KR0125389Y1 - Dynamic focusing circuit of a monitor - Google Patents

Abstract

The present invention detects a horizontal output pulse voltage that varies in accordance with the video input frequency and limits the voltage level when the horizontal output pulse voltage is high so that a constant horizontal / vertical parabola signal is always applied to the dynamic focus circuit. It relates to a focus stabilization circuit. The present invention detects a horizontal output pulse voltage that varies in accordance with the video input frequency in the input frequency detector. At this time, the reference voltage setting unit sets the reference voltage so that the voltage set lower than the zener voltage of the horizontal output stabilization unit is output when the 33.75KHz input is performed. The horizontal output stabilizer is operated by the output voltage of the input frequency detector when the 31.5KHz input is applied so that the horizontal output pulse voltage is lowered. Therefore, according to the present invention, the focus is accurately formed on the screen, and the life span and the number of overlapping capacitors can be reduced to efficiently use the product space.

Description

Dynamic focus stabilization circuit of color monitor

1 is a conventional horizontal / vertical parabola signal generating circuit diagram.

(A) and (b) of FIG. 2 are output waveforms according to the video input frequency of FIG.

3 is a dynamic focus stabilization circuit diagram of a color monitor of the present invention.

(A) and (b) of FIG. 4 are output waveforms according to the video input frequency of FIG.

* Explanation of symbols for main parts of the drawings

10: horizontal output generator 20: rectifier circuit

40: input frequency detection unit 50: reference voltage setting unit

60: horizontal output stabilizer T1: horizontal output transformer

ZD1, ZD2: Zener Diode L1: Horizontal Modulation Coil

C3, C4: Overlap Capacitor TR1-TR5: Transistor

The present invention detects the level of the horizontal output pulse which changes as the video input frequency of the color monitor changes. When the horizontal output pulse voltage is high, the constant horizontal / vertical parabola signal is always applied to the dynamic focus circuit by limiting the voltage level. The present invention relates to a dynamic focus stabilization circuit of a color monitor to ensure that the screen focuses accurately.

In general, in high-vision color monitors or high-definition televisions (HD-TV), horizontal / vertical parabola signals are applied to dynamic focus circuits to deflect the electron beam output from the electron gun, thereby reducing the focus of the electron beam. It is adjusted so that it forms exactly on the fluorescent surface. At this time, if the video input frequency is changed according to the broadcasting method, the voltage level of the horizontal / vertical parabola signal applied to the dynamic focus circuit is also significantly changed.

1 is a conventional circuit diagram for generating a horizontal / vertical parabola signal to be applied to a dynamic focus circuit according to a video input frequency. As shown, the conventional circuit is switched in accordance with the pulse signal applied from the horizontal drive unit resistor R1, transistor TR1, damper diode to generate a pulse signal on the primary coil of the horizontal output transformer T1. (D1) and a horizontal output generator (10) made of a resonant capacitor (C1). A rectifier circuit 20 composed of a diode D2, a capacitor C2, and a resistor R2, R3 is connected to an output terminal of the horizontal output generator 10, and a pulse generated at the collector terminal of the transistor TR1. The signal is rectified and smoothed to convert into a DC voltage. The DC voltage output from the rectifier circuit 20 is applied to the horizontal modulation coil L1 through the resistor R4 in a state in which it is added with the vertical parabola signal applied from the vertical output circuit. On the other hand, the output terminal of the horizontal output generator 10 is also connected to the primary coil of the horizontal output transformer (T1), the other side of the primary coil is connected to the DC power supply (Vcc) through the resistor (R5) to generate a horizontal output It serves as a driving power source for the transistor TR1 of the unit 10. A horizontal modulating coil L1 is connected to the secondary coil of the horizontal output transformer T1, and an overlapping capacitor C4 is connected between the other side of the secondary coil and the horizontal modulating coil L1.

In addition, the conventional circuit includes an input frequency discriminating unit 30 composed of a resistor R7, a transistor TR2, and a diode D3 for switching the power supply to the relay RY1 according to a control signal applied from the microcomputer. . The input frequency determination unit 30 is connected to one end of the relay RY1 coil, and the other end of the relay RY1 coil is connected to the relay driving power supply Vcc through a resistor R6. One terminal of the relay RY1 switch that is turned on / off according to the driving of the relay RY1 is connected to a connection point of the superimposed capacitor C4 and the horizontal modulating coil L1, that is, a horizontal / vertical parabola signal output terminal. The other terminal of the (RY1) switch is connected to the connection point between the secondary side coil of the horizontal output transformer T1 and the overlapping capacitor C4 through another overlapping capacitor C3.

When a pulse signal of 31.5 KHz or 33.75 KHz is input from the horizontal drive unit to the conventional circuit configured as described above, the pulse signal is applied to the base of the transistor TR1 of the horizontal output generator 10 through the resistor R1. The transistor TR1 is turned on and off in response to a pulse signal input to the base, and accordingly, the DC power supply Vcc is supplied and shut off through the primary coil of the horizontal output transformer T1 and the transistor TR1. Pulse signal of 1000V _PP ~ 1800V _PP is generated in the side coil.

The amplitude of the generated pulse signal varies depending on the video input frequency. When a pulse signal of 33.75 KHz is input from the horizontal drive unit, a pulse signal of 1000 V _PP is applied to the rectifier circuit 20 and converted into a DC voltage. That is, after half-wave rectification by the diode D2, the capacitor is smoothed by passing through the capacitor C2 and output in a reduced pressure state by the resistors R2 and R3. The output DC voltage corrects the position of the raster to adjust the deflection of the electron beam, and the DC voltage is horizontal through the resistor R4 in addition to the vertical parabola signal applied from the vertical output circuit. It is applied to the secondary side of the output transformer T1. When the video input frequency is 33.75KHz, the microcomputer outputs a control signal of low potential, and the signal is applied to the base of the transistor TR2 through the resistor R7 of the input frequency discriminator 30 and thus the transistor TR2. ) Is off. Therefore, no current flows through the relay RY1 coil, and the relay RY1 switch is turned off as the relay RY1 is not driven. Therefore, the horizontal parabola signal and the DC voltage output from the secondary coil of the horizontal output transformer T1 are turned off. The added vertical parabola signal is applied to the horizontal modulating coil L1 and the overlapping capacitor C4. Therefore, the parabolic signal of 1000 V _PP can be obtained through the horizontal / vertical parabola signal output stage as shown in FIG.

When the video input frequency is 31.5KHz, the microcomputer outputs a high-potential control signal, so that the transistor TR2 of the input frequency discriminator 30 is turned on, so that the relay driving power supply Vcc becomes the resistor R6. Since the relay RY1 is applied to the coil RY1, the relay RY1 is driven. When the relay RY1 switch is connected by driving the relay RY1, the horizontal parabolic signal and the vertical parabola signal output from the secondary coil of the horizontal output transformer T1 and the DC voltage are added to the horizontal modulation coil L1 and the relay. Since it is applied to a (RY1) switch and an overlapping capacitor (C3) (C4), a horizontal / vertical parabola signal of 1600V _PP as shown in FIG. 2 (b) can be obtained.

However, in this method, the horizontal parabola voltage (1600V _PP , 1000V _PP ) varies considerably according to the video input frequency (31.5KHz, 33.75KHz), and the focus on the screen is shifted due to the amplitude difference of the horizontal parabola signal according to the input frequency. There was a problem that could not be obtained. In addition, when the 31.5KHz input, the horizontal parabola voltage is 1600V _PP and the internal pressure of the capacitor should be about 1.5 ~ 2.0 times higher than that of the 33.75KHz dedicated condenser, which shortens the life of the 31.5KHz dedicated condenser and reduces the reliability of the circuit.

The present invention is to solve the conventional problems as described above, the object of the present invention is to detect the level of the horizontal output pulse fluctuates according to the video input frequency and to always maintain a constant horizontal / by limiting the voltage level when the horizontal parabolic voltage is high The present invention provides a dynamic focus stabilization circuit of a color monitor that allows a vertical parabola signal to be applied to a dynamic focus circuit so that focus is accurately formed on a screen.

Another object of the present invention is to provide a dynamic focus stabilization circuit of a color monitor that can improve the reliability of the circuit by extending the life of the overlapping capacitor by limiting the voltage so that a low horizontal parabola voltage can be used even when the video input frequency is converted. have.

Another object of the present invention is to provide a color monitor dynamic focus stabilization circuit that reduces the number of large-capacity overlap capacitors to reduce the production cost and efficiently use the product space by designing a small area component.

The dynamic focus stabilization circuit of the color monitor of the present invention for achieving the above objects is provided with a horizontal output generator for switching in accordance with the pulse signal applied from the horizontal drive unit to generate a horizontal output pulse voltage. The input frequency detector connected to the output terminal of the horizontal output generator detects a horizontal output pulse voltage that varies in accordance with the video input frequency. The reference voltage setting unit connected to the input frequency detection unit is turned on by the set low voltage so that the voltage set lower than the Zener voltage of the horizontal output stabilization unit is output so as to set the comparison reference voltage at the determination of the input frequency. A horizontal output stabilizer is connected to an output terminal of the input frequency detector and the reference voltage setter, and when the horizontal output pulse voltage is high, the voltage is reduced and stabilized. A rectifier circuit is connected to the output terminal of the horizontal output generator to convert the horizontal output pulse voltage into a DC voltage by rectifying and smoothing the horizontal output pulse voltage. The DC voltage output from the rectifier circuit is applied to the secondary side of the horizontal output transformer in addition to the vertical parabola signal, and the horizontal / vertical parabola signal of a constant level is always output by overlapping the horizontal parabola signal by the horizontal modulating coil and the overlap capacitor. do.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 3 and 4 as follows.

3 is a dynamic focus stabilization circuit diagram of a color monitor of the present invention. As shown, the circuit of the present invention is switched in accordance with the pulse signal applied from the horizontal drive unit resistor (R1), transistor (TR1), damper to generate a pulse signal to the primary coil of the horizontal output transformer (T1) The horizontal output generator 10 includes a diode D1 and a resonant capacitor C1. An output frequency detector 40, a horizontal output stabilizer 60, and a rectifier circuit 20 are respectively connected to the output terminal of the horizontal output generator 10. The input frequency detector 40 is turned on according to the voltage divided by the resistor R8 and the variable resistor VR1 for dividing the output pulse voltage of the horizontal output generator 10 and the resistor R8 and VR1. And an output pulse voltage of the horizontal output generator 10, which is composed of the transistor TR3 and the resistors R9 and R10 that are turned off and which varies according to the video input frequency. The reference voltage setting unit 50 connected to the input frequency detector 40 may include a resistor R11, a Zener diode ZD1, a smoothing capacitor C5, and a resistor for dividing the smoothed voltage. R12) and R13, and a transistor TR4 which is conducted by the divided voltage and sets a comparison reference voltage at the time of discriminating the input frequency. A horizontal output stabilization unit 60 is connected to an output terminal of the input frequency detection unit 40, the DHK reference voltage setting unit 50, and when the pulse voltage output from the horizontal output generation unit 10 is high, the voltage is reduced and stabilized. . The horizontal output stabilizer 60 is connected to the output terminal of the input frequency detector 40 and the reference voltage setting unit 50 to divide the voltage passing through the zener diode ZD2 and the zener diode ZD2 to determine the input frequency. A transistor TR5 for switching the variable resistor VR2 and the resistor R14 and the voltage divided by the resistors VR2 and R14 to limit the pulse voltage output from the horizontal output generator 10; It consists of resistors R15 and R16.

On the other hand, a rectifier circuit 20 composed of a diode D2, a capacitor C2, and a resistor R2 is connected to an output terminal of the horizontal output generator 10, and the rectifier circuit 20 is a horizontal output generator 10. The pulse voltage output from) is rectified and smoothed to convert into DC voltage. The DC voltage output from the rectifier circuit 20 is applied to the connection point between the secondary coil of the horizontal output transformer T1 and the superimposed capacitor C4 in the state of being added to the vertical parabola signal applied from the vertical output circuit. One side of the primary coil of the horizontal output transformer (T1) is connected to the output terminal of the horizontal output generator 10, the other side of the primary coil is connected to the DC power supply (Vcc) through a resistor (R5) to the horizontal output generator It acts as a driving power source for the transistor TR1 of (10). A horizontal modulating coil L1 is connected to one side of the secondary coil of the horizontal output transformer T1, and an overlapping capacitor C4 is connected between the other side of the secondary coil and the horizontal modulating coil L1.

When a pulse signal of 31.5 KHz or 33.75 KHz is input from the horizontal drive unit to the dynamic focus stabilization circuit configured as described above, the pulse signal is transmitted to the base of the transistor TR1 of the horizontal output generator 10 through the resistor R1. Is approved. The transistor TR1 is turned on or off in response to a pulse signal input to the base, so that the DC power supply Vcc is supplied and shut off through the primary coil of the horizontal output transformer T1 and the transistor TR1. Pulse voltage of 1000V _PP ~ 1800V _PP is generated in the secondary coil.

The pulse voltage generated at this time varies depending on the video input frequency. When a pulse signal of 33.75 KHz is input from the horizontal drive unit, a pulse voltage of 1000 V _PP is output. The pulse voltage is divided by the resistor R8 and the variable resistor VR1, the level is lowered, and then applied to the base of the transistor TR3. Since the base voltage is not high enough to conduct the transistor TR3, the transistor (TR3) is turned off. At this time, the low voltage V1 is input to the reference voltage setting unit 50 to smooth the constant voltage by the zener diode ZD1 and the capacitor C5, and the smoothed voltage is divided by the resistors R12 and R13, and then the transistor. It is applied to the base of TR4 to conduct the transistor TR4. Therefore, the output pulse voltage of the horizontal output generator 10 is output to the emitter stage through the resistor R9 and the transistor TR4, and the voltage is set lower than the zener voltage of the zener diode ZD2. The voltage applied to the base of the transistor TR5 through the diode ZD2 and the resistor R14 is in a low potential state.

Therefore, the transistor TR5 of the horizontal output stabilizer 60 is turned off, and the pulse voltage output from the horizontal output generator 10 is applied to the rectifier circuit 20 as it is and converted into a DC voltage. That is, after half-wave rectification by the diode D2, the capacitor is smoothed by passing through the capacitor C2 and outputted in a reduced pressure state by the resistor R2. Here, the DC voltage output serves to adjust the deflection of the electron beam by correcting the position of the raster, and this DC voltage is added to the secondary side of the horizontal output transformer T1 in addition to the vertical parabola signal applied from the vertical output circuit. Is approved. The horizontal parabola signal output from the secondary coil of the horizontal output transformer T1 and the vertical parabola signal added with the DC voltage are applied to the horizontal modulating coil L1 and the overlapping capacitor C4. Therefore, the parabolic signal of 1000 V _PP can be obtained through the horizontal / vertical parabola signal output stage as shown in FIG.

On the other hand, when the video input frequency is 31.5KHz, a pulse voltage of 1600V _PP is output from the horizontal output generator 10. The pulse voltage is divided by the resistor R8 and the variable resistor VR1, the level is lowered, and then applied to the base of the transistor TR3. The transistor TR3 is turned on by the base voltage. At this time, since the transistor TR4 of the reference voltage setting unit 50 is turned on by the low voltage V1, the output pulse voltage of the horizontal output generation unit 10 is the resistance R9 and the transistors TR3 and TR4. Is output to the emitter stage. Since the voltage is considerably higher than the zener voltage of the zener diode ZD2, the voltage applied to the base of the transistor TR5 through the zener diode ZD2 and the resistor R14 is in a high potential state, and the horizontal output stabilization unit ( Transistor TR5 of 60 is conductive.

The transistor (TR5) is output from the horizontal output generating section 10 as the conduction pulse voltage is limited is applied to the transistor (TR5) through a resistor (R15), Thus, the lower a 1000V _PP rectification circuit 20 Pulse voltage is applied. The pulse voltage is half-wave rectified by the diode D2 and then smoothed by the capacitor C2 to become a DC voltage, and the DC voltage output from the rectifying circuit 20 is added to the vertical parabola signal to the horizontal output transformer T1. Applied to the secondary side. Since the horizontal parabola signal and the DC voltage added to the horizontal parabola signal output from the secondary coil of the horizontal output transformer T1 are applied to the horizontal modulating coil L1 and the overlapping capacitor C4, the input is performed as shown in (b) of FIG. Even when the frequency is 31.5 KHz, as in the case of 33.75 KHz, a horizontal / vertical parabola signal of 1000 V _PP can be obtained.

As described above, the present invention detects the level of the horizontal output pulse fluctuating according to the video input frequency. When the horizontal output pulse voltage is high, the voltage level is lowered so that a constant horizontal / vertical parabola signal is always applied. The effect is to make sure the focus is on. In addition, the low horizontal / vertical parabola voltage can be used to improve the reliability of the circuit by extending the life of the overlapping capacitors and to reduce the number of large-capacity overlapping capacitors. There is an effect that can be used efficiently.

Claims (1)

Generates horizontal parabola signal and DC voltage for raster position adjustment by using horizontal output pulse voltage generated by pulse from horizontal drive unit, and outputs horizontal / vertical parabola signal by superimposing these signals and vertical parabola signal. In the circuit, An input frequency detector for detecting the horizontal output pulse voltage that varies with a video input frequency; A reference voltage setting unit configured to set a comparison reference voltage at the time of discriminating the input frequency by conducting by the set low voltage and outputting a voltage set lower than the zener voltage of the horizontal output stabilization unit; And a horizontal output stabilizer for switching the voltage according to the output voltage of the input frequency detector and the reference voltage setter to reduce and stabilize the voltage when the horizontal output pulse voltage is high. 2. The apparatus of claim 1, wherein the input frequency detector comprises: a resistor and a variable resistor for dividing the horizontal output pulse voltage; A transistor turned on and off in accordance with the voltage divided by the resistors; And a resistor connected to the collector and the emitter of the transistor. 3. The apparatus of claim 1, wherein the reference voltage setting unit comprises: a zener diode and a smoothing capacitor for making the set low voltage constant; Resistors for dividing the smoothed voltage; And a transistor which is turned on by the divided voltage and sets a comparison reference voltage at the time of discriminating an input frequency. 4. The apparatus of claim 1, wherein the horizontal output stabilization unit comprises: a zener diode which is turned on / off according to the output voltages of the input frequency detector and the reference voltage setting unit to determine the input frequency; A variable resistor and a resistor for dividing the voltage across the zener diode; A transistor which is switched according to the voltage divided by the resistors to limit the horizontal output pulse voltage to a predetermined level; And a transistor comprising resistors connected to the collector and the emitter.