KR970004496Y1 - Monitor's spool type wave mixing circuit - Google Patents

Abstract

None.

Description

Monitor's Failure Waveform Mixing Circuit

1 is a failure waveform waveform mixing circuit diagram of a conventional monitor.

2 is a waveform diagram of an output signal according to an input signal in FIG.

Figure 3 is an embodiment of the present invention

4 is an output waveform diagram according to the power supply voltage in FIG.

* Explanation of symbols for main parts of the drawings

Q1-Q5: transistor R1-R11: resistor

C1: capacitor D1, D2: diode

100: current supply unit 200: differential amplifier

300: overcurrent prevention part

The present invention relates to a faulty waveform mixing circuit of a monitor. In particular, when a high voltage and a deflection are separated, a failure of a monitor that is suitable for minimizing heat loss caused by a horizontal frequency change and preventing an overcurrent from flowing to an output terminal is prevented. It relates to a waveform waveform mixing circuit.

1 is a failure waveform waveform mixing circuit diagram of a conventional monitor. As shown in FIG. 1, a turn-on amount is formed according to a DC voltage and a parabola waveform input by a resistor R1, R2, R3, a capacitor c1, and a transistor Q1. A current supply control unit 10 that varies; Comprising a resistor (R4) and a transistor (Q2) consists of a current supply unit 20 for adjusting the current according to the power supply voltage (VCC) according to the turn-on amount of the current supply control unit 10 to supply to the horizontal output circuit.

Looking at the operation of the conventional circuit configured as described above are as follows.

According to the change of the screen size or the horizontal frequency, the input signal Vin in which the DC voltage A and the parabolic waveform D are mixed as shown in (a) of FIG. 2 is transferred through the resistor R1 to the transistor Q1. When applied to the base of the transistor Q1, the amount of turn-on current varies in proportion to its input signal Vin.

At this time, the transistor Q2 outputs a current according to the power supply voltage VCC. The turn-on current amount of the transistor Q2 is also changed due to the change in the turn-on current amount of the transistor Q1.

The turn-on amount of the transistor Q2 is inversely proportional to the turn-on amount of the transistor Q1.

For example, when the input signal Vin as shown in a of FIG. 2 is applied due to a change in the horizontal frequency, the turn-on amount of the transistor Q1 is adjusted accordingly, and the transistor is turned on in accordance with the turn-on amount of the transistor Q1. The turn-on amount of Q2 is also adjusted so that a waveform as shown in b of FIG. 2 is output to the output terminal.

At this time, the heat loss of the transistor Q2 is generated by the difference voltage E obtained by subtracting the DC voltage C and the parabolic gain D from the power supply voltage VCC in the waveform shown in FIG.

Therefore, when the DC voltage portion C becomes smaller in the output waveform, the difference voltage E obtained by subtracting the DC voltage C and the parabolic gain D from the power supply voltage VCC becomes large, so that the heat loss of the transistor Q2 is further increased. Grows

As described above, in the conventional circuit, since the power supply voltage is fixed to one, when the DC voltage portion decreases due to the change in the horizontal frequency, the heat loss generated in the output transistor becomes larger.

The purpose of the present invention is to solve the conventional problems, by changing the power supply voltage in accordance with the change in the horizontal frequency to maintain the differential voltage minus the DC voltage portion and the parabolic gain portion of the power supply voltage to the heat loss of the output transistor It is possible to maintain a constant and to prevent the over-current by blocking the output current in the event of an over-current to provide a failure waveform waveform mixing circuit of the monitor.

The failure waveform waveform mixing circuit of the monitor for achieving the object of the present invention includes a current supply means for supplying a current according to the power supply voltage selected according to the magnitude of the horizontal frequency to the horizontal output circuit; Differential amplifying means for receiving a DC voltage and a constant parabola waveform proportional to a change in a horizontal frequency and always applying the DC voltage and a parabola waveform to the current supply means; And an overcurrent preventing means for blocking an overcurrent flowing to the output side of the current supply means.

Hereinafter, an embodiment will be described with reference to the operation and effects of the present invention.

3 is an exemplary embodiment of the present invention, and as shown therein, the currents according to the power supply voltages VCC1 to VCCn selected from the resistors R10 and R11 and the transistor Q4 are selected according to the magnitude of the horizontal frequency. A current supply unit 100 for supplying an output circuit; Resistor (R1-R9), capacitor (C1), diode (D1), transistor (Q1-Q3) is applied to receive an input signal (Vin) mixed with a DC voltage and a constant parabola waveform that increases in proportion to the horizontal frequency change A differential amplifier 200 which always applies a constant DC voltage and a parabola waveform to the current supply unit; Comprising a transistor (Q5) and a diode (D2) consists of an overcurrent prevention unit 300 to block the overcurrent flows to the output side of the current supply unit 100.

The operation of one embodiment of the present invention configured as described above will be described with reference to FIG.

The present invention, first, when the user changes the screen size or the horizontal frequency changes so that the power supply voltage (VCC) changes accordingly.

For example, if the highest voltage is VCC1 and the lowest voltage is VCCn, VCC1 is selected as the power supply voltage when the horizontal frequency is maximum, and VCCn is selected as the power supply voltage when the horizontal frequency is minimum.

A differential amplifier circuit including transistors Q2 and Q3 and resistors R5 and R6 is added and driven according to the output current of the current supply unit 100 fed back through the resistor R8.

Therefore, when the waveform as shown in a of FIG. 4 is referred to as the reference input signal Vin, when a signal having a DC voltage greater or smaller than that of the reference input signal Vin is input, the turn-on amount of the transistor Q1 receiving the input signal must be changed. In the differential amplifier circuit, the transistor Q1 collector current is always constant.

In this case, the parabola waveform of the input signal Vin generates a parabola waveform at a vertical period in order to correct vertical failure shape distortion of the screen.

In the specific operation of the differential amplifier circuit, when the output current increases and the current fed back to the base of the transistor Q3 through the resistor 8 increases, the current applied to the base of the transistor Q2 decreases to decrease the transistor Q1 collector. The current is constant.

In other words, a signal in which a constant DC voltage and a parabola waveform are mixed is always applied to the base of the transistor Q4.

As such, when the input signal applied to the base of the transistor Q4 becomes constant, for example, when the horizontal frequency becomes maximum, VCC1 is selected as the power supply voltage, thereby increasing the amount of current output through the transistor Q4. Therefore, the output waveform has a high DC voltage c as shown in b in FIG.

On the contrary, when the horizontal frequency becomes minimum, VCCn is selected as the power supply voltage so that the amount of current output through the transistor Q4 is reduced, so that the output waveform has a lower DC voltage e as shown in FIG.

At this time, as shown in b and c of FIG. 4, when the DC voltage c increases in the output waveform, the power supply voltage VCC1 is high, and when the DC voltage e decreases in the output waveform, the power supply voltage VCCn is low. Therefore, the difference voltage (k or p) is obtained by subtracting the DC voltage (c or e) and the parabolic gain (d or f) from the power supply voltage (VCC1 or VCCn).

Therefore, the heat loss of transistor Q4 is constant.

At this time, if the output current is Io, the output current Io can be obtained by the following equation.

Ldy: deflection coil, fh: horizontal frequency, VCC: power supply voltage

On the other hand, the voltage across the resistor R11 is determined by the output current output through the emitter of the transistor Q4. For example, if the output current increases and the voltage across the resistor R11 becomes larger than a predetermined value, for example, the transistor When the turn-on voltage of Q5 is equal to or higher than 0.7 V, the transistor Q5 is turned on. As a result, the transistor Q4 is turned off, and the overcurrent is not output and is cut off.

As described in detail above, the power supply voltage of the current supply unit also changes in proportion to the change in the horizontal frequency so that the difference voltage minus the output voltage from the power supply voltage is always constant regardless of the change in the horizontal frequency, thereby minimizing heat loss. In addition, when overcurrent flows to the output side, it blocks the circuit, thereby protecting the circuit.

Claims (1)

Current supply means for supplying a current according to a power supply voltage selected according to the magnitude of the horizontal frequency to the horizontal output circuit; Differential amplifying means for receiving a DC voltage and a constant parabola waveform proportional to a change in a horizontal frequency and always applying the DC voltage and a parabola waveform to the current supply means; Failure waveform mixing circuit of the monitor, characterized in that configured as an over-current prevention means for blocking the over-current flowing to the output side of the current supply means