KR930010486B1 - Picture image encoder and decoder - Google Patents

Abstract

The adaptive video signal encoder and decoder includes an A/D converter for converting video signal to digital signal, a spatial low-pass filter for dividing spatial brightness signal from digital video signal, a low-pass filter for detecting spatial brightness signal in bandwidth of recording tape, a soft switch for mixing spatial brightness signal in the bandwidth and time brightness signal, a frequency overlapping circuit for damping brightness signal level appropriately mixing the damped signal and brightness signal in the bandwidth and a D/A converter for converting mixed signal to analog signal.

Description

Adaptive Video Signal Encoder and Decoder

1 is a block diagram of an adaptive video signal encoder according to the present invention.

FIG. 2 is a detailed block diagram showing one part shown in FIG.

3 is a block diagram of an applied video signal decoder according to the present invention.

4 is a detailed block diagram showing one part shown in FIG.

* Explanation of symbols for main parts of the drawings

100, 300: A-D converter 110: space low pass filter

111: time low pass filter 112: low pass filter

120: adaptive attenuator 130: adaptive soft switch

140: frequency overlapping 150, 330: D-A converter

200, 400: High pass filter 210, 410: Look-up table

220: subtractor 310: frequency spreader

320: adaptive emphasis 420: adder

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for reconstructing a luminance signal in a video recording and reproducing apparatus for recording and reproducing a full bandwidth video signal on a recording medium having a limited bandwidth. And an image signal encoder and decoder capable of providing improved image quality during normal reproduction.

VCRs currently used in homes record video signals in videotape cassettes in one of several ways. The well-known VHS (Video Home System) often plays a deteriorated picture because of insufficient horizontal resolution. The reason why the horizontal resolution is insufficient is that the video signal is recorded only in a limited bandwidth, not all of the video tape cassettes whose bandwidth is limited to 3 MHz or 2.5 MHz.

Complementing the problem of VCRs used in homes, recording devices capable of recording full-bandwidth video signals on video tape cassettes with limited bandwidth and playback of full-bandwidth video signals recorded on video tape cassettes with limited bandwidth A full bandwidth playback device is disclosed in US Patent Application No. 07-569029. According to US Patent Application No. 07-560929, an improved image recording and reproducing apparatus for recording and reproducing a video signal of full bandwidth superimposes a luminance signal of a high frequency component among luminance signals on a luminance signal of a base band corresponding to a limited bandwidth. The superimposed luminance signals are recorded in a video tape cassette which is a recording medium. The improved image recording and reproducing apparatus attenuates a high frequency video signal superimposed on a signal of a baseband to a predetermined width or less before being superimposed so as to maintain backward compatibility with a normal VCR currently used at home.

However, U.S. Patent Application No. 07-560929 attenuates all luminance components of a high frequency band irrespective of a moving image or a still image, and superimposes them on a luminance signal of a basic band to generate a degraded screen during reproduction. This is because the luminance signal of the high frequency band of the same picture which acts as a noise is reproduced and displayed. In addition, since the luminance signal of the high frequency band is adaptively attenuated or decayed depending on the level, the screen may be degraded by the luminance signal of the high frequency band which is superimposed upon backward compatibility with the normal VCR.

Accordingly, an object of the present invention is to provide an adaptive video signal encoder capable of preventing screen deterioration in an image recording apparatus for recording a full bandwidth video signal on a recording medium of limited bandwidth.

Another object of the present invention is to provide an adaptive video signal encoder capable of improving image quality of a screen when backward compatibility with a normal VCR in an image recording apparatus for recording a full bandwidth video signal on a limited recording medium.

It is still another object of the present invention to provide an adaptive video signal decoder capable of improving image quality due to deterioration of a screen in a video reproducing apparatus for reproducing a video signal having a full bandwidth recorded in a limited bandwidth.

In order to achieve the above object, the adaptive video signal encoder of the present invention includes an AD converter for converting a video signal into a digital video signal, an adaptive spatial low pass filter for detecting a spatial luminance signal from the digital video signal, and a new signal from the digital video signal. A low pass filter for detecting the luminance signal, a low pass filter for detecting the spatial luminance signal of the baseband from the spatial luminance signal, an adaptive attenuation circuit for adaptively attenuating the time luminance signal, and an adaptive A soft switch for mixing the spatial luminance signal and the adaptive attenuated temporal luminance signal of the basic band, a frequency overlapping portion for frequency-overlapping the high frequency components of the luminance signal mixed by the soft switch to the basic band components, and a superimposed luminance signal And a DA converter for converting analog signal types.

In order to achieve the above object, the adaptive video signal decoder of the present invention includes a DA converter for converting a reproduced luminance signal into a digital luminance signal, and a frequency for spreading a luminance signal of a high frequency component superimposed on the digital luminance signal into an original band. And an expanding portion and an adaptive highlighting portion that adaptively emphasizes the unfolding luminance signal.

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

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

In FIG. 1, the first input terminal 105 is connected to a video signal source (not shown) for introducing a video signal. The first input terminal 105 is connected to the input terminal of the A-D converter 100. The output terminal of the A-D converter 100 is coupled with the input terminal of the spatial low pass filter 110 and the input terminal of the temporal low pass filter 111. The output terminal of the time low pass filter 111 is connected to the input terminal of the adaptive attenuator 120. The output terminal of the low pass filter 112 is connected to the first input terminal of the soft switch 130. The output terminal of the adaptive attenuator 120 is connected to the second input terminal of the soft switch 130. The second input terminal 115 is connected to a copper signal detection circuit (not shown) for introducing the copper signal. The second input terminal 115 is connected to the control terminal of the soft switch 130. The output terminal of the soft switch 130 is connected to the input terminal of the frequency overlapping unit 140. The output terminal of the frequency overlapping unit 140 is connected to the input terminal of the D-A converter 150. The output terminal of the D-A converter 150 is connected to the output terminal 125. The output terminal 125 is connected to a luminance signal recorder (not shown).

In operation of FIG. 1, the A-D converter 100 converts the digital video signal in the form of an analog signal flowing through the first input terminal 105. The spatial low pass filter 110 detects the co-luminance signal from the digital image signal generated by the A-D converter 100 by a line comb filter using the correlation between lines. The spatial luminance signal detected at this time becomes a luminance signal for the moving image.

The time low pass filter 111 detects the time luminance signal from the digital image signal generated by the A-D converter 100 by a frame comb filter using inter-frame correlation. At this time, the detected time luminance signal becomes a luminance signal for the still image.

The low pass filter 112 filters the spatial luminance signal introduced from the spatial low pass filter 110 to filter the spatial luminance signal of the base band from which the high frequency spatial luminance signal of the base band or higher that acts as a noise during reproduction is removed from the spatial luminance signal. Detect.

The adaptive attenuator 120 adaptively attenuates the high frequency time luminance signal over the base band among the time luminance signals supplied from the time low pass filter 111 and supplies the adaptive attenuated time luminance signal to the soft switch 130. Detailed operation of the adaptive attenuator 120 is described in FIG.

The shift switch 130 applies the spatial luminance signal of the basic band flowing into the first input terminal and the adaptive attenuated time luminance signal flowing into the second incoming terminal to the control terminal through the second input terminal 115. Appropriately mixed according to the signal value, the mixed luminance signal is supplied to the frequency overlapping unit 140.

The frequency overlapping unit 140 appropriately attenuates the high frequency luminance signal of the base band or more among the luminance signals mixed by the soft switch 130 according to its level, and then superimposes the attenuated high frequency luminance signal of the base band or more with the luminance signal of the base band. .

The D-A converter 150 converts the superposed luminance signals into analog signals and supplies them to the luminance signal recorder through the output terminal 125.

FIG. 2 is a block diagram of the adaptive attenuator 120 which is part of the adaptive video signal encoder shown in FIG. In FIG. 2, the input terminal 205 is connected to the input terminal of the adaptive attenuator 20 in FIG. The input terminal 205 is coupled to the input terminal of the high pass filter 200 and the first input terminal of the subtractor 220. The output terminal of the high pass filter 200 is connected to the input terminal of the look-up table 210. The output terminal of the look-up table 210 is connected to the second input terminal of the subtractor 220. The output terminal of the subtractor 220 is connected to the output terminal 215. The output terminal 215 is connected to the output terminal of the adaptive attenuator 120 shown in FIG.

In operation of FIG. 2, the high pass filter 200 filters the time luminance signal flowing through the input terminal 205 and detects the high frequency time luminance signal above the base band.

The look-up table 210 reads the attenuation value having another value stored in advance according to the level of the high frequency time luminance signal detected by the high pass filter 200 and supplies it to the subtractor 220. At this time, the attenuation value output from the look-up table 210 has a maximum value of 11000000 when the high frequency new luminance signal has a maximum value, and has a value reduced from this maximum value at a ratio of y = a (xb). . Attenuation value attenuation table of the look-up table 210 is as follows.

The subtractor 220 subtracts the new light luminance new stream introduced through the input terminal 205 to the attenuation value introduced from the look-up table 210 and transmits the subtracted market brightness signal through the output terminal 215. At this time, the subtracted temporal luminance signal is adaptively attenuated by the high frequency component of the base band or more according to its level. Attenuated at a ratio of ² .

3 is a block diagram of an adaptive video signal decoder of an embodiment according to the present invention. In FIG. 3, the input terminal 305 is connected to a luminance signal reproducing system (not shown) for introducing the reproduced luminance signal. The input terminal 305 is connected to the input terminal of the A-D converter 300. The output terminal of the A-D converter 300 is connected to the input terminal of the frequency spreading unit 310. The output terminal of the frequency spreading unit 320 is connected to the input terminal of the adaptive emphasis unit 320. The output terminal of the adaptive emphasis unit 320 is connected to the input terminal of the D-A converter 330. The output terminal of the D-A converter 330 is connected to the output terminal 315. The output terminal 315 is connected to a luminance / chromatic mixing mixer (not shown).

In operation of FIG. 3, the A-D converter 300 converts the reproduced luminance signal in the form of an analog signal flowing through the input terminal 395 into a digital luminance signal and supplies it to the frequency spreading unit 310. At this time, in the reproduced luminance signal flowing on the input terminal 305, the high frequency luminance signal of the base band or more overlaps with the luminance signal of the base band.

The frequency spreading unit 310 spreads the high frequency luminance signal over the base band overlapped with the luminance signal of the base band among the digital luminance signals to the original frequency band, and then attenuates the frequency overlapping unit 140 at the time of frequency overlap as appropriate. The signal is expanded according to the level and the expanded luminance signal is supplied to the adaptive emphasis unit 320.

The adaptive emphasis unit 320 adaptively emphasizes the luminance signal unfolded by the frequency spreader 310 and supplies the adaptive emphasis luminance signal to the D-A converter 330. The detailed operation of this adaptive emphasis 320 is described in FIG.

The D-A converter 330 converts the luminance signal adaptively enhanced by the adaptive emphasis unit 320 into an analog signal form and supplies the converted analog luminance signal to the luminance / chromatic signal mixer through the output terminal 315. At this time, the analog luminance signal to be converted is a luminance signal of full bandwidth.

4 is a block diagram of an adaptive emphasis unit which is a part of the adaptive image signal decoder shown in FIG. In FIG. 4, the input terminal 405 is connected to the input terminal of the adaptive emphasis unit 320 in FIG. The input terminal 405 is coupled to the input terminal of the high pass filter 400 and the first input terminal of the adder 420. The output terminal of the high pass filter 400 is coupled to the input terminal of the look-up table 410. The output terminal of the look-up table 410 is connected to the second input terminal of the adder 420. The output terminal of the adder 420 is connected to the output terminal 415. The output terminal 415 is coupled to the output terminal of the adaptive emphasis unit 320 in FIG.

In the operation of FIG. 4, the luminance signal of the full bandwidth which flows in through the input terminal 205 of the high pass filter 400 is filtered to detect the high frequency luminance signal of the base band or more.

The look-up table 410 reads an emphasis value having another value which is preset and stored according to the level of the luminance signal above the base band detected by the high pass filter 400 and supplies it to the adder 420. At this time, the emphasis value output from the look-up table 210 is the same as the decrease value of the look-up table 210 in FIG. 2.

The adder 420 adds an emphasis value read from a look-up table 410 to an unfolded full-width luminance signal flowing through the input terminal 405, and then a high frequency of the unfolded full-band luminance signal. Emphasis is placed on ingredients. The unfolded full-width luminance signal adaptively emphasized by the adder 420 is supplied to the D-A converter 330 in FIG. 3 through the output terminal 415.

As described above, the present invention can prevent the deterioration of the screen by removing the high frequency luminance component (high frequency component of the spatial luminance signal) of the moving picture component acting as noise before the high frequency luminance signal is superimposed on the luminance signal of the base band. It has an advantage, and the high frequency luminance component is adaptively attenuated according to its level before being superimposed on the luminance signal of the base band and attenuated again when the frequency is overlapped to minimize the deterioration of the screen due to the overlapped high frequency luminance code when the backward compatibility with the normal VCR. There is an advantage to this.

Claims (6)

A video recording apparatus for recording a full bandwidth video signal on a recording medium having a limited bandwidth, comprising: an AD converter for converting a video signal into a digital video signal, and a space for separating a spatial luminance signal of a moving picture component from the digital video signal. A low pass filter, a time low pass filter for separating a temporal luminance signal of a still picture component from the digital image signal, a low pass filter for detecting only a spatial luminance signal within a bandwidth of a recording medium in the spatial luminance signal, and the recording A soft switch for mixing the spatial luminance signal and the temporal luminance signal within the bandwidth of the medium, and attenuating the luminance signal more than the bandwidth of the recording medium among the luminance signals mixed by the soft switch, and converting the attenuated luminance signal into the bandwidth of the recording medium. A frequency overlapping portion superimposed on the luminance signal and superimposed by the frequency overlapping portion An adaptive video signal encoder comprising a D-A converter for converting a luminance signal into an analog luminance signal. The adaptive attenuation device of claim 1, further comprising an adaptive attenuation means connected between the time lowpass filter and the soft switch to adaptively attenuate a high frequency time luminance signal of at least a bandlock of a recording medium among the time luminance signals. Video signal encoder. 3. The high pass filter of claim 2, wherein the adaptive attenuation means detects a high frequency time luminance signal of at least a bandwidth of a recording medium among the time luminance signals, and attenuation values having different values depending on the level of the high frequency time luminance signal. And a subtractor for generating an adaptively attenuated time luminance signal by subtracting the time luminance signal to the attenuation value. The adaptive image of claim 3, wherein the attenuation value has a maximum value at a maximum value of the high frequency time luminance signal, and decreases at a ratio of y = a (xb) ² as the high frequency time luminance signal is decreased. Signal encoder. A video reproducing apparatus for reproducing a video signal of full bandwidth recorded on a recording medium having a limited bandwidth, comprising: an AD for converting a luminance signal superimposed on a luminance signal of a bandwidth of a recording medium into a digital luminance signal; A converter, a frequency spreader for unfolding the high frequency luminance signal superimposed on the luminance signal of the bandwidth of the recording medium among the digital luminance signals in the original band and picking the unfolded luminance signal; And an DA converter for converting the luminance signal of the adaptive bandwidth full bandwidth into an analog luminance signal. 6. The high frequency filter of claim 5, wherein the adaptive emphasis unit separates a high frequency luminance signal of at least a bandwidth of a recording medium from the spread and peaked luminance signals of a full bandwidth, and a high frequency luminance signal of at least a bandwidth of the recording medium. A look-up table for generating enhancement values having different values, and an adder for generating the luminance signal of the full bandwidth adaptively added by adding the expanded peaked luminance signal of the full bandwidth to the enhancement value. Adaptive video signal encoder.