KR20000001590A - Dynamic focus circuit - Google Patents

Abstract

PURPOSE: Dynamic focus circuit is provided to improve degree of definition by compensating distortion and phase delay of vertical dynamic parabola wave. CONSTITUTION: The circuit comprises vertical parabola amplifier(20) for amplifying vertical parabola wave from horizontal deflector(1), vertical parabola amplifier(30) for amplifying vertical parabola wave from horizontal/vertical processor(50), and dynamic focus output means for composing the horizontal parabola wave of the horizontal parabola amplifier(20) and vertical parabola wave vertical parabola amplifier(30), and let out only good dynamic focus output. Thereby, it is possible to be simple structure of dynamic focus circuit.

Description

Dynamic focus circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dynamic focus circuit, and more particularly, to a dynamic focus circuit for simplifying the configuration of a dynamic focus circuit and for improving phase clarity by compensating phase delay and waveform distortion of a horizontal dynamic parabola waveform.

In general, dynamic focusing (dynamic focusing) is a dynamic change in the focusing voltage in synchronization with the vertical / horizontal deflection so that the beam is focused even in the peripheral portion of the cathode ray tube, in the case of the receiving tube and image tube the center of the fluorescent or photoelectric surface And the distance from the periphery to the center of deflection are different. Therefore, even if the electron beam is focused at the center, it is not focused at the periphery. Therefore, countermeasures are required for high-quality imaging and imaging.

1 is a block diagram of a conventional dynamic focus circuit.

The focus voltage is input to G4 (Grid 4) of the CRT (Cathode Ray Tube) electron gun, which aims to make the screen clear by condensing the electron beams. Currently, medium and large monitors (17 inches or more) are supplied with an AC parabola voltage in addition to a DC voltage, which is a general focus voltage. This is called a dynamic focus voltage.

The dynamic focus voltage includes a horizontal parabola voltage synchronized with a horizontal frequency and a vertical parabola voltage synchronized with a vertical frequency. If the focus voltage is supplied with a constant DC voltage on the monitor screen, the focus on the outside of the center is blurred. If you adjust the focus voltage around the outside, the center will be blurred.

To compensate for this, AC parabolic waveforms synchronized to the horizontal and vertical frequencies are supplied to the DC voltage, focusing on the horizontal line of the screen called horizontal AC wave, and vertical parabola focusing on the vertical line (general horizontal / vertical in Fig. 2). See also the concept of parabolic waveforms).

Thus, in the conventional circuit of FIG. 1, the horizontal / vertical parabola waveform of low voltage is input from the horizontal / vertical processor and the parabola peak voltage is changed to about 100 to 150V vertically and 400 to 500V horizontally using transistors Q1 and Q2 to Q5. Amplified will invert the waveform and send it out to the dynamic focus output.

However, amplification using various transistors Q1 to Q5 causes phase delay of the output waveform relative to the input waveform phase. Thus, as shown in the conceptual diagram showing the output of the monitor due to the phase delay of FIG.

It also amplifies the horizontal parabolic waveform at high frequencies (tens of tens of KHz), resulting in distortion of the waveform. As shown in the conceptual diagram showing the output of the monitor due to the waveform distortion of the conventional circuit of FIG.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to simplify the configuration of the dynamic focus circuit, and to compensate for the phase delay and waveform distortion of the horizontal dynamic parabola waveform to improve the sharpness of the screen. It is to provide a dynamic focus circuit that can be improved.

In order to achieve the above object, the dynamic focus circuit according to the present invention,

A horizontal parabolic amplifier for receiving a parabolic waveform from a horizontal deflection unit and amplifying only a horizontal parabola waveform; A vertical parabola amplifying unit which receives a vertical focus output from a horizontal / vertical processor and amplifies only vertical components; The technical features of the technical configuration of the horizontal parabolic amplification unit and the horizontal parabolic waveform and the vertical parabola amplification unit of the vertical parabolic waveform is composed of a dynamic focus output unit for outputting a dynamic focus output without phase delay and good waveform distortion.

1 is a configuration diagram of a conventional dynamic focus circuit,

2 is a conceptual diagram of a general horizontal / vertical parabola waveform,

3 is a conceptual diagram showing an output of a monitor due to a phase delay of a conventional circuit;

4 is a conceptual diagram showing the output of the monitor by the waveform distortion of the conventional circuit,

5 is a configuration diagram of a dynamic focus circuit according to the present invention;

6 is a view showing input and output waveforms by a transformer in FIG.

7 is a conceptual diagram showing the output of the monitor according to the application of the present invention.

<Explanation of symbols for main parts of the drawings>

10: horizontal deflection portion 20: horizontal parabola amplifier

30: vertical parabola amplifier 40: dynamic focus output unit

50: horizontal / vertical processor 60: main controller

Hereinafter, with reference to the accompanying drawings an embodiment according to the technical concept of the present invention the dynamic focus circuit configured as described above in detail as follows.

5 is a configuration diagram of a dynamic focus circuit according to the present invention.

As shown therein, the horizontal parabola amplifier 20 receives a parabolic waveform from the horizontal deflection unit 10 and amplifies only the horizontal parabola waveform; A vertical parabola amplifying unit 30 which receives a vertical focus output from the horizontal / vertical processor 50 and amplifies only vertical components; Composed of the dynamic parabolic waveform of the horizontal parabolic amplifier 20 and the vertical parabola waveform of the vertical parabola amplifier 30, the dynamic focus output unit 50 outputs a dynamic focus output without phase delay and good waveform distortion. .

The horizontal parabolic amplifier 20 may include surge protection resistors R1 and R2 of waveforms input from the horizontal deflection unit 10; A waveform adjusting unit (C1) for adjusting the shape of the parabolic waveform that is surge protected in the resistor (R1); A transformer (T1) for amplifying only horizontal parabola from the parabola waveform inputted from the waveform control unit (C1) and inputting a waveform having no phase delay and preventing distortion of the waveform to the dynamic focus output unit (50); The horizontal noise removing unit C5 removes the horizontal noise component of the horizontal parabola waveform output from the transformer T1.

In addition, the vertical parabola amplifier 30 includes: a blocking capacitor C4 for DC blocking the vertical focus output from the horizontal / vertical processor; A vertical noise removing unit C3 for removing noise of a waveform input from the blocking capacitor C4 to the base terminal of the transistor Q1; A transistor (Q1) for amplifying a vertical focus input from the blocking capacitor (C4); Resistors R4 and R5 for determining a DC operating point and a voltage amplification ratio of the transistor Q1; And a bias resistor R6 and R7 of a waveform input from the blocking capacitor C4 to the transistor Q1.

In addition, the dynamic focus output unit 50 includes: a synthesis unit C2 (R3) for synthesizing the horizontal parabola waveform of the horizontal parabola amplifier 20 and the vertical parabola waveform of the vertical parabola amplifier 30; A bypass unit (D1) for bypassing the supply voltage when a high surge voltage is generated in the synthesis unit (C2) (R3); Surge protection unit (Spark GAP) for protecting the surge voltage of the synthesis unit (C2) (R3).

Referring to the operation of the present invention in detail as follows.

First, the horizontal parabola waveform is inputted to the pins 1 and 2 of the inverting and amplifying transformer T1 by using the waveform generated from the horizontal high voltage circuit of the horizontal deflection unit 10, respectively. Enter the waveform as shown. Thus, only the parabola waveform is amplified by the transformer T1 and inverted, and the output peak-peak voltage is adjusted to about 450V by adjusting the number of primary and secondary turns.

In addition, the vertical parabolic waveform is input from the horizontal / vertical processor 50 and amplified by the transistor Q1. The horizontal / vertical parabola waveform of the horizontal / vertical processor 50 can be scaled by the control of the main controller 60, where the horizontal component is killed and only the vertical component is output.

Thus, the horizontal parabola is amplified by the transformer (T1), the vertical parabola is amplified by the transistor (Q1) to combine the horizontal and vertical components through the C2 and R3 to output a dynamic focus output.

Accordingly, the horizontal parabola waveform is directly out of the focus output through only the transformer T1, and thus there is almost no phase delay. Also, the horizontal parabola waveform is directly amplified by a large voltage of several tens of volts to prevent distortion of the waveform.

In addition, the vertical parabolic waveform is amplified by only one transistor Q1 (NPN) to simplify the configuration of the overall dynamic focus circuit.

7 is a conceptual diagram showing the output of the monitor according to the application of the present invention. Here, the phase delay between the horizontal input and the horizontal parabola output is almost absent, and the flatness of the horizontal line is uniform due to the good waveform distortion, making it easy to adjust the focus.

As described above, the present invention simplifies the configuration of the dynamic focus circuit and improves the clarity of the screen by complementing the phase delay and the waveform distortion of the horizontal dynamic parabola waveform.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the dynamic focus circuit according to the present invention simplifies the configuration of the dynamic focus circuit and compensates the phase delay and waveform distortion of the horizontal dynamic parabola waveform, thereby improving the sharpness of the screen.

Claims (4)

A horizontal parabolic amplifier 20 which receives the parabolic waveform from the horizontal deflection unit 10 and amplifies only the horizontal parabola waveform; A vertical parabola amplifying unit 30 which receives a vertical focus output from the horizontal / vertical processor 50 and amplifies only vertical components; Composed of a dynamic focus output unit 50 for synthesizing the horizontal parabola waveform of the horizontal parabola amplifier 20 and the vertical parabola waveform of the vertical parabola amplifier 30 to output a dynamic focus output without phase delay and good waveform distortion. Dynamic focus circuit characterized by. The method of claim 1, wherein the horizontal parabola amplifier 20, A surge protection resistor (R1) (R2) of a waveform input from the horizontal deflection portion (10); A waveform adjusting unit (C1) for adjusting the shape of the parabolic waveform that is surge protected in the resistor (R1); A transformer (T1) for amplifying only horizontal parabola from the parabola waveform inputted from the waveform control unit (C1) and inputting a waveform having no phase delay and preventing distortion of the waveform to the dynamic focus output unit (50); And a horizontal noise removing unit (C5) for removing the horizontal noise component of the horizontal parabola waveform output from the transformer (T1). According to claim 1, wherein the vertical parabola amplifier 30, A blocking capacitor (C4) for DC blocking the vertical focus output from the horizontal / vertical processor; A vertical noise removing unit C3 for removing noise of a waveform input from the blocking capacitor C4 to the base terminal of the transistor Q1; A transistor (Q1) for amplifying a vertical focus input from the blocking capacitor (C4); Resistors R3-R5 for determining a DC operating point and a voltage amplification ratio of the transistor Q1; And a resistor (R6) (R7) for bias of a waveform input from the blocking capacitor (C4) to the transistor (Q1). The method of claim 1, wherein the dynamic focus output unit 50, A synthesis unit (C2) (R3) for synthesizing the horizontal parabola waveform of the horizontal parabola amplifier 20 and the vertical parabola waveform of the vertical parabola amplifier 30; A bypass unit (D1) for bypassing the supply voltage when a high surge voltage is generated in the synthesis unit (C2) (R3); A dynamic focus circuit, comprising: a surge protection unit (Spark GAP) for protecting the surge voltage of the synthesis unit (C2) (R3).