KR920001192B1 - Automatic horizoutal s compensating control circuit - Google Patents

Abstract

The horizontal S compensation for multi-sync. monitor is automatically executed by varying power supplied. The circuit comprises a signal generator (10) for detecting and synchronizing horizontal synchronous signal to generate horizontal drive signal, a rectifier and feed back unit (20) for rectifying the horizontal drive signal for generating feedback voltage and feedback horizontal synchronous signal, a S-compensation modulator (30) for modulating the feedback voltage and the feedback synchronous signal, a S-compensation signal generator (40) for generating the S- compensating signal using the output signal of the S- compensation modulator (30), a horizontal drive signal generator (50) for transmitting the horizontal drive signal by the output signal of the generator (40), and a S-compensation unit (60) for overlapping the S-compensating signal and the horizontal drive signal to execute S-compensation.

Description

Automatic horizontal S correction control circuit by feedback

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

3 is a waveform diagram of a circuit according to the present invention;

4 is a circuit diagram of an embodiment according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: horizontal oscillation and dry section 20: rectification and feedback section

30: S correction modulator 40: S correction output unit

50: horizontal output unit 60: S complement

The present invention relates to a multi-sync monitor for high resolution, and more particularly, to a circuit capable of automatically adjusting horizontal S correction by feedback.

In the conventional multi-sink monitor, the S correction circuit places several S correction 1-3 capacitors 1-3 for each horizontal frequency band at 10 KHz, 20 KHz, and 30 KHz. Therefore, the horizontal frequency synchronization signal is sensed by the auto frequency sensing circuit 2 through the horizontal output stage 1 and connected to a manual or automatic switch SW1, so that the S-3 correction capacitor 1-1 is used. Among 3), the mode suitable for the frequency band is selected. When the S correction capacitor is provided for each horizontal frequency, the S correction circuit in the high resolution multi-sink monitor covering the horizontal frequency of 60KHz becomes too complicated and there is a problem in that fine adjustment is not possible.

Accordingly, an object of the present invention is to provide an automatic horizontal S correction control circuit by a feedback capable of automatically adjusting the horizontal S correction by varying the supply power in the monitor for a multi-sink.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 2 is a circuit diagram of the present invention, in which the horizontal oscillation and drive unit 10 for sensing and synchronizing the horizontal synchronization signal HS1 and the output signal of the horizontal oscillation and drive unit 10 are rectified and rectified to receive a frequency range. A rectification and feedback unit 20 for adjusting and generating a feedback voltage VfB and a feedback horizontal synchronization signal HfB, and a feedback voltage VfB and a feedback horizontal synchronization signal HfB outputted from the rectification and feedback unit 20. The S correction modulator 30 for modulating s), the S correction output unit 40 for generating a suitable S correction output signal from the output signal of the S correction modulator 30, and the horizontal oscillation and drive unit 10. A horizontal output unit 50 for outputting a horizontal synchronization signal by inputting an output signal of the output signal of the horizontal output unit 50 and an output signal of the S correction output unit 40 overlaps a desired S correction signal. It consists of the S correction part 60 which outputs.

3 is a waveform diagram of a circuit according to the present invention, FIG. 3a is a fundamental waveform, FIG. 3b is a harmonic waveform, and FIG. 3c is a waveform rectified horizontally by an S correction capacitor, and FIG. 3d is an S correction output section 40 ) Is a waveform in which the output signal of "

4 is a circuit diagram of an embodiment of a circuit according to the present invention, which includes rectification and feedback consisting of a horizontal oscillation and drive unit 10 and capacitors C1-C3 and a resistor R2 connected to the horizontal oscillation and drive unit 10. The unit 20, the S correction modulator 30 connected to the rectifying and feedback unit 20, the resistors R1 and R3 and the transistors Q1 and T1 connected to the S correction modulator 30, respectively. A horizontal output unit (50) consisting of an S correction output unit (40) consisting of the horizontal oscillation and the transistor (Q2) connected to the drive unit (10), the horizontal output unit (50) and the S correction output unit Comprising an S (60) consisting of a resistor (R4) and a capacitor (C4) and diode (D1) and a horizontal deflection coil (HDY) connected to the (40).

Based on the above configuration, the present invention will be described in detail with reference to FIGS. 2-4. First, the horizontal synchronization signal HS1 input from the computer is detected by the horizontal oscillation and the drive unit 10 and then synchronized. The output signal of the horizontal oscillation and drive unit 10 is applied to the rectification and feedback unit 20 and the horizontal output unit 50 so that the feedback voltage VgB and the feedback horizontal synchronous signal ( HfB) is generated and applied to the S correction modulator 30. The S correction modulator 30 modulates an input signal to form an appropriate S correction output waveform in the S correction output unit 40 as in the 3c wave form, and applies the waveform through the waveform and the horizontal output unit 50. The output signal is overlapped with the S correction unit 60. The signal superimposed by the S correction unit 60 obtains a desired S correction waveform like the 3d wave form. Thus, the S correction waveform of any horizontal stage is described below. In the CRT monitor, the distance between the center of CRT and the outer tube of the electron gun is different, that is, the distance of the outer edge is longer than the center. Therefore, when the horizontal current flows only with the dotted line wave like the 3c wave form, the distortion of the screen is generated. The basic wave component of the wave form 3a is the current in the form of a solid line of the 3c wave form using the S correction capacitor. Create a waveform. However, in the multi-sync monitor, when the S correction is performed using only the S correction capacitor, the circuit becomes complicated and inaccurate, so that the S correction is performed as in the present invention, thereby obtaining the 3d wave form. In the waveform of FIG. 3d, (a) the curve is used for component synthesis with reduced fundamental wave, and the power of CRT is used for small or small size CRT, and (b) the curve is used for component synthesis emphasizing fundamental wave. This waveform is S-corrected when using a large or large size VRT. As shown in FIG. 4, an example of the present invention will be described below.

First, the horizontal synchronizing signal HSI through the horizontal oscillation and the drive unit 10 uses the DC voltage rectified by the rectifying capacitors C1 and C2 as the feedback voltage VfB of the S correction modulator 30, and the horizontal oscillation. And a horizontal synchronous signal in which a signal through the drive unit 10 is DC-blocked from the capacitor C3, is used as the feedback horizontal synchronous signal HfB.

When the signal through the S correction modulator 30 is applied to the transistor Q1 through the resistor R3 and the transistor Q1 is turned on, the supply power B + is the transformer T1 through the resistor R1. It is applied to the ground and grounded. Then, the current is induced to the secondary side of the transformer T1, and the current-amplified S correction waveform is applied to the transistor Q2 collector terminal through the resistor R4. The transistor Q2 is turned on and the output signal of the horizontal oscillation and drive unit 10 is horizontal to the S correction signal applied from the transformer T1 through a horizontal resonant capacitor C4 and a damping diode D1. In the deflection coil HDY, the S correction waveform is formed.

As described above, when the monitor needs to cover various frequencies such as multi-sync, it is possible to automatically adjust the horizontal S correction by varying the power supply, so the circuit configuration is simple and the S correction waveform is precisely adjusted for each frequency band. There is an advantage to this.

Claims (1)

In the horizontal S correction control circuit, the horizontal oscillation and drive unit 10 for detecting and synchronizing the horizontal synchronous signal and outputting the horizontal drive signal, and receiving and rectifying the horizontal drive signal to generate a feedback voltage and a feedback horizontal synchronous signal. Rectification and feedback section 20, S correction modulator 30 for modulating the feedback voltage and the feedback horizontal synchronization signal output from the rectification and feedback section 20, and the output signal of the S correction modulator 30 Receives the S correction output unit 40 for generating the S correction output signal and the horizontal drive signal of the horizontal oscillation and drive unit 10 by inputting the horizontal drive signal by the output signal of the S correction output unit 40 A horizontal output unit 50 for outputting, an output signal of the horizontal output unit 50 and the output signal of the S correction output unit 40 by overlapping the S correction unit 60 for outputting the S correction signal Characterized by Automatic horizontal S correction control circuit by feedback.

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