KR0138676B1 - A dc level control circuit of f.g.b brightness signal of a monitor - Google Patents

Abstract

The present invention relates to a DC level control signal of an RGB brightness signal of a monitor. The present invention relates to a grid mixing unit for generating a screen brightness signal by mixing a screen brightness color signal and a DC level signal, and connected to an RGB output terminal of the grid mixing unit. A switching control unit for switching switching, an operational amplifier connected to one end of the switching control unit and inputting a switching control voltage, and a microcomputer supplying a DC level control voltage to the operational amplifier 8, By providing DC level control circuit that can adjust DC level of RGB brightness signal independently at first, the DC level of RGB brightness signal can be adjusted independently for each electron gun, so the color control range of monitor can be expanded accordingly. Of course, since the implementation range of the color signal is wider, the functionality of the system is increased accordingly.

Description

DC level control circuit of monitor R.G.B brightness signal

1 is a block diagram for explaining a DC level control circuit of the R.G.B brightness signal of a conventional monitor,

2 is an explanatory diagram for explaining the waveform of the brightness signal,

3 is a circuit diagram illustrating the present invention.

* Explanation of symbols for main parts of the drawings

1: video signal processor 2: preamplifier

3: output amplification section 4: screen brightness variable circuit section

5: Grid mixing section 6: Pulse rectifying circuit section

7: switching control unit 8: operational amplifier

9: micom 10: cathode ray tube

11A to C: R.G.B electron gun 12: flyback trance

13: Keyboard TR1, TR2: Transistor

R1, R2: Resistance

The present invention relates to a DC level control circuit of an RGB brightness signal of a monitor, and more particularly to a DC level control circuit capable of independently adjusting the DC level of an RGB brightness signal at one end of each RGB electron gun of the monitor. Since the DC level of the RGB brightness signal can be adjusted independently for each electron gun, the color control range of the monitor can be extended accordingly, and the range of the color signal can be broadened accordingly, thus increasing the functionality of the system. It relates to a DC level control circuit of the RGB brightness signal.

In general, the circuit for adjusting the DC level of the RGB brightness signal of the monitor is a brightness variable circuit unit for adjusting the magnitude of the brightness signal according to the RGB image signal output by the image output amplifier 70 as shown in FIG. (71), a grid bias mixing circuit portion (72) for mixing a DC signal with the brightness signal of the brightness variable circuit portion (71), and a fly that supplies an operating voltage to the members (70 to 72) and induces high voltage. It consists of a back transformer 73 and a pulse rectifying circuit portion 74 which forms a DC level of the brightness signal in accordance with the operating voltage of the flyback transformer 73.

The grid bias mixing circuit section 72 is commonly connected to the grid of the R.G.B electron guns 76A to C of the monitor cathode ray tube 75.

On the other hand, referring to the operation of the DC level control circuit of the conventional RGB brightness signal having the above configuration, first, the image signal of the RGB output by the image output amplifier 70 is input to the brightness variable circuit section 71 As shown in FIG. 2, the brightness variable circuit section 71 adjusts the magnitude M of the brightness signal to the set magnitude level in accordance with the input video signal. Then, the adjusted brightness signal is input to the grid bias mixing section 72, and at the same time, the potential of 33 [V] is mixed by using the supply voltage of the flyback transformer 73 in the pulse rectifying circuit section 74. Input to the unit 72. Then, in the grid bias mixing unit 72, the brightness signal according to the image signal is mixed on the input 33 [V] DC reference voltage signal as shown in FIG. Enter each into the grid. Accordingly, electrons are emitted from the RGB electron guns 76A to C within the brightness signal range set by the negative voltage, for example, -40 [V], formed on the fluorescent surface of the cathode ray tube 75 to form a color screen. do.

By the way, if the user adjusts the DC level of the brightness signal to set the required amount by using the control button 77, the grid bias mixing unit 72 according to this setting signal in accordance with the reference DC level signal shown in FIG. Since the size of (R) is adjusted by the set amount, the respective grids of the RGB electron guns 76A to C are simultaneously adjusted according to this DC level adjustment signal.

However, since the DC level control circuit of the conventional brightness signal as described above, the color temperature characteristic (Temperature White Valance) is limited because each grid voltage of the RGB electron gun is controlled at the same time when the DC level of the brightness signal is independently controlled. Not only was the range of expression reduced, but the white was not easily adjusted according to the range of color expression.

Accordingly, the present invention has been made to solve the above-mentioned shortcomings, and by providing a DC level control circuit capable of independently adjusting the DC level of the RGB brightness signal at one end of each RGB electron gun of the monitor, Since the DC level can be adjusted independently for each electron gun, the range of color control of the monitor can be extended accordingly, and the range of color signals can be extended. The purpose is to provide a control circuit.

A grid mixing unit for generating a screen brightness signal by mixing the screen brightness color signal and a DC level signal of the present invention for achieving the above object, a switching control unit connected to an RGB output terminal of the grid mixing unit to perform a switching switching operation; An operational amplifier connected to one end of the switching control unit for inputting a switching control voltage, and a microcomputer for supplying a DC level control voltage to the operational amplifier.

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

According to the present invention, as shown in FIG. 3, an image signal processor 1 for processing RGB video signals and amplified RGB video signals of the video signal processor 1 at a constant voltage level, for example, about 4 [V]. A preamplifier section 2, an output amplifier section 3 which amplifies the video signal of the preamplifier section 2 at a predetermined level, for example, about 60 [V], and the output amplifier section 3 outputted from the output amplifier section 3; Screen brightness variable circuit section 4 for adjusting the magnitude of the brightness signal according to the RGB image signal, and grid mixing section 5 for mixing the DC signal to the screen brightness signal of the screen brightness variable circuit section 4 A pulse rectifying circuit section 6 for supplying a DC level signal to the grid mixing section 5, a switching control section 7 connected to the RGB output terminal of the grid mixing section 5, and switching switching thereon; An operational amplifier connected to one end of the switching control unit 7 and inputting a switching control voltage ( 8) and a microcomputer 9 for supplying the DC level regulating voltage to the operational amplifier 8 and controlling the overall functional operation of the system.

In the switching control unit 7, the emitter stage of the transistor TR1 is connected to each grid of the RGB electron guns 11A to C of the cathode ray tube 10, respectively. The emitter terminal of the transistor TR2 is connected via R1, and the output terminal of the operational amplifier 8 is connected to the base terminal of the transistor TR2. In addition, a microcomputer 9 is connected to the inverting terminal of the operational amplifier 8, and an emitter terminal of the transistor TR2 is connected to a common point in which one end of the microcomputer 9 and the inverting terminal of the operational amplifier 8 are connected. The bias terminal Vcc is connected to the base terminal of the transistor TR1 through a resistor R2. The flyback transformer 12 is connected to the pulse rectifying circuit unit 6.

Here, the switching control unit 7 and the operational amplifier 8 are independently provided at one end of the R.G.B electron guns 11A to C so as to independently adjust the DC level color signals of the R.G.B.

Next, the operation and effect of the present invention having the above configuration will be described.

In the operation of the present invention, first, the video signal of the R.G.B processed by the video signal processor 1 is input to the preamplifier 2 and amplified by a predetermined voltage, for example, about 4 [V]. The video signal once amplified by the preamplifier 2 is input to the output amplifier 3, amplified by an output signal required for the monitor, for example, about 60 [V], and input to the screen brightness variable circuit section 4.

Then, as shown in FIG. 2, the screen brightness variable circuit section 4 adjusts the magnitude M of the brightness signal according to the video signal to the set magnitude level and inputs it to the grid mixing section 5.

Then, in the grid mixing section 5, the brightness signal according to the video signal is mixed with the input reference voltage DC level signal 33 [V] as shown in Fig. 2, and the angles of the RGB electron guns 11A to C are mixed. Enter the grid.

Therefore, the brightness of the color screen is realized within the range of the brightness signal and DC voltage level set as described above by the negative voltage formed on the fluorescent surface of the cathode ray tube 10, for example, -40 [V].

However, if the user wants to emphasize any one of the specific signals, for example, red (R), green (G) or blue (B), than the other colors, the user can specify the microcomputer 9 through the keyboard 13. Input the setting signal to emphasize the color. Then, the microcomputer 9 recognizes this and inputs the DC level control voltage to the switching controller 7 and the operational amplifier 8 of the corresponding color.

For example, if the red (R) of the screen is desired to be made thinner, the microcomputer 9 inputs a DC level control voltage within an adjustable range to the inverting terminal of the corresponding operational amplifier 8 to be emphasized. 8) applies a switching control voltage proportional to the input DC level control voltage to the base terminal of the transistor TR2 of the switching control unit 7. The transistor TR2 is then turned on in accordance with the input switching control voltage to turn on the transistor TR1. Therefore, the DC level voltage of the brightness signal input from the grid mixing section 5 to the grid of the red (R) electron gun 11A is supplied as little as the voltage flowing to the collector of the transistor TR1. Then, the DC level input to the grid of the red (R) electron gun 11A is lowered from the reference level potential (R) as shown in FIG. 2, so that the red signal among the brightness signals of the screen is equal to the level adjustment amount. Thinner.

Here, when the collector current of the transistor TR1 flows less than the DC reference voltage level R of the set brightness signal, it is supplied higher than the DC reference voltage level R of the brightness signal applied to the grid of the red (R) electron tube 11A. Therefore, the brightness signal of red is emphasized more than other colors on the screen.

Therefore, if the switching unit 7 connected to each grid of the RGB electron guns 11A to C is selectively adjusted as described above, the DC voltage level of the corresponding color changes so that the screen brightness of the specific color can be adjusted. .

In addition, if the DC level control voltage input to each of the operational amplifier 8 is finely adjusted, it is possible to finely adjust the DC voltage level of the screen brightness as described above, so that it can be easily expressed from a high color temperature range to a low color temperature range. have.

Claims (2)

In the screen brightness control circuit provided with a grid mixing section 5 for generating a screen brightness signal by mixing the screen brightness color signal of the screen brightness variable circuit section 4 and the DC level signal of the pulse rectifying circuit section 6, the grid mixing A switching control unit 7 connected to each of the RGB output terminals of the unit 5 and performing a switching switching operation; an operational amplifier 8 connected to one end of the switching control unit 7 and inputting a switching control voltage; (8) A DC level control circuit of an RGB brightness signal of a monitor, characterized in that a microcomputer 9 for supplying a DC level adjustment voltage is provided. The transistor of claim 1, wherein the switching controller 7 is connected to each RGB output terminal of the grid mixing unit 5 and performs a switching action, and an operational amplifier connected to the base terminal of the transistor TR1. And a transistor (TR2) for switching operation in accordance with the switching control voltage of (8).