KR970004607B1 - Automatic horizontal raster centering apparatus - Google Patents

Abstract

An automatic horizontal raster centering apparatus controls a duty cycle of a pulse-width-modulated square pulse by using a microcomputer, and always embodies a stable raster without regard to a variation of the horizontal frequency used to a multiple synchronous monitor. The apparatus includes: a flyback transformer(FBT); a power-supply unit(1); microcomputer(2) for outputting a pulse-width-modulated control signal to an integrator(3); an integrator(3) for integrating the pulse-width-modulated pulse from the microcomputer(2), and converting it to a DC format; a reference voltage part(5) for setting a reference voltage identical with the output voltage of the integrator(3) when the pulse-width-modulated pulse's duty cycle is 50%; a controller(4) for outputting a control signal to the driver(6) according to a variation of the output voltage of the integrator(3); a driver(6) for applying a voltage from the power-supply part(1) to a condenser(CS); a horizontal deflection coil for receiving a horizontal deflection current from a horizontal deflection circuit; and a condenser(CS) for discharging/charging the output voltage from the driver(6).

Description

Automatic horizontal raster centering device

1 is a circuit diagram of a conventional horizontal raster centering device.

2 is an output waveform diagram of each part of a conventional horizontal raster centering device.

Figure 3 is a raster adjustment state according to the operation of the conventional horizontal raster centering device.

4 is a circuit diagram of an automatic horizontal raster centering apparatus of the present invention.

* Description of the symbols for the main parts of the drawings *

1: power supply unit 2: microcomputer

3: integral part 4: control part

5: reference voltage unit 6: drive unit

Q11-Q14: Transistor PT1, PT2: Photocoupler

The present invention relates to a horizontal raster centering apparatus used for multiple synchronization monitors, and more particularly, to a change in the horizontal frequency used for multiple synchronization monitors by controlling the duty cycle of a pulse width modulated rectangular pulse using a microcomputer. The present invention relates to an automatic horizontal raster centering device capable of realizing a stable raster at all times.

2 is a circuit diagram of a conventional horizontal raster centering apparatus, the configuration of which is as follows.

First, the flyback transformer (FBT) mounted on the monitor to generate a high pressure pulse, and the B of the flyback transformer (FBT) The first coil LI wound on the secondary side with the center tap as the winding direction of the primary side, and the B of the flyback transformer form FBT. The second coil L2 wound in a direction opposite to the winding direction of the primary side on the secondary side having the voltage as the center tap, and the pulse induced in the first coil L1 are rectified. A diode D1 for outputting a voltage higher than the voltage to the capacitor C1, a capacitor C1 for charging and discharging with a constant voltage output from the diode D1, and a pulse induced in the second coil L1. Rectifying B Two voltage sources formed by the diode D2 for outputting a voltage lower than the voltage to the capacitor C2, the capacitor C2 for charging and discharging with a constant voltage output from the diode D2, and the capacitors C1 and C2. A transistor Q1 connected in series between the variable resistor VR1 and the transistor Q1 outputting a voltage charged in the capacitor C1 to the coil L3 by being turned on and off according to a change in the resistance value of the variable resistor VR1. And a transistor Q2 for turning on and off in response to a change in the resistance value of the variable resistor VR1 to output the voltage charged by the capacitor C2 to the coil L3, and outputting the transistors Q1 and Q2. The capacitor L for outputting the voltage to the horizontal deflection coil HDY and the capacitor S for correction, and the capacitor S for correction for charging and discharging with the voltage input through the coil L3. (CS) and the horizontal deflection current of the sawtooth wave is applied from the horizontal deflection circuit section mounted on the monitor. It is composed of a horizontal deflection coil (HDY).

The above-described reference numerals R1 and R2 are resistors.

The operation of the conventional horizontal raster centering apparatus configured as described above will be described with reference to FIGS. 1 to 3.

First, when a pulse as shown in FIG. 2A is applied to the primary side of the flyback transformer FBT, B of the flyback transformer FBT is applied. The first coil L1 wound on the secondary side with the voltage center tap in the same direction as the primary side of the flyback transformer FBT has a B as shown in FIG. A pulse having a voltage higher than the voltage is induced, and the second coil L2 wound in a direction opposite to the primary side of the FRY transformer FBT is shown in FIG. A pulse of voltage lower than the voltage is induced.

Therefore, the diode D1 rectifies the pulse induced in the first coil L1 and outputs it to the capacitor C1, and the capacitor C1 is B. Charge the voltage higher than the voltage, the diode D2 rectifies the pulse induced in the second coil (L2) and outputs it to the capacitor (C2), the capacitor (C2) is B The voltage also charges a lower voltage.

At this time, when the center tap of the variable resistor VR1 is moved to the A side to change the resistance value, the transistor Q1 is turned on, the transistor Q2 is turned off, and the current flows in the I direction, thereby charging the capacitor C1. Voltage is applied to the S-za correction capacitor CS through the coil L3 and the resistor R3. When the voltage higher than the voltage is charged and the raster of the monitor is moved to the right as shown in FIG. 3, the transistor Q2 is changed when the center tap of the variable resistor VR1 is moved to the B side to change the resistance value. The transistor Q1 is turned off and the current flows in the I 'direction so that the voltage charged in the capacitor C2 is supplied to the capacitor S for correction of the S-za correction through the coil L3 and the resistor R3. As the voltage lower than the voltage is charged and the raster of the monitor moves to the left side as shown in FIG. 3, when the center tap of the variable resistor VR1 is positioned at the center position, the transistors Q1 and Q2 are turned off. As a result, no current flows, and as shown in FIG. 3, the raster of the monitor is located at the center.

3 shows a change in the raster according to the variable resistance value of the variable resistor VR1. The center wrap of the variable resistor VR1 is moved to the A side, and the current flows in the I direction. Since the charged voltage passes through the upper end of the deflection current ipp flowing in the horizontal deflection coil HDY, the raster of the monitor is moved to the right, that is, the left hemisphere L1 is wider than the right hemisphere R1, and the variable resistor ( When the center tap of VR1) is moved toward B and the current flows in the I 'direction, the voltage charged in the S-za correction capacitor CS passes the lower end of the deflection current ipp flowing in the horizontal deflection coil HDY. When the stator is moved to the left, that is, the right hemisphere R3 is wider than the left hemisphere L3, and when the center tap of the variable resistor VR1 is positioned at the center, no current flows and the capacitor is charged in the S-za correction capacitor CS. Voltage flows through the horizontal deflection coil (HDY) Because through the center of the electric current (ipp) to which the raster of the monitor is fixed to the center.

As described above, the conventional horizontal raster centering device adjusts the raster of the monitor while the user watches the state of the screen by varying the variable resistor.

However, in the conventional horizontal raster centering device, there is no problem in adjusting raster according to the mode change in a single mode monitor, but in a multi-synchronous monitor that must operate in a wide frequency band, the raster moves left and right according to the input frequency change. There is a problem.

Therefore, in order to solve the problem, the present invention controls the duty cycle of the pulse-width modulated spherical pulse using a microcomputer so that the raster is always stable regardless of the change in the horizontal frequency used in the multi-synchronous monitor. An object of the present invention is to provide an automatic horizontal raster centering device that can be implemented.

Referring to Figure 4 the configuration of the present invention for achieving the above object is as follows.

A transformer (FBT) mounted on the monitor to induce high-voltage pulses, a power supply (1) for supplying a voltage induced on the secondary side of the flyback transformer (FBT) to the driver (6), and a horizontal frequency change The microcomputer 2 outputting the pulse width modulated control signal to the integrating unit 3, and the pulse width modulated pulses output from the microcomputer 2 are integrated to convert the pulse width modulated into a simile form and output to the control unit 4. A reference voltage section 5 having a reference voltage set to match the voltage output from the integrating section 3 when the duty cycle of the pulse width modulated pulse output from the section 3 and the microcomputer is 50%; A control unit 4 for controlling the driving unit 6 according to the change of the voltage output from the integrating unit 3 and a voltage supplied from the power supply unit 1 as a control signal of the control unit 4. Drive unit 6 for supplying to CS) and horizontal mounted on monitor A horizontal deflection coil HDY to which the horizontal deflection current output from the deflection circuit unit is applied, and an S-Scissor condenser CS which charges and discharges with the voltage output from the driving unit 6.

And, the power supply 1 is the B of the flyback transformer (FBT) The first coil L11 wound on the secondary side with the center tap as the winding direction on the primary side, and the B of the flyback transformer FBT. The second coil L12 submerged in a direction opposite to the winding direction of the primary side and the pulse induced in the first coil L11 are rectified on the secondary side having the voltage as the center tap, B A diode D11 for outputting a voltage higher than the voltage to the capacitor C11, a capacitor C11 for charging and discharging with a constant voltage output from the diode D11, and a pulse induced in the second coil L12. Rectifying B The diode D12 outputs a voltage lower than the voltage to the capacitor C12, and the capacitor C12 charges and discharges at a constant voltage output from the diode D12. The integrating unit 3 includes the micom ( It consists of a resistor (R12, R15, R16) and a capacitor (C13, C14, C15) forming a three-step integral loop for integrating the pulse output from the 2) to a direct current component, the reference voltage section (5) ) Is composed of resistors R17 and R18 for outputting a voltage that matches the voltage output from the integrator 3 when the duty cycle of the pulse output from the microcomputer 2 is 50%. ) Is a transistor that is turned on when the voltage output from the integrating unit 3 is higher than the reference voltage of the reference voltage unit 5 to output the input voltage 12V of the reference voltage unit 5 to the first photo coupler PT1. Q13 and the voltage output from the integrating unit 3 are the reference voltages of the reference voltage unit 5. When it is low, the transistor Q14 is turned on to operate the input voltage 12V of the reference front part 5 to the second photo coupler PT2, and is turned on by the voltage input by the on operation of the transistor Q13. The first photo coupler PT1 for turning on the transistor Q11 of the driver 6 and the voltage input by the on operation of the transistor Q14 are turned on to turn on the transistor Q12 of the driver 6. It is composed of a second photo-coupler (PT2) to operate, the driving unit 6 is operated on the voltage output from the first photo coupler (PT1) of the control unit 4 to the capacitor (C11) of the power supply unit (1) ) Is turned on by the transistor Q11 for applying the voltage charged to the coil L13 and the voltage output from the second photo coupler PT2 of the controller 4 to the capacitor C12 of the power supply unit 1. A transistor Q12 for applying the voltage charged in the coil L13 to the transistor Q12; And a coil L13 for supplying the voltage output from 11, Q12 to the S-za correction capacitor CS.

Reference numerals R11 and R12 described above are resistors.

The operation of the present invention configured as described above is as follows.

First, when a pulse is applied to the primary side of the flyback transformer (FBT), the B of the flyback transformer (FBT) is applied. B on the first coil L1 of the power supply unit wound in the same direction as the primary side of the flyback transformer FBT on the secondary side with the voltage as the center tap. A pulse having a voltage higher than the voltage is induced, and the second coil L2 of the power supply unit wound in a direction opposite to the primary side of the flyback transformer FBT is B. A pulse of voltage lower than the voltage is induced.

Therefore, the diode D11 rectifies the pulse induced in the first coil L11 and outputs it to the capacitor C11, and the capacitor C11 is B Charge the voltage higher than the voltage, the diode D12 rectifies the pulse induced in the second coil (L12) and outputs it to the capacitor (C12), the capacitor (C12) is B Charge voltage lower than voltage.

At this time, when a pulse having a duty cycle of 50% is output from the microcomputer 2, the pulses include the resistors R14, R15 and R16 and the capacitors C13, C14 and C15 of the integrating unit 3 forming a three-step integral loop. ) Is transformed into a DC voltage and then supplied to the controller 4. At this time, since the reference voltage set by the resistors R17 and R18 in the reference voltage section 5 is equal to the voltage value output from the integrating section 3, the photocouplers PT1 and PT2 of the controller 4 operate. Therefore, the transistors Q11 and Q12 of the driving unit 6 are also turned off, so that the B-shaped correction capacitor CS is turned off. Since the voltage value is charged and passes through the center portion of the deflection current flowing in the horizontal deflection coil HDY, the raster is not moved.

On the other hand, when the horizontal frequency is increased and the microcomputer 2 outputs a pulse having a duty cycle of 50% or less, the pulses include the resistors R14, R15 and R16 and the capacitor C13 of the integrating portion 3 forming a three-step integral loop. , C14 and C15 are integrated into a DC voltage and supplied to the controller 4, in which case the reference voltage set in the reference voltage section 5 is higher than the voltage output from the integration section 3. The input voltage 12V of the voltage unit 5 is supplied to the transistor Q14 of the controller 4 after turning on the diode of the second photo coupler PT2 through the resistor R17.

The transistor of the second photo coupler PT2 is turned on by the on operation of the diode of the second photo coupler PT2, so that the transistor Q12 of the driving unit 6 is turned on and thus the capacitor 12 of the power supply unit 1 is turned on. The charged voltage is charged in the S-za corrective consor CS through the coil L13, and the raster is moved to the left.

On the other hand, the horizontal frequency is lowered so that the microcomputer 2 outputs a pulse having a duty cycle of 50% or more, and the pulses include the resistors R14, R15, R16 and the condenser C13 of the integrating unit 3 forming a three-step integral loop. , C14 and C15 are integrated into a DC voltage and supplied to the controller 4, in which case the reference voltage set in the reference voltage unit 5 is lower than the voltage output from the integration unit 3. The input voltage 12V of the voltage unit 5 turns on the diode of the first photo coupler PT1 through the transistor Q13 of the controller 4 and then is supplied to the resistor R18 of the reference voltage unit 5.

The transistor of the first photo coupler PT1 is turned on by the on operation of the diode of the first photo coupler PT1, and the transistor Q11 of the driving unit 6 is turned on, and thus the capacitor C12 of the power supply unit 1 is turned on. ) Is charged to the S-za correction capacitor CS through the coil L13, and the raster is moved to the right. That is, because the raster is moved to the right when the horizontal frequency increases, the microcomputer 2 outputs a pulse with a duty cycle of 50% or less to move the raster to the left, and when the horizontal frequency decreases, the raster is moved. In order to compensate for this, the microcomputer 2 outputs a pulse having a duty cycle of 50% or more, and moves the raster to the right to automatically correct the horizontal raster.

As described above, the present invention can implement a stable raster at all times regardless of the horizontal frequency change used in the multi-synchronous monitor by controlling the duty cycle of the pulse-width-modulated spherical pulse using the microcomputer according to the change of the horizontal frequency. Automatic horizontal raster centering device.

Claims (2)

A flyback transformer (FBT) mounted on the monitor to induce a high voltage pulse, a power supply unit (1) for supplying a voltage induced on the secondary side of the flyback transformer (FBT) to the driving unit (6), and a horizontal frequency The microcomputer 2 outputs a pulse width modulated control signal to the integrating unit 3 according to the change, and the pulse width modulated pulses output from the microcomputer 2 are integrated to convert the DC signal into a direct current form. A reference voltage unit 5 having a reference voltage set to match the voltage output from the integrating unit 3 when the duty cycle of the integrating unit 3 to output and the pulse width modulated pulse output from the microcomputer is 50% And a controller 4 for outputting a control signal to the driver 6 according to the change of the voltage output from the integrator 3 and the power supply 1 according to the control signal of the controller 4. Drive unit for supplying voltage to the S-za correction capacitor (CS) (6), a horizontal deflection coil HDY to which the horizontal deflection current output from the horizontal deflection circuit unit mounted on the monitor is applied, and an S-Shi correction consor CS which charges and discharges the voltage output from the drive unit 6; Automatic horizontal raster centering device, characterized in that configured. According to claim 1, wherein the power supply unit 1 is the B of the flyback transformer (FBT) The first coil L11 wound on the secondary side with the center tap as the winding direction on the primary side, and the B of the flyback transformer FBT. The second coil L12 wound in a direction opposite to the winding direction of the primary side and the pulse induced in the first coil L11 are rectified on the secondary side of which the voltage is the center tap B. A diode D11 for outputting a voltage higher than the voltage to the capacitor C11, a capacitor C11 for charging and discharging with a constant voltage output from the diode D11 and the diode D11, and the second coil L12. Rectified pulse at) The diode D12 outputs a voltage lower than the voltage to the capacitor C12, and the capacitor C12 charges and discharges at a constant voltage output from the diode D12. The integrating unit 3 includes the micom ( It consists of a resistor (R14, R15, R16) and a capacitor (C13, C14, C15) forming a three-step integral loop for integrating the pulse output from the 2) to a direct current component, the reference voltage section (5) ) Is composed of resistors R17 and R18 for outputting a voltage that matches the voltage output from the integrator 3 when the duty cycle of the pulse output from the microcomputer 2 is 50%. ) Is a transistor that is turned on when the voltage output from the integrating unit 3 is higher than the reference voltage of the reference voltage unit 5 to output the input voltage 12V of the reference voltage unit 5 to the first photo coupler PT1. Q13 and the voltage output from the integrating unit 3 are the reference voltages of the reference voltage unit 5. When it is low, the operation unit is turned on by the voltage input by the operation of the transistor Q14 and the transistor Q13 to turn on the input voltage 12V of the reference voltage unit 5 to the second photo coupler PT2. The first photo coupler PT1 for turning on the transistor Q11 of (6) and the voltage Q inputted by the turning-on operation of the transistor Q14 to turn on the transistor Q12 of the driving section 6 It consists of a second photo coupler (PT2), the driving unit 6 is turned on by the voltage output from the first photo coupler (PT1) of the control unit 4 to charge the capacitor C11 of the power supply unit (1) The transistor Q11 for applying the applied voltage to the coil L13 and the voltage output from the second photo coupler PT2 of the controller 4 are turned on to charge the capacitor C12 of the power supply unit 1. A transistor Q12 for applying a voltage to the coil L13; And a coil (L13) for supplying the voltage output from Q12) to the S-za correction capacitor (CS).