KR100299172B1 - S correction circuit of the monitor - Google Patents

Abstract

The S correction circuit of the monitor of the present invention, in which the ideal linearity of the horizontal sawtooth signal is always maintained regardless of the frequency band of the horizontal oscillation signal, generates a sinusoidal signal through an S correction capacitor, and converts the sinusoidal signal into a horizontal deflection yoke. A S correction circuit of a monitor which applies and corrects linearity of a horizontal sawtooth wave signal, comprising: a parabolic signal generator for outputting a parabolic signal kept in synchronization with a horizontal oscillation signal; and a PWM signal for adjusting the amplitude and wavelength of the parabolic signal. And a parabolic amplifier for amplifying the parabolic signal whose amplitude and wavelength are adjusted by the PWM signal to a level required for linearity correction of the horizontal sawtooth signal and applying it to the S correction capacitor. It features.

Description

S correction circuit of the monitor

The present invention relates to a horizontal deflection portion of a monitor, and more particularly, to an S correction circuit of a monitor capable of ideally correcting linearity of a horizontal sawtooth wave signal regardless of a frequency band of a horizontal oscillation signal.

A monitor, which is widely used as a peripheral device of a computer, emits an electron beam into a cathode ray tube (abbreviated as CRT), and light generated when an electron beam penetrating the CRT collides with a fluorescent surface in front of the CRT. To implement the image.

1 is a horizontal output circuit diagram provided in the monitor.

The horizontal output circuit generates a sawtooth signal and applies it to a deflection yoke mounted at the rear of the CRT. The deflection yoke receiving the sawtooth signal from the horizontal output circuit exerts a deflection force to deflect the electron beam in the horizontal direction.

As shown in FIG. 1, the horizontal output circuit includes a horizontal output transistor Q1 for switching in response to a horizontal drive signal, a horizontal deflection yoke H-DY connected to a collector end of the horizontal output transistor Q1, And a S correction capacitor Cs for improving the linearity of the horizontal sawtooth wave signal applied to the horizontal deflection yoke H-DY.

In detail, the damping diode D2 and the capacitor C1 are connected in parallel between the horizontal output transistor Q1 and the horizontal deflection yoke H-DY.

When the horizontal output transistor Q1 is turned on, the high voltage signal applied from the FBT to the horizontal deflection yoke H-DY is transferred to the capacitor C1 when the horizontal output transistor Q1 is turned off. When the horizontal output transistor Q1 is turned on, it is applied to the horizontal deflection yoke H-DY again. The damping diode D2 prevents the excitation of the signal generated in this process. Reference numeral D1 denotes a driving power source applied with FBT ( B ⁺ ) Is a diode that rectifies.

Since the sawtooth signal applied to the horizontal deflection yoke (H-DY) through this process is very strong linearity, a sinusoidal wave having an appropriate resonant frequency is generated using the S correction capacitor (Cs), and the sinusoidal signal is a sawtooth wave signal. The linearity of the sawtooth signal is corrected by superimposing on the.

The phase (Phase) of the sine wave superimposed on the sawtooth signal is determined by the capacitance of the capacitor S for correction (Cs). Since the linearity correction degree of the sawtooth signal is determined according to the phase of the sine wave, the linearity degree of the sawtooth signal depends on the capacity of the capacitor S for correction S.

When the frequency of the horizontal oscillation signal applied from the computer video card (not shown) to the monitor is changed, the period of the horizontal sawtooth signal also changes, so to correct the linearity of the horizontal sawtooth signal with the changed period, the S correction capacitor (Cs) The capacity also needs to be varied.

As described above, in order to vary the capacitance of the S correction capacitor Cs according to the frequency of the horizontal sawtooth wave signal, a plurality of capacitors are connected in parallel to the S correction capacitor Cs as shown in FIG. 1. Method was used. 1 shows an example in which eight capacitors C2... C9 are connected for convenience.

In general, the total capacity of the capacitors connected in parallel is calculated by summing the capacity of each capacitor. Therefore, capacitors C2… C9 having a unit size of a constant size are connected in parallel to the S correction capacitor Cs, and FET1… series connected in series to each capacitor C2… C9. By selecting whether or not the capacitors C2 to C9 are grounded by conducting or not conducting FET8, the total capacitance on the S correction capacitor Cs side can be changed discretely.

That is, when the frequency of the horizontal oscillation signal is changed, the microcomputer (not shown) fetches the data corresponding to the displacement of the frequency from the memory (EPROM, etc.) to the capacitor (C2) connected in parallel to the S correction capacitor (Cs) … Ground and unground C9).

The patched data is connected to each of the capacitors C2... C9 connected in parallel to the S correction capacitor Cs. It is a combination of HIGH or LOW signals that conduct or not conduct FET8.

The signal transmitted by the microcomputer to the S correction capacitor (Cs) stage causes the FET1... It is determined whether the FET8 is conductive and whether the capacitors C2 ... C9 are grounded, and ultimately, the total capacity of the S correction capacitor Cs stage is determined.

However, in such a manner that the plurality of capacitors C2 to C9 are connected in parallel to vary the total capacitance of the S correction capacitor Cs stage, the variable width of the total capacitance of the S correction capacitor Cs side is changed to the S correction capacitor ( It is limited to the capacity of the unit capacitors connected in parallel to Cs).

Therefore, the frequency range of the horizontal oscillation signal capable of correcting linearity is limited by the S correction capacitor Cs, and the linearity of the sawtooth wave signal applied to the horizontal deflection yoke H-DY in a specific frequency band. There is a problem of this deterioration.

It is an object of the present invention to provide an S correction circuit of a monitor which can ideally correct the linearity of a horizontal sawtooth wave signal irrespective of the frequency band of the horizontal oscillation signal.

For this purpose, the S correction circuit of the monitor of the present invention generates an sine wave signal through an S correction capacitor, and applies the S sine wave signal to the horizontal deflection yoke to correct the linearity of the horizontal sawtooth wave signal. A parabolic signal generator for outputting a parabola signal synchronized with a horizontal oscillation signal, a PWM controller for outputting a PWM signal which can convert an amplitude of the waveform by combining with a parabola waveform output from the parabola signal generator, and the parabola A coupling capacitor connected to an output terminal of a signal generator to remove the DC component of the parabola signal, a resistor and a smoothing capacitor connected to an output terminal of the PWM controller to smooth the PWM signal, and output through the coupling capacitor and the smoothing capacitor Each output is overlapped and connected to the contact output A preamplifier for performing impedance matching and preliminary amplification of a predetermined level; and a parabolic amplifier for amplifying a parabolic signal output from the preamplifier and receiving the amplified parabola signal through a coupling capacitor to be applied to the S correction capacitor Cs. There is a characteristic.

1 is a horizontal output circuit diagram provided in the monitor,

2 is an S correction circuit diagram of a monitor according to the present invention;

3 is a waveform diagram of a signal output at each point shown in FIG. 2.

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

2 is an S correction circuit diagram of a monitor according to the present invention, and FIG. 3 is a waveform diagram of a signal output at each point shown in FIG.

In the S correction circuit of the present invention, instead of connecting a plurality of capacitors having a unit capacitance to the S correction capacitor Cs in parallel, the S correction circuit generates and amplifies a parabola signal through a separate circuit unit and applies the S correction capacitor Cs to the S correction capacitor Cs. The method corrects the straightness of the horizontal sawtooth wave signal.

In detail, the parabolic signal generator 10 which is provided in a horizontal / vertical oscillation signal processing circuit not shown for outputting a horizontal oscillation signal and a vertical oscillation signal, and outputs a parabola signal (waveform) in synchronization with the horizontal oscillation signal And a PWM controller 20 which is provided in a microcomputer and synthesizes the parabola waveform to output a PWM (pulse width modulation) signal for converting the amplitude of the parabola waveform, and is connected to an output terminal of the parabola signal generator 10. A coupling capacitor (C10) for removing the DC component of the parabola signal, a resistor (R1) and a smoothing capacitor (C11) connected to an output terminal of the PWM controller 20 to smooth the PWM signal, and the coupling capacitor ( C10) and the respective outputs output through the smoothing capacitor C11 are connected to a contact output terminal which is overlapped and output to perform impedance matching and preliminary amplification of a predetermined level. The preliminary amplifier stage 30 and the modified parabola signal output from the preamplifier stage 30 are inputted through the coupling capacitor C12 and amplified again and output through the coupling capacitor C13 to the S correction capacitor Cs. It consists of a parabola amplifier 40 to be applied.

The PWM controller 20 is a circuit for outputting a PWM signal whose duty width is determined according to a horizontal synchronous signal. The PWM controller 20 overlaps the parabola waveform and adjusts the amplitude thereof. The PWM signal is output in accordance with the duty width control data.

The preamplifier 30 has a contact output terminal of the coupling capacitor C10 and the smoothing capacitor C11 connected to a base of a transistor Q2 having an emitter grounded through a resistor R2, and the transistor Q2. The collector of is connected to the coupling capacitor (C12) and at the same time the bias power supply (Vcc) is configured to be applied through the resistor (R3).

In addition, the parabola amplifier 40 may be composed of an amplifier or a transformer composed of a multi-stage coupling of transistors.

The operation of the present invention configured as described above will be described below.

First, the parabola signal generator 10 outputs a parabola signal synchronized with the horizontal synchronous signal. The signal waveform at this time becomes a waveform as shown in FIG.

In addition, the PWM controller 20 outputs a PWM signal corresponding to the horizontal synchronization signal currently input as shown in FIG.

The parabola signal is removed from the DC component through the coupling capacitor C10, and at the same time, the PWM signal is smoothed through the resistor R1 and the smoothing capacitor C11, and the respective signals overlap. At this time, the amplitude of the parabola waveform is changed by the PWM signal (according to the horizontal synchronization signal), and an example in which the amplitude of the parabola waveform is changed is not clearly shown. This is because the parabolic waveform and the PWM signal may be part of the overlapping signal.

The superimposed parabola signal and the PWM signal are applied to the base of the transistor Q2 through the resistor R2 of the preliminary amplifier stage 30, and the parabolic waveform shown in FIG. 3C is applied to the collector output terminal of the transistor Q2. This amplified output. The waveform at this time amplifies the superposed parabola waveform to less than 10Vpp.

In addition, the signal output from the preamplifier 30 is applied to the parabola amplifier 40 through the coupling capacitor (C12), the parabola amplifier 40 in the linear signal of the horizontal sawtooth signal It is amplified again to a size (300 to 400 Vpp) that can be used for correction and applied to the S correction capacitor Cs via the coupling capacitor C13.

The signal waveform D of FIG. 3 shows the waveform of the signal amplified by the parabola amplifier 40 as described above.

Accordingly, the parabola signal, which is the signal waveform D applied from the parabola amplifier 40 to the S correction capacitor Cs, is superimposed on the horizontal sawtooth signal of the horizontal deflection yoke H-DY to the input horizontal synchronous signal. The optimal S correction is performed.

The amplitude and wavelength of the parabola signal applied to the S correction capacitor are freely changed according to the frequency of the horizontal oscillation signal by the S correction circuit of the monitor of the present invention, so even when the frequency of the horizontal oscillation signal is changed, the horizontal sawtooth wave The linearity of the signal can be corrected effectively.

Claims (3)

A S correction circuit of a monitor which generates a sinusoidal signal through an S correction capacitor and applies the sinusoidal signal to a horizontal deflection yoke to correct linearity of a horizontal sawtooth wave signal, A parabolic signal generator for outputting a parabolic signal kept in synchronization with the horizontal oscillation signal; A PWM controller for outputting a PWM signal for adjusting the amplitude and wavelength of the parabolic signal; And A parabolic amplifier configured to amplify a parabola signal whose amplitude and wavelength are adjusted by the PWM signal to a level required for linearity correction of the horizontal sawtooth signal and apply it to the S correction capacitor; Correction circuit. The method of claim 1, The parabola amplifier unit preliminary amplifier stage for amplifying and outputting a parabola signal whose amplitude and wavelength is controlled by the PWM signal at a relatively small magnification; And a main amplifier stage for amplifying and outputting the output signal of the preliminary amplifier stage to a level required for the linearity correction operation of the horizontal sawtooth signal. The method of claim 2, And the preliminary amplifier stage is implemented by an emitter ground type transistor amplifier.