KR0113917Y1 - Horizontal laster centering circuit - Google Patents

Abstract

The present invention relates to a horizontal raster centering circuit that adjusts the centering of a horizontal raster in a multi-synchronous monitor having a variety of horizontal frequencies. In particular, in a circuit in which a high voltage generator and a horizontal deflector are separated, a horizontal This invention relates to a horizontal raster centering circuit that receives a raster centering adjustment voltage from a high voltage generator and minimizes a change range of the adjustment voltage due to a horizontal frequency change.

In the conventional horizontal raster centering circuit, since the horizontal deflection portion 2 having a short retrace period wound the winding for the power supply of the raster centering portion 1 on the secondary side of the dummy flyback transformer 3, the positive (+ ) And negative pulse width or shorter, and this change is severely changed by the change of the horizontal frequency, so the ripple becomes large when rectified and smoothed, and the positional deviation of the raster increases according to the horizontal frequency. Problems are brought about, and this problem not only brings inconvenience of centering adjustment of the horizontal raster, but also causes problems that make accurate centering adjustment difficult.

The present invention does not receive the power for the centering adjustment of the horizontal raster in the horizontal deflection portion (2), the centering portion (1) is received by the centering portion (1) in the high-pressure generating unit (4) with a relatively long return period, thereby performing horizontal adjustment This minimizes the centering adjustment variation due to the frequency variation, so that the horizontal raster centering adjustment work can be conveniently and reliably performed.

Description

Horizontal Raster Centering Circuit

1 is a circuit diagram of a conventional horizontal raster centering circuit.

2a and 2b are signal waveform diagrams of a conventional horizontal raster centering circuit.

3 is a circuit diagram of a horizontal raster centering circuit of the present invention.

4a, b is a signal waveform diagram of a horizontal raster centering circuit of the present invention.

* Explanation of symbols for main parts of the drawings

1 horizontal raster centering part 2 horizontal leveling part

3: dummy flyback transformer 4: high pressure generator

FBT: High Pressure Generated Flyback Trans

The present invention relates to a horizontal raster centering circuit that adjusts the centering of a horizontal raster in a multi-synchronous monitor having various horizontal frequencies, particularly in a circuit in which a high voltage generator and a horizontal deflector are separated from each other. This invention relates to a horizontal raster centering circuit that receives a raster centering adjustment voltage from a high voltage generator and minimizes a change range of the adjustment voltage due to a horizontal frequency change.

In the multi-synchronous monitor operating with various horizontal frequencies (f _H = 30kHZ-100kHZ), the high voltage generator and the horizontal deflection are separated, and the horizontal raster changes on the screen according to the horizontal frequency fluctuation so A circuit is provided. In the conventional horizontal raster centering circuit, as shown in FIG. 1, the dummy flyback driven by the horizontal deflecting unit 2 drives the centering adjustment power of the horizontal raster centering unit 1. It is obtained from the secondary winding of the transformer (3).

That is, the collector of the switching transistor Q1 of the horizontal deflection portion 2 driven by the horizontal driving pulse is connected to the primary winding of the dummy flyback transformer 3 so as to be switched, and the dummy flyback transformer 3 The diode (D2) and the condenser are composed of the diode (D1) and the capacitor (C1), respectively, on the middle tap of the secondary winding and the positive and negative pulse output taps. (C2) constitutes a negative rectifying circuit, and adjusts the bias of the transistors Q2 and Q3 and the transistor Q2 and Q3 which are turned on or off by the power supplied from the respective rectifying circuits. A variable resistor VR1 is connected between the rectifier circuit and the transistors Q2 and Q3. A positive power supply or a negative power is supplied as the transistor Q2 or the transistor Q3 is turned on and off. Even if the power is applied to the S-shaped correction capacitor Cs of the horizontal deflection section 2 to change the DC level, the raster is adjusted. It was constructed.

In FIG. 1, R1-R5 is a resistor, L1 is a choke coil, 2a is a horizontal linearity correction coil, 2b is a horizontal resonant capacitor, 2c is a horizontal resonant damper ion, and DY is a horizontal deflection coil.

Looking at the operation of the conventional horizontal raster centering circuit of the above configuration as follows.

When the horizontal driving pulse is applied to the base of the switching transistor Q1 of the horizontal deflection portion 2, the transistor Q1 is switched on and off by the horizontal driving pulse, and the resonant capacitor 2b and the damper ion at the collector stage thereof. The horizontal deflection current flows through the horizontal deflection coil DY by the switching action with 2c. At this time, the secondary side of the dummy flyback transformer 3 is switched by the switching transistor Q1. Positive and negative pulses are output as waveforms as shown in (a) and (b) of FIG.

The positive pulse is rectified by the resistor R1 and the diode D1 and the capacitor C1, and the negative pulse is rectified by the resistor R2, the diode D2 and the capacitor C2. The rectified power is divided by the resistor R3, the variable resistor VR1, and the resistor R4 to be biased by the transistors Q2 and Q3.

At this time, when the variable resistor VR1 is adjusted toward the resistor R3, the bias of the transistor Q2 increases, so that the transistor Q2 is turned on and the transistor Q3 is turned off, so that a positive power supply voltage is connected to the resistor R5. Since the DC bias level is increased by being applied to the condenser Cs of the horizontal deflection portion 2 through the choke coil L1, the horizontal raster by the deflection coil DY moves to the left side of the screen.

However, when the variable resistor VR1 is adjusted toward the resistor R4, the virus of the transistor Q3 increases, so that the transistor Q3 is turned on and the transistor Q2 is turned off, so that the negative power supply voltage is the resistor R5. And the choke coil (L1) is applied to the capacitor (Cs) of the horizontal deflection portion 2 to reduce the DC bias level, so the horizontal raster by the deflection coil (DY) is moved to the right side of the screen.

In this way, the centering of the horizontal raster is adjusted. In this case, a multi-synchronous monitor having a wide horizontal frequency range has a short return period because the horizontal deflection must be compatible with computer signals having various timings at various frequencies. It is necessary to design a margin between the raster and the effective data (video signal period), so design the retrace time of the horizontal deflection section as short as possible (e.g. tr = 2.5μsec) The return period of the high-voltage generator should be designed longer than the horizontal deflection section 2 because the period between the collector and the emitter of the switching transistor Q1 must be lowered to make the transistor wider than the horizontal deflection section. (E.g. tr = 4μsec -5μsec).

However, as described above, when the winding for the power supply of the raster centering part 1 is wound on the secondary side of the dummy flyback transformer 3 of the horizontal deflection part 2 having a short return period, the positive and negative outputs are output here. The pulse width of (-) is also shortened, and this change becomes severe as the horizontal frequency changes, so the ripple becomes large when rectified and smoothed, causing the positional deviation of the raster to increase according to the horizontal frequency. In addition, this problem not only brings inconvenience to the centering adjustment of the horizontal raster, but also causes a problem of making accurate centering adjustment difficult.

For example, as shown in (a) of FIG. 2, when the horizontal frequency (f _H = 31.5 kHz), the voltage average value (for example, 8 V) across the capacitor C1 is lowered due to the large ripple. When the frequency (f _H = 81.3kHz), the average voltage (eg 9V) across the capacitor (C1) is higher than when the horizontal frequency is low, and the variation of the centering adjustment voltage value increases according to the horizontal frequency.

The present invention solves the above-mentioned problems by performing the centering adjustment by receiving the power for the centering adjustment of the horizontal last from the horizontal deflection portion, and receiving it from the high-pressure generator having a relatively long return period, thereby solving the horizontal problem as described above. The purpose of the present invention is to provide convenience and reliability in minimizing the adjustment of horizontal raster centering by minimizing the deviation of the centering adjustment due to the variation of the present invention. Hereinafter, the configuration of the present invention will be described with reference to FIGS. The following describes the effects and effects.

First, referring to FIG. 3, the horizontal raster centering circuit of the present invention receives positive and negative pulses from the secondary winding of the high-pressure generating flyback transformer (FBT) of the high-pressure generating unit 4. A horizontal raster centering unit 1 for applying a raster adjustment voltage to the horizontal deflection unit 2 by rectifying and smoothing it, and a positive (+) or negative portion (+) supplied from the horizontal raster centering unit 1. It was composed of a horizontal deflection portion 2 in which raster centering is adjusted by applying a voltage of-), and a high pressure generator 4 supplying a high voltage power to the horizontal raster centering portion 1.

That is, the primary-side winding of the high-pressure generating flyback transformer (FBT) of the high-pressure generating unit 4 is configured to be switched by the transistor Q4, and the horizontal tap power source of the secondary tap of the secondary-side winding of the high-pressure generating flyback transformer (FBT) is switched. When positive and negative pulses are output based on the middle tap of the secondary winding of the high-pressure generating flyback transformer (FBT), the positive and negative pulses are rectified and smoothed. A diode D1 and a capacitor C1 are connected to each other, a diode D2 and a capacitor C2 for rectifying and smoothing a negative pulse are connected to each other. A transistor (D2) for rectifying and smoothing the positive and negative pulses and a variable resistor (VR1) for dividing the negative rectified voltage, and connected by the variable resistor (VR1). Q2) and Q3 are connected to the S-shaped correction capacitor Cs of the horizontal deflection portion 2 so that raster centering adjustment is performed.

In FIG. 3, reference numeral 3 denotes a dummy flyback transformer, R1-R5 is a resistor, L-1 is a choke coil, DY is a horizontal deflection coil, 2a is a linearity correction coil, 2b is a deflection resonant capacitor, 2c is a deflector damper diode, Q1 is a deflector switching transistor, 4a is a dummy horizontal deflection coil of the high voltage generator, 4b is a resonant capacitor of the high voltage generator, 4c is a damper diode of the high voltage generator, and 4d is an S-shaped correction capacitor. .

Looking at the centering adjustment operation of the horizontal raster centering circuit of the present invention configured as described above are as follows.

The high voltage generator 4 interrupts the primary side of the high-voltage generating flyback transformer FBT by the resonance of the resonant capacitor 4b and the damper diode 4c in accordance with the switching of the transistor Q4. Positive and negative pulse voltages are output from the windings.

The positive and negative pulse voltages are shown in (a) and (b) of FIG. 4 because the return period of the high voltage generator is shorter than the return period of the horizontal deflection section 2 (4 μsec −5 μsec). As shown in FIG.

The horizontal deflection power (B +) is supplied from the middle tap of the secondary winding of the high-voltage generating flyback transformer (FBT), and the positive pulse voltage is the resistance (R1) and the diode (D1) of the horizontal raster centering part (1). ) And the negative pulse is rectified by the resistor R2, the diode D2, and the capacitor C2, and the rectified power supply is the resistor R3 and the variable resistor VR1. ) And the resistor R4 are divided by the bias of the transistors Q2 and Q3.

At this time, if the variable resistor VR1 is adjusted toward the resistor R3, the bias of the transistor Q2 increases, so that the transistor Q2 is turned on and the transistor Q3 is turned off, so that a positive power supply voltage is connected to the resistor R5. Since the DC bias level is increased by being applied to the condenser Cs of the horizontal deflection portion 2 through the choke coil L1, the horizontal raster by the deflection coil DY moves to the left side of the screen.

However, when the variable resistor VR1 is adjusted toward the resistor R4, the bias of the transistor Q3 is increased so that the transistor Q3 is turned on and the transistor Q2 is turned off, so that the negative power supply voltage is the resistor R5. And the choke coil (L1) is applied to the capacitor (Cs) of the horizontal deflection portion 2 to reduce the DC bias level, so the horizontal raster by the deflection coil (DY) is moved to the right side of the screen.

As described above, since the centering correction voltage supplied from the horizontal raster centering unit 1 to the horizontal deflection unit 2 has a wide pulse width, the smoothing characteristic of the load is improved, and the variation of the variation is remarkable despite the change of the horizontal frequency. Is reduced.

For example, as shown in (a) of FIG. 4, when the horizontal frequency is 31.5 kHz, the voltage average value across the capacitor C1 is 9 V, which is stable because of less ripple than in the case of (a) of FIG. As shown in (b), even when the horizontal frequency is 81.3 kHz, the average voltage across the capacitor C1 is about 9.5V, which is more stable than in the case of (b) of FIG.

That is, although the voltage deviation across the capacitor C1 according to the horizontal frequency conventionally reaches 1V, the present invention is reduced to 0.5V.

This effect is similarly applied to the voltage across the capacitor C2.

Therefore, since the variation in the centering adjustment voltage applied to the horizontal deflection portion 2 is small, the movement variation of the raster is reduced at a low horizontal frequency or at a high frequency, which is convenient for raster centering operation and of course, reliability of adjustment. Will result in an improvement.

As described above, the present invention can minimize the raster shift deviation according to the horizontal frequency of the multi-synchronous monitor, and when the raster is centered in the intermediate frequency mode of the highest horizontal frequency and the lowest horizontal frequency in the multi-synchronous monitor, The movement width of the raster moving to the center is minimized, so it is possible to adjust the raster quickly and accurately.

Claims (2)

Positive and negative pulses are applied from the secondary winding of the high-pressure generating flyback transformer (FBT) of the high-pressure generating unit 4 to rectify and smooth them to adjust the raster adjustment voltage to the horizontal deflection unit 2. Horizontal raster centering unit (1) for applying a horizontal deflector (2) to adjust the raster centering by receiving a positive (+) or negative (-) voltage supplied from the horizontal raster centering unit (1) And a high pressure generator 4 for supplying a high voltage power to the horizontal raster centering unit 1 to reduce the movement deviation of the horizontal raster center according to the horizontal frequency variation of the multi-synchronous monitor. Horizontal raster centering circuit. The method of claim 1, wherein the high-pressure generator (4) outputs a horizontal deflection power (B +) at the secondary side as the primary side is switched, and outputs positive and negative centering adjustment pulses A high pressure generating flyback transformer (FBT) is provided so that the high pressure generating flyback transformer (FBT) primary winding is switched by a transistor (Q4), and the horizontal raster centering part (1) is a high pressure generating flyback. When the positive and negative pulses are output based on the middle tap of the secondary winding of the back transformer (FBT), the diode (D1) and the capacitor (C1) rectifying and smoothing the positive spread are described. The secondary winding of the high voltage generating flyback transformer (FBT) is connected to the secondary winding of the high voltage generating flyback transformer (FBT) and the diode (D2) and capacitor (C2) rectifying and smoothing the negative pulse. A variable for dividing the positive and negative rectified voltages smoothed in the capacitors C1 and C2. Raster centering adjustment is performed by connecting resistor VR1 and connecting transistors Q2 and Q3 conducted by the variable resistor VR1 to the S-shaped correction capacitor Cs of the horizontal deflection section 2. Horizontal raster centering circuit, characterized in that the configuration.