KR100248720B1 - Aspect ratio control circuit of a wide screen - Google Patents

Abstract

The present invention relates to an aspect ratio change control circuit of an optical screen for the purpose of preventing an image from being changed due to an aspect ratio change in an optical screen display device. An object of the present invention is to provide a current output from a horizontal drive means. And a horizontal output drive current control means for comparing the unbalanced current with and controlling the horizontal output drive current as a result, and a buffer for buffering and outputting the horizontal size control signal according to an aspect ratio change signal input from the outside, An integrating means for integrating and outputting the output signal, a voltage compensating means for supplying a B ⁺ voltage in accordance with the signal output from the integrating means and compensating for a B ⁺ voltage according to the current value fed back ^; and the horizontal output driving current Driven according to the current obtained from the control means, the current output from the voltage compensation means And a deflection current correction coefficient which compares the integral voltage output from said integrating means with each set reference voltage and corrects the linearity of the current flowing into the deflection coil as a result.

Description

Aspect ratio change control circuit of optical screen

1 is an aspect ratio control circuit diagram of a conventional optical screen.

2 is a current state diagram of a deflection coil according to the aspect ratio of FIG.

3 is a screen state diagram according to FIG.

3a is a screen state diagram when the aspect ratio is 4: 3.

3B is a screen state diagram when the aspect ratio is 16: 9.

4 is an aspect ratio control circuit diagram of an optical screen applied to the present invention.

5 is a current diagram of a deflection coil according to the aspect ratio of FIG.

6 is a screen state diagram according to FIG.

4A is a screen state diagram when the aspect ratio is 4: 3.

4B is a screen state diagram when the aspect ratio is 16: 9.

* Explanation of symbols for main parts of the drawings

1: horizontal drive unit 2: horizontal output unit

5: deflection current correction unit 7: horizontal output drive current control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an aspect ratio control circuit of a wide screen, and in particular, to prevent an image from changing (e.g., a slim person to a fat person) in response to a change in aspect ratio. It relates to an aspect ratio change control circuit.

The aspect ratio control circuit of the conventional optical screen is a horizontal drive unit 100 for amplifying, shaping and outputting a horizontal oscillation waveform according to a pulse output from a horizontal oscillation circuit (H.OSC) as shown in FIG. And a damper diode (D1) and a resonant capacitor (C2) according to the pulse output from the horizontal drive unit (100) to flow a sawtooth current through the horizontal deflection coils (D, Y), A horizontal output unit 101 for generating a DC power source, a buffer 102 for buffering and outputting a horizontal size control signal H.SC according to the vertical and horizontal change signals AS, and a signal output from the buffer 102 To the integrating circuit 103 for integrating and outputting, the switching unit 104 for supplying and cutting off the power supply B ⁺ by switching according to the signal output from the integrating circuit 103, and the deflection coil DY. Straightening the flowing current to correct left and right three distortion Left and right three distortion correction unit 105 is configured.

The operation of the aspect ratio change control circuit of the conventional optical screen configured as described above will be described in detail with reference to FIGS. 2 and 3.

First, when a driving pulse is input from the horizontal oscillation circuit (H.OSC) to the horizontal drive unit 100, the switching elements Q1 and Q2 operate.

When the driving pulse is in a high state, the switching element Q1 is turned on, and as the switching element Q1 is turned on, the voltage charged in the capacitor C1 discharges, and the discharged voltage is It flows through the emitter of the 0+ switching element Q1 to the primary side of the transformer T1.

In the above, when the switching device Q1 is turned on, the switching device Q3 is turned off.

The voltage excited to the secondary side of the transformer T1 turns on the switching element Q1 in the horizontal output unit 101.

When the switching device Q4 is turned on, the power source B ⁺ flows to the emitter of the switching device Q4 through the emitter and the coil L2 of the switching device Q3 and flows to the ground.

On the other hand, when the switching element Q4 is turned off, the power source B ⁺ is converted into a sawtooth wave by the resonant capacitor C2 and the damper diode D1 after passing through the emitter and the coil L2 of the switching element Q3. It flows into the horizontal deflection coil DY.

The current flowing through the horizontal deflection coil DY is charged in the capacitor C3 through the coil L1 in the left and right three right distortion correction units 105.

Here, the coil L1 and the condenser C3 in the left and right three distortion correction units 105 perform S correction and C correction on the triangular wave flowing through the horizontal deflection coil DY, and thus the image interval from the center of the screen is 3a. As shown in FIG. 3B, adjustments are made at equal intervals.

In addition, when the switching device Q4 is turned on, the voltage charged in the capacitor C3 in the left and right three distortion correction units 105 is discharged, and the discharged voltage is horizontally passed through the coil L1. The deflection coil (DY) flows to the right side from the center of the screen.

In addition, the voltage flowing through the deflection coil DY flows to the ground through the emitter of the switching element Q4.

On the other hand, the current flowing through the deflection coil DY depends on the vertical and horizontal conversion signal, which is as follows.

If the aspect ratio of the screen is configured to be 4: 3, the switch SW1 is attached to the contact b by the aspect change signal AS.

Accordingly, the horizontal size control signal HSC is buffered and output through the buffer 102, and the output signal is integrated through the integrating circuit 103 and input to the switching unit 104.

The switching unit 104 determines the supply amount of the power source B ⁺ by switching the switching element Q3 according to the integrated signal.

In addition, when the aspect ratio of the screen is configured to be 16: 9, the switch SW1 is connected to the contact point a by the aspect change signal AS, and the voltage Vcc is input to the buffer 102.

Accordingly, the horizontal size control signal HSC is buffered and output by the input voltage Vcc in the buffer 102, and the output signal is integrated through the integrating circuit 103 and input to the switching unit 104. The switching unit 104 supplies the power B ⁺ by adjusting the turn-on time of the switching element Q3 according to the integrated signal.

The current flowing through the deflection coil DY according to the switching time, that is, the turn-on time of the switching element Q3 is different when the aspect ratio is 4: 3 and 16: 9, as shown in FIG. Will flow.

In addition, as shown in FIG. 3, the screen configuration diagram is different from FIG. 3a when the aspect ratio is 4: 3, and FIG. 3b when the aspect ratio is 16: 9 by the current flowing through the deflection coil DY.

However, the aspect ratio control circuit of the conventional optical screen has a problem that the vertical size does not change and the linearity does not change when the aspect ratio is changed, so that the shape of the image changes when the aspect ratio is changed.

Accordingly, an object of the present invention is to provide an aspect ratio change control circuit of an optical screen to prevent an image from being changed by an aspect ratio change.

4 is an aspect ratio control circuit diagram of an optical screen according to the present invention. As shown therein, the horizontal drive unit 1 amplifies, shapes and outputs a horizontal oscillation waveform according to a pulse output from a horizontal oscillation circuit H.osc. And a transformer T2 for converting the voltage output from the horizontal drive unit 1 to a predetermined level, and a damper diode D1 and a resonance capacitor C2 according to the voltage output from the secondary side of the transformer T2. A horizontal output unit 2 for transmitting a sawtooth wave current to the horizontal deflection coil DY, and a buffer for buffering and outputting the horizontal size control signal H.SC according to the vertical and horizontal change signals AS ), An integrated circuit 4 for integrating and outputting the signal output from the buffer 3, and an integrated voltage output from the integrated circuit 4 with the respective reference voltages Vcc1 and Vcc2. A side for converting the linearity of the current flowing through the unary coil DY into a value Current correcting section (5) and, with the integrated circuit 4, the integrated voltage and the voltage compensator (6) to retrieve and supply the appropriate B ⁺ voltage of the current flowing in the deflection coil (DY) output from said transformer ( A horizontal output drive current control unit for detecting the current IB flowing to the primary side of T2 and comparing the current output from the voltage compensator 6 to control the drive current of the horizontal output unit 2 as a result value. It consists of 7).

In the figure, reference numeral T1 denotes a transformer.

The operation and effect of the aspect ratio change control circuit of the optical screen of the present invention configured as described above will be described in detail with reference to FIGS. 5 and 6.

When the driving pulse is input from the horizontal oscillation circuit H.osc to the horizontal drive unit 1, the switching elements Q1 and Q2 operate.

When the driving pulse is in the "high" state, the switching element Q1 is turned on and as the switching element Q1 is turned on, the voltage Vc is transmitted through an emitter of the switching element Q1. It flows to the primary side of T2.

In addition, when the driving pulse is in the "low" state, the switching element Q1 is turned off, and the switching element Q2 is turned on so that a current flowing to the primary side of the transformer T2 is applied to the switching element Q2. Through to ground.

Accordingly, the current flowing to the primary side of the transformer T2 is excited to the secondary side, and the current excited to the secondary side is applied as the base driving current of the switching element Q3 in the horizontal output unit 2.

In addition, the current Ib flowing to the primary side of the transformer T2 is detected through the current detector 7a in the horizontal output drive current control unit 7.

The current detected through the current detector 7a is input to one input terminal of the comparator 7b, and the current flowing through the deflection coil DY is input to the type force terminal of the comparator 7b, whereby the comparator 7b has two heads. Compare the input current value of the input stage and input the result value corresponding to the difference to the integrator 7c.

The integrator 7c integrates this input current value and controls the voltage Vc with the integrated value to flow to the primary side of the transformer T2 and the base of the switching element Q3 of the horizontal output unit 2. Drive current is controlled.

Here, controlling the base driving current of the switching element Q3 eliminates the condition of the UNDER DRIVE and the OVER DRIVE and supplies a compensation voltage for the size to provide a suitable B as a step down circuit. It is to regulate the ⁺ voltage.

On the other hand, when the switching element Q3 in the horizontal output unit 2 is turned on due to the "high" of the base driving current, the B ⁺ voltage through the switching element Q4 in the voltage compensating unit 6 is the diode D2. After sequentially passing through the coil L1, the capacitor L5 smoothes through the capacitor C5 and flows to the primary side of the transformer T1, and then flows to the ground through the emitter of the switching element Q3.

In addition, when the switching element Q3 is turned off due to the "low" of the base driving current, the B ⁺ voltage passes through the primary side of the transformer T1 and then becomes a sawtooth wave to the resonant capacitor C1 and the damper diode D1 and deflects. It flows to the coil DY.

Here, the linearity of the current flowing through the deflection coil DY is different depending on the aspect ratio of the screen 4: 3 and 16: 9.

When the vertical and horizontal change signal AS is 4: 3, the switch SW2 is switched to the contact b '.

Accordingly, the horizontal size control signal HSC is buffered through the buffer 3 and outputted, and the buffered voltage is integrated through the integrating circuit 4.

The voltage output from the integrating circuit 4 is input to the deflection current compensator 5 and the voltage compensator 6, respectively, and the voltage compensator 6 is driven in accordance with the input voltage to switch the switching element Q4. It controls the turn-on of.

In addition, the deflection current correction unit 5 receives the integrated voltage output from the integration circuit 4 into the first and second comparators 5a and 5b, respectively.

Accordingly, the first and second comparators 5a and 5b compare the input voltages with the reference voltages Vcc1 and Vcc2 that are set differently, respectively, and output a result value corresponding to the difference. Since AS) is 4: 3, the integral voltage is relatively low, and both the outputs of the first and second comparators 5a and 5b become " low ".

Therefore, the current waveform flowing to the deflection coil DY is the same as that of FIG. 5a and the screen state is the same as that of FIG. 6a.

All of the switches SW3 and SW4 are turned off by the "low" signal. Accordingly, the current flowing through the deflection coil DY is discharged through the coil L2, and the voltage charged in the capacitor C2 discharges. In this way, the discharged voltage flows through the coil L2 to the deflection coil DY to deflect the right side of the screen.

On the other hand, when the screen aspect change signal AS is 16: 9, the switch SW2 is switched to the contact a 'and accordingly the voltage Vcc is input to the buffer 3 in a "high" state. A horizontal size control signal (HSC) is input to the buffer (3), so that the buffer (3) buffers and outputs the control signal (HSC) in the "high" voltage state.

The voltage output from the buffer 3 is integrated through the integrating circuit 4 and input to the deflection current compensator 5 and the voltage compensator 6, respectively.

The voltage compensator 6 outputs a pulse to turn on the switching element Q4 by the integrated voltage and detects the feedback current to compensate for the amount of current lost, thereby controlling the switching element Q4. .

In addition, the integral voltages respectively input to the first and second comparators 5a and 5b in the deflection current correction unit 5 are compared with the reference voltages Vcc1 and Vcc2 that are set differently, in which case the aspect ratio of the screen is 16: 9. The voltage becomes higher than the reference voltage Vcc1 to make the output of the first comparator 5a "high". Here, the reference voltages Vcc1 and Vcc2 set are different, but only when the screen aspect ratio is 16: 9, when the integrated voltage is greater than the reference voltage Vcc1 and 16: 9, the integrated voltage becomes smaller than the reference voltage Vcc2 and the second comparator ( The output of 5b) becomes a "low" state.

Accordingly, the switch SW4 is turned off, and the reason why the second comparator 5b and the switch SW4 are configured is to change the linearity when the screen aspect ratio is other than 16: 9.

On the other hand, when the output of the first comparator 5a becomes "high", the switch SW3 is turned on and the current through the deflection coil DY is charged to the capacitor C2 through the coil L2 and the coil ( L3) and the switch SW3 are sequentially charged to the capacitor C3.

The S and C curves CURVE are corrected by the operation of the coil L3, the switch SW3 and the condenser C3 so that the screen state has a linearity change from the center to the periphery as shown in FIG. The screen intervals 1,2,3,4 in the figure have a relationship of 4> 3> 2> 1.

Therefore, even when the aspect ratio is 4: 3 or 16: 9, the state of the screen is almost unchanged.

As described in detail above, the present invention seems to increase the horizontal size by appropriately correcting the linearity of the deflection current corresponding to the screen aspect ratio, but the actual image does not change even when 4: 3 or 16: 9. There is an effect that can prevent the change of the image due to the aspect ratio change, which is a problem.

Claims (3)

The horizontal output drive current control means for comparing the current output from the horizontal drive means with the unbalanced current and controlling the horizontal output drive current as a result, and buffering the horizontal size control signal according to the aspect ratio change signal input from the outside. A buffer for outputting, an integrating means for integrating and outputting the signal output from the buffer, and a voltage compensation for supplying a B ⁺ voltage according to the signal output from the integrating means and compensating for the B ⁺ voltage according to the current value fed back. A horizontal output means which is driven according to the current obtained by the horizontal output drive current control means, and which the current output from the voltage compensating means is a sawtooth wave and flows to the deflection coil, and a reference set differently from the integral voltage output from the integrating means. Deflection current correction means for comparing the voltage and correcting the linearity of the current flowing through the deflection coil as a result Also by an aspect ratio change of an optical screen which is characterized to become the control circuit. According to claim 1, The horizontal output drive current control means is a current detector for detecting the current output from the horizontal drive means, a comparator for comparing the current output from the current detector and the deflection current and outputs the result, An aspect ratio change control circuit for an optical screen, characterized by consisting of an integrator for controlling the current output from the horizontal drive means by integrating the voltage output from the comparator. The first and second comparators of claim 1, wherein the deflection current correcting means comprises: first and second comparators for comparing the integral voltages output from the integrating means with respective preset reference voltages and outputting the resultant values; First and second switches switched according to a signal output from the first and second and second coils and first and second correctors for correcting linearity of a current flowing in the deflection coil according to the switching of the first and second switches. Aspect ratio change control circuit of an optical screen, characterized in that consisting of a capacitor.