KR200197411Y1 - Osd control circuit for monitor - Google Patents

Abstract

The disclosed OSD control circuit prevents duplication and interference of the horizontal synchronization signal and the horizontal flyback pulse signal generated when the image signal and the OSD signal are displayed together on the cathode ray tube of the monitor.

According to the present invention, when a horizontal synchronization signal is input from a computer system, an OSD signal is generated and displayed on a cathode ray tube according to the input horizontal synchronization signal and a vertical flyback pulse signal generated by the monitor itself, and the horizontal synchronization signal from the computer system. If is not input, the OSD signal is generated and displayed on the cathode ray tube according to the horizontal flyback pulse signal and the vertical flyback pulse signal self-oscillated from the monitor. The video signal and OSD signal can be displayed together on the cathode ray tube of the monitor. In this case, the OSD signal is generated according to the horizontal synchronous signal input from the computer system and the horizontal flyback pulse signal generated by the monitor itself, and thus the display position of the video signal is adjusted while displaying the OSD signal and the video signal together on the cathode ray tube. Horizontal Flyback Pulse Signal and Horizontal Sync Signal Eliminates bounding in the OSD by avoiding interference and interference.

Description

OS control circuit of monitor

The present invention is a monitor that is connected to a computer system and used as an image display device, wherein the horizontal synchronization signal and the horizontal flyback pulse signal generated when an on-screen display (OSD) signal and an image signal are displayed together on a screen. The present invention relates to an OSD control circuit of a monitor to prevent duplication and interference.

In general, a monitor includes a cathode ray tube as display means, and displays a predetermined video signal input from a computer system on the cathode ray tube.

In order to display a predetermined image on the cathode ray tube, a synchronization signal is required. The computer system outputs a horizontal synchronization signal and a vertical synchronization signal together with the predetermined image signal, and outputs a horizontal synchronization signal and a vertical synchronization signal output from the computer system. According to the synchronization signal, the monitor displays a predetermined image on the cathode ray tube.

In addition, the monitor is equipped with an OSD control circuit to display the current operating state and the set value according to the user's operation, and generates an OSD signal according to the horizontal flyback pulse signal and the vertical flyback pulse signal to display on the cathode ray tube Doing.

This conventional technique will be described in detail with reference to the drawings of FIG.

1 is a conventional OSD control circuit diagram.

Here, reference numeral 1 denotes a first stage amplifier for ultra-amplifying a predetermined video signal input from a computer system (not shown), and reference numeral 2 denotes a horizontal flyback pulse signal H_FLB when an OSD control signal is inputted. An OSD device generates an OSD signal according to the vertical flyback pulse signal V_FLB, and outputs an image signal input from the first stage amplifier 1 when the OSD control signal is not input.

Reference numeral 3 is an image output unit for amplifying the output signal of the OSD integrated device 2 and outputting the amplified signal to the cathode ray tube 4 to be displayed on the screen.

The conventional OSD control circuit configured as described above amplifies the image signal input from the computer system by the first stage amplifier 1 and sends the image signal to the OSD integrated device 2.

When the OSD control signal is not input, the OSD integrated device 2 amplifies the image signal input from the first stage amplifier 1 and outputs the image to the cathode ray tube 4 through the image output unit 3 to display the screen. Displayed on the screen.

When the OSD control signal is input in this state, the OSD integrated device 2 generates an OSD signal according to the horizontal flyback pulse signal H_FLB and the vertical flyback pulse signal V_FLB. It is output to the cathode ray tube 4 through the image output unit 3 is displayed on the screen.

Here, when displaying the video signal input from the computer system on the cathode ray tube 4, the horizontal synchronous signal and the vertical synchronous signal input together with the video signal from the computer system are used.

When the OSD signal is generated and displayed on the cathode ray tube 4, the horizontal flyback pulse signal (H_FLB) generated by the monitor itself regardless of the horizontal synchronization signal and the vertical synchronization signal input together with the image signal from the computer system. And a vertical flyback pulse signal V_FLB.

Therefore, the monitor generates OSD signals according to the horizontal flyback pulse signal (H_FLB) and vertical flyback pulse signal (V_FLB) generated by the monitor itself, even if the horizontal and vertical synchronization signals are not input from the computer system. (4), the horizontal flyback pulse signal (H_FLB) and the vertical flyback pulse signal (V_FLB) can be adjusted to adjust the position of the OSD signal displayed on the cathode ray tube (4).

However, the above-described conventional technique uses a horizontal flyback pulse signal (H_FLB) used to generate an OSD signal when the display position of the image signal is adjusted while displaying the OSD signal and the image signal together on the screen of the cathode ray tube. And the vertical flyback pulse signal V_FLB and the horizontal synchronous signal HSY and the vertical synchronous signal inputted from the computer system cross each other.

When the horizontal flyback pulse signal H_FLB and the vertical flyback pulse signal V_FLB and the horizontal synchronous signal HSY and the vertical synchronous signal cross each other, a redundancy and interference may occur. As a result, a bounding phenomenon occurs in the OSD displayed on the screen of the cathode ray tube.

This bounding phenomenon is hardly influenced by the vertical flyback pulse signal V_FLB, but is affected by the horizontal flyback pulse signal H_FLB when adjusting the horizontal position at which the image is displayed.

Therefore, an object of the present invention is to prevent the overlapping and interference of the horizontal synchronous signal and the horizontal flyback pulse signal generated by adjusting the display position of the video signal while displaying the OSD signal and the video signal together on the cathode ray tube. It is to provide an OSD control circuit of a monitor that can be displayed clearly.

Another object of the present invention is to provide an OSD control circuit of a monitor which generates an OSD signal according to the input horizontal synchronization signal and a vertical flyback pulse signal generated by the monitor when the horizontal synchronization signal is input from a computer system. have.

Another object of the present invention is to provide an OSD control circuit of a monitor which generates an OSD signal according to a horizontal flyback pulse signal and a vertical flyback pulse signal which are oscillated by the monitor when a horizontal synchronization signal is not input from a computer system. There is.

1 is a conventional OSD control circuit diagram.

2 is an OSD control circuit diagram of the present invention.

3 is a detailed circuit diagram showing a switching unit in the OSD control circuit of the present invention.

* Explanation of symbols for main parts of the drawings

11: ultra-short amplifier 12: switching unit

13: OSD integrated device 14: video output unit

15: cathode ray tube 121: integrator

122: multiplexer V_FLB: vertical flyback pulse signal

H_FLB: Horizontal Flyback Pulse Signal HSY: Horizontal Synchronization Signal

According to the OSD control circuit of the present invention for achieving this object, a first stage amplifier for first amplifying the video signal input from the computer system; A switching unit for outputting the horizontal synchronous signal when the horizontal synchronous signal is input from the computer system, and outputting a horizontal flyback pulse signal that is oscillated by the monitor when the horizontal synchronous signal is not input; When the OSD control signal is input, an OSD signal is generated according to the output signal of the switching unit and the vertical flyback pulse signal, and when the OSD control signal is not input, the OSD integrated to output the video signal input from the ultra-stage amplifier device; And an image output unit for amplifying the output signal of the OSD integrated device and outputting the amplified output signal to the cathode ray tube.

Therefore, according to the present invention, when displaying the video signal and the OSD signal on the cathode ray tube together, the OSD signal is generated according to the horizontal synchronous signal inputted from the computer system and the horizontal flyback pulse signal generated by the monitor itself. Remove it.

Hereinafter, the OSD control circuit of the monitor of the present invention will be described in detail with reference to the attached second and third drawings.

2 is an OSD control circuit diagram of the present invention.

As shown in FIG. 2, the OSD control circuit of the present invention comprises: an ultra-short amplifier 11 for ultra-short amplifying a video signal input from a computer system; When the horizontal synchronizing signal HSY is input from the computer system, the horizontal synchronizing signal HSY is outputted. When the horizontal synchronizing signal HSY is not input, the horizontal flyback pulse signal H_FLB which is self-oscillated by the monitor is output. Switching unit 12 for outputting; When the OSD control signal is input, the OSD signal is generated and output according to the output signal of the switching unit 12 and the vertical flyback pulse signal V_FLB. If the OSD control signal is not input, the OSD control signal is output from the first stage amplifier 11. An OSD integrated device 13 for outputting an input video signal; And an image output unit 14 for amplifying the output signal of the OSD integrated device 13 and outputting the amplified signal to the cathode ray tube 15.

3 is a detailed circuit diagram showing a switching unit in the OSD control circuit of the present invention.

As shown in FIG. 3, the switching unit 12 includes an integrator 121 for integrating a horizontal synchronization signal input from the computer system; And a multiplexer 122 for selectively outputting a horizontal synchronous signal input from the computer system or a horizontal flyback pulse signal generated by the monitor according to the output signal of the integrator 121.

Here, the horizontal flyback pulse signal H_FLB is applied to the first input terminal X0 of the multiplexer 122, and the horizontal synchronous signal HSY is applied to the second input terminal of the multiplexer 122 through the resistor R1. Is applied to (X1). In addition, the horizontal synchronization signal HSY is applied to the selection terminal SEL of the multiplexer 122 through the resistor R2 of the integrator 121 and the ground capacitor C1.

The output signal of the multiplexer 122 is applied to the input terminal of the OSD integrated device 13 through the resistor R3.

The OSD control circuit of the monitor according to the present invention configured as described above does not input the horizontal synchronization signal HSY when the image signal is not input from the computer system.

When the horizontal synchronization signal HSY is not input, the high potential is input from the synchronization signal processing unit (not shown) provided in the monitor, and the high potential input is through the resistor R1. The high potential is applied to the select terminal SEL of the multiplexer 122 while being charged in the capacitor C1 through the resistor R2 of 121.

Then, the multiplexer 122 selects the horizontal flyback pulse signal H_FLB applied to the first input terminal X0 according to the high potential applied to the selection terminal SEL, outputs it to the output terminal, and from the multiplexer 122. The output horizontal flyback pulse signal H_FLB is input to the OSD integrated device 13 through the resistor R3.

When the OSD control signal is input to the OSD integrated device 13 in this state, the OSD integrated device 13 is input from the vertical flyback pulse signal V_FLB and the multiplexer 122 of the switching unit 12. The OSD signal is generated according to the horizontal flyback pulse signal H_FLB, and the generated OSD signal is output to the cathode ray tube 15 through the image output unit 14 and displayed on the screen.

On the other hand, when the horizontal synchronization signal HSY is input together with the image signal from the computer system, the input horizontal synchronization signal HSY is the second input terminal of the multiplexer 122 through the resistor R1 of the switching unit 12. The signal is applied to (X1) and integrated by the resistor R2 of the integrator 121 and the capacitor C1 and applied to the selection terminal SEL of the multiplexer 122.

Here, the integral time constant of the integrator 121 is set so that the low potential is continuously applied to the selection terminal SEL of the multiplexer 122 when the horizontal synchronization signal HSY is input.

Then, since the low potential is continuously applied to the selection terminal SEL of the multiplexer 122, the multiplexer 122 selects and outputs the horizontal synchronization signal HSY applied to the second input terminal X1, and outputs the horizontal synchronization signal. The HHS is input to the OSD integrated device 13 through the resistor R3.

When the OSD control signal is input to the OSD integrated device 13 in such a state, the OSD integrated device 13 is input from the vertical flyback pulse signal V_FLB and the multiplexer 122 of the switching unit 12. The OSD signal is generated according to the horizontal synchronization signal HSY, and the generated OSD signal is output to the cathode ray tube 15 through the image output unit 14 and displayed on the screen.

When the OSD control signal is not input to the OSD integrated device 13, the OSD integrated device 13 transmits an image signal amplified by the first stage amplifier 121 to the cathode ray tube 15 through the image output unit 14. To be displayed on the screen.

As described above, the present invention generates the OSD signal according to the horizontal synchronous signal inputted from the computer system and the horizontal flyback pulse signal generated by the monitor when displaying the video signal and the OSD signal together on the cathode ray tube of the monitor. It eliminates the OSD's bounding phenomenon by preventing overlapping and interference between the horizontal flyback pulse signal and the horizontal synchronization signal that occur when adjusting the display position of the video signal while displaying the OSD signal and the video signal together on the cathode ray tube. .

Claims (2)

A first stage amplifier for first amplifying the video signal input from the computer system; A switching unit for outputting a self-oscillating horizontal flyback pulse signal from a monitor when a horizontal synchronization signal is not input from the computer system; The OSD control signal outputs the input horizontal synchronization signal, and when the horizontal synchronization signal is not input, generates and outputs an OSD signal according to the output signal and the vertical flyback pulse signal of the switching unit, and the OSD control signal is not input. An OSD integrated device for outputting an image signal input from the first stage amplifier; And an image output unit for amplifying an output signal of the OSD integrated device and outputting the amplified output signal to a cathode ray tube. The method of claim 1, wherein the switching unit; An integrator for integrating the horizontal synchronizing signal input from the computer system; And a multiplexer for selectively outputting a horizontal synchronous signal input from the computer system or a horizontal flyback pulse signal self-oscillated from the monitor according to the output signal of the integrator.