KR100661369B1 - An apparatus for stabilizing a sync. signal in a video display system - Google Patents

Abstract

The present invention relates to a synchronization signal stabilization device of a video display device,

The mode is determined by the first synchronization signal sync1 input from the outside, the mode control signal con1 is output, the second synchronization signal sync2 generated by the self-oscillating circuit is output, and the switching control is performed according to the operation state. A microcomputer 10 which outputs a signal con2; Switching means for selectively outputting the first synchronization signal sync1 input from the outside and the second synchronization signal sync2 input from the microcomputer 10 by the switching control signal con2 of the microcomputer 10. 20; The deflection circuit 30 generates a deflection current by a mode control signal con1 input from the microcomputer 10 and a synchronization signal sync1 or sync2 input from the switching means 20 to deflect the scanning electron beam. Consist of

When the synchronous signal input from the outside is stable, the synchronous signal input from the outside is directly supplied to the deflection circuit without passing through the microcomputer, thereby preventing the noise induced in the synchronous signal by the microcomputer.

Image display device, microcomputer, synchronization signal, horizontal deflection

Description

An apparatus for stabilizing a synchronization signal of an image display device. signal in a video display system}

1 is a perspective view of a general image display device;

2 is a block diagram of a general video display device;

3 is a block diagram of a first embodiment showing a synchronizing signal stabilization apparatus of a video display device according to the present invention;

4 is a circuit diagram showing the switching means of FIG.

5 is a block diagram of a second embodiment showing an apparatus for stabilizing a synchronization signal of a video display device according to the present invention;

FIG. 6 is a circuit diagram showing the switching means of FIG. 5.

* Names of symbols for main parts of the drawings

10 microcomputer 20 switching means

30: deflection circuit 31: deflection processor

32: horizontal deflection circuit 33: vertical deflection circuit

Q 1,2,3,4: 1,2,3,4 transistor R 1,2,3,4,5,6: resistance

The present invention relates to a synchronization signal stabilization apparatus of a video display device.

More particularly, the present invention relates to a synchronizing signal stabilization device of an image display device, which is configured to supply a synchronizing signal input from the outside to a deflection circuit directly without passing through a microcomputer when the synchronizing signal input from the outside is stable.

In general, a cathode ray tube (CRT) used in a video display device strikes a fluorescent substance of R, G, B (red, green, blue) coated with a different amount of electron beam on the surface of the cathode ray tube according to the intensity of the image signal. It uses the principle of emitting light of different brightness or color and is widely used because of its excellent price and display performance.

1 is a perspective view of a general image display device, which receives an image signal and a synchronization signal received from a video card of a computer and displays an image on a cathode ray tube screen.

2 is an overall block diagram of a general image display device, wherein the image display device includes a microcomputer 1, a deflection circuit 2, a high voltage circuit 3, a video amplifier 4, a cathode ray tube (CRT), and the like. .

As shown in Fig. 2, the RGB image signal input from the video card of the computer is amplified through the video amplifier 4 and then applied to the cathode terminal of the cathode ray tube (CRT) and displayed on the screen.

At this time, in order to display the RGB image signal on the cathode ray tube (CRT) screen, by supplying sawtooth current to the horizontal deflection coil and the vertical deflection coil, the electron beam is deflected in the horizontal direction and the vertical direction to provide the raster to the entire cathode ray tube screen. As to be formed, the sawtooth wave current is generated in the deflection circuit 2 by the horizontal synchronizing signal and the vertical synchronizing signal inputted from the video card of the computer and provided to the horizontal deflection coil and the vertical deflection coil.

Here, the video card supports various video modes, and the video mode outputs a horizontal frequency and a vertical frequency differently according to a resolution to be implemented, and the screen flicker is prevented as the horizontal and vertical frequencies increase from a low frequency to a high frequency. Reduces eye strain.

A multi-mode video display device is a video display device that is compatible with at least two video modes. It is possible to change the size and position of images according to various horizontal frequencies (about 30 to 75 KHz) output from the video card, and to synchronize the horizontal and vertical. And an image display device capable of optimizing the deflection unit and adjusting various deflection correction circuits.

Currently, image display apparatuses must cover a wide range of input frequency bands, and the microcomputer 1 determines and controls them.

That is, the microcomputer 1 receives the synchronization signal sync to determine the video mode, and then outputs the mode control signal con and the synchronization signal sync to the deflection circuit 2, and then the deflection circuit 2. The deflection current is generated by the mode control signal con and the synchronization signal sync to deflect the scanning braille beam.

At this time, the deflection circuit 2 adjusts the screen state by the mode control signal and the synchronization signal inputted through the microcomputer 1.

At this time, when there is no synchronization signal input from the outside or the signal cable is disconnected, in order to display the OSD screen to inform the user or a test screen during the production process, the synchronization generated by the self-oscillating circuit of the microcomputer 1 The signal is supplied to the deflection circuit 2.

However, as described above, the microcomputer 1 receives the synchronization signal from the outside and supplies it to the deflection circuit. In this process, the noise is induced in the synchronization signal by the microcomputer 1, and thus the noise component in a specific mode or in a specific situation. There was a problem that it was displayed on this screen.

Accordingly, the present invention has been made to solve the above problems, and in order to prevent noise from being applied to the synchronous signal supplied to the horizontal deflection circuit, when the synchronous signal input from the outside is stable, An object of the present invention is to provide a synchronizing signal stabilization device for an image display device that is directly supplied to a deflection circuit without going through a computer.

In accordance with an aspect of the present invention, there is provided a device for stabilizing a synchronous signal according to an exemplary embodiment of the present invention, determining a mode based on a first synchronous signal input from an external device, outputting a mode control signal, and generating a self-oscillating circuit. A microcomputer for outputting a synchronization signal and outputting a switching control signal in accordance with an operating state; Switching means for selectively outputting a first synchronization signal input from the outside and a second synchronization signal input from the microcomputer by a switching control signal of the microcomputer; And a deflection circuit for generating a deflection current by deflecting the mode control signal inputted from the microcomputer and the synchronization signal inputted from the switching means to deflect the scanning electron beam.

Another synchronizing signal stabilization apparatus of a video display device according to the present invention for achieving the above object, by judging the mode by the first synchronization signal input from the outside to output a mode control signal, according to the operation state itself A microcomputer outputting a second synchronization signal and a switching control signal generated in the oscillation circuit; Switching means for outputting or interrupting the first synchronization signal input from the outside by a switching control signal of the microcomputer; And a deflection circuit which generates a deflection current by the synchronization signal input from the switching means or the microcomputer and the mode control signal input from the microcomputer to deflect the scanning electron beam.

Hereinafter, a synchronization signal stabilization apparatus of a video display device according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of a first embodiment showing a synchronizing signal stabilization apparatus of a video display device according to the present invention, Figure 4 is a circuit diagram showing the switching means of FIG.

3 and 4, according to the first embodiment of the present invention, the mode is determined by the first synchronization signal sync1 input from the outside to output the mode control signal con1, and the self-oscillating circuit A microcomputer 10 which outputs a second synchronization signal sync2 generated by the second control signal and outputs a switching control signal con2 according to an operation state; Switching means for selectively outputting the first synchronization signal sync1 input from the outside and the second synchronization signal sync2 input from the microcomputer 10 by the switching control signal con2 of the microcomputer 10. 20; The deflection circuit 30 generates a deflection current by a mode control signal con1 input from the microcomputer 10 and a synchronization signal sync1 or sync2 input from the switching means 20 to deflect the scanning electron beam. It consists of.

Here, the microcomputer 10 outputs the switching control signal con2 of the first level in the normal operation, and outputs the switching control signal con2 of the second level in the abnormal operation.

In addition, the switching means 20, the first switching unit (Q1, Q2) which is switched on by the switching control signal (con2) of the first level and outputs a first synchronization signal (sync1) input from the outside; And second switching units Q3 and Q4 which are switched on by the second level switching control signal con2 and output a second synchronization signal sync2 input from the microcomputer 10.

Next, the operation and effects of the first embodiment according to the present invention configured as described above will be divided into normal operation and abnormal operation.

1. In normal operation

The microcomputer 10 receives the first synchronization signal sync1 from the outside, determines the mode, outputs the mode control signal con1 to the deflection circuit 30, and generates a stable frequency generated by the self oscillation circuit (about 68 KHz). Outputs the second synchronization signal sync2 to the switching means 20.

In addition, the microcomputer 10 outputs a switching control signal con2 of the first level to the switching means 20 because the current operating state of the image display device is a normal operation state.

Accordingly, the switching means 20 receives the first synchronization signal sync1 from the outside and the second synchronization signal sync2 from the microcomputer 10.

At this time, the switching means 20 selectively deflects one of the first synchronization signal sync1 and the second synchronization signal sync2 by the switching control signal con2 of the first level input from the microcomputer 10. Output to the circuit 30.

That is, the first transistor Q1 and the second transistor Q2 of the first switching unit are sequentially switched on by the switching control signal con2 of the first level, so as to receive the first synchronization signal sync1 input from the outside. It outputs to the deflection processor 31 of the deflection circuit 30.

At this time, the third transistor Q3 and the fourth transistor Q4 of the second switching unit are sequentially switched off by the switching control signal con2 of the first level, and the second synchronization input from the microcomputer 10 is performed. The output of the signal sync2 is cut off.

The deflection circuit 30 deflects the scanning electron beam by generating a deflection current by the mode control signal con1 input from the microcomputer 10 and the first synchronization signal sync1 input from the switching means 20. make someone do.

That is, since the first synchronization signal sync1 input from the outside in the normal operation is supplied to the deflection processor 31 of the deflection circuit 30 through the switching means 20, the deflection processor 31 is the microcomputer 10 The screen state is adjusted by the mode control signal con1 inputted from) and the first synchronization signal sync1 inputted from the outside.

2. When abnormal operation

When there is no synchronization signal input from the outside or the signal cable is disconnected and the OSD screen is displayed to inform the user of this, or the test screen is displayed during the production process, the microcomputer 10 switches the switching control signal con2 of the second level. Is output to the switching means 20.

Accordingly, the third transistor Q3 and the fourth transistor Q4 of the second switching unit are sequentially switched on by the second level switching control signal con2 and the second synchronization input from the microcomputer 10 is performed. The signal sync2 is output to the deflection processor 31 of the deflection circuit 30.

At this time, the first transistor Q1 and the second transistor Q2 of the first switching unit are sequentially switched off by the switching control signal con2 of the second level, so that the first synchronization signal sync1 input from the outside is switched off. The output is cut off.

The deflection circuit 30 deflects the scanning electron beam by generating a deflection current by the mode control signal con1 input from the microcomputer 10 and the second synchronization signal sync2 input from the switching means 20. make someone do.

That is, in the abnormal operation, the second synchronization signal sync2 generated from the microcomputer 10 is supplied to the deflection processor 31 of the deflection circuit 30 through the switching means 20, so that the deflection processor 31 is The screen state is adjusted by the mode control signal con1 and the second synchronization signal sync2 input from the microcomputer 10.

FIG. 5 is a block diagram of a second embodiment showing a synchronizing signal stabilization apparatus of an image display apparatus according to the present invention, and FIG. 6 is a circuit diagram showing the switching means of FIG.

5 and 6, according to the second embodiment of the present invention, the mode is determined by the first synchronization signal sync1 input from the outside, and the mode control signal con1 is output. A microcomputer 10 for outputting a second synchronization signal sync2 and a switching control signal con2 generated by the self-oscillating circuit according to the present invention; Switching means (20) for outputting or blocking the first synchronization signal (sync1) input from the outside by the switching control signal (con2) of the microcomputer (10); A scanning current beam is generated by generating a deflection current by the synchronization signal sync1 or sync2 input from the switching means 20 or the microcomputer 10 and the mode control signal con1 input from the microcomputer 10. It consists of a deflection circuit 30 for deflecting.

Here, the microcomputer 10 outputs the switching control signal con2 of the first level in the normal operation, and the second synchronization signal sync2 and the switching control signal of the second level generated by the oscillation circuit in the abnormal operation. Output (con2)

In addition, the switching means 20 is switched on by the switching control signal con2 of the first level and outputs a first synchronization signal sync1 input from the outside, and the switching control signal con2 of the second level. It is composed of the third switching unit (Q5, Q6) which is switched off by a) and cuts off the output of the first synchronization signal (sync1) input from the outside.

Next, the operation and effects of the second embodiment according to the present invention configured as described above will be divided into normal operation and abnormal operation.

3. In normal operation

The microcomputer 10 receives the first synchronization signal sync1 from the outside, determines the mode, and outputs the mode control signal con1 to the deflection circuit 30.

In addition, the microcomputer 10 outputs a switching control signal con2 of the first level to the switching means 20 because the current operating state of the image display device is a normal operating state.

Accordingly, the switching means 20 outputs the first synchronization signal sync1 input from the outside to the deflection circuit 30 by the switching control signal con2 of the first level input from the microcomputer 10. .

That is, the fifth transistor Q5 and the sixth transistor Q6 of the third switching unit are sequentially switched on by the switching control signal con2 of the first level, so as to receive the first synchronization signal sync1 input from the outside. It outputs to the deflection processor 31 of the deflection circuit 30.

The deflection circuit 30 deflects the scanning electron beam by generating a deflection current by the mode control signal con1 input from the microcomputer 10 and the first synchronization signal sync1 input from the switching means 20. make someone do.

That is, since the first synchronization signal sync1 input from the outside in the normal operation is supplied to the deflection processor 31 of the deflection circuit 30 through the switching means 20, the deflection processor 31 is the microcomputer 10 The screen state is adjusted by the mode control signal con1 inputted from) and the first synchronization signal sync1 inputted from the outside.

4. When abnormal operation

When there is no synchronization signal input from the outside or the signal cable is disconnected and the OSD screen is displayed to inform the user of this, or the test screen is displayed during the production process, the microcomputer 10 switches the switching control signal con2 of the second level. Is output to the switching stage 20 and the second synchronization signal sync2 of stable frequency (about 68 KHz) generated by the self oscillation circuit is output to the deflection circuit 30.

Accordingly, the fifth transistor Q5 and the sixth transistor Q6 of the third switching unit are sequentially switched off by the switching control signal con2 of the second level, so that the first synchronization signal sync1 input from the outside is switched off. The output of is cut off.

The deflection circuit 30 generates a deflection current by the mode control signal con1 and the second synchronization signal sync2 input from the microcomputer 10 to deflect the scanning electron beam.

That is, in the abnormal operation, the deflection processor 31 of the deflection circuit 30 adjusts the screen state by the mode control signal con1 and the second synchronization signal sync2 input from the microcomputer 10.

As described above, the apparatus according to the present invention, when the synchronous signal input from the outside is stable, by supplying the synchronous signal input from the outside to the deflection circuit directly without passing through the microcomputer, it is induced by the microcomputer to the synchronous signal The effect is that noise can be prevented.

Claims (6)

A microcomputer for outputting a mode control signal according to the video mode of the first synchronization signal input from the outside, a second synchronization signal generated by the self oscillation circuit, and a switching control signal according to an operation state;  Switching means for selectively outputting the first synchronization signal and the second synchronization signal by a switching control signal of the microcomputer; And a deflection circuit configured to deflect the scanning electron beam by generating a deflection current based on any one of the mode control signal and the first synchronization signal or the second synchronization signal. The method of claim 1 wherein the microcomputer, A switching control signal of the first level is output in the normal operation, and the switching control signal of the second level is output in the abnormal operation. The method of claim 2 wherein the switching means, A first switching unit which is switched on by the switching control signal of the first level and outputs a first synchronization signal input from the outside; And a second switching unit which is switched on by the switching control signal of the second level and outputs a second synchronization signal input from the microcomputer. A microcomputer for outputting a mode control signal according to the video mode of the first synchronization signal input from the outside, a second synchronization signal and a switching control signal generated by the oscillation circuit according to the operation state; Switching means for outputting or interrupting the first synchronization signal by the switching control signal; And a deflection circuit configured to deflect the scanning electron beam by generating a deflection current according to the synchronization signal input from the switching means or the microcomputer, and the mode control signal. The method of claim 4 wherein the microcomputer, Outputting a switching control signal of a first level in a normal operation, and outputting a second synchronization signal and a switching control signal of a second level generated in a self-oscillating circuit in an abnormal operation; . The method of claim 5 wherein the switching means, The first synchronization signal is switched on by the switching control signal of the first level and outputs a first synchronization signal input from the outside, and the output is switched off by the switching control signal of the second level to block the output of the first synchronization signal input from the outside. A synchronization signal stabilization circuit of a video display device, characterized in that consisting of a third switching unit.

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