KR19990041600A - Television's Overmodulation Control - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overmodulation control apparatus for a television. When the overmodulation of a video signal is performed, the present invention relates to an apparatus for outputting a normal video signal by adjusting a synchronization signal. The present invention utilizes a detection function of a synchronization signal mixed and transmitted in a video signal, and when the overmodulated video signal is received, the synchronization signal mixed in the video signal is detected under the control of a microcomputer. After converting the synchronized signal into a DC signal, the level of the DC signal is reduced so that the amplification gain performed in the image amplification unit is the same as a normal amplification process, thereby eliminating the BUZZ phenomenon generated during overmodulation. It is proposed a over seat control device of a television that is effective.

Description

Television's Overmodulation Control

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overmodulation control apparatus for a television. When the overmodulation of a video signal is performed, the present invention relates to an apparatus for outputting a normal video signal by adjusting a synchronization signal.

In general, since a video signal transmitted from a broadcasting station has a broadband frequency of 0-4.2 MHz, these transmissions are amplitude-modulated and transmitted using VHF or UHF as carriers. Currently, the amplitude-modulated signal transmission method is used. VESTIGIAL SIDE BAND transmission method is used. Because the AM modulated wave transmitted by amplitude modulation is a double side band (DOUBLE SIDE BAND) method in which both side bands of the two side bands are transmitted around the carrier, the frequency range of both side bands is 8.4 MHz. If all of them are used as one channel, the frequency band required for one channel becomes wider, and the efficiency of radio wave is decreased. When the single side band method using only one side band of the two side bands is used, However, because the transient distortion occurs, which adversely affects the image, the residual sideband that transmits one channel within 0.75 MHz from the video carrier to both sides and cuts off a portion of the lower sideband with only 1.25 MHz width is almost 6 ( VESTIGIAL SIDE BAND)) The transmission method is used. The reason for leaving only the 1.25 MHz width of the lower band is because the vicinity of the carrier frequency is a low frequency component of the video signal, and even if this is removed, the image has a bad effect.

In addition, the modulation of the video signal is AM sub-modulation, and the sub-modulation method is such that the amplitude of the carrier is the smallest at the back level of the video signal, while the maximum at the synchronous tip. For example, when the peak value of the carrier by 100, the synchronous state-of-the-art is 100, blanking level is 75 ± 2.5% and the white peak becomes 12.5 ± 2.5, 1V _PP video signal input during the not modulated or that modulation of The modulation rate is set to 87.5%.

However, when the video signal is over-modulated when modulated, a BUZZ may occur and the screen of the video signal may be separated, and the bright part may appear blurred, which causes considerable inconvenience in viewing. There is this.

Accordingly, the present invention has been invented to solve the above problems, and an object of the present invention is to detect a synchronization signal and convert it to a DC signal when an overmodulated video signal is received, and then reduce the level of the DC signal. By reducing the amplification gain of the video signal, to provide an over-modulation control device for a television that allows the normal video signal reproduction.

1 is a block diagram showing an overmodulation control apparatus for a television according to the present invention;

FIG. 2 is a block diagram illustrating a synchronization signal controller, which is a main part of FIG. 1.

3 is a flowchart for explaining an overmodulation control apparatus for a television of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: antenna 150: tuner

200: IF amplifier 250: image detector

300: video amplifier 350: Y / C separation unit

400: color signal output unit 450: water pipe

500: microcomputer 551: synchronization signal detection unit

552: Integrator 553: Comparator

554: signal control unit 600: color demodulation unit

650: key input unit

Hereinafter, with reference to the accompanying drawings will be described a specific embodiment for achieving the above object of the present invention.

1 is a block diagram showing an overmodulation control apparatus for a television according to the present invention.

Referring to FIG. 1, the present invention performs a high frequency amplification on an image signal of a channel selected for display on a screen among high frequency signals received through an antenna 100, and mixes the oscillation frequency generated by the channel being tuned. A tuner unit 150 for converting to an intermediate frequency for easy amplification and then amplifying to generate a composite video signal, an IF amplifier 200 for intermediately amplifying the composite video signal applied from the tuner unit 150, An image detector 250 for extracting an image signal from the complex image signal amplified by the intermediate frequency amplifier from the IF amplifier 200, and an image amplifier for amplifying the image signal output from the image detector 250 ( 300 and a Y / C separator 350 for separating the color signal (C signal) and the luminance signal (Y signal) mixed among the image signals output from the image amplifier 300, and the Y / C separation. To part 350 A color demodulation unit 600 for receiving a color signal (C signal) and outputting a color difference signal, and receiving a luminance signal (Y signal) and a color difference signal from the Y / C separation unit 350 and the color demodulation unit 600, respectively. Control of the color signal output unit 400 for outputting the RGB signal of the primary color, the water pipe 450 for receiving the RGB signal from the color signal output unit 400 to reproduce the color image on the screen, and the microcomputer 500 described later. A synchronization signal detection unit 550 for detecting and adjusting a synchronization signal from the image amplifier 300 and a tuner unit 150 according to a signal, and connected to the tuner unit 150 according to a signal generated from a user's key input unit 650. The microcomputer 500 applies a control signal to the synchronization signal detector 550.

Hereinafter, the operation according to an embodiment of the present invention made as described above will be described in detail.

First, the composite image signal received through the antenna 100 is converted into an intermediate frequency signal by the tuner unit 150, and then amplified by the IF amplifier 200 to be amplified to the image detector 250. Is output. In addition, the image detector 250 detects only an image signal among the intermediate frequency signals, and then outputs it to the image amplifier 300 to be amplified.

Therefore, the image signal output from the image amplification unit 300 is displayed on the screen of the water pipe 450 through the color demodulation and color signal output process.

Here, when a user manipulates an image confirmation key (not shown) included in the key input unit 650 while watching an image displayed on the screen of the water pipe 450, the image generated from the key input unit 650. The confirmation signal is received by a signal receiver (not shown) mounted in the system of the television and sensed by the microcomputer 500.

As described above, the microcomputer 500 that detects the image confirmation signal generated from the key input unit 650 applies the synchronous detection control signal to the synchronous signal detection unit 550 connected to the image amplifier 300. The synchronization signal detector 550 detects a synchronization signal mixed in the image signal output from the image amplifier 300 and, when over-amplified due to overmodulation, reduces the signal and outputs it to the image amplifier 300. .

Accordingly, the image signal reduced by the synchronization signal detector 550 is amplified by the image amplifier 300 and then output to the Y / C separator 350, and the Y / C separator 350 is Color signals (C signals) and luminance signals (Y signals) mixed in the video signals are separated and output to the color demodulator 600 and the color signal output unit 400, respectively.

That is, the color demodulator 600 receives the color signal (C signal) from the Y / C separation unit 350, synthesizes the burst signal, detects the color difference signal (RY, GY, BY), and detects and amplifies the color difference signal (RY, GY, BY). While outputting to the color signal output unit 400, the color signal output unit 400 is the luminance signal (Y signal) and the color difference signal (RY, GY, BY) from the Y / C separation unit 350 and the color demodulation unit 600, respectively ) Is synthesized, and the RGB signal, which is a primary color signal, is generated, amplified by the size necessary for the output of the water pipe 450, and output to the water pipe 450.

Therefore, the water pipe 450 receives the RGB signal from the color signal output unit 400, outputs the deflection, and equally deflects the transmission side, and simultaneously causes the three primary colors of red, green, and blue to overlap the fluorescent screen. Allow color images to be reproduced.

Subsequently, the operation of the synchronization signal adjusting unit 550 for converting the overmodulated video signal into a normal video signal by controlling the synchronization signal and displaying the same will be described in detail with reference to FIG. 2. .

First, the sync signal controller 550 integrates a sync signal detector 551 for detecting a sync signal from the image amplifier 300, and an integrator 552 for integrating the sync signal detected by the sync signal detector 551. ), A comparator 553 for comparing the signal level integrated through the integrator 552 with a reference voltage, and a signal controller 554 for adjusting the level of the signal compared from the comparator 553.

Hereinafter, the operation of the synchronization signal adjusting unit 550 will be described in detail with reference to the accompanying drawings.

First, the image confirmation signal generated by the user's key input unit 650 is detected by the microcomputer 500, and the microcomputer 500 is detected by the synchronization signal detector 551 in the synchronization signal controller 550. For the control signal. That is, the sync signal detector 551 slices and processes the sync signals mixed among the video signals output from the video amplifier 300 below the pedestal level, and then integrators 552. Will print to

In addition, the integrator 552 integrates the synchronous signal supplied from the synchronous signal detector 551 and converts the synchronous signal into a DC signal, and then outputs it to the comparator 553. The comparator 553 is a reference voltage of the normal synchronous signal. After comparison with the signal, if overmodulated by the reference voltage, the output signal is output to the signal controller 554. The signal controller 554 reduces the level of the DC signal to the image amplifier 300 and amplifies the gain. To reduce this.

Accordingly, the image amplifier 300 processes the amplification gain to be reduced during demodulation of the image signal by the DC signal level of the synchronization signal input from the signal controller 554 so that the normal image signal is in a display state.

3 is a flowchart illustrating an overmodulation control apparatus for a television according to the present invention, in which the power supply of the television is switched on (S10) and the power supply switching step (S10) of the television is switched on. After that, the user outputs the broadcast program of the corresponding channel through the channel selection (S20) and the broadcast program is output through the broadcast program output step (S20), while controlling the microcomputer 500 Accordingly, the integration signal detection step (S30) and the synchronization signal detected in the synchronization signal detection step (S30) of the image signal output from the image amplifier 300 is integrated through an integrator 552 In step S40, the level comparison step S50 in which the level of the DC signal integrated in the integration step S40 is compared with the reference voltage level, and the DC signal level compared in the level comparison step S50 is overmodulated. Whether or not If the overmodulation determination step (S60) and the overmodulation determination step (S60) is discriminated, the signal adjustment step (S70) and the signal control step (S70) that the signal is adjusted is adjusted If the signal is output to the image amplifier 300 to output a normal video signal (S80) and the over-modulation is not determined in the over-modulation determination step (S60), the existing broadcast program outputs a broadcast program The output step (S20) is made.

Hereinafter, an operation after the synchronization signal detecting step S30 will be described with reference to the accompanying drawings.

First, when a user manipulates an image confirmation key (not shown) provided in the key input unit 650, the microcomputer 500 that detects the detection signal is transmitted to the sync signal detector 551 in the sync signal controller 550. Is applied to allow the synchronization signal to be detected.

The detected synchronization signal is converted into a DC signal through an integration process of the integrator 552, and the DC signal is output to the comparator 553 for level comparison with a reference voltage, and to the comparator 553. As a result of the comparison, the DC signal level is reduced by the signal adjusting unit 554 only when it is over-modulated larger than the reference voltage level, and then applied to the image amplifier 300.

As described above, the present invention utilizes a detection function of a synchronization signal mixed and transmitted in a video signal to detect a synchronization signal mixed in a video signal under the control of a microcomputer when an overmodulated video signal is received. And converting the detected synchronization signal into a DC signal, and then reducing the level of the DC signal so that the amplification gain performed in the image amplifier is the same as a normal amplification process. BUZZ) Eliminates the phenomenon.

Claims (2)

A television for receiving an overmodulated video signal and converting the video signal into a normal video signal for output. Sync signal detecting means for detecting a sync signal from the image amplifier 300; Integrating means for integrating the synchronization signal detected by the synchronization signal detecting means; Comparison means for comparing the DC signal output from the integration means, and And a signal adjusting means for reducing the level of the DC signal compared through said comparing means. The method of claim 1, wherein the signal adjusting means converts the level of the DC signal to reduce the level of the DC signal compared by the comparison means, and then applies the signal to the image amplifier 300. And the gain adjustment of the DC signal is reduced, thereby reducing the amplification gain of the video signal.