KR200183045Y1 - High voltage control circuit using micom - Google Patents

Abstract

The present invention relates to a high voltage control circuit using a microcomputer, and integrates a second microcomputer for outputting a compensation signal for high voltage adjustment by operating a separate second microcomputer regulator and a compensation signal output from the second microcomputer. The high voltage regulator is configured to control the FBT output by dividing and inputting it to the high voltage regulator, eliminating the difficulty of sealing the variable resistor after adjusting the high voltage, and increasing the high voltage using a separate high voltage controlled microcomputer regulator. It has the effect of satisfying the DHHS management specs.

Description

High Voltage Control Circuit Using Micom

The present invention relates to a high voltage control circuit using a microcomputer. In particular, a high voltage regulator outputs a flyback trans (hereinafter abbreviated as FBT) using a microcomputer and receives feedback through a high voltage regulator. Color display tube (hereinafter abbreviated as CDT) relates to a high voltage control circuit using a microcomputer to apply a stable high voltage.

In general, a display device forms a high voltage anode surface in a CDT to display an image signal generated from a computer. That is, an image signal generated by a computer or the like is scanned with an electron beam through an electron gun mounted in the CDT, and an electron beam according to the scanned image signal is adjusted through an anode surface of a high voltage formed in the CDT to form an image.

The conventional display device will be described with reference to the accompanying drawings.

1 is a block diagram showing the internal circuit of a conventional display device. As shown in the drawing, the computer 100 receives and processes a keyboard signal and generates and outputs data according to the processed result, and receives an image signal R receiving data output from the CPU 110. The video card 120 outputs the horizontal sync signal H-SYNC and the vertical sync signal V-SYNC to simultaneously process the outputted video signals R, G, and B, and output the processed video signals G, B. Consists of

A display device that receives and processes the image signals R, G, and B, the horizontal synchronization signal H-SYNC, and the vertical synchronization signal V-SYNC output from the video card 120 in the computer 100. 200 is a video amplifier 210 for receiving and amplifying and outputting video signals R, G and B output from the video card 120, and video signals R and G output from the video amplifier 220. , CD, 220 to receive and display B, and a horizontal sync signal H-SYNC and a vertical sync signal V-SYNC output from the video card 120 to receive the video signals R and G. , Microcomputer 230 for determining a resolution of B, and outputting a reference oscillation signal according to the determined result, a reference oscillation signal output from the microcomputer 230 and a horizontal synchronization signal output from the video card 120. Horizontal and vertical output of horizontal and vertical oscillation pulses by receiving (H-SYNC) and vertical sync signal (V-SYNC) Horizontal deflection circuit for generating a horizontal sawtooth current in the vertical and vertical deflection yoke (H / V-DY) by receiving the oscillation signal processor 240 and the horizontal oscillation pulses output from the horizontal and vertical oscillation signal processors 240 ( 250 and a vertical deflection circuit 260 receiving vertical oscillation pulses output from the horizontal and vertical oscillation signal processors 240 to generate vertical sawtooth wave currents in the horizontal and vertical deflection yoke H / V-DY; A high voltage circuit unit 270 for applying a high voltage to the anode terminal 220-1 formed on the CDT 220 by receiving an oscillation pulse output from the horizontal and vertical oscillation signal processor 240, and receiving a commercial power And a power supply circuit unit 280 for rectifying the commercial current and outputting a DC voltage to a block of an internal circuit.

Looking at each block in the display device 200 having such a configuration in more detail as follows.

The video signals R, G, and B output from the computer 100 are received by the video amplifier 210, amplified, and applied to the CDT 220. A video signal (R, G, B,), a video amplifier 210 is authorized to have, a peak-to-peak voltage through the front end amplifier; 4 a signal of less than (Peak to peak voltage as represented below V _PP) ~ 6V _PP Amplify to the signal of. The video signals R, G, and B, amplified by the signals of 4 to 6V _PP , are amplified by the signals of 40 to 60V _PP through post-amplification and applied to the CDT 220.

Meanwhile, the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 120 of the computer 100 are applied by the microcomputer 230 which stores various screen control data.

The microcomputer 240 receiving the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC may determine the resolution of the image signal output from the computer 100 and output a phase adjustment signal and a reference oscillation signal. . The phase adjustment signal and the reference oscillation signal output from the microcomputer 230 are applied by the horizontal and vertical oscillation signal processor 240. The horizontal and vertical oscillation signal processors 231 receiving the phase adjustment signal and the reference oscillation signal are applied with the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 120. Outputs a vertical oscillating pulse.

The horizontal deflection circuit 250 receiving the horizontal oscillation pulses output from the horizontal and vertical oscillation signal processors 240 generates horizontal sawtooth wave currents in the horizontal and vertical deflection yokes H / V-DY according to the applied oscillation pulses. Done. In addition, the vertical deflection circuit 260, which receives the vertical oscillation pulse output from the horizontal and vertical oscillation signal processor 240, is perpendicular to the vertical and horizontal deflection yoke (H / V-DY) according to the applied vertical oscillation pulse. Will generate a current.

As described above, the CDT 220 receiving the video signal amplified and output from the video amplifier 210 to the signal of 40 to 60 V _PP is horizontal and vertical sawtooth wave generated in the horizontal and vertical deflection yoke (H / V-DY). The image is displayed by scanning the image signals R, G, and B according to the period of the current.

At this time, the high voltage circuit unit 270 receives the oscillation pulses output from the horizontal and vertical oscillation signal processors 240 by the high voltage circuit 271 to generate and output a high voltage through the FBT 272. That is, high voltage is generated in the high voltage circuit 271 and the FBT 272 using harmonics due to inductance and distributed capacitance. The generated high voltage is applied to the anode terminal 220-1 of the CDT 220. The anode terminal 220-1 receiving the high voltage forms the anode surface of the CDT 220.

At this time, when the high voltage generated through the FBT 220 and applied to the anode terminal 220-1 of the CDT 220 is changed, the high voltage regulation circuit 273 detects the high voltage. The high voltage regulation circuit 273 that senses the fluctuation of the high voltage controls the high voltage circuit 271 as the fluctuation of the high voltage is detected, thereby preventing the fluctuation of the high voltage output through the FBT 272. At this time, the high voltage regulation circuit 273 is controlled through the high voltage regulation circuit 274.

The power supply circuit unit 280 that supplies a driving voltage for displaying the image signals R, G, and B through the screen of the display device receives the AC through the AC input terminal 281 receiving commercial AC. AC supplied through AC input 281 is rectified through rectifier 282 and applied to switching transformer 283. The switching transformer 282 applied with the rectified DC through the rectifier 282 outputs and supplies various driving voltages required in the display apparatus 200 through the voltage regulator 284.

At this time, the switching transformer 283 controls the on / off operation by the pulse width modulation (PWM) IC 285. That is, when the output voltage output through the voltage regulator 284 changes, the PWM IC 285 senses this and controls the on / off operation of the switching transformer 283 to output the DC voltage output through the voltage regulator 284. The output will stabilize.

In addition, the PWM IC 285 receives a power off signal according to a display power management signal (hereinafter, referred to as DPMS) mode output from the microcomputer 230 to receive the switching transformer 283. By controlling the output of the DC voltage supplied into the display device 200 to reduce the power consumption.

In the conventional display device, the high voltage adjusting circuit 274 that adjusts and sets the high voltage supplied to the anode terminal 220-1 of the CDT is set by using a variable resistor. As described above, when the high voltage is set (raised) using the variable resistor, there is a difficulty in not satisfying the safety standard of the D.H.H.S management specification.

Therefore, in the case of using such a variable resistor, after setting the high voltage to meet the safety standards of the DHHS management specification (Spec.), The variable resistor is sealed, but this has a difficult problem in the process of sealing the variable resistor. .

Accordingly, the present invention provides a high voltage control circuit using a microcomputer to satisfy the safety standards of the DHHS management specification according to the high voltage by varying the high voltage by using a microcomputer when the high voltage is set to solve the above problems. The purpose.

The present invention for achieving the above object is, in the high voltage control circuit of the display device, a second micom for outputting a compensation signal for high voltage adjustment by the operation of a separate second micom regulator and from the second micom And a high voltage adjusting unit for integrating and dividing the output compensation signal and inputting it to a high voltage regulator to control the FBT output.

1 is a block diagram showing an internal circuit of a conventional display device.

Figure 2 is a block diagram according to the internal circuit of the display device according to the present invention.

FIG. 3 is a detailed circuit diagram of the high voltage adjuster shown in FIG.

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

2 is a block diagram of an internal circuit of the display device according to the present invention. As shown in the drawing, the computer 10 receives a CPU 11 which executes a program by a user to generate data, and receives and processes data output from the CPU 11 to process image signals R, G, and B. And a video card 12 for generating and outputting the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC.

Receives and processes the image signals R, G, and B, the horizontal synchronizing signal H-SYNC, and the vertical synchronizing signal V-SYNC output from the computer 10 including the CPU 11 and the video card 12. The display device 20 includes a video amplifier 21 that receives and amplifies and outputs video signals R, G, and B output from the video card 12, and an image output from the video amplifier 21. CDT for receiving and displaying signals R, G, and B, horizontal sync signal H-SYNC and vertical sync signal V-SYNC outputted from video card 12, and receiving video signals R, G, B. A microcomputer 22 that outputs a phase adjustment signal and a reference oscillation signal by analyzing G and B, and a horizontal synchronization signal output from the video card 12 and the phase adjustment signal and reference oscillation signal output from the micom 22. Horizontal and vertical outputs horizontal and vertical oscillation pulses by receiving the signal H-SYNC and the vertical sync signal V-SYNC. A horizontal signal generating horizontal and vertical sawtooth wave in the horizontal and vertical deflection yoke (H / V-DY) by receiving the true signal processor 23 and the horizontal and vertical oscillation pulses output from the horizontal and vertical oscillation signal processor 23. And a vertical deflection circuit 24 and an oscillation pulse output from the horizontal and vertical oscillation signal processors 23 to receive a flyback signal to generate a high voltage according to the flyback pulse to generate an anode terminal A of the CDT. The high voltage regulator 29 outputs the compensated voltage to the high voltage circuit 25 by feeding back the FBT 26 and the voltage output from the FBT 26, and compensating for the detected voltage variation. In the usual configuration of), the high voltage regulator receives a signal corrected by integrating and dividing a second microcom 27 that performs a predetermined output for high voltage compensation and an output of the second microcom 27. High voltage adjustment section 28 for output to the emitter 29 is a further configuration.

In addition, the second micom 27 of the display device 20 is configured to be connected to a separate second micom adjuster 30 provided outside, the second micom adjuster 30 is the second micom 27 By inputting a constant adjustment signal to the second microcomputer 27 to perform a predetermined output of several steps for adjusting the high voltage.

Referring to the operation according to the configuration as follows.

When the user uses the computer 10, the CPU 11 generates data according to the details of the user's work. The generated data is processed and outputted as image signals R, G, and B through the video card 12. In addition, the video card 12 outputs a horizontal synchronizing signal H-SYNC and a vertical synchronizing signal V-SYNC for synchronizing the output image signals R, G, and B.

The video signals R, G, and B output from the video card 12 of the computer 12 are amplified through the video amplifier 21 of the display device 20 and applied to the CDT. At the same time, the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 12 are applied by the microcomputer 22 of the display device 20 and the horizontal and vertical oscillation signal processor 23. Receive.

The microcomputer 22 receiving the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC receives the image signals R, G, and B from the applied synchronizing signals H-SYNC and V-SYNC. The resolution and horizontal and vertical frequencies are determined, and the phase adjustment signal and the reference oscillation signal are output according to the determined result. The phase adjustment signal and the reference oscillation signal output from the microcomputer 22 are applied by the horizontal and vertical oscillation signal processor 23.

The horizontal and the horizontal synchronization signal H-SYNC and the vertical synchronization signal V-SYNC outputted from the video signal 12 of the computer 10 and the phase adjustment signal and the reference oscillation signal output from the microcomputer 22; The vertical oscillation signal processor 23 outputs horizontal and vertical oscillation pulses according to the applied signals.

The horizontal and vertical oscillation pulses output from the horizontal and vertical oscillation signal processor 23 are applied by the horizontal and vertical deflection circuits 24. The horizontal and vertical deflection circuits 24 receiving the horizontal and vertical oscillation pulses sufficiently drive the applied oscillation pulses to generate horizontal and vertical sawtooth currents in the horizontal and vertical deflection yoke (H / V-DY). do.

In this way, the video signal amplified and applied from the video amplifier 21 according to the period of the horizontal and vertical sawtooth wave current generated in the horizontal and vertical deflection yoke H / V-DY by the horizontal and vertical deflection circuits 24 ( R, G, and B) are displayed on the screen of the CDT. At this time, a high voltage generated from the FBT 26 is applied to the anode terminal A to form an anode surface in the CDT.

According to the anode surface formed on the CDT, an electron beam corresponding to the image signals R, G, and B output from the video amplifier 21 is guided to a fluorescent film (not shown) to display an image. The FBT 26, which applies a high voltage to the anode terminal A, receives a flyback signal output from the high voltage circuit 25 that processes and receives an oscillation pulse output from the horizontal and vertical oscillation signal processor 23. Will occur.

The high voltage circuit 25 that applies the high voltage to the anode terminal A is generally classified into a circuit used by combining a horizontal output circuit and a high voltage circuit and a circuit used in a separate form. In the present invention, a high voltage circuit which is widely used in a high resolution display device and separated from a horizontal output circuit having good high voltage regulation will be described. Of course, the same applies to high voltage circuits used in combination with horizontal output circuits.

The high voltage applied to the anode terminal A changes according to the brightness of the CDT screen. When the high voltage applied to the anode terminal A changes, the high voltage output from the secondary side of the FBT 26 changes. In order to stabilize the high voltage fluctuating on the secondary side of the FBT 26, the fluctuation of the high voltage is applied by the high voltage regulator 29.

The high voltage regulator 29, which has received the change of the high voltage fluctuating on the secondary side of the FBT 26, outputs a compensation signal corresponding to the change of the high voltage and applies it to the high voltage circuit 28. At this time, in order to adjust and set the voltage supplied to the anode terminal A of the CDT, the second microcomputer regulator 30 is operated. The second microcomputer 27 that receives the control signal generated by the above operation outputs a signal according to the above, and the high voltage adjuster 28 that receives the compensation signal output from the second microcomputer 27 receives the applied compensation. The signal is integrated, divided and applied to the high voltage regulator 29.

The high voltage regulator 29 which receives the compensation signal (high voltage adjustment setting signal) integrated and divided from the high voltage adjusting unit 28 and outputs the high voltage circuit 25 controls the high voltage circuit 25. That is, when the high voltage output to the secondary side of the FBT 26 decreases, the high voltage regulator 29 controls the high voltage circuit 25 according to the reduced variation of the high voltage to output the high voltage output to the secondary side of the FBT 26. It is increased by stabilizing.

Further, when the high voltage output through the FBT 26 is greatly increased, the high voltage regulator 29 adjusts the period of the flyback signal output from the high voltage circuit 25 according to the increased variation of the high voltage, thereby increasing the FBT 26. It is stabilized by reducing the high voltage output to the secondary side.

In this high voltage control circuit, the high voltage adjusting unit 28 will be described in detail with reference to the accompanying drawings.

FIG. 3 is a detailed circuit diagram of the high voltage adjuster 28 shown in FIG. As shown, a high voltage adjustment portion 28 is connected to the output terminal of the second microcomputer 27, and the high voltage voltage portion 28 includes an integrator 28a and a voltage divider 28b.

More specifically, the output terminal of the second microcomputer 27 is connected to the input terminal of the integrator 28a composed of the resistor R1 and the capacitor C, and the output of the integrator 28a is connected to the resistor R2 and the resistor. And connected to the high voltage regulator 29 through a voltage divider 28b consisting of an R3 and a resistor R4.

The operation according to the configuration will be described with reference to the accompanying drawings.

The video signals R, G and B, which are amplified from the video amplifier 21 (shown in FIG. 2), are applied by the CDT, and the images according to the applied image signals R, G and B are displayed. .

On the other hand, the high voltage circuit 25 receiving the oscillation pulses output from the horizontal and vertical oscillation signal processors 23 processes the applied oscillation pulses and outputs a flyback signal. The flyback signal output from the high voltage circuit 25 is applied by the FBT 26 and processed to generate a high voltage according to the flyback pulse.

The high voltage output from the FBT 26 is applied from the anode terminal A to form an anode surface inside the CDT. According to the anode surface formed in the CDT, an electron beam corresponding to the image signals R, G, and B output from the video amplifier 21 flows to a fluorescent film (not shown) to display an image.

The high voltage applied to the anode terminal A changes in accordance with the brightness of the CDT screen, so that the high voltage output from the secondary side of the FBT 26 varies. When the high voltage output from the secondary side of the FBT 26 changes, the screen size of the image displayed on the CDT changes. In addition, since the focus of the image is affected, the screen state is degraded.

In order to prevent such a state, when the product is shipped, the high voltage output through the secondary side of the FBT 26 is set. For this adjustment, the second microcom regulator 30 connected to the second microcomputer 27 is adjusted. . The control signal adjusted through the second microcomputer regulator 30 is input to the second microcomputer 2, and the second microcomputer 27 transmits a control signal for the high voltage compensation output according to the high voltage regulator 28. Output to integrator 28a. The integrator 28a of the high voltage adjuster 28 receiving the compensation signal output from the second microcomputer 27 receives a pulse according to the applied compensation signal according to the time constants of the resistor R1 and the capacitor C. Output the integral waveform. The integral waveform output through the integrator 28a is applied by the voltage divider 28b.

The voltage divider 28b receiving the integral waveform outputted through the integrator 28a divides the applied integral waveform through the resistors R2, R3, and R4 and applies it to the high voltage regulator 29. The high voltage regulator 29 receiving the compensation signal according to the high voltage output adjusts the high voltage output to the secondary side of the FBT 26 to stabilize the high voltage applied to the anode terminal A. FIG.

Here, in order to adjust the high voltage output through the secondary side of the FBT 26 through the second micom 27, it is adjusted through the controller 30 of the second micom, the setting as described above Upon completion, the second micom adjuster 30 is separated from the display device 20. Therefore, the process of sealing the variable resistor after the high voltage adjustment can be eliminated, and in order to adjust the second microcomputer 27 for high voltage control, a separate second microcomputer regulator 30 must be used. Satisfied.

As described above, the present invention eliminates the difficulty of fixing the variable resistor after adjusting the high voltage by using the high voltage control microcomputer and increases the high voltage by using a regulator of a separate high voltage control microcomputer, so that the DHHS management specification (Spec .) Has the effect of satisfying

Claims (4)

A high voltage control circuit of a display device, the high voltage control circuit comprising: a second micom configured to output a compensation signal for high voltage adjustment by an operation of a separate second microcomputer regulator; And a high voltage adjusting unit configured to control the FBT output by integrating, dividing and compensating the compensation signal output from the second micom and inputting the high voltage regulator to the high voltage regulator. The electronic device of claim 1, wherein the high voltage adjusting unit comprises: an integrator configured to receive an compensation signal output from the second microcomputer and output an integrated waveform; And a voltage divider which receives an integral waveform output from the integrator and divides the applied integral waveform to output a compensation signal. The high voltage control circuit according to claim 2, wherein the integrator comprises a resistor (R1) and a capacitor (C) to integrate the compensation signal output from the second micom. The high voltage control circuit according to claim 2, wherein the voltage divider is composed of a resistor (R2), a resistor (R3), and a resistor (R4) in order to divide and receive an integral waveform output from the integrator.