KR0127537B1 - Horizontal frequency hold control circuit of monitor - Google Patents

Abstract

The horizontal frequency hold adjusting circuit of a monitor comprises a frequency/voltage converting unit for converting inputted horizontal frequency into voltage, a shaping unit for shaping the voltage outputted from the frequency/voltage converting unit, an incline controlling unit for varying a determined reference incline by voltage outputted from the shaping unit and outputting a hold signal having the incline varied according to each horizontal frequency, and an amplifying unit for amplifying the hold signal adjusted in the incline in the incline controlling unit, whereby simplifying the construction of a circuit and curtailing a cost and also providing a stabilized circuit operation through an easy adjustment of a hold signal.

Description

Horizontal frequency hold adjustment circuit of the monitor

1 is a diagram showing the configuration of a horizontal frequency hold adjustment circuit of a general monitor.

2 is a diagram showing the configuration of the horizontal frequency hold adjustment circuit of the monitor according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: frequency / voltage conversion unit 20: shaping unit

30: tilt control unit 40: amplification unit

R21 to R24, R31 to R35, R41: Resistor Q31: Transistor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitor, and more particularly, to a horizontal frequency hold adjustment circuit of a monitor that generates hold signals having different inclinations depending on the input horizontal frequency.

As shown in FIG. 1, the horizontal frequency hold adjustment circuit of a general monitor includes an F / V converter 1 in which an input horizontal frequency is converted into a voltage, and a voltage output from the F / V converter 1. Comparing the amplification voltages of the reference voltage and the F / V voltage with each of the amplification unit 2 for amplifying a and a control signal for outputting a hold signal synchronized with the voltage output from the amplifying unit 2 Hold voltage adjusting unit composed of a control unit (3) configured as a comparator to control the switching unit, and an OP-AMP amplified by a different slope by the voltage output from the amplifier (2) and the hold voltage set by the user ( 4) and a switching section 5 which is switched by a control signal output from the control section 3 so as to pass a hold signal having a slope output from the hold voltage adjusting section 4.

Here, the comparator 4 biases the variable resistors VR41-VR43 in which the hold adjustment voltage is set by the user, and the hold voltages output through the respective variable resistors VR41-VR43. The resistors R41-R43, the output voltages of the resistors R41-R43 are applied to the capacitors C41-C43 and the + terminals of the amplifiers OP41-OP43. R48, R45, R44, R49, R47, R46 and R50, R51, R52 were used to amplify and modulate the amplified voltages of F / V to voltages having different slopes. In other words, R48, R45, R49, R47, R50, and R51 are used to divide the voltage connected to the negative terminal of the hold voltage regulation amplifier from Vcc2, and the slope is the same as that of the non-inverting amplifier circuit. The output voltage of the OP-AMP is, respectively, the voltage of the amplifier 2 x (1 + R44 / R45), the amplifier 2 voltage x (1 + R46 / R47), and the amplifier 2 voltage x ( 1 + R52 / R51 are configured as amplifiers OP41-OP43 which respectively hold hold voltages having different inclinations are output using the voltage output from the amplifier 2.

In the horizontal frequency hold adjustment circuit of a general monitor configured as described above, first, the input horizontal frequency is applied to the F / V converter 1, converted into a voltage, and then applied to the amplifier 2 to be amplified.

The amplified voltage of the amplifying unit 2 is applied to the control unit 3 to switch the switching unit 5 to synchronize the amplified modulation voltages having different slopes configured using the amplified voltage with the hold adjustment voltage. A control signal for outputting is output.

On the other hand, the amplified voltage of the amplifier 2 is input to the amplifiers OP1-OP3 of the hold voltage adjusting unit 4, respectively, and the voltage set by the variable resistors VR41-VR43 is a resistor ( Bypassed via R41)-(R43) respectively.

The hold adjustment voltages, each of which is divided by the resistors R41-R43 and the equivalent resistances of the hold adjustment terminals, are shaped by (C41)-(C43).

On the other hand, the resistors R44, R45, R46, R47, and R51, R52 become resistors for determining the respective slopes. That is, it becomes a feedback resistor which causes the output voltage of each of (OP41)-(OP43) of resistors R44, R46, and R52 to be fed back.

The voltages to be divided between the resistors R44, R45, R46, R47, and R51, R52 overlap with the power supply Vcc input through the resistors R48, R49, and R50. After that, the voltage is applied to the negative terminal of the amplifiers OP41 (OP42) and OP43 and amplified to different slopes by the voltage applied to the positive terminal of the amplifiers OP41 (OP42) and OP43.

A signal output from the amplifiers OP41-OP43 and a voltage input through the resistors R41-R43 overlap and are output as a hold adjustment signal, and the hold adjustment signal is output to each switch of the switching unit 5. (SW1)-(SW3), wherein the switches (SW1)-(SW3) are configured as a comparator for switching control for each frequency section by comparing the amplified voltage of the F / V voltage with the self-set voltage. It is switched by the control signal output from the control part 3.

That is, the hold adjustment signal output from the hold voltage adjustment unit 4 is applied to the hold adjustment terminal via a switch switched by a control signal generated by the voltage output from the amplifier 2. The hold adjustment signal has a different slope according to each input horizontal frequency.

The hold adjustment signal passing through the switching unit 5 is applied to an oscillator not shown in the figure to output a triangular waveform horizontal deflection signal.

As described above, the horizontal frequency hold adjustment circuit of a general monitor does not operate stably because the circuit configuration is complicated, and in particular, when the temperature rises, the control unit malfunctions and the correct hold adjustment signal is not output.

Accordingly, an object of the present invention is to solve the above problems, and an object of the present invention is to provide a horizontal frequency hold adjustment circuit of a monitor that can be stably operated as well as easy to adjust the horizontal frequency hold adjustment circuit. have.

The object of the present invention as described above is frequency / voltage converting means for varying the input horizontal frequency into voltage, shaping means for shaping the voltage output from the frequency / voltage converting means, and the set reference slope is output from the shaping means. A tilt control means for outputting a hold signal having a slope which is variable by voltage and variable according to each horizontal frequency, and an amplification means for amplifying the hold signal whose slope is adjusted by the tilt control means The purpose is to provide a frequency hold adjustment circuit.

An embodiment of a horizontal frequency hold adjustment circuit of a monitor according to the present invention will be described in more detail with reference to the accompanying drawings.

2 is a diagram illustrating a configuration of a horizontal frequency hold adjustment circuit of a monitor according to the present invention. As shown in FIG. 2, a frequency / voltage converter 10 in which an input horizontal frequency is changed into a voltage and the frequency / voltage A shaping unit 20 for shaping the voltage output from the converting unit 10, a tilt control unit 30 for varying the set reference slope by the voltage output from the shaping unit 20 and outputting a hold adjustment circuit; An amplifier OP41 and a resistor R41 configured to amplify the voltage output from the shaping unit 20 outputted by modulation from the slope control unit 30 to a desired hold adjustment voltage. It is composed.

Here, the shaping unit 20 may include a resistor R21 through which an input voltage is bypassed, a resistor R22 through R23 through which an input power Vcc is distributed, and a resistor R22 through R23. It is composed of a capacitor (C21) (C22) and a resistor (R24) for shaping a DC component after the voltage and the voltage output through the resistor (R21) is superimposed.

The inclination controller 30 may include resistors R31 and R32 for generating a reference inclination of the hold adjustment signal output from the amplifier 40, and a resistor for distributing a signal output from the shaping unit 20. The current flowing through the resistor R32 is adjusted according to the switching state of the transistor Q31 and the transistor Q31 which are switched by the divided signals of the resistors R33 and R34. And a resistor R35 for adjusting the reference slope.

In the horizontal frequency hold adjustment circuit of the monitor according to the present invention configured as described above, first, the horizontal frequency input to the frequency / voltage converter 100 is converted into a voltage and then through the resistor R21 of the shaping unit 20. Bypassed. The power source Vcc input at that time is distributed by the resistors R22 and R23.

The voltage bypassed through the resistor R21 and the voltage distributed by the resistors R22 and R23 are superimposed and then shaped by the capacitors C21 and C22 and the resistor R24 to be proportional to the DC signal. Is output.

The signal output from the shaping unit 20 is initially amplified by the amplifying unit 40, and the hold signal that is amplified and then output is a reference determined by the resistors R31 and R32 of the slope control unit 30. You have a slope.

Meanwhile, the signal output from the shaping unit 20 is distributed by the resistors R33 and R34 of the tilt control unit 30 and then applied to the base side of the transistor Q31 so that the transistor Q31 is always in an active state. Is maintained at the base side of the transistor Q31 so that the transistor Q31 is always kept in an active state, and the current flowing through the resistor R35 is controlled by the active state of the transistor Q31. It also sets resistor R35 so that transistor Q31 is always active.

That is, since the amount of current flowing through the resistor R32 is adjusted by the transistor Q31 and the resistor R35, the reference slope determined by the resistors R31 and R32 is adjusted.

At this time, the signal output from the shaping unit 20 is applied to the amplifier OP41 of the amplifier 40 and the applied voltage is a hold signal having a slope adjusted by the tilt controller 30. After the amplification in the amplifier OP41 is biased through the resistor (R41), the hold signal output from the resistor (R41) is applied to the oscillation circuit not shown in the figure is oscillated after the horizontal deflection signal of the triangular waveform is output do.

As described above, the horizontal frequency hold adjustment circuit of the monitor according to the present invention has an effect that the circuit configuration is simple and the cost is reduced and the hold signal is easily adjusted to operate stably.

Claims (3)

A frequency / voltage converting means in which an input horizontal frequency is changed into a voltage, a shaping means for shaping a voltage output from the frequency / voltage converting means, and a set reference slope is varied by a voltage output from the shaping means and each horizontal And a tilt control means for outputting a hold signal having a slope which varies with frequency, and an amplification means for amplifying the hold signal whose slope is adjusted by the tilt control means. The method according to claim 1, wherein the shaping means includes a resistor R21 through which an input voltage is bypassed, a resistor R22 through R23 through which an input power Vcc is distributed, and the resistors R22 through R23. The horizontal frequency hold of the monitor, characterized in that it consists of a capacitor (C21) (C22) and a resistor (R24) to which the hold signal is output after being superimposed on the divided voltage and the voltage output through the resistor (R21). Adjustment circuit. 2. The resistor R33 of claim 1, wherein the tilt control means comprises: resistors R31 and R32 for generating a reference slope of a hold signal output from the amplifying means, and a resistor R33 for distributing a signal output from the shaping unit 20. R34, the transistor Q31 switched by the divided signals of the resistors R33 and R34, and the current flowing through the resistor R32 are adjusted according to the switching state of the transistor Q31, and the reference is made. A horizontal frequency hold adjustment circuit of a monitor, characterized in that it is not only composed of a resistor (R35) whose slope is adjusted, but also allows the transistor (Q31) to operate in an active region.