KR200153717Y1 - Circuit for preventing fluctuation of osd in a monitor - Google Patents

Abstract

The present invention relates to on-screen display (OSD) technology in the monitor.

This configuration of the present invention is a monitor equipped with an on-screen display integrated circuit (OSD IC) for receiving a flyback pulse input from the FBT as a horizontal synchronous signal to form a predetermined on-screen display (OSD) screen, the FBT A zener diode (ZD21) for blocking a predetermined voltage or less from the FBP signal input from the digital signal; A capacitor C21 for blocking a DC level in the FBP signal passing through the zener diode; Inverting means for inverting the output of the capacitor; And an amplifier for amplifying and waveform shaping the output of the inverting means and providing the horizontal synchronization signal of the on-screen display integrated circuit.

Therefore, when the on-screen display integrated circuit generates the R, G, and B signals for the on-screen display by using the flyback pulses output by the FBT as horizontal synchronization signals, the noise inserted together with the flyback pulse signal according to the present invention. Stabilize the on-screen display by removing and shaping the waveform.

Description

Circuit for preventing fluctuation of OSD in a monitor

The present invention relates to an on-screen display (OSD) technology for a monitor, and more particularly to a circuit that improves image quality by preventing the OSD screen from shaking.

In general, the 'On Screen Display (OSD)' in the monitor is a parameter adjustment menu that allows the user to adjust various parameters related to image quality (e.g., contrast, horizontal size, pincushion, vertical size, etc.). It is a part of the mark.

For most monitors, when the user presses the menu key, Micom recognizes this and then controls the on-screen display integrated circuit (OSD IC) to display menus related to parameter adjustment on the CRT screen. If you select the parameter to be adjusted, the current setting status of the parameter is displayed as a bar, so that the user can change the data value of the parameter set by using the up-down key.

That is, FIG. 1 is a circuit diagram showing a conventional video-related part in a monitor, which is a horizontal synchronous signal for the flyback pulse FBP from the video preamplifier 100, the blanking unit 110, and the FBT 120. FIG. OSD IC 130, mixer 140, video power amplifier 150, CRT 160, etc., which are input as H.sync and output R, G, B signals for an on-screen display (OSD) It includes.

At this time, the OSD IC 130 receives the FBP pulse from the FBT 120 through the transistor Q1 and uses it as the horizontal synchronization signal H.sync, which is shown in FIG. 2 because the flyback pulse FBP is unstable. As shown, noise is generated in the OSD screen A1. If this is explained in more detail as follows.

A horizontal output transistor for switching according to a horizontal drive signal synchronized with a horizontal synchronous signal is connected to the primary winding of the FBT 120 to generate a flyback pulse FBP on the secondary side of the FBT, which is a flyback pulse FBP. It is used in the OSD IC 130, which is synchronized with the horizontal synchronization signal and needs the horizontal synchronization signal.

However, since the flyback pulse FBP has a lot of noise, noise is generated in the horizontal synchronous pulse input to the OSD IC 130, and thus, noise is generated in the OSD screen A1 as shown in FIG. .

Therefore, the present invention was devised to solve the above problems, and stabilized the flyback pulse waveform input to the on-screen display integrated circuit (IC) to prevent the shaking of the on-screen display screen. The purpose is to provide.

In order to achieve the above object, the circuit of the present invention, an on-screen display integrated circuit (OSD IC) for receiving a flyback pulse input from the FBT as a horizontal synchronization signal to form a predetermined on-screen display (OSD) screen In the monitor equipped with,

A zener diode for blocking a predetermined voltage or less from the FBP signal input from the FBT; A capacitor for blocking a DC level in the FBP signal passing through the zener diode; Inverting means for inverting the output of the capacitor; And an amplifier for amplifying and waveform shaping the output of the inverting means and providing the horizontal synchronization signal of the on-screen display integrated circuit.

1 is a circuit diagram showing a conventional video related portion in a monitor,

2 is a circuit diagram showing a video related portion according to the present invention in a monitor;

3 is an operation waveform diagram of each part shown in FIG. 2.

* Explanation of symbols for main parts of the drawings

100: video preamplifier 110: blanking unit

120: FBT 130: OSD IC

140: mixer 150: video power amplifier

160: CRT 200: OSD screen shake prevention unit

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

2 is a circuit diagram illustrating a video related part according to the present invention in a monitor.

As shown in FIG. 2, the video portion of the monitor to which the present invention is applied includes a video preamplifier 100 and a blanking unit for blanking an output of the video preamplifier according to a fast blank (FB) signal input from an OSD IC. 110, the FBT 120, the OSD IC 130, the mixer 140, the video power amplifier 150, the CRT 160, the OSD image stabilization circuit 200, and the like.

And the OSD screen shake prevention circuit 200 according to the present invention is a zener diode (ZD21) for blocking a predetermined voltage or less in the FBP signal input from the FBT 120, as shown in Figure 2 and the zener diode The on-screen display integrated circuit (C21) for blocking the DC level in the FBP signal passing through, the inverting unit (Q21) for inverting the output of the capacitor, and amplifying and waveform shaping the output of the inverting unit. And amplifiers Q22 and Q23 which serve as the horizontal synchronization signal H.sync of 130.

Referring to FIG. 2, the video preamplifier 100 amplifies R, G, and B signals input from a video card (not shown) of a computer through a de-sub (D-SUB) connector (not shown). The brightness of the screen is controlled by adjusting the amplification degree according to the contrast signal of the microcomputer (not shown).

That is, since the video signal input through the D-sub connector is a low signal of about 1V or less, the video preamplifier 100 amplifies the AC gain of about 4 to 10, and then the cathode of the CRT in the video output amplifier 150. Amplify the signal from approximately 30V to 50V to drive. Here, since the video power amplifier (CRT driver) 150 is a fixed gain amplifier, the video preamplifier 100 can adjust the level of the video signal. Examples include LM1203, LM1203A, LM1204, LM1207, and LM1208 of NS Corporation.

The blanking unit 110 blocks the output of the video preamplifier 100 when the OSD R, G, and B signals are output according to the fast flanking (FB) signal output from the OSD IC 130. That is, when the OSD IC outputs 'high' as a fast blanking (FB) signal, a forward bias is applied to the transistor Q2 through the diode D1 and the resistor R3 to turn on the transistor Q2. Accordingly, the diodes D2, D3, and D4 connected to the R, G, and B output terminals of the video preamplifier 100 are turned on to block the output of the video preamplifier 100. FIG.

The FBT 120 generates a flyback pulse FBP to the secondary side according to on and off of a horizontal output transistor (not shown).

The flyback pulse is blocked with noise carried on the low voltage through the zener diode ZD21, and the DC level is blocked through the capacitor C21. In this way, the 'FBP', in which the noise and the DC level are cut off, is inverted by the transistor Q21 of the inverter, and the output of the inverted transistor is amplified and waveform-formed by the push-pull amplifiers Q22 and Q23, and the on-screen display integrated circuit Input 130.

The on-screen display integrated circuit (OSD IC) receives a horizontal synchronous signal and a vertical synchronous signal, receives control data, generates R, G, and B signals of a predetermined character or figure, and outputs them to the mixer unit 140. In this case, when the OSD R, G, B signals are output for the on-screen display (OSD), a fast blank (FB) signal is first generated to block the output of the video preamplifier 100 from the blanking unit 110. Therefore, the on-screen screen output by the OSD IC 130 appears on the CRT screen. The mixer 140 receives and outputs the output of the video preamplifier 100 or the output of the OSD IC 130.

3 is an operation waveform diagram in each part of FIG. 2, and (A) is a waveform diagram showing a flyback pulse (FBP) waveform output from the FBT, and it can be seen that a lot of noise is inserted. (B) is a waveform diagram showing that the noise is removed while the FBP of (A) passes through the zener diode (ZD21), and (C) shows that the DC level is blocked while the (B) waveform passes through the capacitor (C21). It can be seen that the magnitude is reduced, (D) indicates that the (C) waveform is inverted in the inverting section, (E) indicates that the (D) waveform is amplified in the amplifying section.

As described above, when the on-screen display integrated circuit uses the flyback pulse output by the FBT as a horizontal synchronous signal to generate the R, G, and B signals for the on-screen display, the flyback pulse signal is applied to the flyback pulse signal according to the present invention. Stabilizes the on-screen display screen by removing the noise inserted together and shaping the waveform.

Claims (3)

In the monitor equipped with an on-screen display integrated circuit (OSD IC) for receiving a flyback pulse input from the FBT as a horizontal synchronization signal to form a predetermined on-screen display (OSD) screen, A zener diode (ZD21) for blocking a predetermined voltage or less from the FBP signal input from the FBT; A capacitor C21 for blocking a DC level in the FBP signal passing through the zener diode; Inverting means for inverting the output of the capacitor; And And an amplifier for amplifying and waveform shaping the output of said inverting means and providing it as a horizontal synchronization signal of said on-screen display integrated circuit. The anti-shake circuit of an on-screen display screen as claimed in claim 1, wherein said inverting means comprises an emitter grounding transistor (Q21). The anti-shake circuit of an on-screen display screen as claimed in claim 1, wherein said inverting means is implemented by a push-pull transistor circuit (Q22, Q23).