KR200143628Y1 - Horizontal size correction circuit of image displayer - Google Patents

Abstract

The present invention relates to a horizontal size correction circuit of an image display device. In particular, the horizontal size that changes according to the beam current size is set to the horizontal size control circuit by setting an upper limit and a lower limit through a variable range of the current sensing terminal of the flyback transformer. By feeding back, the horizontal size that changes according to the beam current is uniformly compensated. Conventionally, when the user adjusts the screen contrast and brightness, the beam current supplied to the CRT is minimized when the contrast and brightness are minimum, and the high pressure is horizontal. When the size is reduced, and the contrast and brightness are maximized, the beam current is much reduced, and the high pressure is reduced, thereby increasing the horizontal size.

In order to solve such a conventional problem, the present invention sets an upper limit and a lower limit through the variable range of the current sensing terminal of the flyback transformer to change the horizontal size, which changes according to the beam current size, and feeds it back to the horizontal size control circuit. Therefore, it is applied to the screen display device by adjusting the horizontal size to be changed constantly.

Description

Horizontal Size Correction Circuit of Image Display

The present invention relates to a horizontal size correction circuit. In particular, the horizontal size that changes according to the size of the beam current is set to the upper limit and the lower limit through the variable range of the current sensing terminal of the flyback transformer to feed back to the horizontal size control circuit. The horizontal size changes according to the constant correction.

In the conventional horizontal size correction circuit diagram, as shown in FIG. 1, a parabolic waveform is received by receiving a vertical drive signal a input through a resistor R1 and a vertical synchronization signal b input through a deflection coil DY. the first variable resistor (VR1) and the second amplifier (2) for adjusting the side pin cushion of the parabola waveform amplified and output from the first amplifier (1) for amplifying and outputting (c). The transistor Q1 is controlled by receiving a second variable resistor VR2 for determining the supplied DC level, a signal output from the first variable resistor VR1 and a DC level determined by the second variable resistor VR2. A low pass filter unit connected to the second amplifier 2, the transistor Q2 switched by the horizontal drive transformer 3, and the collector of the transistor Q2 to filter the signal output from the transistor Q2. (4), and the primary side is connected to the low pass filter unit 4, the anode, poker on the secondary side A flyback transformer (FBT) for adjusting a screen and a screen, a horizontal deflection coil (HDY) connected between the low pass filter unit (4) and the primary side of the flyback transformer (FBT) for detecting a horizontal deflection current; It consists of a coil L1 which transfers the horizontal deflection current detected by the horizontal deflection coil HDY to the emitter of the transistor Q2 controlled by the second amplifier 2, wherein reference numerals R2-R5 are resistors, C1-C4 is a capacitor, D1, D2 is a diode.

In the conventional horizontal size correction circuit configured as described above, as shown in FIG. 1, first, the non-inverting terminal of the first amplifier 1 is connected to the vertical driving signal a through the resistor R1 as shown in FIG. (B) is inputted to the inverting terminal (-) of the first amplifier 1 as shown in (b) of FIG. 2 through the deflection coil DY. When the parabolic waveform (c) is output from the first amplifier 1 as described above, when the output parabolic waveform is distorted left and right, the first variable resistance VR1 is adjusted to adjust the side pin cushion of the parabola waveform.

When the left and right distortion of the parabola waveform is adjusted and output by the first variable resistor VR1, the capacitor C1 removes the DC component and applies only the AC component to the non-inverting terminal (+) of the second amplifier 2.

On the other hand, under the control of the horizontal drive transformer 3, the waveform e of about 1 KV as shown in FIG. 2E is filtered through the low pass filter unit 4 to the collector of the transistor Q1, and the horizontal deflection coil is filtered. When supplied to the primary side of the (HDY) and the flyback transformer (FBT), the horizontal deflection coil (HDY) at the same time the deflection side of the horizontal deflection coil (F) is supplied with a waveform (f) of about 120V as shown in (f) of FIG. The DC voltage g is supplied to the emitter of the transistor Q1 controlled by the second amplifier 2 as shown in FIG. 2 (g) via the coil L1 connected to the deflection side of the coil HDY.

Therefore, when the voltage of the AC component from which the DC component is removed is applied to the non-inverting terminal (+), the second amplifier 2 receives the DC level supplied to the inverting terminal (-) by the second variable resistor VR2. Since the determined DC level is supplied, the second amplifier 2 amplifies the non-inverting input waveform by the resistors R4 and R5 and outputs the waveform d as shown in (d) of FIG. Supply to the base of).

That is, when the DC level determined by the second variable resistor VR2 is low, the voltage supplied to the base of the transistor Q1 is low, so that a large amount of current is supplied to the emitter of the transistor Q1, thereby increasing the amount of correction of the left and right distortion of the screen. When the determined DC level is high, the voltage supplied to the base of the transistor Q1 is high, so that a small current is supplied to the emitter of the transistor Q1, thereby reducing the amount of distortion of the screen left and right.

However, in the related art, when a high voltage is displayed on a CRT such as black, white, and black, the high pressure supplied to the anode cap is changed depending on black and white, and thus black, white, and black. When the signal is displayed on the CRT, the high voltage is temporarily reduced in the area where white signals are carried during the vertical scanning period, the horizontal size increases, and the distortion occurs on the left and right sides of the screen. Also, when the user adjusts the screen contrast and brightness, As the gain changes, the high pressure fluctuates and the horizontal size changes.

In other words, when the contrast and brightness are minimum, the beam current supplied to the CRT is minimized and the high pressure is increased, thereby reducing the horizontal size. When the contrast and brightness are maximized, the beam current flows a lot and the horizontal size is increased because the beam current flows a lot. .

In order to solve such a conventional problem, the present invention sets the upper and lower limits through the variable range of the current sensing terminal of the flyback transformer to change the horizontal size, which is changed according to the size of the beam current, and feeds it back to the horizontal size control circuit. Therefore, the purpose of adjusting the horizontal size to be changed constantly to explain the configuration and effect of the present invention by the accompanying drawings as follows.

1 is a conventional horizontal size correction circuit.

2A to 2G are waveform diagrams of respective parts of a conventional horizontal size correction circuit.

3 is a horizontal size correction circuit of the present invention.

4 is a flyback transformer voltage output waveform diagram of the horizontal size correction circuit of the present invention.

* Explanation of symbols for main parts of the drawings

11: flyback transformer 12: horizontal size control unit

13: upper limit setting unit 14: lower limit setting unit

First, as shown in FIG. 3, the horizontal size correction circuit of the present invention has a high voltage induced by the transistor Q11 that is turned on / off in response to the horizontal drive signal Vi and the transistor Q11 is turned on or off. An upper limit setting unit 13 connected to the flyback transformer 11 and the beam sensing terminal bs of the flyback transformer 11 to set an upper limit of the beam current fed back to the horizontal size control unit 12; A horizontal size in a range set when a horizontal size control signal is input by feeding back a change in beam current set by the lower limit line setting unit 14 and the upper limit line setting unit 13 and the lower limit line setting unit 14 to set the lower limit line of the beam current; A horizontal size control unit 12 for correcting and outputting the control unit, and a contrast control unit 15 for adjusting the screen contrast, wherein R11-R17 is a resistor, D11-D13 is a diode, and C11-C13 is a capacitor. ZD11 is the first A diode, a variable resistor VR11 is, Q12 is a transistor.

As shown in FIG. 3, when the horizontal driving signal Vi is input, the transistor Q11 is turned on / off and high voltage is induced in the flyback transformer 11. In the beam sensing terminal bs of the flyback transformer 11, unlike the conventional wide variable range OV-VC, the upper limit V _A of the beam current set by the upper limit setting unit 13 and the lower limit setting unit 14 is determined. The lower limit line V _B is sensed and applied to the horizontal size control unit 12.

That is, when the screen contrast is adjusted through the variable resistor VR11 in the contrast control unit 15 when the horizontal drive signal Vi is input, the beam current supplied to the CRT is minimized when the screen contrast is minimum, and the screen contrast is reduced. Since the beam current supplied to the CRT at the maximum becomes the maximum, the current set by the upper limit setting unit 13 and the lower limit setting unit 14 for detecting the change in the beam current is sensed and fed back to the horizontal size control unit 12. The horizontal size control unit 12 corrects and outputs the horizontal size control signal uniformly between the upper and lower limit lines of the fed back beam current.

As described above, the horizontal size that changes according to the beam current is fed back to the horizontal size control circuit by setting the upper and lower limits through the variable range of the current sensing terminal of the flyback transformer. By making constant correction, the reliability of the product is improved.

Claims (1)

A horizontal size correction circuit including a flyback transformer for switching high voltage to a secondary side by switching in response to a horizontal drive signal input, wherein the beam current fed back when feeding back a beam current detected from the flyback transformer to a horizontal size control unit An upper limit setting unit for setting an upper limit of the lower limit unit, a lower limit setting unit for setting a lower limit of the beam current fed back when the beam current detected from the flyback transformer is fed back to the horizontal size control unit, and the upper limit setting unit and the lower limit setting unit And a horizontal size control unit for correcting and outputting the horizontal size in a range set when the horizontal size control signal is input in response to a change in the beam current fed back by the horizontal current control.