KR0119362Y1 - The horizontal linear compensation circuit of multi synchronizing monitor - Google Patents

Abstract

The present invention relates to a circuit for correcting horizontal linearity in a multi-synchronous monitor. In particular, the present invention detects a change in a flyback transformer power that changes according to a horizontal frequency change, and corrects a deflection coil of a horizontal output circuit according to the detected signal level. The present invention relates to a horizontal linear correction circuit of a multi-synchronous monitor in which an inductance value is changed so that linear linearity correction can be performed at various horizontal frequencies.

The horizontal linear correction circuit of a conventional multi-sync monitor does not linearly correct as the horizontal frequency is high and low, and the output of the microcomputer becomes high or low at a specific frequency, causing a sudden and uneven correction. There is this.

In order to solve the conventional problem, the present invention detects a flyback transformer power supply level that changes according to a horizontal frequency through a resistor R11, and is proportional to the detected power supply level, and the operational amplifier A2 and the transistor Q11. By providing a linearly varying inductance value of the correction coil (L11 / L12) through a linear linear correction circuit of a multi-synchronous monitor to linearly correct the horizontal linearity.

Description

Horizontal Linear Correction Circuit in Multiple Sync Monitors

1 is a horizontal linear correction circuit diagram of a conventional multi-synchronous monitor

2 is a horizontal linear correction circuit diagram of a multi-synchronous monitor of the present invention.

(A), (b), and (c) of FIG. 3 show frequency versus voltage characteristics of the inventive circuit.

* Explanation of symbols for the main parts of the drawings

A1, A2: operational amplifier Q11, Q12: transistor

VR11: Variable resistance R11-R18: Resistance

L11, L12: Coil FBT: Flyback Trans

H-DY: Horizontal Deflection Yoke

The present invention relates to a circuit for correcting horizontal linearity in a multi-synchronous monitor. In particular, the present invention detects a change in a flyback transformer power that changes according to a horizontal frequency change, and corrects a deflection coil of a horizontal output circuit according to the detected signal level. The present invention relates to a horizontal linear correction circuit of a multi-synchronous monitor in which an inductance value is changed so that linear linearity correction can be performed at various horizontal frequencies.

As shown in FIG. 1, the horizontal linear correction circuit of a conventional multi-synchronous monitor is

A horizontal output transistor (Q2) for switching a flyback transformer (FBT), a horizontal deflection yoke (H-DY), a horizontal driving pulse to receive a deflection current through the horizontal deflection yoke (H-DY), and A linearity correction coil L1, L2 and a condenser C1-C3 connected in series to the horizontal deflection yoke H-DY, a microcomputer for outputting a high or low control signal according to a horizontal frequency, and the microcomputer The linearity correction coil L2 is used as a contact switch of the transistor Q1 that is turned on or off by receiving a control signal of the signal, the relay RL1 that is turned on or off by the transistor Q1, and the relay RL1. It consists of a relay switch (SW) for short-circuit or operation, and d1 and d2 are diodes, and + B1 and + B2 are power sources.

Looking at the conventional circuit operation configured as described above is as follows.

The microcomputer outputs a high or low control signal according to the horizontal frequency range. For example, when a high signal is output, the transistor Q1 is turned on by the high signal and the relay RL1 is operated to switch the switch SW. Contact bc is connected.

Therefore, at this time, the coil L2 is connected in series with the coil L1 to change the inductance value for linearity correction to L1 + L2.

On the other hand, when the low signal is output from the microcomputer, the transistor Q1 is turned off, so that the relay RL1 does not operate, and the contacts a-b of the relay switch SW are connected.

Therefore, at this time, both ends of the coil L2 are short-circuited and the inductance value for linearity correction is changed to L1.

As described above, by shorting or opening both ends of the linearity correction coil L2 in a specific horizontal frequency range, an appropriate current through the horizontal deflection yoke H-DY, coils L1 and L2, and capacitors C1-C3. The linearity as much as the inductance value that flows through is corrected.

However, such a conventional circuit has a problem in that the correction is not performed linearly as the horizontal frequency is high and low, and the output of the microcomputer becomes high or low at a specific frequency, thereby causing a sudden and uneven correction.

In order to solve the above-mentioned problems, the present invention detects a flyback transformer power level that varies according to a horizontal frequency, and linearly varies an inductance value of a correction coil in proportion to the detected power level. It aims to provide a horizontal linear correction circuit of a multi-synchronous monitor that can linearly correct horizontal linearity.

Hereinafter, with reference to the accompanying drawings, the circuit configuration of the present invention, the operation, and the effects thereof will be described.

First, referring to FIG. 2, the configuration of the horizontal linear correction circuit of the multi-synchronous monitor of the present invention will be described.

A horizontal deflection yoke through which a horizontal output transistor Q12 switched by a horizontal driving pulse, a flyback transformer FBT switched by the horizontal output transistor Q12, and a deflection current flow by the horizontal output transistor Q12. (H-DY), resistors R17 (R18) and variable resistor VR11 for dividing the power supply (+ B1) voltage and setting the voltage for offset adjustment, the offset voltage set by the variable resistor VR11. The operational amplifier A1 for amplifying and outputting the resistor; and the resistors R11-R13 for sensing by overlapping the power supply (+ B1) voltage and the power supply (+ B2) voltage which is changed according to the horizontal frequency. An operational amplifier A2 for receiving and amplifying the voltage superposed by R13 and the offset voltage amplified by the operational amplifier A1, and a current flowing in proportion to the output voltage level of the operational amplifier A2. The transistor Q11 and the transistor The current flows to the primary side by the stirrer Q11, and a current proportional to the primary side current is induced on the secondary side so that its inductance value is linearly changed, and is connected in series with the horizontal deflection yoke H-DY. A horizontal linear correction circuit of a multi-synchronous monitor, characterized by comprising coils L11 and L12 for correcting linearity.

In the figure, R14, R15 and R16 are resistors, D11 and D12 are diodes, and C11-C16 are capacitors.

The linearity correction operation by the horizontal linear correction circuit of the multi-synchronous monitor of the present invention configured as described above will be described with reference to FIGS. 2 and 3 (a), (b) and (c) as follows. same.

The power supply (+ B1) voltage is divided by the resistor (R17), the variable resistor (VR11), and the resistor (R18) and applied to the input terminal (+) of the operational amplifier A1 to be amplified. The operational amplifier A1 is a buffer. It works. The amplified voltage is applied to the input terminal (−) of the operational amplifier A2.

At this time, the output voltage of the operational amplifier A1 is changed according to the variation of the variable resistor VR11 as shown in FIG. 3A to vary the offset voltage of the operational amplifier A2.

On the other hand, the power supply (+ B2) of the flyback transformer is applied to the input terminal (+) of the operational amplifier (A2) through the resistor (R11), and the level of the power supply (+ B2) voltage is proportional to the horizontal frequency. .

Therefore, the voltage input through the resistor R11 and the voltage of the power supply + B1 divided and input by the resistors R12 and R13 overlap each other and are inputted to the input terminal (+) of the operational amplifier A2. The voltage level input to the circuit becomes a level proportional to the horizontal frequency as shown in FIG.

Since the operational amplifier A2 amplifies and outputs the input voltage, a voltage proportional to the horizontal frequency is applied to the base of the transistor Q11 as shown in FIG.

Therefore, the higher the horizontal frequency, the greater the amount of current flowing through the collector-emitter of transistor Q11, and the lower the horizontal frequency.

Therefore, a current having a magnitude proportional to the horizontal frequency also flows in the primary coil L11, and a voltage having a magnitude proportional to the horizontal frequency is induced in the secondary coil L12 in proportion to the horizontal deflection yoke (H-DY). The secondary coil (L12) connected in series to be able to perform a linear horizontal deflection correction.

At this time, the linearity at the lower frequency is adjusted by adjusting the offset voltage of the operational amplifier A2 in accordance with the variation of the variable resistor VR11 as shown in FIG.

As described above, in the horizontal linear correction circuit of the multi-synchronous monitor of the present invention, when the linearity is adjusted at the horizontal reference frequency, linear distortion correction is automatically performed according to the horizontal frequency variation, and the DC voltage is adjusted using the variable resistor. If only variable, the linearity adjustment is made, thereby improving the convenience of adjustment.

Claims (1)

A horizontal deflection yoke through which a horizontal output transistor Q12 switched by a horizontal driving pulse, a flyback transformer FBT switched by the horizontal output transistor Q12, and a deflection current flow by the horizontal output transistor Q12. In the video horizontal deflection output circuit including (H-DY), the resistors R17 and R18 and the variable resistor VR11 for dividing the power supply (+ B1) voltage and setting a voltage for offset adjustment are variable. An operational amplifier A1 for amplifying and outputting the offset voltage set by the resistor VR11 and a resistor R11− for sensing by overlapping the power supply (+ B1) voltage and the power supply (+ B2) voltage which varies depending on the horizontal frequency. R13), an operational amplifier A2 for receiving and amplifying the voltage sensed by being superimposed by the resistors R11 to R13 and the amplified offset voltage of the operational amplifier A1, and of the operational amplifier A2. In proportion to the output voltage level A current flows on the primary side by the transistor Q11 and the transistor Q11, and a current proportional to the primary side current is induced on the secondary side, and the inductance value is linearly changed, and the horizontal deflection is performed. A horizontal linear correction circuit of a multi-synchronous monitor, characterized in that it comprises a coil (L11) (L12) connected in series with the yoke (H-DY) to correct the linearity.