KR200184826Y1 - Dynamic focus circuit of monitor - Google Patents

Abstract

The present invention relates to a dynamic focus circuit of a monitor in which the amplitude of the dynamic focus is automatically compensated according to the change in the horizontal size, and the sawtooth wave generator circuit is integrated in the first order to generate the sawtooth wave by applying the horizontal flyback pulse (E). (10), a parabola generating circuit 20 for secondarily integrating the sawtooth wave generated by the sawtooth wave generating circuit 10 into a parabola wave, and a parabola amplifying circuit for amplifying the parabola wave generated by the parabola generating circuit ( 30), the transformer T driven by the parabola amplified by the parabola amplification circuit 30, the vertical dynamic focus amplification circuit 50 for amplifying the vertical dynamic focus signal VD, and the high pressure adjustment of the CRT. The voltage (HV) and the horizontal size adjustment voltage are applied and the parabola is fed back so that the By the compensation in accordance with the same consists of a feedback amplitude adjustment circuit 40 for re-output to a sawtooth wave generating circuit 10.

As a result, since the amplitude of the dynamic focus is determined according to the geometric position of the CRT, precise focusing is achieved.

Description

Dynamic focus circuit of the monitor

The present invention relates to a dynamic focus circuit of a monitor, and more particularly, to a dynamic focus circuit of a monitor to automatically compensate for the amplitude of the dynamic focus according to the change in the horizontal size.

The conventional case will be described with reference to FIG.

Referring to FIG. 1, the dynamic focus circuit of a conventional monitor receives a horizontal flyback pulse to drive a deflection yoke DY, and outputs the output signal of the deflection yoke DY (waveform at point A). Is applied to the Han family of transformer T, and the horizontal flyback waveform as in junction B is applied to the other primary side of the transformer. This signal obtains a parabolic waveform of the required amplitude from the secondary side of the transformer.

(Like the waveform at junction C).

The disadvantage of this circuit

1. Because it depends on the waveform behind the input deflection yoke (DY), it is impossible to obtain an accurate parabola waveform.

2. The optimal dynamic focus amplitude must be determined according to the geometrical position of the CRT. The prior art always has the same amplitude regardless of the horizontal size and thus cannot obtain the correct focus voltage.

3. The waveform behind the deflection yoke (DY) varies in amplitude and shape depending on the horizontal deflection frequency. Therefore, a case where the focus is not good depending on the frequency occurs.

Accordingly, the present invention is to overcome the above-mentioned conventional problems, and the present conventional case will be described with reference to FIG.

Referring to FIG. 1, the dynamic focus circuit of a conventional monitor receives a horizontal flyback pulse to drive a deflection yoke DY, and outputs the output signal of the deflection yoke DY (waveform at point A). Is applied to the Han family of transformer T, and the horizontal flyback waveform as in junction B is applied to the other primary side of the transformer. This signal obtains the parabolic waveform of the required amplitude from the secondary side of the transformer (as the waveform at junction C).

The disadvantage of this circuit

1. Because it depends on the waveform behind the input deflection yoke (DY), it is impossible to obtain an accurate parabola waveform.

2. The optimal dynamic focus amplitude must be determined according to the geometrical position of the CRT. The prior art always has the same amplitude regardless of the horizontal size and thus cannot obtain the correct focus voltage.

3. The waveform behind the deflection yoke (DY) varies in amplitude and shape depending on the horizontal deflection frequency. As a result, a poor focus occurs depending on the frequency.

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

2 is a dynamic focus circuit diagram of a monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: sawtooth wave generating circuit 20: parabola generating circuit

30: parabola amplifier circuit 40: feedback amplitude adjustment circuit

50: vertical dynamic focus amplifier circuit

Accordingly, the present invention is to overcome the above-described conventional problems, and referring to FIG. 2, the dynamic focus circuit of the monitor according to the present invention is primarily applied to generate a sawtooth wave by receiving a horizontal flyback pulse (E). The sawtooth wave generation circuit 10 to be integrated with the parabolic wave generation circuit 20 to generate the parabolic wave again by integrating the sawtooth wave generated by the sawtooth wave generation circuit 10 again with parabolic wave; A parabolic amplification circuit 30 for amplifying, a transformer T driven by a parabola wave amplified by the parabola amplifying circuit 30, and a vertical dynamic focus amplifying circuit 50 for amplifying a vertical dynamic focus signal VD. The high voltage adjustment voltage (HV) and the horizontal size adjustment voltage of the CRT are applied, and the parabola is fed back so that the high voltage adjustment voltage (HV) and the horizontal size adjustment voltage By the compensation in accordance with the same consists of a feedback amplitude adjustment circuit 40 for re-output to a sawtooth wave generating circuit 10.

The sawtooth wave generation circuit 10 firstly integrates the horizontal pulses including the transistors Q10, Q11, Q12, and Q13 to form a sawtooth wave.

The parabolic generating circuit 20 includes op amps OP20 and OP21 to quadratically integrate the input sawtooth wave into parabolic waveforms.

The parabola amplifier circuit 30 includes transistors Q31, Q32, Q33, and Q34 to amplify the parabola waveform.

The parabola waveform thus amplified is transformed into a high pressure horizontal parabola waveform through the transformer T and applied to the dynamic focus DF of the CRT.

The feedback amplitude adjustment circuit 40 corrects the parabola fed back including the op amp OP41 according to the high voltage adjustment voltage HV and the horizontal size adjustment voltage H-SIZE of the CRT to the sawtooth wave generation circuit 10. send.

At this time, the high voltage adjustment voltage HV input to the non-inverting terminal of the OP41 through the resistor R41 of the feedback amplitude adjustment circuit 40 is a voltage for adjusting the anode high voltage applied to the anode of the CRT. The horizontal size adjustment voltage (H-SIZE) input to the non-inverting terminal of the OP41 through the resistor R42 is a voltage for adjusting the horizontal size of the screen.

The high voltage adjustment voltage HV and the horizontal size adjustment voltage H-SIZE are respectively output from the monitor's main control unit (MCU; not shown) and are fed back via the DAC (digital / analog converter; not shown). It is applied to OP41 of the amplitude adjustment circuit 40.

In general, since the dynamic focus characteristic varies according to the anode high voltage of the CRT, the MCU outputs a high voltage regulation voltage (HV) for decreasing the amplitude of the parabola when the anode high voltage is increased to correct the dynamic focus characteristic. When the high voltage of the anode is lowered, a high voltage adjustment voltage (HV) is output to increase the amplitude of the parabola.

In addition, since the optimal dynamic focus voltage is determined according to the geometric distance from the center of the CRT, and the amplitude of the dynamic focus voltage is changed according to the horizontal size of the screen, the focus characteristic is changed. Therefore, when the horizontal size is small, the MCU adjusts the amplitude of the parabola. The horizontal size adjustment voltage (H-SIZE) is outputted to reduce the height, and when the horizontal size increases, the horizontal size adjustment voltage (H-SIZE) is outputted to increase the amplitude of the parabola.

As described above, if the high voltage of the anode is high, the amplitude of the parabola is lowered. If the voltage of the anode is low, the amplitude of the parabola is small, and if the horizontal size is small, the amplitude of the parabola is small. When the horizontal size adjustment voltage (H-SIZE) for increasing the amplitude of the parabola is input to the non-inverting terminal of the OP41 of the feedback amplitude adjustment circuit 40, the OP41 is the high voltage adjustment voltage (HV) and the horizontal size adjustment voltage. The parabolic wave fed back according to the input of (H-SIZE) is corrected and sent to the sawtooth wave generating circuit 10.

For example, as the high voltage of the anode decreases and the horizontal size decreases, the high voltage adjusting voltage HV for increasing the amplitude of the parabola and the horizontal size adjusting voltage H-SIZE for decreasing the amplitude of the parabola are inputted to the OP41 or the high voltage of the anode is reduced. When the high-voltage adjustment voltage HV for lowering the amplitude of the parabola increases and the horizontal size increases, when the horizontal size adjustment voltage H-SIZE for increasing the amplitude of the parabola is input to the OP41, the OP41 is a difference between the two input voltages. Correct the parabola by increasing or decreasing its amplitude according to the voltage corresponding to.

In addition, as the high voltage of the anode decreases and the horizontal size increases, the high voltage adjusting voltage (HV) and the horizontal size adjusting voltage (H-SIZE) for increasing the amplitude of the parabola are inputted to the OP41 or the anode high pressure increases and the horizontal size decreases. Therefore, when the high voltage adjusting voltage HV and the horizontal size adjusting voltage H-SIZE for lowering the amplitude of the parabola are input to the OP41, the OP41 increases or decreases the amplitude of the parabola according to the sum of the input voltages. By correcting, the dynamic focus characteristic is improved.

As described above, the dynamic focus circuit of the monitor according to the present invention receives the high voltage adjustment voltage (HV) and the horizontal size adjustment voltage of the CRT and feeds back the parabola to the high voltage adjustment voltage (HV) and the horizontal size adjustment voltage. Since the compensation is output to the sawtooth wave generating circuit 10 again, the amplitude of the dynamic focus is determined according to the geometric position of the CRT.

What has been described above is just one embodiment for implementing the dynamic focus circuit of the monitor according to the present invention, the present invention is not limited to the above embodiment, this invention claimed in the following utility model registration claims Various changes can be made by those skilled in the art without departing from the gist of the present invention.

Claims (3)

A sawtooth wave generation circuit 10 for integrating the sawfly wave firstly by receiving a horizontal flyback pulse E and a parabolic generation for generating parabolic waves by secondly integrating the sawtooth wave generated in the sawtooth wave generation circuit 10 again. A circuit 20, a parabola amplification circuit 30 for amplifying the parabola waves generated by the parabola generating circuit, a transformer T driven by the parabola waves amplified by the parabola amplification circuit 30, and vertical dynamics. The vertical dynamic focus amplification circuit 50 that amplifies the focus signal VD, the high voltage adjustment voltage HV and the horizontal size adjustment voltage of the CRT are applied, and the parabola is fed back to feed the high voltage adjustment voltage HV and the horizontal size adjustment voltage. Dynamics of the monitor, characterized in that consisting of a feedback amplitude adjustment circuit 40 for compensating for the variation of the output to the sawtooth wave generation circuit 10 to output again Focus circuit. The dynamic focus circuit of claim 1, wherein a high CRT anode voltage makes the parabola amplitude low, and a low anode voltage makes the parabola amplitude high. 2. The dynamic focus circuit of a monitor according to claim 1, wherein the amplitude of the parabola is reduced when the horizontal size is small, and the amplitude of the parabola is increased when the horizontal size is large.