KR960016842B1 - Focus control circuit - Google Patents

Abstract

The circuit is provided for adjusting the focus in the optimization state by controlling the focus voltage for the vertical and horizontal synchronizer, and includes a vertical deflection amplifier amplifying the vertical deflection signal providing in the vertical deflection coil of a picture tube, a horizontal deflection amplifying part amplifying the horizontal deflection signal providing in the horizontal deflection coil of a picture tube, a mixing part providing the vertical deflection signal and the horizontal deflection signal into the coil of a grounded transformer, a control signal generator outputting the switching control signal by amplifying the output signal of the mixing part, a focus voltage control part adjusting the focus voltage by the control signal.

Description

Focus control circuit

1 is a conventional focus control circuit diagram.

2 illustrates a focus control circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10: vertical sync signal amplifier 20: horizontal sync signal amplifier

30: mixing unit 40: control signal generator

50: focus voltage control unit.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a focus control circuit of a cathode ray tube for an electronic deflection type that converts a traveling direction of an electron beam emitted from an electron gun into a magnetic field. In particular, the focus voltage is controlled in accordance with a change in a vertical synchronization signal and a horizontal synchronization signal. A focus control circuit for adjusting focus to an optimal state throughout a periphery.

In the conventional focus control circuit, as shown in FIG. 1, the voltage applied from the flyback transformer FBT is rectified through the diode DI and supplied to the anode terminal of the CRT. It is configured to supply a constant voltage to the fourth grid (G4) according to the variable, but this is because the vertical and horizontal focus of the CRT is controlled by supplying a constant voltage up, down, left and right with respect to the center of the CRT. The vertical and horizontal side centers have a problem in that the focus is accurately adjusted while the focus of the periphery is not accurately adjusted.

Accordingly, the present invention has been made to solve the above-mentioned conventional defects, and an object of the present invention is to control the focus voltage according to the vertical deflection synchronization signal and the horizontal deflection signal to optimize the overall state of the CRT and the periphery. It is to provide a focus control circuit that controls the focus.

In order to achieve the above object, the focus control circuit according to the present invention includes a vertical deflection signal amplifying unit for amplifying a vertical deflection signal supplied to a vertical deflection coil of a water pipe as an input, and a horizontal deflection coil of the water pipe. A horizontal deflection signal amplifying unit for amplifying a horizontal deflection signal as an input, a mixing unit for mixing signals output from the vertical and horizontal deflection signal amplifying units, and a predetermined switching control signal according to a signal output from the mixing unit And a focus voltage controller configured to control the focus voltage supplied to the water pipe according to the level of the switching control signal output from the control signal generator.

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

2 is a diagram illustrating a focus control circuit according to the present invention, in which the vertical deflection signal amplifying unit 10 inputs and outputs a vertical deflection signal supplied to a vertical deflection coil of a water pipe as an input. Comprising resistors R1 to R3, the horizontal deflection signal amplifying unit 20 inputs the horizontal deflection signal supplied to the horizontal deflection coil of the water pipe as an input and amplifies the transistors Q3 and Q4 and the resistors R4 through R6).

The mixing unit 30 is connected to supply the signals output from the vertical deflection signal amplifying unit 10 and the horizontal deflection signal amplifying unit 20 to both end taps of a transformer (TNS) primary coil in which an intermediate tap is grounded. The signal induced by the transformer (TNS) secondary coil is configured to be supplied to a control signal generator later.

The control signal generator 40 is configured with an amplifying transistor Q5 to amplify the signal output from the mixing unit 30 and output a predetermined switching control signal. The focus voltage controller 50 is the control signal. The field effect transistors F1 and F2 adjust the focus voltage according to the control signal output from the generator 40.

Referring to the operation of the present invention with the embodiment as described above as follows.

In the state where the focus voltage is determined by the voltage applied from the flyback transformer (FBT) shown in FIG. 2, the horizontal deflection signal supplied to the deflection coil of the water pipe is amplified by the vertical deflection signal amplifier 10 and the horizontal deflection signal amplification. Since the current is amplified by the transistors Q1, Q2 (Q3, Q4) of the unit 20 and supplied to both ends of the transformer TNS primary coil of the mixing unit 30, the secondary coil has a vertical deflection signal and a horizontal deflection. The mixed level of the signal is output, where the level corresponds to the position at which the beam is scanned.

When the signal output from the mixing unit 30 is amplified by the transistor Q5 of the control signal generator 40 and then supplied to the focus voltage controller 50, the field effect transistor of the focus voltage controller 50 ( F1) and F2 operate according to the signal level to control the focus voltage FG.

According to the present invention operating as described above, since the focus voltage is controlled according to the mixing of the level of the horizontal deflection signal and the vertical deflection signal, the focus can be precisely adjusted in all the upper, lower, left, and right sides of the CRT, thereby providing a clear screen to the user. There is an effect to provide.

Claims (5)

A vertical deflection signal amplifying unit using a vertical deflection signal supplied to a vertical deflection coil of the water pipe as a input, and a horizontal deflection signal amplifying unit as a input of a horizontal deflection signal supplied to a horizontal deflection coil of the water pipe; A mixing unit for mixing signals output from the deflection signal amplifying unit, a control signal generating unit for outputting a predetermined switching control signal according to the signal output from the mixing unit, and a switching control signal output from the control signal generating unit. And a focus voltage controller for controlling the focus voltage supplied to the water pipe according to the level. The vertical deflection signal amplifying unit 10 and the horizontal deflection signal amplifying unit 20 include a first transistor for buffering an input signal and a second transistor for amplifying a signal output from the first transistor. Focus control circuit, characterized in that configured. The mixer 30 of claim 1, wherein the mixing unit 30 has a signal output from the vertical deflection signal amplifying unit 10 and the horizontal deflection signal amplifying unit 20 at both ends of a transformer (TNS) primary coil in which an intermediate tap is grounded. And a signal induced in the secondary coil of the transformer (TNS) to be supplied to a control signal generator (40). The focus control circuit of claim 1, wherein the control signal generator 40 comprises an amplifying transistor Q5 to amplify a signal output from the mixing unit 30 and output a predetermined switching control signal. . The method of claim 1, wherein the focus voltage controller 50 adjusts the left / right or up / down balance of the focus according to the control signal output from the control signal generator 40. A focus control circuit comprising a variable resistor (VR) and two field effect transistors.