inverts and amplifies a predetermined RGB image signal containing the parabolic component again. Since it is supplied to the correlation CRT, the brightness | luminance of the center part and the edge part of a water pipe CRT becomes uniform.

Description

Brightness equalization circuit of the monitor

The present invention relates to a water tube (CRT) of the monitor, and more particularly to a brightness equalization circuit that makes the brightness of the water tube (CRT) uniform.

In general, a color receiver tube (CRT) used in a computer has three electron guns, and the three electron guns are monitors each of which an RGB video signal output from the computer is a video preamplifier and a video power amplifier through a D sub connector. After input to the video signal amplification unit, the amplification is sufficiently amplified and applied to each cathode, so that the cathode emits predetermined hot electrons as the heater is heated. In addition, the hot electrons emitted from the cathode of the electron gun pass through the control grid (G1), screen grid (G2), focus grid (G3), dynamic focus grid (G4), and are deflected by vertical and horizontal deflection magnetic fields to produce shadow masks. It passes through the fluorescent surface and displays a predetermined video screen.

Here, the brightness of the video screen is variable according to the magnitude of the RGB video signal supplied to the cathode of the water pipe (CRT) through a video preamplifier for amplifying the RGB video signal and a video power amplifier for inverting and amplifying the amplified RGB video signal again. (Contrast adjustment), but the voltage supplied to the control grid (G1) and the screen grid (G2) can also be adjusted by adjusting (Brightness), it is usually supplied to the control grid (G1) and the screen grid (G2) The voltage is derived from the secondary winding of the flyback transformer (FBT) that generates the high voltage supplied to the anode as the horizontal output transistor of the horizontal deflection circuit portion of the monitor performs the switching operation and exhibits a constant DC voltage value.

However, even when the contrast is adjusted or the brightness of the image screen is adjusted by adjusting the voltage supplied to the control grid G1 and the screen grid G2, the edge of the screen is due to the structural characteristics of the water pipe CRT. There was a problem that the brightness of the portion and the brightness of the center portion of the screen does not match. That is, since the front portion of the water pipe (CRT) is curved, there is a problem in that the edge portion of the screen becomes darker than the center portion of the screen.

Accordingly, in order to solve the above problems, the present invention inverts and applies an AC component of the dynamic focus signal supplied to the dynamic focus grid G4 to the RGB image signal output from the video preamplifier. It is an object of the present invention to provide a brightness equalization circuit of a monitor which makes the brightness of the uniform.

In order to achieve the above object, the present invention is a video preamplifier for amplifying the RGB image signal; A video power amplifier inverting and amplifying the RGB video signal amplified by the video preamplifier again; A dynamic focus signal generator for outputting a dynamic focus signal supplied to the dynamic focus grid G4 of the water pipe CRT; And an inverting unit for filtering and inverting an AC parabola component of a predetermined dynamic focus signal output from the dynamic focus signal generating unit and buffering the inverted parabola signal into an output signal of the video preamplifier. do.

The apparatus of the present invention configured as described above is output from the dynamic focus signal generator, so that the focus of the screen appearing in the water tube CRT is prevented from being blurred from the center portion of the water tube CRT toward the edge portion. When an AC parabola component of a dynamic focus signal supplied to a focus grid G4 is applied to an RGB image signal output from the video preamplifier, the video power amplifier inverts and amplifies a predetermined RGB image signal in which the parabolic component is mixed. Therefore, since the supply is made to the water pipe CRT, the brightness of the center portion and the corner portion of the water tube CRT is uniform.

1 is a view showing a brightness equalization circuit according to the present invention,

2 is a waveform diagram illustrating the operation according to the present invention.

* Explanation of symbols for main parts of the drawings

10: video preamplifier 20: video power amplifier

30: dynamic focus signal generator 40: inverter

41: OP-AMP C1, C2: Capacitor

Q1: Transistor VR: Variable resistor

R1, R2, R3, R4, R5, R6: Resistance

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

1 is a view showing a brightness equalization circuit according to the present invention, Figure 2 is a waveform diagram for explaining the operation according to the present invention.

As shown in FIG. 1, an embodiment according to the present invention includes a video preamplifier 10; Video power amplifier 20; A dynamic focus signal generator 30; It consists of the inversion part 40. The video power amplifier 20 inverts and amplifies the RGB video signal output from the video preamplifier 10, and the dynamic focus signal generator 30 focuses the screen on the picture tube (CRT). A predetermined dynamic focus signal is outputted to prevent the blurring from the center portion of the water pipe CRT to the edge portion and supplied to the dynamic focus grid G4 of the water pipe CRT. In addition, the inverting unit 40 includes: a DC removing capacitor C1 for filtering a DC component of the dynamic focus signal output from the dynamic focus signal generating unit 30; An OP-AMP (41) for inverting a predetermined parabola signal obtained by filtering the direct current component of the dynamic focus signal; It consists of a buffer transistor Q1 which buffers a predetermined inverted signal output from the OP-AMP 41 and mixes it into an output signal of the video preamplifier 10. The resistors R1, R4, R6, which are not described in this inverting section 40, are current control resistors, the resistors R2, R3, R5 are bias resistors, VR is a variable resistor, and the capacitor C2 is a DC removal capacitor.

The action of the embodiment according to the present invention configured as described above is as follows.

The RGB image signal output from the video preamplifier 10 may have a waveform as shown in FIG. 2 when the inverting unit 40 is not present. In addition, the dynamic focus signal output from the dynamic porter signal generator 30 and supplied to the dynamic focus grid G4 of the water pipe CRT is a predetermined DC level as shown in FIG. It shows a waveform in which a predetermined alternating parabolic component is mixed with.

Therefore, when the dynamic focus signal output from the dynamic focus signal generator 30 is input to the inverting unit 40, the dynamic focus signal is filtered by the DC removing capacitor C1 of the inverting unit 40 to generate a direct current component. This waveform is removed, and the waveform from which the DC component of the dynamic focus signal is removed is represented as a predetermined parabola signal as shown in FIG. In addition, when a predetermined parabola signal obtained by the filtering action of the DC removing capacitor C1 is input to the inverting terminal of the inverting OP-AMP 41, the predetermined parabola signal is inverted and outputted. The magnitude of the signal is determined by the values of the resistor R1 and the variable resistor VR connected to the inverting terminal of the inverting OP-AMP 41, and the waveform thereof is as shown in Fig. 2C.

Subsequently, a predetermined inverted parabola signal output from the inverting OP-AMP 41 is applied to the base of the buffer transistor Q1 of the inverting portion 40. Accordingly, when the buffer transistor Q1 is conducted, The transistor Q1 outputs a predetermined buffered inverted parabola signal through an emitter output terminal and applies it to the RGB image signal output from the video preamplifier 10. In this case, as shown in (e) of FIG. 2, an RGB video signal having a concave video signal waveform is input to the video power amplifier 20, and the RGB video signal having a concave video signal waveform is concave. Inverted and amplified again by the video power amplifier 20, the image signal waveform between the syringes is modulated into a convex RGB image signal like a curved surface of the water tube (CRT), as shown in FIG. Supplied to the cathode of the correlation CRT. Therefore, when the RGB image signal as shown in (bar) of FIG. 3 is supplied to the cathode of the water tube CRT, the brightness of the center portion C of the water tube CRT and the left and right corner portions L and R are different. The brightness is uniform.

As described above, in order to prevent the focal point of the screen output from the dynamic focus signal generator according to the present invention appearing in the water pipe CRT from the central portion of the water pipe CRT to the edge portion. When the AC parabola component of the dynamic focus signal supplied to the dynamic focus grid G4 is applied to the RGB video signal output from the video preamplifier, the video power amplifier again outputs a predetermined RGB video signal containing the parabolic component. When inverted and amplified and supplied to the water tube CRT, the brightness of the center portion and the corner portion of the water tube CRT is uniform.

Claims (2)

A video preamplifier 10 for amplifying the RGB image signal; A video power amplifier 20 which inverts and amplifies the RGB video signal amplified by the video preamplifier 10 again; A dynamic focus signal generator 30 for outputting a dynamic focus signal supplied to the dynamic focus grid G4 of the water pipe CRT; The AC parabola component obtained by filtering the DC component of the predetermined dynamic focus signal output from the dynamic focus signal generator 30 is inverted, and the inverted parabola signal is buffered to the output signal of the video preamplifier 10. The brightness equalization circuit of the monitor, characterized in that it comprises a inverting portion 40 to be mixed. The method of claim 1, wherein the inversion unit 40, OP- for filtering the DC component of the dynamic focus signal output from the dynamic focus signal generator 30 using a DC removing capacitor C1 connected to the inverting terminal, and inverting a predetermined parabola signal obtained by filtering. AMP 41 and; And a buffer transistor (Q1) for buffering a predetermined inverted signal output from the OP-AMP 41 and mixing it into the output signal of the video preamplifier 10. .