KR0172697B1 - Horizontal drive duty controlling circuit of a monitor - Google Patents

Abstract

The present invention relates to a horizontal drive duty control circuit of a monitor capable of properly compensating the duty for determining the on / off time of a horizontal deflection drive waveform in a multi-sync monitor according to a high frequency band in a low frequency band. The reliability of the monitor can be improved by easily configuring the horizontal drive condition from the band to the high frequency band.

Description

Horizontal Drive Duty Control Circuit of Monitor

1 is a conventional horizontal drive control circuit diagram.

2 is a horizontal drive duty control circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10: sink processor 20: switching unit

30: horizontal oscillator 40: voltage control unit

50: horizontal drive circuit 60: voltage generator

70: low pass filter 80: inverted amplifier

90: DC divider

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a horizontal drive circuit of a monitor. More specifically, a duty for determining on and off time of a horizontal deflection drive waveform in a multisync monitor is most appropriate according to a high frequency band in a low frequency band. It relates to a horizontal drive duty control circuit of the monitor that can compensate for this.

In general, the frequency of 31.5 KHZ ~ 48 KHZ or more than 48 KHZ is applied to the multi-sync monitor, and the optimum drive condition for each frequency can be satisfied by appropriate compensation according to the frequency.

As shown in FIG. 1, the conventional horizontal drive control circuit includes a sync processor 10 for outputting a high signal or a low signal according to a state of a frequency applied to a monitor, a transistor Q1, and a resistor ( R4) is configured by the switching unit 20 to perform the on and off switching operation in accordance with the signal applied from the sink processor 10, and resistors R1 to R3 to the DC voltage according to the state of the switching unit 20 The voltage control unit 40 determines and applies a constant voltage to the horizontal oscillator 30, and outputs a constant pulse signal by a DC voltage and a triangular wave applied to the voltage adjusting unit 40 to generate a horizontal drive circuit 50. It consists of a horizontal oscillator 30 applied to.

The horizontal drive control circuit of the conventional monitor configured as described above outputs a high signal when the sink processor 10 has a level higher than or equal to a frequency required, and outputs a low signal when the level is lower than a required frequency. If a high signal is applied to the base terminal of the transistor Q1, the transistor Q1 is turned on to lower the average DC voltage of the voltage regulator 40.

That is, the DC voltage level at point A is lowered and applied to the horizontal oscillator 30 while the resistor R1 and the resistor R3 of the voltage adjusting unit 40 are switched in parallel.

Therefore, in the horizontal oscillator 30, the average level of triangular waves generated therein is determined by the DC voltage applied through the voltage adjusting unit 40, and a pulse waveform having a duty value of a predetermined period is output.

In addition, when a pulse waveform having a constant duty value output from the horizontal oscillator 30 is applied to the horizontal drive circuit 50, the output signal of the horizontal deflection portion is sufficiently deflected, as can be seen from the above description. The pulse waveform could not be output to have a duty value suitable for the frequency level, but in order to have a duty value for each frequency level, a number of switching parts between the horizontal oscillator and the sink processor must be configured to match each frequency level. There was a problem that the circuit was very complicated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is the duty of an oscillation signal applied to a horizontal drive circuit so as to satisfy a horizontal drive condition from a low frequency band to a high frequency band in a multi-sync monitor without difficulty. It is to provide a horizontal drive duty control circuit of the monitor that can convert the value properly.

In order to achieve the above object, the present invention provides a voltage generator for converting an input horizontal frequency into a DC voltage or a PWM output voltage in proportion to a corresponding frequency and outputting a DC voltage when the signal connected to the voltage generator is a PWM voltage. A low pass filter for converting the voltage, an inverting amplifier connected to the low pass filter for amplifying and inverting a DC voltage applied from the voltage generator by a predetermined slope and magnitude, and inverting connected to the inverting amplifier A DC splitter for dividing the DC voltage applied from the amplifier into a constant DC voltage, and a horizontal level for determining the reference level of the triangular wave by the DC voltage connected to the DC splitter and outputting an oscillation signal having a corresponding duty value. The oscillator and the drive unit according to the pulse signal applied to the horizontal oscillator That comprises a horizontal drive circuit for biasing an arc is characterized.

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

2 is a horizontal drive duty control circuit according to the present invention, in which a voltage generator 60 converts a horizontal frequency into a direct current voltage or a PWM output voltage in proportion to the magnitude of an input horizontal frequency, and outputs a resistor R8 and The low pass filter unit 70 is configured as a capacitor (C1) for converting only the PWM voltage output from the voltage generator into a DC voltage, resistors (R1 ~ R4) and amplifier (OP1) is composed of a voltage generator 60 Inverter amplifier 80 and the resistor (R5 ~ R7) to invert the DC voltage output from the amplifier through the inverting terminal of the amplifier (OP1) and amplified to a predetermined size again, the bias voltage (VCC) and inverted amplifier A triangular wave by a DC splitter 90 for dividing the voltage applied from 80 to generate a constant DC voltage, and a DC voltage connected to the DC splitter 90 and applied from the DC splitter 90. Enter the reference level by determining the reference level It made an oscillation signal having a duty value appropriate to the number of the horizontal oscillator 30 to output to the horizontal drive circuit 50.

Hereinafter, the operation of the present invention having such a configuration will be described in detail.

When the horizontal frequency of 31.5KHZ ~ 48KHZ or more than 48KHZ is input to the voltage generator 60, the voltage generator 60 is converted into a DC voltage or PWM voltage to be output in proportion to the input horizontal frequency.

In this case, when the PWM voltage is output from the voltage generator 60, the low pass filter 70 rectifies the DC voltage of a predetermined magnitude by the resistor R8 and the capacitor C1 and applies it to the inverting amplifier 80.

Then, since the voltage waveform output from the voltage generator 60 is actually smaller than the DC voltage VCC applied to the DC divider 90, the inversion amplifier 80 performs inversion and amplification.

Therefore, the output voltage V ₀ = ((− R 2 / R 1) × A) + (1+ (R 2 / R 1)) × B is determined. (A and B are potential values of the parts shown in the drawing.)

As described above, if the horizontal frequency input of using the inverting amplifier 80 is high, the voltage at point A is high. In order to actually compensate, the inverting and amplifying is used.

Also, if the input frequency is low, the voltage at point A is low, but the voltage required for compensation should be high.

Therefore, the output voltage decreases linearly as the input frequency increases, and increases as the input frequency decreases.

Therefore, when the input frequency is low, the voltage of V _O is increased to increase the DC voltage level having the point C of the DC splitter 90 so that the duty value of the oscillation signal generated in the horizontal oscillator 30 is reduced, thereby reducing the horizontal drive circuit 50. Since a large amount of current is applied to the horizontal signal, the deflection force of the horizontal signal is improved, and when the input frequency is high, the voltage of V _O is lowered, thereby lowering the DC voltage level having the point C of the DC divider 90. The duty value of the generated oscillation signal is increased, so that a small current is applied to the horizontal drive circuit 50, so that the deflection force of the horizontal signal is lowered.

Therefore, as described above, the level of the duty value is appropriately changed according to the level of the input frequency, thereby obtaining sufficient horizontal deflection.

As can be seen from the above description, the present invention has an effect of improving the reliability of the monitor by configuring the horizontal drive condition from the low frequency band to the high frequency band without difficulty in the multi-sync monitor.

Claims (1)

The voltage generator 60 converts the input horizontal frequency into a DC voltage or a PWM output voltage in proportion to the corresponding frequency and outputs the DC voltage when the signal connected to the voltage generator 60 is a PWM voltage. A low pass filter 70 for converting and an inverted amplifier 80 connected to the low pass filter 70 to amplify and invert DC voltage applied from the voltage generator 60 to a predetermined slope and magnitude. And a reference level of the triangular wave is determined by a DC splitter 90 for dividing the DC voltage applied from the inverted amplifier 80 into a constant DC voltage and a DC voltage applied from the DC splitter 90. By outputting an oscillation signal having a corresponding duty value, the horizontal drive circuit 50 is driven by a pulse signal to form a horizontal oscillator 30 configured to deflect the horizontal signal. The horizontal drive duty control circuit.