KR19990003574U - Monitor's luminance equalization circuit - Google Patents

Abstract

The present invention is a screen voltage generator 110 for generating a predetermined screen voltage by rectifying the predetermined AC voltage induced in the secondary winding of the flyback transformer (FBT) to generate a high pressure supplied to the anode; A horizontal deflection circuit unit 120 for outputting a predetermined horizontal output signal as a sawtooth wave; An absolute value circuit portion 130 for converting a predetermined horizontal output signal output from the horizontal deflection circuit portion 120 into a predetermined absolute value signal; The predetermined absolute value signal outputted from the absolute value circuit section 130 and the predetermined screen voltage outputted from the screen voltage generator 110 are added to each other, and the addition voltage is added to the screen grid G2 of the water pipe CRT. It relates to a brightness equalization circuit of the monitor, characterized in that it comprises an adder (140) for supplying. This circuit is variable at the same period as the horizontal output signal so that the horizontal voltage from the left side to the right side of the screen is performed. In the portion, the absolute value signal which causes the voltage supplied to the screen grid G2 to represent the highest value is leveled up by the predetermined screen voltage V _G2 output from the screen voltage generator 110, thereby screening the water pipe CRT. Since the grid G2 is supplied to the grid G2, the brightness of the screen is uniform.

Description

Monitor's luminance equalization circuit

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

In general, a color receiver tube (CRT) used in a computer is provided with three electron guns, which are sufficient after the RGB video signal output from the computer is input to the video signal amplifier of the monitor through the D sub connector. When amplified and applied to each cathode, as the heater is heated, the cathode is configured to emit predetermined hot electrons. In addition, the hot electrons emitted from the cathode of the electron gun pass through the control grid (G1), the screen grid (G2), the focus grid (G3), and are deflected by vertical and horizontal deflection magnetic fields and impinge upon the fluorescent surface through the shadow mask. Will display the video screen.

Here, the brightness of the video screen may be varied depending on the size of the RGB video signal, but may be varied by adjusting the voltage supplied to the control grid G1 and the screen grid G2. Typically, the voltage supplied to the control grid G1 and the screen grid G2 is two of the flyback transformers FBT that generate a high voltage supplied to the anode as the horizontal output transistor of the monitor performs the switching operation. It is derived from the primary winding and shows 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 side part and the brightness of the center part of the screen did 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 provides a luminance equalization circuit of a monitor which makes the brightness of the receiving tube uniform by adding a horizontal output signal of the horizontal deflection circuit unit to the voltage supplied to the screen grid G2. Its purpose is to.

In order to achieve the above object, the present invention rectifies a predetermined AC voltage induced in a secondary winding of a flyback transformer (FBT) that generates a high voltage supplied to an anode, thereby generating a screen voltage. Wealth; A horizontal deflection circuit unit for outputting a predetermined horizontal output signal as a sawtooth wave; An absolute value circuit portion for converting a predetermined horizontal output signal outputted from the horizontal deflection circuit portion into a predetermined absolute value signal; And an adder for adding a predetermined absolute value signal outputted from the absolute value circuit portion and a predetermined screen voltage outputted from the screen voltage generating portion to each other and supplying the added voltage to the screen grid G2 of the water pipe CRT. Characterized in that configured.

The apparatus of the present invention configured as described above is variable in the same period as the horizontal output signal so that the voltage supplied to the screen grid G2 of the water pipe CRT in the center portion of the screen while the horizontal scanning is performed from the left to the right of the screen. The absolute value signal indicating this lowest value and causing the voltage supplied to the screen grid G2 to indicate the highest value in the left and right portions of the screen is leveled up by a predetermined screen voltage V _G2 output from the screen voltage generator. Since the screen grid G2 of the correlation CRT is supplied, the brightness of the screen becomes uniform.

1 is a block diagram showing a luminance equalization circuit according to the present invention;

FIG. 2 is a circuit diagram showing an absolute value circuit unit shown in FIG. 1;

3 is a waveform diagram showing an operating waveform according to the present invention.

* Explanation of symbols for main parts of the drawings

110: screen voltage generator 120: horizontal deflection circuit

130: absolute value circuit 140: adder

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

1 is a block diagram illustrating a luminance equalization circuit according to the present invention, FIG. 2 is a circuit diagram showing an absolute value circuit part shown in FIG. 1, and FIG. 3 is a waveform diagram showing an operation waveform according to the present invention.

As shown in FIG. 1, an embodiment according to the present invention generates a predetermined screen voltage by rectifying a predetermined AC voltage induced in a secondary winding of a flyback transformer (FBT) that generates a high pressure supplied to an anode. A screen voltage generator 110; A horizontal deflection circuit unit 120 for outputting a predetermined horizontal output signal as a sawtooth wave; An absolute value circuit portion 130 for converting a predetermined horizontal output signal output from the horizontal deflection circuit portion 120 into a predetermined absolute value signal; The predetermined absolute value signal outputted from the absolute value circuit section 130 and the predetermined screen voltage outputted from the screen voltage generator 110 are added to each other, and the addition voltage is added to the screen grid G2 of the water pipe CRT. It consists of an adder 140 to supply.

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

First, as shown in FIG. 2, the absolute value circuit unit 130 includes an inverting OP having a predetermined input signal input to an inverting terminal of one inverting OP-AMP and an output signal of the inverting OP-AMP. It consists of two inverting OP-AMPs that are simultaneously input to the inverting terminal of -AMP, and all negative polarity components included in a predetermined input signal input to the input terminal are all positive polarities. Inverted and output to the output. In addition, the screen voltage generation unit 110 is to output a screen voltage of a constant DC level, the horizontal deflection circuit unit 120 outputs a predetermined horizontal output signal for generating a high voltage supplied to the anode of the monitor The B + voltage supplied from the main power supply unit SMPS to the primary winding of the flyback transformer FBT is switched, and the horizontal output signal output from the horizontal deflection circuit unit 120 is output in a sawtooth wave form.

As shown in FIG. 3A, when the horizontal output signal, which is a predetermined sawtooth wave, is output from the horizontal deflection circuit unit 120, the negative polarity component of the horizontal output signal is the absolute value circuit unit 130. ) Are all inverted to positive polarity components and converted into absolute value signals as shown in FIG. In this case, a section in which the horizontal output signal rises corresponds to a horizontal scanning period. During this horizontal scanning period, a horizontal scan line in which the point at which the horizontal output signal indicates zero voltage progresses from the left side to the right side of the water tube (CRT) is centered. The absolute value signal decreases the voltage value from the highest value to the lowest value on the left side, and the voltage value increases from the lowest value to the maximum value on the right side.

In this way, a predetermined absolute value signal output from the absolute value circuit unit 130 is input to the adder 140, and at the same time, a predetermined screen voltage V _{G2 as} shown in FIG. When the output from the screen voltage generator 110 is input to the adder 140, the adder 140 adds the predetermined absolute value signal to the predetermined screen voltage V _G2 to (D) of FIG. As shown in FIG. 6, the absolute value signal is increased by the screen voltage V _G2 .

Accordingly, a predetermined absolute value signal leveled up by the screen voltage V _G2 is supplied to the screen grid G2 of the water pipe CRT. When this occurs, the screen grid _G2 is positioned when the scan line is positioned at the center of the screen. The voltage supplied to the screen grid G2 increases gradually as the scanning line moves to the outside of the screen compared to the voltage supplied to G2), so that the brightness of the center portion as well as the brightness of the center portion are uniform. do.

As described above, according to the present invention, while the horizontal scanning from the left side to the right side of the screen is performed at the same period as the horizontal output signal, the central portion of the screen is supplied to the screen grid G2 of the water pipe CRT. In the left and right portions of the screen, the absolute voltage is increased by the predetermined screen voltage V _G2 outputted from the screen voltage generator, so that the voltage supplied to the screen grid G2 is the highest. When the power supply is supplied to the screen grid G2 of the water pipe CRT, the brightness of the center portion of the screen and the brightness of the edge portion of the screen are uniform.

Claims (1)

A screen voltage generator (110) for generating a predetermined screen voltage by rectifying a predetermined AC voltage induced in a secondary winding of a flyback transformer (FBT) for generating a high voltage supplied to the anode; A horizontal deflection circuit unit 120 for outputting a predetermined horizontal output signal as a sawtooth wave; An absolute value circuit portion 130 for converting a predetermined horizontal output signal output from the horizontal deflection circuit portion 120 into a predetermined absolute value signal; The predetermined absolute value signal outputted from the absolute value circuit section 130 and the predetermined screen voltage outputted from the screen voltage generator 110 are added to each other, and the addition voltage is added to the screen grid G2 of the water pipe CRT. The brightness equalization circuit of the monitor, characterized in that it comprises an adder (140) for supplying.