KR940005077Y1 - Dynamic focus compensating circuit for multi sink monitor - Google Patents

Abstract

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Description

Dynamic Focus Correction Circuit of Multi Sync Monitor

1 is a conventional dynamic focus correction circuit diagram.

2 is an output waveform diagram showing each conventional circuit portion.

3 is a dynamic focus correction circuit diagram according to the present invention.

4 is an output wave diagram shown in each circuit part according to the present invention.

* Explanation of symbols for main parts of the drawings

1: first inverted amplifier 2: non-inverted amplifier

4: second inverting amplifier 3: integrating circuit

6: third inverting amplifier 5: buffer circuit

7: waveform amplification and shaping

The present invention relates to a dynamic focus correction circuit of a multi-sync monitor, and is particularly suitable for providing a clear picture at all times regardless of an input frequency by applying a constant dynamic focus over a wide frequency band in a multi-sync monitor.

1 shows a conventional dynamic focus correction circuit, in which the horizontal deflection yoke (H-DY) output terminal is connected to the capacitor C ₁ and the resistor R ₁ through the horizontal linear correction coil H-LIN and the correction capacitor C ₅ . Is connected to the base of transistor Q ₁ (Q ₂ ) through a capacitor C ₂ .

The emitter of the transistor Q ₁ is connected to a picking circuit composed of an amplification adjusting resistor R ₆ , a resistor R ₇ , and a capacitor C ₃ , and a transistor between the base and the emitter of the transistor Q ₁ . The protective diode D ₁ of Q ₁ is connected.

Also connected to the collector of the emitter of the transistor (Q ₁₎ of said one transistor (Q _2), and is configured such that the collector of the transistor (Q ₂₎ is connected to the cathode-ray tube focus terminal 8 through the capacitor (C _4).

In the drawings, reference numerals R ₂ to R ₅ denote bias resistors.

In the conventional dynamic focus correction circuit having the above-described configuration, the dynamic focus voltage passing through the horizontal deflection yoke (H-DY) and the horizontal linear correction coil (H-LIN) is output as a square waveform such as point A of FIG. The point A waveform is differentiated by the capacitor C ₁ and the resistor R ₁ and output as a shaped waveform such as the point B. The point B waveform passes through only the AC component through the capacitor C ₂ , and then the transistor Q. ₁ ), amplified by (Q ₂ ) and the C point waveform appears through the condenser (C ₄ ) to be superimposed on the CRT focus terminal 8 so that the center and corner portions of the screen correct the focus.

That is, when the input horizontal frequency is increased or decreased, the input waveform is shaped and amplified in a state where the amplitude is changed and applied to the monitor through the CRT focus terminal 8.

As described above, when a waveform having a different frequency is applied to the CRT focus terminal 8, the monitor has a problem in that the focus of the screen is changed according to the frequency or mode change.

The object of the present invention is to solve the above problems, and in particular, to provide a clear screen at all times by applying a constant focus voltage to a screen regardless of frequency or mode change in a multi-sync monitor.

To achieve this purpose, the present invention is characterized by generating a constant output voltage irrespective of the input by compensating the input voltage whose height varies with frequency by overlapping with the frequency-voltage conversion output.

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

2 shows a dynamic focus correction circuit according to the present invention, wherein the first inverting amplifier 1 for inverting and amplifying the input flyback pulse waveform FP and the frequency-voltage conversion output F / V are not shown. A non-inverting amplifier 2 for inverting and amplifying, an integrating circuit unit 3 for integrating the output signal of the non-inverting amplifying unit 2, and an output voltage of the integrating circuit unit 3 inverted and amplified regardless of the frequency A second inverting amplifier 4 for generating a voltage waveform having a constant amplitude, a buffer circuit 5 for amplifying the output of the second inverting amplifier 4, and an output of the buffer circuit 5 And a third inverting amplifier 6 for inverting and amplifying the waveform, and a waveform amplification and shaping section 7 for amplifying and shaping the output waveform of the third inverting amplifier 6.

The operation and effects of the present invention configured as described above will be described with reference to FIG.

When a high frequency flyback pulse FP is input in a multi-sync monitor having a wide frequency band, a high amplitude waveform such as the point D waveform of FIG. 4 is output through the resistor R ₁ and the capacitor C ₁ . The same point D waveform is inverted and amplified through the transistor Q ₁ .

Thus when a pulse having a higher frequency input non-inverting amplifier (A ₁₎ non-inverting (A) to be applied with a high voltage input terminal of the transistor through the integrating circuit (3) and a resistor (R _7), after the non-inverting amplifier (Q ₂ ) is turned on, and a waveform having a relatively low amplitude is output to the collector side such as the waveform of point E in FIG.

On the other hand, if the flyback pulse (FP) of the low frequency input non-inverting amplifier (A ₁₎ non-inverting (+) is to enter the low voltage input terminals non-inverting amplifier (A ₁₎ the output stage has been displayed a low level signal transistor of the Since (Q ₂ ) is not conducting, the waveform of point E outputs a relatively high amplitude voltage waveform.

That is, a voltage waveform having a constant amplitude is output at point E regardless of the height of the input frequency.

As such, the E-point waveform having a predetermined amplitude is buffered through the transistor Q ₃ , the resistor R ₁₁ , and the capacitor C ₄ and then applied to the base of the transistor Q ₄ .

The tkdrl point E waveform is first inverted and amplified by transistor Q ₄ to form a point F waveform, which is driven by transistors Q ₅ and Q ₆ through resistors R ₁₅ and R ₁₇ . After amplified, the shaped waveform such as G point is applied to the focus terminal 8 of the CRT, thereby providing a clear screen regardless of frequency.

Here, resistors R ₁₆ and R ₁₈ are bias resistors for transistor Q ₅ and resistors R ₁₉ connected to the emitter of transistor Q ₆ are transistors Q ₅ and Q ₆ . The peaking circuit by determining the amplification degree of the resistor R ₂₀ and the capacitor C ₆ is for shaping the output voltage.

As described above, since the present invention forms a voltage waveform having a constant magnitude regardless of the input voltage difference, the same focus voltage is applied to the CRT regardless of frequency and mode, thereby providing a clear screen at all times.

Claims (1)

A first inverting amplifier 1 for inverting and amplifying the input flyback pulse waveform FP, a noninverting amplifier 2 for noninverting a frequency-voltage conversion output (F / V), and the noninverting amplification An integrating circuit section 3 for integrating the output signal of the section 2 and a second inverting amplifier section for inverting and amplifying the output voltage of the integrating circuit section 3 to generate a voltage waveform having a constant amplitude regardless of frequency. (4), a buffer circuit section 5 for amplifying the output of the second inverting amplifier section 4, a third inverting amplifier section 6 for inverting and amplifying the output of the buffer circuit section 3, and the second And a waveform amplifying and shaping section (7) for amplifying and shaping the output waveform of the three inverting amplifying section (6).