KR930000855Y1 - Deflection yoke - Google Patents

Abstract

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Description

Horizontal Formation Control Circuit

1 is a conventional horizontal deflection drive circuit diagram.

2 is a waveform diagram of each part of a conventional horizontal deflection driving circuit.

3 is a screen state diagram of a conventional horizontal deflection drive circuit.

4 is a horizontal line forming adjustment circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

100: signal transmission unit 200: horizontal output unit

300: control means Q1 to Qn: transistor

C1 to Cn: capacitor D1: diode

T1: transformer R1: resistance

VR1: Variable resistor A / D: A / D converter

VL1: Horizontally formed asymmetric adjustment coil HL: Horizontal deflection coil

The present invention relates to a horizontal deflection driving circuit, and more particularly, to a horizontal line formation adjusting circuit capable of controlling the linearity of horizontal scanning according to the frequency of the horizontal synchronizing signal applied to the horizontal deflection driving circuit.

In general, a display monitor or a multi-frequency monitor for a computer or the like applies a horizontal oscillation wave to a horizontal deflection oak to control the horizontal deflection of the scan line scanned on the monitor.

1 is a conventional horizontal deflection driving circuit. When the horizontal oscillation wave signal HD is applied to the horizontal driving transistor Q1, the transistor Q1 is driven when the horizontal oscillation wave signal HD is at a high level. As the voltage VCC is induced to the horizontal output transformer T1, the horizontal output transistor Q2 is turned on.

As the transistor Q2 is driven, a current is applied to the horizontal deflection coil HL so that the horizontal deflection coil HL controls the horizontal deflection of the scan line.

At this time, a strong electric vibration is generated due to the resonance frequency of the magnetic deflection coil L 'and the capacitance C' of the horizontal deflection coil HL, but the waveform is disturbed, but the damper diode D1 And the condenser C1 prevent the occurrence of such vibration.

At this time, the waveform of the current flowing in the horizontal deflection coil HL rises during the horizontal deflection period t1 and falls during the horizontal retrace period t2 as in the pulse P1 of FIG. However, since the cathode ray tube is a curved surface rather than a planar state, a horizontal line formed by the horizontal deflection coil HL is not purified, and a distorted state is displayed as shown in FIG.

In order to improve the screen of the distorted state, the capacitor C2 is connected to the horizontal deflection coil HL in series to adjust the capacitance of the horizontal deflection coil HL to be output from the horizontal deflection coil HL. By changing the triangular wave into an S-shape like the pulse P2 of FIG. 2, it is possible to correct the distortion generated on the screen to some extent.

However, even in this case, an inductance value of the horizontal deflection coil HL may be asymmetrical in the S-shaped current waveform according to the curvature of the cathode ray tube, such as pulse P3. This may be displayed distorted.

Accordingly, in order to prevent distortion caused by curvature of the cathode ray tube due to the frequency of the horizontal oscillation wave signal HD applied to the deflection oak driving circuit, the S correction capacitor C2 is applied to the horizontal deflection coil HL. On the other hand, by connecting a horizontal forming asymmetric adjusting coil (VL) to the S correction capacitor (C2) to correct the asymmetry, and converts the triangular wave of the horizontal deflection coil (HL) to the S-shaped to obtain a clear picture quality Was.

In this case, in the case of the multi-mode monitor, since the horizontal oscillation wave signal HD is applied at a frequency of several bands, the S correction capacitor C2 is configured as a variable capacitor to the frequency of the horizontal oscillation wave signal HD applied. Accordingly, by adjusting the open and close capacitance value of the variable capacitor, it is possible to prevent distortion on the screen caused by the curvature of the cathode ray tube.

However, such a variable capacitor has not been used because of its large volume and very high price.

Therefore, in the current multi-mode monitor, the asymmetry problem of linearity is solved by a variable coil, but the S correction capacitor cannot convert the triangular wave output from the horizontal deflection coil (HL) into a purified S wave according to a frequency variable according to the mode. There was a problem that the screen is distorted.

The object of the present invention is to solve this problem, and the purpose of the scheme is to connect a plurality of capacitors in parallel to the S correction capacitor and to drive the capacitor according to the horizontal oscillation wave applied to the deflection yoke driving circuit. It is an object of the present invention to provide a horizontal line forming adjustment circuit that can always display a clear image even if is applied.

A feature of this invention for achieving this object is a signal transmission unit for transmitting a horizontal oscillation wave signal to be applied, and a horizontal scanning deflection in accordance with the horizontal oscillation wave signal applied from the signal transmission unit connected to the signal transmission unit A horizontal deflection circuit having a horizontal output unit for controlling, comprising: control means for controlling deflection of the horizontal output unit according to a voltage applied to the horizontal output unit, and a funnel control signal connected to the control unit; A horizontal line adjustment circuit having an A / D converter for applying a and a variable resistor connected to the A / D converter for varying the analog signal applied to the A / D converter.

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

4 is a horizontal line adjustment circuit diagram according to Io, which is composed of a signal transmission unit 100, a horizontal output unit 200, a control unit 300, an A / D converter (A / D), and a variable resistor VR1. The signal transmission unit 100 and the horizontal output unit 200 are configured in the same manner as in the prior art.

In more detail, the signal transmission unit 100 for transmitting the applied horizontal oscillation wave signal HD may be a horizontal driving transistor Q1 and a transformer T1 connected to the collector side of the transistor Q1, so that the transistor When Q1 is driven, the voltage VCC1 is induced to be induced in the transformer T1.

The horizontal output unit 200 for controlling the deflection of the horizontal scan according to the horizontal oscillation wave signal applied from the signal transmission unit 100 connects a horizontal output transistor Q2 to the transformer T1, and the transistor Q2. It is made by connecting the damper diode (D10) and the capacitor (C1) to the collector side.

The horizontal output unit 200 connects a horizontal deflection coil HL to the condenser C1 in parallel, and horizontally asymmetric coil VL1 that can be variably adjusted in series with the horizontal deflection coil HL. Connect S correction capacitor (C2).

The control means 300 for controlling the horizontal output unit 200 is connected to a plurality of capacitors (C3, C4, ... Cn) in parallel to the capacitor (C2) of the horizontal output unit 200, the condenser ( A plurality of transistors Q3, Q4, Qn are connected to C3, C4, Cn, and the capacitors C3, C4, Qn are driven when the transistors Q3, Q4, Qn are driven. The switching capacitance of the S correction capacitor C2 applied to the horizontal deflection coil HL is changed by Cn, and the collector side of the transistors Q3, Q4, Qn is the capacitor C3. , C4, ... Cn), respectively, and the emitter side is grounded.

The transistors Q3, Q4, ... Qn of the control means 300 connect the base side to the output terminals A1, A2, ... An-2 of the A / D converter A / D. The driving of the transistors Q3, Q4, ... Qn is controlled in accordance with the A / D converter A / D output.

And the A / D converter (A / D) is made to control the output of the A / D converter (A / D) according to the customer's wish by connecting the variable resistor (VR1) to the input terminal (DATA) ; Unexplained symbol R1 is a resistor.

In this scheme, the horizontal oscillation signal HD is applied to the horizontal output unit 200 through the signal transmission unit 100, so that the horizontal deflection coil HL outputs a triangular wave like the pulse P1 of FIG. However, the S-correction capacitor C2 converts the triangular wave into an S-shape like the pulse P2 to deflect the scan according to the curvature of the cathode ray tube.

At this time, the asymmetry of the S-shaped pulse is adjusted by adjusting the horizontally formed asymmetric coil VL1 to prevent distortion of the screen caused by the asymmetry.

At this time, when the frequency of the horizontal oscillation wave signal HD applied to the signal transmission unit 100 is single, the S correction capacitor C2 has an S-shape to match the triangular wave of the horizontal deflection coil HL to the curvature of the cathode ray tube. The impedance is determined to convert to.

Therefore, when the frequency of the horizontal oscillation wave signal HD applied on the multi-mode monitor is different, the S correction capacitor C2 does not convert the horizontal oscillation wave signal HD to the S-shape exactly to fit the cathode ray tube. Distortion of the displayed image occurs.

However, this invention applies to the horizontal deflection coil HL by controlling the output of the A / D converter A / D by adjusting the variable resistor VR1 configured in the A / D converter A / D. By varying the capacitance, the triangular wave of the horizontal deflection coil HL is exactly converted to the S-type pulse required by the cathode ray tube according to the frequency of the horizontal oscillation wave signal HD applied.

That is, when the consumer adjusts the variable resistor VR1 to output the high level only to the terminal A1 of the A / D converter A / D, the consumer drives the transistor Q3 connected to the terminal A1. The capacitor C3 and the S correction capacitor C2 are in a parallel state, and the capacitance value applied to the horizontal deflection coil HL becomes (C2 + C3) so that the horizontal deflection coil HL appropriately applies the triangular pulse applied thereto. Will be converted to S pulses.

As the consumer adjusts the variable resistor VR1 of the A / D converter A / D, the A / D converter A / D outputs the data shown in Table 1.

That is, by adjusting the variable resistance VR1 of the A / D converter A / D, the capacitance value of the horizontal deflection coil HL is possible to adjust the horizontal deflection in accordance with the applied horizontal oscillation signal HD. The triangular wave of the coil HL can be changed into an S-shaped pulse. In Table 1, 0 denotes a low level and 1 denotes a high level in columns A0, A1, ..., An-2. At this time, the capacitor value of the control means 300 is applied to the horizontal deflection coil HL by setting the capacitor value according to the capacitors C3, C4, ..., Cn driven by the phase A / D converters A / D. The total capacitance value can be changed linearly. That is, the voltage applied to the capacitors C3, C4, ... Cn when the capacitance value is configured as Cn = 2 ^n-1 , such as C3 = 1, C4 = 2, C5 = 4, C6 = 8 ... ... The capacitance by the control means is changed as shown in Table 2.

As such, this design connects multiple capacitors in parallel to the S compensation capacitor. In order to convert the pulse of the horizontal deflection coil into the correct S-shaped pulse according to the frequency of the applied horizontal oscillation wave signal without using a variable capacitor by controlling the capacitor by an A / D converter operated under the control of the consumer. This has the effect of converting the required capacitance value.

Claims (2)

Horizontal scanning according to the horizontal oscillation signal HD applied from the signal transmission unit 100 and the signal transmission unit 100 and the signal transmission unit 100 which transmits the applied horizontal oscillation signal HD. In the horizontal deflection circuit having a horizontal output unit 200 for controlling the deflection of the control means for controlling the deflection of the horizontal output unit 200 in accordance with the voltage applied to the horizontal output unit 200 ( 300 and an A / D converter (A / D) connected to the control means 300 to apply a deflection control signal to the control means 300 and the A / D converter (A / D). A horizontal forming adjustment circuit having a variable resistor (VR1) for varying an analog signal applied to the A / D converter (A / D). According to claim 1, wherein the control means 300 is connected to the S correction capacitor (C2) of the horizontal output unit 200 in parallel with a plurality of condensers for controlling the horizontal scanning linearity of the horizontal output unit 200 ( The collector side is connected to C3, C4, ... Cn, and the capacitors C3, C4, ... Cn, and the base side is connected to the A / D converter (A / D). A horizontal formation adjustment circuit comprising a plurality of transistors (Q3, Q4, ... Qn) for controlling the driving of the capacitors (C3, C4, ... Cn) in accordance with the output of A / D).