KR19990052740A - Horizontal Deflection Linearity Correction Circuit of Multimode Monitor - Google Patents

Abstract

The present invention relates to a horizontal deflection linearity correction circuit for a multi-mode monitor that improves the screen horizontal width and linearity by changing the inductance according to the horizontal frequency variation of each video card supported by the multi-mode monitor. The circuit of the microcomputer receives a horizontal synchronization signal output from the video card and outputs a control voltage according to the horizontal frequency; Amplifying means for outputting a voltage of -Vcc to + Vcc according to the control voltage output from the microcomputer; Voltage-current conversion means for outputting a control current while being switched by the voltage output from the amplification means; And a variable inductor connected in series between the horizontal deflection coil and the correction capacitor, the inductance being variable according to the magnitude and direction of the control current output from the voltage-current conversion means.

Therefore, according to the present invention, when the horizontal frequency is changed from 31 to 75KHz according to the video mode to be implemented in the multi-mode monitor, the inductance of the variable inductor for adjusting the horizontal linearity of the screen is varied so that the left and right symmetry of the screen can be accurately matched. Image quality is improved.

Description

A compensation circuit of horizon-deflection linearity in a multi-mode monitor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a horizontal deflection circuit of a monitor. In particular, a horizontal mode for a multi-mode monitor can be improved by changing inductance according to the horizontal frequency variation of each video card supported by a multi-mode monitor. It relates to a deflection linearity correction circuit.

In general, a monitor is a device that receives information from a computer video card and a synchronization signal and displays information on a CRT screen. The monitor includes a video system for processing a video signal, a deflection system for vertical and horizontal deflection, and a power supply. It consists of a system.

Here, the video card is classified into various modes. The classification of the monitor according to the mode of the video card will be described with reference to Table 1 below.

That is, the video mode outputs a horizontal frequency and a vertical frequency differently according to the resolution to be implemented. As the vertical frequency increases from a low frequency to a high frequency, screen flicker is prevented, thereby reducing eyestrain of users. .

Classification by video mode Video mode Horizontal frequency (KHz) Vertical frequency (Hz) Resolution (H * V) CGA 15.75 60 640 * 200 EGA 21.8 60 640 * 350 VGA 31.5 60/70 720 * 350 640 * 480 SVGA 35 to 37 INTERLACE 1024 * 768 High resolution mode 64 to 75 50 to 90 1024 * 7681280 * 1024

Here, the multi-mode monitor is a monitor that is compatible with at least two video modes, and changes the size and position of images according to various horizontal frequencies (about 30 to 75 KHz) output from the video card, horizontal and vertical synchronization, and This means that the monitor can be used to optimize the deflection unit and to adjust various deflection correction circuits.

Before describing the horizontal deflection circuit of the multi-mode monitor, the deflection principle of a general monitor is as follows. The electron beam emitted from the cathode of the monitor is accelerated through the grid, and moves the light spot of the fluorescent surface by changing its course by the electromagnetic action of the magnetic field of the deflection coil.

At this time, the deflection distance of the electron beam is proportional to the strength of the magnetic field, and the magnetic field uses the principle of electron deflection, which is proportional to the current of the deflection coil. The monitor scans at a constant speed from left to right and at a very high speed from right to left. In order to return, the horizontal deflection coil which moves a light spot in a horizontal direction (left-right), and the vertical deflection coil which moves a light point in a vertical direction (up-down) are used.

That is, a sawtooth current as shown in FIG. 1 flows through the horizontal deflection coil, and at the point a of the sawtooth current, a force that deflects the electron beam to the leftmost direction acts on the electron beam, and at the point b, the current Does not flow, the electron beam goes straight. In addition, at point b, the current that causes the electron beam to bend to the right gradually increases, and at point c, the electron beam is deflected to the right, and the current rapidly decreases, and the above process is repeated from point a '.

FIG. 2 illustrates a horizontal deflection circuit of a monitor generating the sawtooth wave current as described above. The horizontal synchronizing signal output from a video card (not shown) is a horizontal drive signal (H.drive) in a horizontal oscillator (not shown). The signal is properly modulated and supplied to the horizontal driving transistor TR1. The horizontal driving signal H.drive turns on the horizontal driving transistor TR1 and turns on the driving power supply Vcc, the horizontal driving transistor TR1, and the horizontal driving transformer HDT, so that the base terminal of the horizontal output transistor TR2 is turned on. Supply current to

At this time, when the horizontal output transistor TR2 is turned on, the B + power current of the flyback transformer (not shown) flows to the horizontal output transistor TR2 through the horizontal deflection coil HD.Y. As described above, while the horizontal output transistor TR2 is turned on, it corresponds to the second half of the effective syringe of the sawtooth wave (that is, between the point b and the point c), and the horizontal output transistor TR2 is in accordance with the horizontal drive signal H.drive. When turned off abruptly, current accumulated in the horizontal deflection coil HD.Y charges the retrace capacitor RE.C.

Here, when the retrace capacitor RE.C is fully charged, it is discharged again to the horizontal deflection coil HD.Y, and accordingly, current is accumulated in the horizontal deflection coil HD.Y. At this time, the period between the charging and discharging of the retrace capacitor is a period corresponding to the retrace period (that is, between c point and a 'point).

In addition, when the energy is accumulated in the horizontal deflection coil HD.Y as described above, and the deflection coil voltage is such that the forward bias is applied to the damper diode DD, the damper diode DD is conducted and the horizontal deflection coil HD is applied. The current flowing in .Y) drops to zero. In this way, the period in which current flows through the damper diode D.D corresponds to the first half of the effective syringe of the sawtooth wave (that is, between point a and point b).

When the current flowing in the horizontal deflection coil HD.Y becomes zero as described above, the horizontal output transistor TR2 is turned on again by the horizontal drive signal H.drive, and the above process is repeated. The sawtooth current flows through the horizontal deflection coil HD.Y, thereby causing horizontal deflection of the electron beam.

However, when the complete sawtooth current shown in FIG. 3A flows to the horizontal deflection coil HD.Y, a non-linear phenomenon of the screen horizontal width occurs as shown in FIG. 3B, which is the fluorescent surface of the monitor and the horizontal deflection coil HD. Since the distance from the center of Y) becomes longer toward the edge of the fluorescent screen, if the amount of change in the horizontal deflection angle of the horizontal deflection coil HD.Y is constant throughout the screen, the image sagging appears at the edge of the screen. ( l ₂ > l ₁ <l ₃ )

Therefore, in order to improve the linearity of the screen as shown in FIG. 3D, the S-shaped sawtooth wave as shown in FIG. 3C must be flowed into the horizontal deflection coil HD.Y. As described above, the horizontal deflection linearity correction circuit 50 that generates S-shaped sawtooth current by S-correcting the complete sawtooth current is connected in series with the horizontal deflection coil HD.Y.

That is, the horizontal deflection linearity correction circuit 50 includes a horizontal linear coil L _S and a correction capacitor C _S connected in series with the horizontal deflection coil HD.Y, and the horizontal linear coil L _S. It consists of a resistor (R) and a capacitor (C) connected in parallel to the bar, the horizontal deflection linearity correction circuit 50 configured as described above is oscillated by forming a series and parallel resonant circuit together with the retrace capacitor (RE.C) Generates an appropriate sigmoidal sawtooth current.

In this case, the horizontal linear coil (L _S ) is adjusted so that the horizontal width of the screen is symmetrical, the correction capacitor (C _S ) to compensate the S sawtooth wave current to prevent the left and right of the horizontal scan, the resistance (R) ) And the capacitor C remove noise, and the inductance of the horizontal linear coil L _S and the capacitance of the correction capacitor C _S determine the oscillation frequency and magnitude of the sawtooth current.

When the S-shaped sawtooth current determined as described above flows to the horizontal deflection coil HD.Y, the screen horizontal width and linearity are corrected by deflecting the electron beam according to the strength of the magnetic force generated in proportion to the magnitude of the sawtooth current.

Here, the horizontal linear coil (L _S ), which is a factor for determining the horizontal width of the screen, can be obtained by winding a conductive wire around a permanent magnet, and has the characteristics as shown in FIG. 4, and the inductance when a sawtooth wave does not flow is constant. It is fixed to a value, so that the inductance increases rapidly while the sawtooth current is in the positive period, and decreases slowly while the sawtooth current is in the negative period. As described above, while the inductance is changed to the S-shape, the screen having the same distance from the center of the screen to the screen left and right is balanced.

However, the horizontal linear coil L _S can be suitably applied to a single mode monitor because the inductance of the sawtooth current is not fixed. However, the horizontal linear coil L _S can be applied to a multi mode monitor designed to realize various modes. There is a problem that cannot be done.

Accordingly, the present invention has been made to solve the above problems of the prior art, by varying the inductance of the horizontal linear coil (L _S ) in accordance with the horizontal frequency variation of each mode in the multi-mode monitor to improve the unbalance of the screen It is an object of the present invention to provide a horizontal deflection linearity correction circuit for a multi-mode monitor to improve image quality.

The circuit of the present invention for achieving the above object comprises a micom receiving a horizontal synchronization signal output from the video card and outputs a control voltage according to the horizontal frequency; Amplifying means for outputting a voltage of -Vcc to + Vcc according to the control voltage output from the microcomputer; Voltage-current conversion means for outputting a control current while being switched by the voltage output from the amplification means; And a variable inductor connected in series between the horizontal deflection coil and the correction capacitor, the inductance being variable according to the magnitude and direction of the control current output from the voltage-current conversion means.

1 is a graph of the sawtooth current;

2 is a circuit diagram illustrating a horizontal deflection circuit of a single mode monitor to which a conventional horizontal deflection linearity correction circuit is applied;

3 is a diagram illustrating the necessity of a horizontal deflection linearity correction circuit of a monitor;

3a is a graphical representation of a complete sawtooth current;

3b is a plan view showing a non-linear state of the screen horizontal width when a complete sawtooth current flows through the deflection coil;

3C is a graph of the S-shaped sawtooth current;

3d is a plan view showing a linear state of a screen horizontal width when an S-shaped sawtooth current flows through a deflection coil;

4 is a graph showing a change in inductance of a correction coil;

5 is a circuit diagram illustrating a horizontal deflection linearity correction circuit for a multi-mode monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

210: microcomputer 220: integrated circuit

221: first operational amplifier 222: second operational amplifier

230: voltage-current conversion means 240: variable inductor

Q21, Q22: Transistors C22, C23: Noise-cancelling capacitor

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

5 shows a horizontal deflection linearity correction circuit according to the present invention applied to a horizontal deflection circuit of a multi-mode monitor, which receives a horizontal synchronizing signal output from a video card and outputs a control voltage according to a horizontal frequency. And amplifying means for outputting a voltage of -Vcc to + Vcc according to the control voltage output from the microcomputer 210, and outputting a control current Ic while being switched by the voltage output from the amplifying means. Magnitude and direction of the control current Ic connected in series between the voltage-current converting means 230 and the horizontal deflection coil HD.Y and the correction capacitor Cs and output from the voltage-current converting means 230. The inductance is variable according to the variable inductor 240 is configured.

Here, the amplifying means is implemented as an integrated circuit 220 composed of a first op amp 221 for amplifying the current driving non-inverting and a second op amp 222 for amplifying the current, the control voltage output from the microcomputer 210 is The voltage is divided by the resistor R21 and the capacitor C21 and then input to the positive input terminal of the first op amp 221, and the negative input terminal of the first op amp 221 is grounded through the resistor R22. The negative input terminal and the output terminal of the first op amp 221 are connected to the resistor R23.

The output terminal of the first op amp 221 is connected to the negative input terminal of the second op amp 222 through the resistor R24, and the negative input terminal and the output terminal of the second op amp 222 are resistor R25. Connect with On the other hand, the + Vcc power is divided by the voltage divider R26 and R27 and applied to the positive input terminal of the second op amp 222.

In addition, the voltage-current conversion means 230 is turned on when the voltage output from the amplifying means is changed to + Vcc at zero potential, the first transistor flowing a control current (Ic) in the direction in which the inductance of the variable inductor 240 increases ( Q21), a second transistor Q22 which flows the control current Ic in a direction in which the inductance of the variable inductor 240 is reduced while being turned on when the voltage output from the amplifying means is changed to −Vcc at zero potential, and the first transistor. The first noise removing capacitor C22 for removing the noise component included in the collector current of the transistor Q21 and the second noise for removing the noise component included in the collector current of the second transistor Q22. It consists of the removal capacitor C23. Here, the first transistor Q21 is an npn type transistor, and the second transistor Q22 is a pnp type transistor.

In addition, the variable inductor 240 includes a primary coil through which a sawtooth current I _DY flows, a secondary coil through which a control current Ic output from the voltage-current converting means 230 flows, and the primary coil; The secondary coil is wound around the magnetic core, and the inductance is varied according to the magnitude and direction of the sawtooth wave current I _DY flowing to the primary coil and the control current Ic flowing to the secondary coil.

Looking at the operation of the present invention configured as described above are as follows.

The microcomputer 210 receives a horizontal synchronization signal from a video card and outputs a control voltage according thereto, and typically outputs a control voltage of 0 to 5V. That is, when the frequency of the horizontal synchronization signal is low, a control voltage of 5V is output. When the frequency of the horizontal synchronization signal is high, a control voltage of 0V is output. This control voltage is amplified by a voltage of -12 to + 12V in the amplifying means. When the control voltage is 0V, the amplifying means outputs a -12V voltage, and when the control voltage is 5V, the amplifying means outputs a + 12V voltage.

When the voltage output from the amplifying means increases to + 12V at zero potential, the first transistor Q21 of the voltage-to-current converting means 230 is turned on and the second transistor Q22 is turned off, and the first transistor Q21 is turned on. The control current (Ic) according to the base current of the flows to the secondary coil of the variable inductor 240. That is, the control current flows in the same direction as the arrow A in FIG. 5, and the inductance of the variable inductor 240 increases by the control current.

On the other hand, when the voltage output from the amplifying means is lowered to -12V at zero potential, the first transistor Q21 is turned off and the second transistor Q22 is turned on, and the control current according to the base current of the second transistor Q22 is (Ic) flows to the secondary coil of the variable inductor 240. At this time, the flow direction of the control current becomes the direction opposite to the arrow A in FIG. 5, and the inductance of the variable inductor 240 is reduced by the control current Ic.

That is, when a low frequency horizontal synchronizing signal is input from the video card, the microcomputer 210 outputs a control voltage having a high potential, the amplifying means amplifies it, and outputs a voltage higher than zero potential, and the voltage-current converting means 230 has an arrow. By outputting the control current I _{C in the} same direction as (A), the inductance of the variable inductor 240 becomes relatively high.

However, when a video mode is converted from a low resolution to a high resolution and a high frequency horizontal synchronizing signal is input from the video card, the microcomputer 210 outputs a control voltage having a low potential, and the amplifying means amplifies it to output a voltage below zero potential. The output voltage-current conversion means 230 outputs the control current Ic in the opposite direction to the arrow A, so that the inductance of the variable inductor 240 is lowered.

As described above, in the device of the present invention, when the horizontal frequency is changed from 31 to 75KHz according to the video mode to be implemented in the multi-mode monitor, the inductance of the variable inductor that adjusts the horizontal linearity of the screen is changed, thereby making the screen symmetric Because it can match exactly, the picture quality is improved.

Claims (4)

A microcomputer receiving a horizontal synchronization signal output from a video card and outputting a control voltage according to a horizontal frequency; Amplifying means for outputting a voltage of -Vcc to + Vcc according to the control voltage output from the microcomputer; Voltage-current conversion means for outputting a control current while being switched by the voltage output from the amplification means; And And a variable inductor connected in series between a horizontal deflection coil and a correction capacitor and having an inductance variable according to the magnitude and direction of a control current output from the voltage-current conversion means. The first transistor according to claim 1, wherein the voltage-current converting means turns on when the voltage output from the amplifying means is changed to + Vcc at zero potential, and flows a control current in a direction in which the inductance of the variable inductor increases. A horizontal deflection linearity correction circuit of a multi-mode monitor, comprising: a second transistor configured to flow a control current in a direction in which the inductance of the variable inductor decreases when the output voltage is changed to -Vcc at zero potential. 3. The noise canceling device of claim 2, wherein the voltage-current converting means comprises: a first noise removing capacitor for removing a noise component included in a collector current of the first transistor, and a noise component included in a collector current of a second transistor. And a second noise removing capacitor for removing the horizontal deflection linearity correction circuit. The variable inductor of claim 1, wherein the variable inductor includes a primary coil through which a sawtooth current flows, a secondary coil through which a control current output from the voltage-current converting means flows, and a magnetic core wound around the primary coil and the secondary coil. And inductance is variable according to the magnitude and flow direction of the sawtooth current and the control current.