KR100667734B1 - Dynamic focus apparatus - Google Patents

Abstract

Disclosed is a dynamic focus device for simultaneously applying vertical parabola to a horizontal parabola wave to maintain a constant dynamic focus voltage at all times. The present invention is a horizontal parabolic wave generating unit for generating a high voltage pulse output from a horizontal deflector as a parabolic waveform of horizontal frequency, a vertical parabola wave generating unit for generating a signal output from the vertical deflection as a parabolic waveform of vertical frequency, the vertical The first mixer unit generating a vertical focus waveform by mixing a DC voltage with the vertical parabola waveform generated in the parabola wave generating unit, and the vertical parabola waveform generated in the horizontal parabola wave generating unit is generated vertically in the first mixer unit. And a second mixer unit mixing the focus waveform to generate a uniform dynamic focus voltage according to the CRT peripheral distance.

Description

Dynamic focus apparatus

1 is a view for explaining a conventional dynamic focus device.

2 is a view for explaining a dynamic focus apparatus according to the present invention.

3A is a vertical parabola waveform diagram amplified by the first amplifier.

3B is a horizontal parabolic waveform diagram amplified by the second amplifier.

3C is a diagram of a focus voltage waveform generated in the apparatus of FIG. 2.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dynamic focus apparatus in a display apparatus, and more particularly, to a dynamic focus apparatus for maintaining a constant dynamic focus voltage by applying vertical parabolas simultaneously to a horizontal parabola wave.

In general, in a display device, in order to make a clear image appear on a fluorescent surface by an electron beam emitted from an electron gun of a water tube (CRT), an electrostatic lens formed between an anode electrode and an appropriate voltage is applied to a focus electrode G4. The beam is focused.

In the electrostatic focusing method currently used, a uni-potential type using a voltage of about 0 to 400 V at the second electrode G2 as a focus voltage and a bi-potential in which about 30% of the water pipe anode voltage is used as a focus voltage There are two representative methods of the type. Currently, the black-and-white water tube and the small color water tube adopt the uni-potential type, and the medium-sized and higher color water tube adopt the bi-potential type.

When the aberration of the focusing lens is large or the focusing voltage is lower than the prescribed adjustment value, a halo called halo can be seen around the spot in the dot, and the focusing voltage is higher than the prescribed adjustment value. When it is high, the bright spots may be greatly enlarged or blooming may occur, such as only white highlights on the screen.

In general, the distance between the arrival point of the electron beam and the electron gun in the receiving tube is different from the center of the receiving tube to the upper side, the lower side, the left side and the right side. This also means that the proper focus voltage varies with its position. Therefore, in order to obtain proper focus, the focus voltage must be variable according to the arrival position of each beam, and this variable focus is called dynamic focus.

Dynamic focus has become more important as the current trend of increasing the size of all TV receivers or monitor devices, that is, the distance that the electron beam must move to reach the slope from the center of the screen.

1 is a view for explaining a conventional dynamic focusing apparatus.

Referring to FIG. 1, when a horizontal parabola waveform is inputted by a horizontal driving pulse, the sawtooth waveform current generated by the deflection coil L3 is input to the primary side transformer T1 by the resonance of the capacitors Cs and C1. T2). The horizontal parabola waveform induced in the primary side transformer T1 is induced into the secondary side transformer T2 and applied from the ground terminal to the focus terminal direction.

However, the focus device as shown in FIG. 1 has only a horizontal waveform input to the focus terminal, so that there is almost no voltage variation around the CRT. Therefore, only a uniform parabola waveform is applied around the CRT, so there is a problem in that blurring on the screen and secondary focus adjustment are required.

The technical problem to be achieved by the present invention is to provide a dynamic focus device that is applied to the vertical and horizontal parabola waveform at the same time to be in a uniform focus state around the CRT.

In order to solve the above technical problem, in the focus device of the CRT having a horizontal deflector and a vertical deflector for displaying an applied image signal on the screen,

A horizontal parabolic wave generating unit generating a high voltage pulse output from the horizontal deflector as a parabolic waveform having a horizontal frequency;

A vertical parabola wave generator for generating a signal output from the vertical deflection as a parabolic waveform having a vertical vertical frequency;

A first mixer unit generating a vertical focus waveform by mixing a DC voltage with the vertical parabola waveform generated by the vertical parabola wave generating unit;

A dynamic focus device including a second mixer for generating a uniform focus voltage according to the CRT peripheral distance by mixing the horizontal parabola waveform generated by the horizontal parabola wave generator to the vertical focus waveform generated by the first mixer. to be.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a view for explaining a dynamic focus apparatus according to the present invention.

Referring to FIGS. 3A to 3C, the horizontal parabolic wave generator 220 transforms and outputs a high pressure pulse output from a horizontal deflector (not shown) into a parabolic waveform having a horizontal frequency. The vertical parabola wave generator 210 converts the signal output from the vertical deflector (not shown) into a parabola waveform having a vertical frequency and outputs the parabola wave.

The first amplifier 230 amplifies the vertical parabola wave output from the vertical parabola wave generator 210 to 200V _PP . The second amplifier 240 outputs the horizontal parabola output from the horizontal parabola wave generator 220. Amplify the wave to 800V _PP , the second amplifier 40 amplifies the vertical parabola wave output from the vertical parabola wave generator 30 to 200V _PP . 3A illustrates a vertical parabola waveform amplified by the first amplifier 230 and FIG. 3B illustrates a horizontal parabola waveform amplified by the second amplifier 240.

The first mixer 250 mixes a predetermined DC voltage with the vertical parabola waveform amplified by the first amplifier 230 to generate a vertical parabola waveform corresponding to the vertical focus voltage in which DC voltage is added.

The second mixer 260 mixes the horizontal parabola waveform amplified by the second amplifier 240 and the vertical parabola waveform generated by the first mixer 250 to generate a dynamic focus voltage waveform in which two waveforms overlap. Let's do it. That is, the horizontal parabola waveform induced from the second amplifier 240 through the coil L1 to the primary transformer T1 is induced in the secondary transformer T2 to repeat the on / off operation at the vertical frequency. It is mixed with the waveform. Waveforms in which the vertical and horizontal parabola waveforms are superimposed are generated with a dynamic focus voltage suitable for CRT characteristics as shown in FIG.

As described above, according to the present invention, when the CRT focus is adjusted, the vertical and horizontal waveforms are simultaneously applied to allow a uniform focus voltage to be applied to the entire CRT periphery, thereby improving the blurring of the screen. There is an advantage to this.

Claims (1)

A focusing apparatus of a CRT having a horizontal deflector and a vertical deflector for displaying an applied video signal on a screen, A horizontal parabolic wave generating unit generating a high voltage pulse output from the horizontal deflector as a parabolic waveform having a horizontal frequency; A vertical parabolic wave generator for generating a signal output from the vertical deflection as a parabolic waveform having a vertical frequency; A first mixer unit generating a vertical focus waveform by mixing a DC voltage with the vertical parabola waveform generated by the vertical parabola wave generating unit; A dynamic focus device including a second mixer for generating a uniform dynamic focus voltage according to the distance around the CRT by mixing the horizontal parabola waveform generated by the horizontal parabola wave generating unit with the vertical focus waveform generated by the first mixer unit. .

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