KR19990003571U - Monitor's luminance equalization circuit - Google Patents

Abstract

The present invention is a vertical deflection circuit unit 10 for outputting a predetermined vertical output signal; An integrating circuit 20 for integrating a predetermined vertical output signal outputted from the vertical deflection circuit section 10 and outputting a predetermined parabola signal; And a reversal unit 30 for inverting the predetermined parabola signal and mixing the predetermined parabola signal output from the integrating circuit 20 into the control grid G1 of the water pipe CRT. It relates to a luminance equalization circuit of the monitor. The circuit is variable at the same period as the vertical output signal so that the vertical voltage from the upper side to the lower side of the screen is performed, and the voltage supplied to the control grid G1 of the water pipe CRT is the lowest value in the center portion of the screen. In the portion, a predetermined parabola signal such that the voltage supplied to the control grid G1 indicates the highest value is derived from the secondary winding of the flyback transformer FBT, and the predetermined control grid voltage V _G1 having a constant DC voltage value. The brightness of the screen is made uniform because it is leveled up by) and supplied to the control grid G1 of the water pipe CRT.

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 then impinges on the fluorescent surface through a shadow mask to display a predetermined image screen. The hot electrons are vertically deflected from the upper side to the lower side of the water tube CRT or horizontally deflected from the left to the right by the vertical deflection magnetic field and the horizontal deflection magnetic field.

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 incorporates a predetermined parabola signal having the same period as the vertical output signal of the vertical deflection circuit portion to the voltage supplied to the control grid G1 to uniformly adjust the brightness of the water pipe. It is an object of the present invention to provide a luminance equalization circuit of a monitor.

In order to achieve the above object, the present invention includes a vertical deflection circuit unit for outputting a predetermined vertical output signal; An integrating circuit for integrating a predetermined vertical output signal output from the vertical deflection circuit section and outputting a predetermined parabola signal; And a reversal unit 30 which inverts the predetermined parabola signal and mixes the predetermined parabola signal output from the integrating circuit into the control grid G1 of the water pipe CRT.

The device of the present invention configured as described above is variable in the same period as the vertical output signal, and the voltage supplied to the control grid G1 of the water pipe CRT at the center portion of the screen while the vertical scanning is performed from the upper side to the lower side of the screen. The predetermined parabola signal, which indicates this lowest value and causes the voltage supplied to the control grid G1 to exhibit the highest value in the left and right portions of the screen, is derived from the secondary winding of the flyback transformer FBT to produce a constant DC voltage value. Since the branch is leveled up by a predetermined control grid voltage V _G1 and supplied to the control grid G1 of the water pipe CRT, the brightness of the screen is uniform.

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

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

* Explanation of symbols for main parts of the drawings

10: vertical deflection circuit portion 20: integrating circuit

30: inverting unit Q1: transistor

R1, R2, R3, R4, R5: Resistor C1, C2: Capacitor

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

1 is a block diagram showing a luminance equalization circuit according to the present invention, Figure 2 is a waveform diagram showing an operating waveform according to the present invention.

As shown in FIG. 1, an embodiment according to the present invention includes a vertical deflection circuit unit 10 for outputting a predetermined vertical output signal; An integrating circuit 20 for integrating a predetermined vertical output signal outputted from the vertical deflection circuit section 10 and outputting a predetermined parabola signal; When a predetermined parabola signal outputted from the integrating circuit 20 is inputted, the predetermined parabola signal is inverted to be incorporated into the control grid G1 of the water pipe CRT. Here, the integrating circuit 20 is composed of a resistor R1 and a condenser C1, and the inverting unit 30 is composed of an emitter grounding transistor Q1 for inverting a predetermined parabola signal output from the integrating circuit 20. The resistors R2 and R3 of the inverting unit 30 are bias resistors, the resistors R4 and R5 are voltage drop resistors, 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.

If no signal is output from the inverter 30, the control grid G1 of the water pipe CRT is supplied from the main power supply SMPS of the monitor to the primary winding of the flyback transformer FBT. B + voltage is the second predetermined control grid voltage (V _G1) induced in a winding of according the flyback transformer (FBT) As switched by the horizontal output transistor of the horizontal output stage this is fed, with a predetermined control grid voltage (V _G1 ) Has a constant DC voltage value (e.g., 0-120V).

However, a predetermined vertical output signal output from the vertical deflection circuit section 10 is integrated by the integrating circuit 20 and is converted into a predetermined parabola signal as shown in FIG. A predetermined parabola signal output from 20 is applied to the base of transistor Q1 of the inverting unit 30 and output as a predetermined inverted parabola signal as shown in FIG. 2B through the collector output terminal. When applied to the control grid G1 of the correlation CRT, the secondary grid of the flyback transformer FBT is connected to the control grid G1 of the water pipe CRT as shown in FIG. A predetermined inverted parabola signal leveled up by a predetermined control grid voltage V _G1 is applied. At this time, the size of the concave predetermined inverted parabola signal is determined to be a predetermined value according to the values of the voltage drop resistors R4 and R5 of the transistor Q1. The lowest point is the point where the scanning line is located in the center of the water tube during the vertical scanning period, and this point is the peak and the left side of the scanning line moves from the upper edge of the water tube to the center. The right side is a section that moves from the center portion of the water pipe (CRT) to the lower edge portion.

In this way, a predetermined inverted parabola signal leveled up by a predetermined control grid voltage V _G1 induced in the secondary winding of the flyback transformer FBT is applied to the control grid _G1 of the water pipe CRT. When the scan line is positioned at the center of the screen during the vertical scanning period, the voltage supplied to the control grid G1 increases as the scan line moves to the upper or lower side of the screen compared to the magnitude of the voltage supplied to the control grid G1. Since the brightness increases, the brightness of the upper and lower edges of the screen as well as the brightness of the center are all uniform.

As described above, the center part of the screen is supplied to the control grid G1 of the water pipe CRT during the vertical scanning from the upper side to the lower side of the screen according to the present invention. The predetermined parabola signal is generated from the secondary winding of the flyback transformer FBT such that the voltage to be displayed is the lowest value and the voltage supplied to the control grid G1 is the highest value in the left and right portions of the screen. By leveling up the predetermined control grid voltage V _G1 having a value and supplying it to the control grid G1 of the water pipe CRT, the brightness of the center of the screen and the brightness of the corner of the screen are uniform. have.

Claims (2)

A vertical deflection circuit unit 10 for outputting a predetermined vertical output signal; An integrating circuit 20 for integrating a predetermined vertical output signal outputted from the vertical deflection circuit section 10 and outputting a predetermined parabola signal; And a reversal unit 30 for inverting the predetermined parabola signal and mixing the predetermined parabola signal output from the integrating circuit 20 into the control grid G1 of the water pipe CRT. Monitor luminance equalization circuit. 2. The luminance equalization circuit of a monitor according to claim 1, wherein said inverting portion (30) is composed of an emitter grounding transistor (Q1) for inverting a predetermined parabola signal output from said integrating circuit (20).