KR920010167B1 - Video signal overlaping and spreading circuit - Google Patents

Abstract

The super VHS and the standard VHS become compatible using the video signal overapping and dividing circuit. The frequency band- width of video signal is expanded to effective band-width of video tape using the circuit. The circuit includes an analog to digital converter (10) for digitizing analog video signal, a brightness signal divider (20) for dividing brightness signal from digital video signal throughout the whole frequency range, a frequency overlapping circuit (30) for generating brightness signal having limited band width by overlapping high frequency brightness signal to low frequency brightness signal, an adder (50) for adding the limited band brightness signal and the whole range brightness signal, and a brightness signal recorder (60) for modulating the brightness signal to record on a tape.

Description

Video signal overlap and spread circuit

1 is a block diagram of a video signal superimposition circuit of an embodiment according to the present invention.

2 is an output characteristic diagram for each part of the circuit shown in FIG.

3 is a block diagram of a video signal spreading circuit of an embodiment according to the present invention.

4 is an output characteristic diagram for each part of the circuit shown in FIG.

* Explanation of symbols for the main parts of the drawings

10, 130, 131: A-D converter 20: luminance signal separation unit

21: chroma signal separator 22: synchronization signal separator

30: frequency overlapping part 40, 140: low pass filter

50, 160: adder 60: luminance signal recorder

70: chromatic / dynamic signal mixer 71: chromatic / luminance signal recorder

80: standard chroma signal recorder 90: magnetic recording head

100: magnetic reproduction head 110: chromatic / luminance signal separator

111: chromatic / copper signal separator 120: luminance signal regenerator

141: basic band processing unit 150: frequency spreading unit

170: chroma signal reproducer 180: composite video signal generator

The present invention relates to an image recording and reproducing apparatus using a frequency overlapping technique for recording a large amount of image information. In particular, the frequency overlapping and spreading for extending the bandwidth of the basic video signal limited by the frequency overlapping to the effective bandwidth of the recording medium. It is about a circuit.

VCRs currently used in homes record video signals in videotape cassettes in one of several ways. Well-known VHS systems often produce degraded pictures because of insufficient horizontal resolution.

In general, an improved VHS scheme called Super VHS (S-VHS) generates an improved image quality by recording an image signal of full bandwidth on the video tape cassette and outputting the improved image quality. Such systems require high quality tapes and high quality recording and playback equipment in cassettes. However, the S-VHS system is not backward compatible with the standard VHS type VCR. The S-VHS type VCR can play both cassettes recorded in the S-VHS type or the standard VHS type VCR, but the standard VHS type VCR cannot play back the images recorded in the S-VHS type VCR. In addition, it is possible to record a video signal having a bandwidth wider than that of the video signal recorded by the standard VHS type VCR on a standard quality cassette, and also has a standard VHS type VCR which is a problem of the VCR of the S-VHS type. US Application No. 07-569029, filed with US application dated Aug. 17, 1990, by Samsung Electronics Co., Ltd., that maintains compatibility and does not require a high quality recording and playback device. Is disclosed. According to the US patent application Ser. No. 07-569029, the high frequency component of the recorded luminance signal is reduced, and then the signal generated after superimposing the attenuated high frequency component on the low frequency component is superimposed on the low frequency component. In this way, all information existing in the entire bandwidth of the luminance signal is included in the overlapped luminance signal having a bandwidth of about 2.5 MHz. During reproduction, a low-pass filter having a cutoff frequency of about 2.5 MHz in order to spread all information existing in the entire bandwidth of the luminance signal included in the overlapped luminance signal having a bandwidth of about 2.5 MHz to the original band. Filter by, and spread the filtered luminance signal to be distributed in the original frequency band. As a result, the U.S. application number "07-569029" is supposed to process luminance signals within 2.5 MHz during recording and reproduction.

However, a standard VHS type VCR can record and reproduce luminance signals within approximately 3 MHz on a video tape cassette. Therefore, when the videotape cassette in which the video signal is recorded by the VCR described in US Application No. 07-569029 is reproduced by the VCR of the standard VHS system, the video information distributed in the frequency band of 2.5 MHz or more is lost. Even when a video tape cassette in which a video signal is recorded by a standard VHS-type VCR is reproduced by the VCR described in US Application No. 07-569029, video information distributed in a frequency band of 2.5 MHz or more is lost.

Accordingly, an object of the present invention is to superimpose and unfold the video signal that can extend the frequency band of the recorded and reproduced video signal to the induction bandwidth on the recording medium in order to prevent the loss of the high-frequency luminance signal when compatible with the standard VHS VCR In providing.

The video signal superimposition circuit of the present invention for achieving the above object is an AD converter for converting the video signal of the full bandwidth to a multi-bit digital video signal, and the luminance signal for separating the luminance signal of the full-band lock from the digital video signal A separator, a frequency overlapping portion that generates a superimposed luminance signal having a limited bandwidth by overlapping a high frequency luminance signal among the luminance signals of the full band with a limited low frequency luminance signal, and an overlapping luminance signal having the limited bandwidth and the full bandwidth. An adder for adding a luminance signal, a DA converter for converting the added digital signal in analog form, a luminance signal recorder for modulating the output of the DA converter to be recorded on a recording medium, and the luminance signal recorder And a recording element for recording the output of the recording medium on a recording medium.

The video signal spreading signal of the present invention for achieving the above object comprises a reading element for reading information recorded on a recording medium, and a brightness signal reproducing unit for demodulating the information read by the reading element to reproduce the luminance signal. And an AD converter for converting the reproduced luminance signal into a digital luminance signal, a frequency spreader for spreading a high frequency luminance signal superimposed on a limited low frequency luminance signal among the digital luminance signals into an original occupied band, and an output of the frequency spreader. And an adder for adding the output of the AD converter.

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

1 is a block diagram of a video signal overlapping circuit of an embodiment of the present invention. In FIG. 1, the input terminal 5 is connected to a video signal source (not shown) to introduce a composite video signal CV, and the input terminal 5 is connected to the input terminal of the AD converter 10. In FIG. Connected. The output terminal of the A-D converter 10 is coupled to an input terminal of the luminance signal separation unit 20, an input terminal of the same signal separation unit 22, and an input terminal of the chromaticity signal separation unit 21. The output terminal of the luminance signal separation unit 20 is coupled to the input terminal of the frequency overlapping unit 30 and the input terminal of the low pass filter 40. The output terminal of the frequency overlapping section 30 and the output terminal of the low pass filter 40 are respectively coupled to the first input terminal and the second input terminal of the adder 50, respectively. The output terminal of the adder 50 is connected to the input terminal of the D-A converter 11, and the output terminal of the D-A converter 11 is connected to the input terminal of the luminance signal recorder 60. The output terminal of the luminance signal recorder 60 is coupled with the first input terminal of the chromaticity / luminance signal mixer 71. The output terminal of the chroma signal separator 21 is coupled to the first input terminal of the chroma / dong signal mixer 70. The output terminal of the copper signal separator 22 is coupled to the control terminal of the luminance signal separator 20 and the second input terminal of the chromaticity / dong signal mixer 70. The output terminal of the chromatic / dynamic signal mixer 70 is coupled to the input terminal of the D-A converter 12. The output terminal of the D-A converter 12 is coupled to the input terminal of the standard chroma signal recorder 80. The output terminal of the standard chroma signal recorder 80 is connected to the second input terminal of the chroma / luminance mixer 71. The output terminal of the chroma / luminance signal mixer 71 is connected to the magnetic recording head 90.

2 is an operating characteristic diagram for each part of the circuit shown in FIG. 2a is an output characteristic diagram of the luminance signal separator 20, FIG. 2b is an operation characteristic diagram when the frequency overlapping portion 30 overlaps, and FIG. 2c is an output characteristic of the frequency overlapping portion 30. 2D is an output characteristic diagram of the low pass filter 40, and FIG. 2E is an output characteristic diagram of the adder 50. FIG.

The operation of the circuit shown in FIG. 1 will be described in conjunction with the characteristics shown in FIG. The A-D converter 10 samples the composite video signal CV by a sampling clock of about 10 MHz, encodes the sampled signal, and generates a digital composite video signal DCV. The moving signal separator 22 separates the moving signal M representing the movement amount of the pixels on the screen from the digital composite video signal DCV.

The luminance signal separation unit 20 separates the luminance signal derived spatially from the digital composite image signal DCV and the luminance signal derived in time, and combines the two luminance signals appropriately based on the value of the same signal. To generate the luminance signal L. In this case, the luminance signal L has a bandwidth equal to that of FIG. 2a.

The chroma signal separator 21 separates the chroma signal C from the digital composite image signal DCV.

The frequency overlapping unit 30 attenuates the high frequency component (a luminance signal of 2.5 MHz or more) of the luminance signal L, and then samples the sub Nyquest to show the high frequency luminance signal as shown in FIG. 2B. The superimposed low-frequency luminance signal is superimposed, and the superimposed luminance signal is low-pass filtered so as to have a high frequency cut-off characteristic of 2.5 MHz to generate the superimposed luminance signal L ^{* as} shown in FIG. The low pass filter 40 removes the high luminance component of the luminance signal L of 3 MHz or more to generate a basic bandwidth luminance signal BL distributed in the effective bandwidth (3 MHz) of the video cassette tape as shown in FIG. The adder 50 adds the superimposed luminance signal L ^* and the baseband luminance signal BL distributed in the limited band to generate the luminance signal BL + L ^{* as} shown in FIG. 2e. The DA converter 11 converts the adder digital luminance signal BL + L ^* into the analog form in the adder 50. The luminance signal recording unit 60 frequency modulates the analog luminance signal BL + L ^* generated by the DA converter 11 to be recorded on the recording medium. The chromaticity / movement signal mixer 70 mixes the copper signal and the chroma signal C + M and supplies it to the DA converter 12. The DA converter 12 converts the chromaticity signal C + M in the digital form into the analog form. The chroma signal recording unit 80 modulates the chroma signal C + M introduced from the DA converter 12 by a carrier wave of about 629 kHz. The chroma / luminance signal mixer 71 mixes the frequency-modulated luminance signal and the amplitude-modulated chroma signal and supplies them to the magnetic recording head 90. The magnetic recording head 90 records the output of the chroma / luminance signal mixer 71 on the video tape cassette.

3 is a block diagram of a video signal spreading circuit of an embodiment according to the present invention. In FIG. 3, the magnetic reproduction head 100 is coupled to an input terminal of the chroma / luminance signal separator 110. The first output terminal of the chroma / luminance signal separator 110 is coupled to the input terminal of the luminance signal regeneration unit 120, and the second output terminal of the chroma / luminance signal separator 110 is the standard chroma signal regeneration unit 170. Is coupled to the input terminal of. The output terminal of the luminance signal reproducing unit 120 is connected to the input terminal of the A-D converter 130. The output terminal of the A-D converter 130 is coupled with the input terminal of the low pass filter 140 and the input terminal of the baseband processor 141. The output terminal of the low pass filter 140 is coupled to the input terminal of the frequency spreader 150. The output terminal of the frequency spreader 150 is coupled to the first input terminal of the adder 160. The output terminal of the baseband processor 141 is coupled to the second input terminal of the adder 160. The output terminal of the adder 160 is coupled to the input terminal of the D-A converter 132. The output terminal of the D-A converter 132 is coupled to the first input terminal of the composite video signal generator 180. The output terminal of the chroma signal reproducing unit 170 is coupled to the input terminal of the A-D converter 131. The output terminal of the A-D converter 131 is connected to the input terminal of the chromaticity / copper signal separator 111. The first output terminal of the chromaticity / copper signal separator 111 is coupled to the input terminal of the D-A converter 133. The second output terminal of the chromaticity / copper signal separator 111 is connected to the control terminal of the frequency spreader 150. The output terminal of the D-A converter 133 is coupled to the second input terminal of the composite image signal generator 180.

4 is an output characteristic diagram for each part of the circuit shown in FIG. 4A to 4A are output characteristic diagrams of the luminance signal reproducing unit 120 when reproducing a video tape cassette in which a video signal is recorded by a standard VHS system VCR, and FIG. 4B is a video signal produced by the VCR of the present invention. The output characteristic diagram of the luminance signal reproducing unit 120 when reproducing the recorded video tape cassette. 4C is an output characteristic diagram of the low-pass filter 140 when reproducing a video tape cassette in which a video signal is recorded by a standard VHS VCR. FIG. 4D is a video tape cassette in which a video signal is recorded by a VCR of the present invention. Is an output characteristic diagram of the low pass filter 140 in the case of regeneration. 4E is an output characteristic diagram of the baseband processor 141. 4f is an output characteristic diagram of the frequency spreader 150 when reproducing a video tape cassette on which a video signal is recorded by a standard VHS type VCR, and FIG. 4g is a video tape cassette on which a video signal is recorded by a VCR of the present invention. This is an output characteristic diagram of the frequency spreader 150 in the case of reproduction.

The operation of the circuit shown in FIG. 3 is described in detail in conjunction with the output characteristic shown in FIG.

The magnetic reproduction head 100 reads the information recorded on the video tape cassette and supplies it to the chromaticity / luminance signal separator 100.

The chroma / luminance signal separator 100 separates the frequency-modulated luminance signal and the amplitude-modulated color signal from the information supplied from the magnetic reproduction head 110.

The luminance signal regenerator 120 generates a luminance signal by frequency demodulating the frequency modulated luminance signal separated by the chroma / luminance signal separator 110. The luminance signal generated by the luminance signal regenerator 120 has a frequency characteristic as shown in FIG. 4A when the video tape cassette currently being reproduced is a video tape cassette in which a video signal is recorded by a standard VHS VCR. When the video tape cassette is a video tape cassette in which a video signal is recorded by the VCR of the present invention, it has the frequency characteristic as shown in FIG. 4B.

The A-D converter 130 converts the demodulated luminance signal into a plurality of digital video signals.

The low pass filter 140 filters the digital luminance signal and detects a luminance signal distributed within a limited bandwidth (within 2.5 MHz). The filtered luminance signal has a frequency characteristic as shown in FIG. 4c when a luminance signal having a frequency characteristic as shown in FIG. 4a is introduced into the low filter 140, and has a frequency characteristic as shown in FIG. 4b in the low filter 140 as shown in FIG. When the luminance signal is introduced, it has a frequency characteristic as shown in FIG. 4d.

The frequency spreader 150 spreads the superimposed high frequency luminance component among the luminance signals having the filtered limited bandwidth introduced from the low frequency filter 140 into the original frequency band, and then is applied from the chromatic / motion signal separator 111. According to the magnitude of the signal, a low frequency luminance signal and a high frequency luminance signal are appropriately combined to generate a luminance signal of full bandwidth. The luminance signal output from the frequency spreading unit 150 has a frequency characteristic as shown in FIG. 4f when the luminance signal having the frequency characteristic as shown in FIG. 4c flows into the frequency spreading unit 150, and the frequency spreading unit 150. When the luminance signal having the frequency characteristic as shown in FIG. 4d is introduced into the channel, the luminance signal has the frequency characteristic as shown in FIG.

The baseband processor 141 filters the digital luminance signal, detects a luminance signal distributed in a frequency band within 3 MHz, which is an effective bandwidth of the standard video tape cassette, and removes the high frequency luminance signal superimposed among the detected luminance signals to obtain the fourth e A luminance signal having the same frequency characteristic is generated.

The adder 160 adds the luminance signal generated by the frequency spreader 150 and the luminance signal processed by the baseband processor 141 to reproduce the video tape cassette on which the image signal is recorded by the standard VHS type VCR. A luminance signal having a frequency characteristic as shown in FIG. 4E is generated, and when a video tape cassette on which a video signal is recorded by the VCR of the present invention is reproduced, a luminance signal having frequency characteristic as shown in FIG. 4G is generated.

The D-A converter 132 converts the output of the adder 160 into an analog form.

The chroma signal regenerator 170 amplitude demodulates the amplitude modulated chroma signal to generate a chroma signal. The chroma signal includes the same signal when the video tape cassette on which the video signal is recorded by the VCR of the present invention is reproduced.

The A-D converter 131 converts the demodulated chroma signal into a digital chroma signal.

The chromaticity / motion signal separator 111 separates the digital chromaticity signal into a dynamic signal and a chromaticity signal, and supplies the same signal to the frequency spreader 150 and the chroma signal to the complex image signal generator 180.

The D-A converter 133 converts the digital chromaticity signal, which is the output of the chromaticity / copper signal separator 111, into an analog form.

The composite image signal generator 180 operates in a conventional manner to combine the luminance signal output from the DA converter 132 and the chroma signal output from the DA converter 133 to form a standard composite image signal. do.

As described above, the present invention provides an effective frequency to the recording medium by adding a second path for processing the luminance signal distributed in the effective bandwidth of the recording medium to the frequency overlapping path and the frequency spreading path for processing the distributed luminance signal of the limited band. By recording and reproducing the luminance signal of the band together with the superimposed luminance elongation, there is an advantage that the standard VHS method and the VCR can maintain the same resolution even when compatible with the standard VHS method VCR.

Claims (7)

An AD converter for recording a video signal distributed over a full band including a chroma signal and a luminance signal on a recording medium having a desired bandwidth, and converting the full-band video signal into a multi-bit digital video signal. 10), a luminance signal separation unit 20 for separating the luminance signal of the entire band from the digital image signal, and a luminance signal having a limited bandwidth by superimposing a high frequency luminance signal among the luminance signals of the entire band onto a limited low frequency luminance signal; A frequency overlapping unit (30) for generating a signal, an adder (50) for adding the superimposed luminance signal of the limited bandwidth and the luminance signal of the full band, and a luminance for modulating the added luminance signal to be recorded on a recording medium. And a recording device (90) for recording the output of said luminance signal recorder on a recording medium. The low frequency filter (40) of claim 1, further comprising a low pass filter (40) connected between the luminance signal separation unit and the adder to detect a luminance signal distributed over an effective bandwidth among recording signals of all bands and to supply it to the adder. Image signal overlapping circuit, characterized in that. 2. The chromaticity signal recorder (80) of claim 1, further comprising: a chromaticity signal separator (21) for separating chromaticity signals from digital image signals, and a chromaticity signal recorder (80) for frequency converting the chromaticity signals to be recorded on a recording medium; And a chromaticity / luminance signal mixer 70 connected between a signal recorder, the luminance signal recorder, and a recording element for mixing the frequency-converted chroma signal and the modulated luminance signal to supply the recording element. Signal overlapping circuit. 4. The apparatus according to claim 3, further comprising a copper signal separator (22) for separating the copper signal from the digital video signal, and the copper signal separator, the chromaticity signal separator, and the chromaticity signal recorder. And a chroma / dynamic signal mixer (70) for mixing and supplying the chroma signal to the chroma signal recorder. 5. The video signal overlapping circuit according to claim 4, wherein the recording element comprises a magnetic head (90). An image reproducing apparatus for reproducing a luminance signal and a chromaticity signal recorded on a recording medium having an effective bandwidth in a full-band video signal, comprising: a reading element 100 for reading information recorded on a recording medium; A luminance signal regenerator 120 for demodulating the information read by the reading element to reproduce the luminance signal, an AD converter 130 for converting the reproduced luminance signal into a digital luminance signal, and a limited low frequency luminance among the digital luminance signals. And a frequency spreader 150 for spreading the high frequency luminance signal superimposed on the signal into an original occupation band, and an adder 160 for adding the output of the frequency spreader and the output of the AD converter. Circuit. 7. The high frequency luminance signal of claim 6, further connected between the AD converter and the adder to detect a luminance signal distributed in an effective bandwidth of a recording medium during the output of the AD converter, and to output a high frequency luminance signal superimposed on a limited low frequency luminance signal. And a basic band processor for removing and supplying the adder to the adder.