KR19990003563U - Screen distortion correction circuit in monitor - Google Patents

Abstract

The present invention relates to a screen distortion correction circuit in a monitor. The circuit of the present invention provides a reference voltage when the center of the screen is located at the center of the CRT, and provides the input information of the screen with the positive input terminal. The first differential amplifier 321 and the output signal of the first differential amplifier 321 are provided as a negative input terminal, the vertical position signal V.pos is input to the positive input terminal, and the output signal is a vertical output IC ( It comprises a correction means consisting of a second differential amplifier 322 provided to 330.

Therefore, the present invention compensates this by varying the vertical position signal applied to the vertical output IC if the vertical position of the screen is not located at the center of the CRT due to the deviation of the monitor set. There is an effect that can be prevented.

Description

Screen distortion correction circuit in monitor

The present invention relates to a circuit for correcting screen distortion (GD) in a monitor, and more particularly, to a circuit for correcting screen distortion generated when a vertical position is moved up and down.

Generally, GD (geometry distortion) is a general term that the monitor display screen is distorted in the horizontal direction or the vertical direction due to various factors, and in this type, pincushion for correcting a failure-shaped screen in the vertical direction. (pincushion) correction, trapezoid correction for correcting a trapezoidal screen in the horizontal direction, tilt correction by a geomagnetic field, and the like.

On the other hand, the monitor is provided with a circuit for adjusting the size of the screen according to the user's control, the circuit for adjusting the vertical position of the monitor screen, as shown in Figure 1, the microcomputer 110 and the resistor (R1) ) And a capacitor C1, a vertical output IC 120 and a deflection IC 130 for GD compensation.

The microcomputer 110 outputs the vertical position signal V.pos of the PWM waveform in order to adjust the vertical position of the screen according to user control. The vertical position signal includes the resistor R1 and the capacitor C1. Is converted into an analog DC signal in the integrating circuit and input to the vertical center terminal VC of the deflection IC 130 for the GD compensation via the buffer OP and voltage drop by a plurality of resistors R3 and R4. It is then converted into a vertical shift signal and applied to the vertical output IC 120.

Here, the vertical output IC 120 varies the current flowing in the vertical deflection coil to adjust the position of the screen according to the vertical shift signal, and the GD compensation deflection IC 130 corrects the GD according to the vertical position signal. Be sure to

That is, a reference voltage necessary for correcting GD is applied to the vertical center terminal VC of the deflection IC 130 for the GD compensation. When the center of the screen is displayed at the center of the CRT, the vertical center terminal ( VC) is applied to the reference voltage of 3.5V, while the screen is raised to the upper side of the CRT, while the reference voltage of 3.7V is applied to the vertical center terminal (VC), while the screen is lowered to the lower side of the CRT. A 3.3V reference voltage is applied to the vertical center terminal VC.

2 illustrates a state in which screen distortion occurs according to the vertical position of the screen before the GD compensation, and a state in which the screen distortion is compensated even when the vertical position of the screen after the GD compensation is changed.

That is, if the voltage input to the vertical center terminal VC of the GD compensation deflection IC 130 is fixed at 3.5V even if the vertical position of the screen is changed, the screen is located above the CRT as shown in FIG. When the screen is located on the lower side, distortion occurs. When the screen is located on the upper side of the CRT, distortion occurs that the lower horizontal width of the screen becomes narrower than the upper horizontal width. Distortion occurs in which the width becomes narrower than the lower horizontal width.

However, when the voltage input to the vertical center terminal VC of the GD compensation deflection IC 130 is varied according to the vertical position of the screen, the screen distortion is compensated as shown in FIG. 2B, and the screen is lower than the CRT. If it is located at, the 3.3V reference voltage is applied to the vertical center terminal, and if the screen is located above the CRT, if the reference voltage of 3.7V is applied to the vertical center terminal, the screen will be distorted even if the screen moves up and down the CRT. This will not happen.

However, if the reference voltage of 3.5V is applied to the vertical center terminal of the GD compensation deflection IC in a state where the center of the CRT and the screen do not coincide due to the deviation of each monitor, the display position of the screen is biased upward or downward. The screen is distorted.

Accordingly, an object of the present invention is to provide a circuit for correcting a screen distortion caused by a change in the vertical position due to the variation of each monitor, which has been devised to solve the above problems of the prior art.

In order to achieve the above object, the circuit of the present invention, in the monitor comprising a microcomputer for varying the vertical position signal output under the control of the user, and a vertical output IC and the deflection IC for GD compensation,

And a correction means for varying the vertical position signal output from the micom according to the center of the screen displayed on the CRT and supplying the vertical position signal to the vertical output IC.

1 is a circuit diagram showing a vertical position correction circuit in a monitor;

2 is a view illustrating a state where screen distortion occurs and a state where screen distortion is corrected according to a vertical position in a conventional circuit;

3 is a circuit diagram illustrating a screen distortion correction circuit according to the present invention in a monitor.

* Explanation of symbols for main parts of the drawings

310: microcomputer 320: correction means

321: first differential amplifier 322: second differential amplifier

323: current mirror device 330: vertical output IC

340: deflection IC for GD correction

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

3 is a circuit diagram showing a screen distortion correction circuit according to the present invention in the monitor, which includes a microcomputer 310, a correction means 320, a vertical output IC 330, a deflection IC 350 for GD correction. It is composed.

Here, the correction means 320 includes a first differential amplifier 321 in which a reference voltage when the center of the screen is located at the center of the CRT is provided as a negative input terminal and the position information of the screen is input to the positive input terminal. And a second differential amplifier in which an output signal of the first differential amplifier 321 is provided as a negative input terminal, a vertical position signal V.pos is input as a positive input terminal, and an output signal is provided to the vertical output IC 330. 322 and is configured.

In addition, the position information of the screen can be obtained with the current mirror 323, the current (I1) and -12V power voltage line flowing from the 12V power voltage line to the + Vs terminal of the vertical output IC 330. In this case, the ratio of the current I2 flowing into the -Vs terminal of the vertical output IC 330 is always 3 to 2 regardless of the vertical position of the screen, and the I1 and I2 are varied according to the vertical position of the screen. You can get the current position of the screen.

That is, when the screen is located above the CRT, the I1 and I2 are increased than when the screen is located at the center of the CRT. After the I1 and I2 overlap, the voltage due to the resistor R7, i.e., the first differential The voltage applied to the positive input terminal of the amplifier 321 is divided by the resistors R5 and R6 to be higher than the reference voltage applied to the negative input terminal of the first differential amplifier 321.

As described above, when the voltage of the positive input terminal is higher than the reference voltage of the negative input terminal, the first differential amplifier 321 applies a high output voltage to the negative input terminal of the second differential amplifier 322. When the voltage of the input terminal increases, the vertical position signal V.pos applied to the positive input terminal of the second differential amplifier 322 is reduced and then input to the vertical output IC 330.

Therefore, the vertical position signal V.pos output from the microcomputer 310 is input to the vertical output IC 330 after being reduced, and thus the vertical output IC 330 displays the screen as a whole downwardly. Allow the center to be displayed at the center of the CRT.

On the other hand, when the screen is located below the CRT, the I1 and I2 are reduced than when the screen is located at the center of the CRT, and after the I1 and I2 overlap, the voltage due to the resistor R7, that is, the first differential amplifier The voltage applied to the positive input terminal of 321 is divided by the resistors R5 and R6 to be lower than the reference voltage applied to the negative input terminal of the first differential amplifier 321.

As described above, when the voltage of the positive input terminal is lower than the reference voltage of the negative input terminal, the first differential amplifier 321 applies a low output voltage to the negative input terminal of the second differential amplifier 322. When the voltage of the negative input terminal decreases, the vertical position signal V.pos applied to the positive input terminal of the second differential amplifier 322 is increased and then input to the vertical output IC 330.

Accordingly, the vertical output IC 330 is inputted after the vertical position signal V.pos output from the microcomputer 310 is increased, and thus the vertical output IC 330 displays the screen as a whole to upwardly display the screen. Allow the center to be displayed at the center of the CRT.

In addition, when the screen is positioned at the center of the CRT, voltages and resistors R7 and R8 applied to the positive input terminals of the first differential amplifier 321 by the currents I1 and I2 supplied from the current mirror 323. As a result, the reference voltage applied to the negative input terminal of the first differential amplifier 321 is the same.

That is, the first differential amplifier 321 outputs a signal having a '0' level as an output signal, and the second differential amplifier 322 outputs the signal without increasing or decreasing the vertical position signal V.pos. When the vertical position signal V.pos is applied to the vertical output IC 330, the vertical output IC 330 displays a screen at a vertical position according to the vertical position signal V.pos.

While correcting the position of the screen as described above, the vertical position signal V.pos is applied to the vertical center terminal VC of the GD compensation deflection IC 340, and the GD compensation deflection IC 340 is applied. The GD of the horizontal deflection signal output from the vertical output IC 330 is compensated according to the voltage applied to the vertical center terminal VC of FIG.

As described above, the present invention compensates this by varying the vertical position signal applied to the vertical output IC if the vertical position of the screen is not located at the center of the CRT due to the deviation of the monitor set, so that the screen is displayed at the center of the CRT. There is an effect that can be prevented from being distorted.

Claims (2)

A monitor comprising a microcomputer for varying and outputting a vertical position signal under a user's control, and a vertical output IC and a deflection IC for GD compensation, And a correction means for varying the vertical position signal output from the micom according to the center of the screen displayed on the CRT, and then supplying the vertical position signal to the vertical output IC. The first differential amplifier of claim 1, wherein the correcting means comprises: a first differential amplifier in which a reference voltage when the center of the screen is located at the center of the CRT is provided as a negative input terminal and the position information of the screen is input to the positive input terminal; And a second differential amplifier configured to provide an output signal of the first differential amplifier to a negative input terminal, a vertical position signal to a positive input terminal, and an output signal to a vertical output IC. Distortion correction circuit.