KR940003513B1 - Video signal system - Google Patents

Abstract

The system includes a video signal generator for converting a light signal into an electrical signal, a video frequency band compressor for compressing the full-band video signal into a limited bandwidth, and a high-frequency modulator for shifting the compressed video signal to a predetermined frequency band, the compressor having a luminance/chrominance signal separator for separating a video signal into a luminance and chrominance signals, an adaptive frequency overlapping portion for overlapping a high-frequency luminance signal with a low-frequency luminance signal, a frequency limiter for limiting the separated chrominance signal to a predetermined bandwidth, and a luminance/chrominance signal mixer for mixing the frequency-limited chrominance signal and the overlapped luminance signal, thereby increasing the resolution of the image receiver.

Description

Video signal transmission system

1 is a block diagram of a transmission and reception apparatus according to an embodiment of the present invention.

2 is a detailed block diagram of an embodiment of the image frequency band compression unit of FIG.

3 is a detailed block diagram of another embodiment of the image frequency band compression unit of FIG.

4 is a block diagram of an improved video signal receiving apparatus of the embodiment according to the present invention.

5 is a detailed block diagram of an embodiment of the image frequency band extension of FIG.

6 is a detailed block diagram of another embodiment of the image frequency band extension of FIG.

7 is a frequency characteristic diagram of a video signal transmitted by the present invention.

* Explanation of symbols for main parts of the drawings

10: camera 20: image frequency band compression unit

30: high frequency modulator 100,300: luminance / chromatic signal separator

110,111: first and second selection switch 120: adaptive luminance processing unit

130,350: copper signal detector 140: frequency band limiter

150: same color / copper signal mixer 160: modulator

170: luminance / chromatic signal mixer 180: chroma signal demodulator

210: tuner 220: intermediate frequency amplifier

230: image demodulation unit 240: image frequency band extension unit

250: voice demodulator 310: frequency spreader

320: adaptive luminance processing unit 330: basic band processing unit

340: Adder 360: Chromaticity / Copper Signal Separator

The present invention relates to a system for transmitting and receiving video signals of full bandwidth over a transmission channel having a limited bandwidth.

The current video signal is transmitted in one of several broadcasting methods. In addition, the methods for transmitting the video signal have been limited in frequency band for each transmission channel for the efficient use of airwaves and the common use of everyone. For example, the NTSC scheme is limited to a bandwidth of 4.2 MHz. Therefore, the amount of information that can be transmitted through the transmission channel of limited bandwidth is also limited. The limitation of the amount of information limits the resolution of the screen displayed by the video signal.

Recently, as a means of improving the resolution of the screen, a method of transmitting a single video signal through two or more transmission channels [aka: (HDTV High definition Television) method] has been developed. Lowers.

Accordingly, an object of the present invention is to provide an improved video signal transceiving system capable of transmitting a full bandwidth video signal through a limited bandwidth transmission channel.

In order to achieve the above object, the present invention provides a video signal generating means for converting an optical image of a subject into a video signal having an electrical signal form, and a frequency band for compressing a frequency band of the video signal to be a limited bandwidth of a transmission channel. An improved video signal transmitting device comprising a compression means, a high frequency modulating means for modulating the band-compressed video signal into a high frequency signal, a tuner for tuning a high frequency signal including a video signal among high frequency signals, and a frequency of the tuned high frequency signal. Intermediate frequency processing means for converting, an image demodulation unit for generating a compressed video signal by demodulating the frequency converted signal, and for extending the compressed video signal demodulated in the image demodulation unit to an original frequency band. An improved video signal receiving apparatus including video frequency band extension means It features.

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

1 is a block diagram of an improved video signal transmitting apparatus of the embodiment according to the present invention. In Fig. 1, the output terminal of the video camera 10 is connected to the input terminal of the video frequency band compression unit 20. The output terminal of the image frequency band compression unit 20 is coupled to the input terminal of the high frequency modulator 30. The output terminal of the high frequency modulator 30 is coupled to the output terminal 5.

In the operation of FIG. 1, the video camera 10 converts the optical image of the subject into a composite video signal in the form of an electrical signal or a luminance and modulated color difference signal.

The dual modulated color difference signal refers to an FM modulated color difference signal before being mixed with the luminance signal. The reason for FM modulation of the color difference signal is to prevent the occurrence of interference when mixed with the luminance signal.

The image frequency band compression unit 20 compresses the composite video signal generated by the video camera 10 or the occupied frequency band of the luminance and color difference signals to be included in the bandwidth of the transmission channel to generate a compressed composite video signal.

The high frequency modulator 30 converts the compressed composite video signal into a frequency band of a allocated transmission channel (for example, channel 9 or 11) among a plurality of transmission channels through the output terminal 5. Send it out.

The output terminal 5 is connected to the aerial ANT or a wire.

FIG. 2 is a detailed block diagram of the image frequency band compression unit 20, which is a part of FIG. In the second diagram, the first input terminal 105 is coupled to the input terminal of the luminance / chromatic signal separator 100 and the first selection contact S1 of the first selection switch 110. The first output terminal of the luminance / chromatic signal separator 100 is connected to the second selection contact S2 of the first selection switch 110. The second output terminal of the luminance / chromatic signal separator 100 is connected to the second selection contact S2 of the second selection switch 111.

The second selection input terminal 115 is connected to the first selection contact S1 of the second selection switch 111. The reference contact S0 of the first selection switch 111 is coupled to an input terminal of the adaptive frequency overlapping unit 120 and an input terminal of the dynamic signal detection unit 130.

The output terminal of the adaptive frequency overlapping unit 120 is coupled to the first input terminal of the luminance / chromatic signal mixer 170. The output terminal of the dynamic signal detector 130 is coupled to the control terminal of the luminance / chromatic signal separator 100 and the first input terminal of the dynamic / chromatic signal mixer 150. The reference contact S0 of the second selection switch 111 is coupled to the input terminal of the chroma signal demodulator 180. The output terminal of the chroma signal demodulator 180 is connected to the input terminal of the frequency band limiter 140. The output terminal of the frequency band limiter 140 is connected to the second input terminal of the same / chromatic signal mixer 150. The output terminal of the same / chromatic signal mixer 150 is connected to the input terminal of the modulator 160. The output terminal of the modulator 160 is coupled to the second input terminal of the luminance / chromatic signal mixer 170. The output terminal of the luminance / chromatic signal mixer 170 is connected to the output terminal 125. The output terminal 125 is coupled to the input terminal of the high frequency modulator 30 during the first. The first and second input terminals 105 and 115 are coupled to the output terminal of the first video camera 10.

In the operation of FIG. 2, the first input terminal 105 receives a luminance signal or a composite image signal from the video camera 10. The second input terminal 115 receives the chroma signal from the video camera 10.

The luminance / chromatic signal separator 100 separates the composite video signal into a luminance signal and a chroma signal, and the separated luminance signal is adaptively processed by the same signal to generate an adaptive processed luminance signal. In this case, the separated chroma signal is a frequency modulated signal.

The luminance / chromatic signal separator 100 supplies the separated chroma signal to the second selection contact S2 of the second selection switch 111, and the adaptive luminance signal is applied to the second selection switch 110. Supply to the selection contact S2. The luminance / chromatic signal separator 100 can be easily configured by the technique described in US Patent Application No. "07-569029" filed in the United States in August 1990 by fixed perfection.

The first selection switch 110 and the second selection switch 111 are switched by a user, and the second selection switch 111 is linked with the first selection switch 110.

In addition, the first and second selection switches 110 and 111 contact the second selection contact S2 and the reference contact S0 when the composite video signal flows into the first input terminal 105. When the luminance signal flows on the input terminal 105 and the modulated chromaticity signal flows on the second input terminal 115, the first selective contact S1 and the reference contact S0 come into contact with each other.

The moving signal detector 130 detects a moving signal representing the movement of the image from the luminance signal and supplies the same to the luminance / chromatic signal separator 100 and the same / chromatic signal mixer 150. The copper signal detection unit 130 is configured in accordance with the technical contents described in the patent application No. "90-17612", which was patented in Korea on October 31, 1990 by fixed perfection.

The adaptive frequency overlapping unit 120 superimposes a high frequency component of the luminance signal on a low frequency component and adds the superimposed luminance signal to a luminance signal having a base band so that the luminance signal of the high frequency component is included in the low frequency component of the luminance signal of the base band. Generate a signal. The adaptive frequency overlapping unit 120 may be configured in accordance with the contents described in Korean Patent Application No. 90-17580 filed on October 31, 1990 by Yoon Jong-kyung.

The chroma signal demodulator 180 demodulates the modulated chroma signal from the reference contact of the second selection switch 111 to generate a chroma signal.

The frequency band limiter 140 is a low pass filter that detects only a chroma signal of a 1 MHz band and supplies it to the same / chromatic signal mixer 150 to limit the occupied frequency band of the demodulated chroma signal to 1 MHz.

The copper / chromatic signal mixer 150 mixes the copper signal with the limited chroma signal and supplies it to the second modulator 160. The modulator 160 frequency modulates the chroma signal including the same signal to supply the frequency modulated chroma signal to the luminance / chromatic signal mixer 170.

The luminance / chromatic signal mixer 170 mixes the adaptive frequency superimposed luminance signal and the frequency modulated chromaticity signal to generate a frequency band compressed composite image signal.

3 is a detailed block diagram of another embodiment of an image frequency band compression unit which is a part of FIG. FIG. 3 has a circuit configuration in which the copper signal detection unit 130 and the copper / chromatic signal mixer 150 are removed from the circuit diagram shown in FIG. The output terminal of the frequency band limiter 140 is connected to the input terminal of the second modulator 161.

In the operation of FIG. 3, the first and second selection switches 110 and 111, the adaptive frequency overlapping unit 120, the frequency band limiter 140, the first and second modulation units 160 and 161, and the luminance / chromaticity The operation of the signal mixer 170 is the same as that described in FIG.

However, the luminance / chromatic signal separator 100 separates the composite image signal flowing through the input terminal 105 into luminance, chromaticity, and the same signal, and then adaptively processes the luminance signal separated by the same signal. In addition, the luminance / chromatic signal separator 100 supplies the adaptive luminance signal to the second selection contact S2 of the first selection switch 110, and the separated chromaticity signal is the second of the second selection switch 111. Supply to the selection contact S0.

The video signal on the output terminal 125 includes only the luminance signal and the chroma signal superimposed on the frequency.

As a result, the image frequency band compression unit shown in FIG. 3 generates an image signal including a luminance signal and a chroma signal in which high frequency components are superimposed on low frequency components.

On the other hand, the detailed circuit diagram of the image frequency band compression unit shown in FIG. 2 generates an image signal including a luminance signal in which a high frequency component is superimposed on a low frequency component and a chroma signal including the same signal.

4 is a block diagram of an improved video signal receiving apparatus of the embodiment according to the present invention. In FIG. 4, the input terminal 205 is connected to the input terminal of the tuner 210. In FIG. The tuner 210 is connected to the input terminal of the intermediate frequency amplifier 220. The first output terminal of the intermediate frequency amplifier 220 is connected to the input terminal of the image demodulator 230, and the second output terminal of the intermediate frequency amplifier 220 is connected to the input terminal of the audio demodulator 250. It is. The output terminal of the image demodulator 230 is connected to the input terminal of the image frequency band extension unit 240.

The output terminal of the video frequency band extension unit 240 is connected to the first output terminal 215. The output terminal of the audio demodulator 250 is connected to the second output terminal 225. The first output terminal 215 is connected to the display device. The second output terminal 225 is connected to the speaker. The input terminal 205 is connected to the speaker. The input terminal 205 is connected to an aerial line ANT or a wired line to receive a high frequency signal.

In operation of FIG. 4, the tuner 210 outputs a high frequency signal of a frequency band corresponding to a user-specified transmission channel (for example, channel 9, channel 11, etc.) among high frequency signals introduced through the input terminal 205. Select and supply to the intermediate frequency amplifier 220.

The intermediate frequency amplifier 220 frequency-converts the high frequency signal selected by the tuner 210 and filters the frequency converted intermediate frequency signal into an intermediate frequency signal including an image signal and an intermediate frequency signal including an audio signal. do. The intermediate frequency amplifier 220 supplies the intermediate frequency signal including the video signal to the image demodulator 230 and the intermediate frequency signal including the audio signal to the voice demodulator 250.

The image demodulator 230 detects an intermediate frequency signal including the image signal and demodulates the image signal. In this case, the demodulated video signal includes a luminance signal in which the luminance signal of the high frequency component is attenuated and superimposed on the luminance signal of the low frequency component.

The image frequency band extension unit 240 extends the frequency band so that the image signal demodulated by the image demodulation unit 230 is distributed in the original occupied frequency band and displays the expanded composite image signal through the first output terminal 215. To feed.

The voice demodulator 250 detects an intermediate frequency signal including the voice signal and demodulates the voice signal. The voice demodulator 250 supplies the demodulated voice signal to the speaker through the second output terminal 225.

FIG. 5 is a detailed block diagram of an embodiment of the image frequency band extension unit 240, which is part of FIG. In FIG. 4, the input terminal 305 is connected to the output terminal of the image demodulator 230 in the third diagram. The input terminal 305 is connected to the input terminal of the luminance / chromatic signal separator 300. The first output terminal of the luminance / chromatic signal separator 300 is connected to an input terminal of the frequency spreading unit 310 and an input terminal of the basic band processing unit 330. The second output terminal of the luminance / chromatic signal separator 300 is connected to the second output terminal 325. The output terminal of the frequency spreading unit 310 is connected to the input terminal of the adaptive luminance processing unit 320 and the input terminal of the same signal detection unit 350. The output terminal of the dynamic signal detection unit 350 is connected to the control terminal of the adaptive luminance processing unit 320. The output terminal of the adaptive luminance processing unit 320 is connected to the first input terminal of the adder 340. The output terminal of the reference band processor 330 is connected to the second input terminal of the adder 340. The output terminal of the adder 340 is connected to the first output terminal 315. The first and second output terminals 315 and 325 are connected to the output terminal 215 in the third diagram.

In the operation of FIG. 5, the composite video signal flowing into the input terminal 305 is processed by the video frequency band compression circuit shown in FIG. 3 included in the video signal transmitting apparatus, and the high frequency component is included in the low frequency component. It consists of luminance signal and chroma signal.

The luminance / chromatic signal separator 300 separates the luminance signal and the chroma signal from the composite image signal and supplies the chroma signal to the second output terminal 325, and the luminance signal is the frequency spreading unit 310 and the reference band processing unit 330. Supplies).

The frequency spreader 310 detects a luminance signal existing in a band within 3 MHz of the luminance signal, and then spreads the luminance signal of the high frequency component included in the detected luminance signal into the original band. The frequency spreader 310 removes the overlapped carrier and the sideband components included in the unfolded luminance signal, and then applies the unfolded luminance signal from which the overlapped carrier and the sidebands are removed to the adaptive luminance processor 320 and the dynamic signal detector 350. Supply.

The dynamic signal detector 350 detects a dynamic signal representing the movement of the image from the unfolded luminance signal and supplies the same to the adaptive luminance processor 320.

The adaptive luminance processing unit 320 recombines the unfolded luminance signal by the same signal and supplies the recombined and unfolded luminance signal to the adder 340.

The reference band processor 330 filters the luminance signal to detect the luminance signal of the reference band existing in the band within 4.2 MHz, and removes the high frequency luminance component included in the detected luminance signal of the reference band. The reference band processor 330 supplies the brightness signal of the reference band from which the high frequency luminance component has been removed to the adder 340. As a result, the reference band processor 330 supplements the luminance signal of the 3 MHz to 4.2 MHz band lost by the frequency spreader 310 when receiving the television signal broadcast by the conventional television broadcasting system. The adder 340 adds the luminance signal processed by the reference band processor 330 and the luminance signal processed by the adaptive luminance processor 320 to output the added luminance signal. The luminance signal output from the adder 340 has the same frequency characteristic as that of the output signal of the adaptive luminance processing unit 320 when the image signal transmitted by the image signal transmitting apparatus of the present invention is received. When the video signal broadcasted by the receiver has the same frequency characteristic as the output signal of the reference band processor 330.

FIG. 6 is a detailed block diagram of another embodiment of the image frequency band extension unit 240 which is a part of the circuit shown in FIG. 6 is an output terminal of the luminance / chromatic signal separator 300 instead of the dynamic signal detector 350 connected between the output terminal of the frequency spreading unit 310 and the control terminal of the adaptive luminance processing unit 320 in the circuit diagram of FIG. In addition, the chromaticity / motion signal separator 360 is installed between the control terminal of the adaptive luminance processing unit 320 and the second output terminal 325, which is the same as FIG. 5.

In the operation of FIG. 6, the luminance / chromatic signal separator 300, the frequency spreader 310, the adaptive luminance processor 320, the baseband processor 330, and the adder 340 are described in the operation description of FIG. 5. Is the same as However, the composite video signal flowing on the input terminal 305 is a luminance signal (a luminance signal in which a high frequency component is superimposed on a low frequency component), a chromaticity signal, and a dynamic signal generated by the video frequency band extrusion circuit shown in FIG. It becomes an included video signal. The chroma signal output from the luminance / chromatic signal separator 300 to the chroma / dynamic signal separator 360 includes the same signal.

The chromaticity / copper signal separator 360 separates the copper signal and the chromaticity signal from the chromaticity signal including the copper signal, and supplies the chromaticity signal to the output terminal 325 and the copper signal to the adaptive luminance processor 320.

The adaptive luminance processing unit 320 supplies the combined luminance signal to the adder 340 by combining the luminance signals unfolded by the copper signals flowing from the chromaticity / motion signal separator 360. As a result, the difference between FIG. 5 and FIG. 6 is that the dynamic signal is detected from the unfolded luminance signal, and the unfolded luminance signal is combined with the detected dynamic signal. The point is to combine the luminance signals spread by the separated and separated copper signals.

7 is a frequency characteristic diagram of a video signal transmitted by the present invention. In FIG. 7, 400 is a luminance signal of a reference band, 410 is a chroma signal, and 420 is a luminance signal of a high frequency component attenuated and superimposed on a low frequency component (a luminance signal of 3 MHz or less) by a frequency overlapping portion.

As described above, the present invention is capable of attenuating and superimposing a high frequency component of a video signal on a low frequency component, and transmitting a full bandwidth video signal through a transmission channel limited by spreading a high frequency component attenuated on a low frequency component into an original frequency band. There is an advantage. In addition, there is an advantage in that the resolution of the image receiving apparatus can be improved.

Claims (7)

Video signal generating means for converting the opticality of the subject into a video signal in the form of an electrical signal; Video frequency band compression means for compressing the video signal of the entire band to be included in a limited bandwidth of a transmission channel; And high frequency modulation means for moving the compressed video signal to a frequency band of an assigned transmission channel, wherein the video frequency band compression means separates the video signal generated by the video signal generating means into a luminance signal and a chromaticity signal. Luminance / chromatic signal separator; An adaptive frequency superimposition unit for superposing a high frequency luminance signal of the separated luminance signals onto a low frequency luminance signal within a limited bandwidth of a transmission channel; Frequency limiting means for limiting a frequency band of the separated chroma signal to a predetermined bandwidth; And a luminance / chromatic signal mixer for mixing the frequency-limited chromaticity signal and the superimposed luminance signal and outputting the mixture to the high frequency modulation means. 2. The apparatus of claim 1, wherein the frequency limiting means comprises: a chroma signal demodulation unit for demodulating the separated chroma signal; A frequency band limiter for detecting only a chroma signal within a predetermined band of the demodulated chroma signal; And a modulator for modulating the output of the frequency band limiter and supplying the modulated chromaticity signal to the luminance / chromatic signal mixer. A tuner for tuning a high frequency signal including an image signal among high frequency signals; Intermediate frequency processing means for frequency converting the tuned high frequency signal; An image demodulator for demodulating the frequency converted signal to generate a compressed video signal; And an image frequency band extension means for extending the compressed image signal demodulated by the image demodulation unit to an original frequency band. 4. The apparatus of claim 3, further comprising: a luminance / chromatic signal separator for separating the demodulated image signal into luminance and chroma signals; A frequency spreading unit for spreading the superimposed high frequency luminance signal among the separated luminance signals into an original band; A dynamic signal detector for detecting a dynamic signal from the unfolded luminance signal; An adaptive luminance signal processor for recombining the unfolded luminance signal by the same signal; A baseband processor for generating a luminance signal of a baseband by removing the overlapped high frequency luminance signal among the separated luminance signals; And an adder for adding the luminance signal of the basic band and the unfolded luminance signal. 4. The apparatus of claim 3, further comprising: a luminance / chromatic signal separating unit for separating the demodulated image signal into a luminance signal and a chroma signal including the same signal; A frequency spreading unit for spreading a high frequency luminance signal superimposed on a low frequency luminance signal among the separated luminance signals into an original band; A chromaticity / copper signal separator for separating the chromaticity signal including the copper signal separated by the luminance / chromatic signal separator into the copper signal and the chroma signal; An adaptive luminance signal processing unit for recombining the unfolded luminance signal by the separated synchronization; A baseband processor for generating a luminance signal of a baseband by removing the high frequency luminance signal included in the separated luminance signal; And an adder for adding the luminance signal of the basic band and the unfolded luminance signal to be adaptively processed. Video signal generating means for converting the opticality of the subject into a video signal having an electrical signal form; Frequency band compression means for compressing the frequency band of the video signal to be a limited bandwidth of a transmission channel; A video signal transmission device including high frequency modulation means for modulating the band-compressed video signal into a high frequency signal; And a tuner for tuning a high frequency signal including an image signal among high frequency signals; Intermediate frequency processing means for frequency converting the tuned high frequency signal; An image demodulator for demodulating the frequency-converted signal to generate a compressed video signal; And a video signal receiving device including a video frequency band extension means for extending the compressed video signal demodulated by the video demodulator to an original frequency band. Video signal generating means for converting the opticality of the subject into a video signal in the form of an electrical signal; Video frequency band compression means for extruding the video signal of the entire band to be included in a limited bandwidth of a transmission channel; And high frequency modulation means for moving the compressed video signal to a frequency band of an assigned transmission channel, wherein the video frequency band compression means separates the video signal generated by the video signal generating means into luminance and chroma signals. Luminance / chromatic signal separator; An adaptive frequency superimposition unit for superposing a high frequency luminance signal of the separated luminance signals onto a low frequency luminance signal within a limited bandwidth of a transmission channel; A dynamic signal detector for detecting a dynamic signal from the separated luminance signal and supplying the same to the luminance / chromatic signal separator; A chroma signal demodulator for demodulating the chroma signal; A frequency band limiter for detecting only chroma signals within a predetermined band of the demodulated chroma signals; A chromaticity / freeze signal mixer for mixing the chromaticity signal of a predetermined band which is the output of the frequency band limiter and the same signal; A modulation unit for modulating the chroma signal which is an output of the chroma / dong signal mixer; And a luminance / chromatic signal mixer for mixing the modulated chromaticity signal and the superimposed luminance signal to supply the high frequency modulation means.