Abstract:
A filter is used for separating luminance and color signals from a composite color television signal in which the frequency of the color signal is multiplexed over the high-frequency region of the luminance signal. When a picture is detected with respect to its motion under frame correlation and if that motion is relatively small, the separation of luminance and color signals is performed based on the interframe correlation. If the motion is relatively large, the separation of luminance and color signals is made based on the interfield correlation. The luminance and color signal separation based on the interfield correlation is attained from a correlation with signals in a field spaced forwardly away from the subject field by one field. This is accomplished by selecting a calculation having the highest correlation in calculations for an objective sample point and a plurality of sample points located about the objective sample point. Such a correlation is determined by checking the correlation of image signals in the set of sample points which are spaced apart from one another by one frame and located around the objective sample point.

Description:
This application is a continuation of application Ser. No. 08/015,677 filed on Feb. 9, 1993, now abandoned; which is a continuation of application Ser. No. 07/717,889 filed on Jun. 19, 1991, now abandoned; which is a continuation-in-part of application Ser. No. 07/676,320 filed on Mar. 28, 1991, now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a motion adaptive luminance signal and color signal separating filter for separating a luminance signal (hereinafter referred to as &#34;Y signal&#34; or simply &#34;Y&#34;) and a color signal (hereinafter referred to as &#34;C signal&#34; or simply &#34;C&#34;) from a composite color television signal (hereinafter referred to as &#34;V signal&#34;) in which the frequency of the C signal is multiplexed on the high frequency region of the Y signal. 
     The motion adaptive YC separating filter is a filter which locally judges whether a picture is a still or motion picture and executes YC separation suitable to the pixel signal in that picture at each of the locations thereof. 
     2. Description of the Related Art 
     The current NTSC signal system provides a composite signal comprising a C signal and a Y signal having its high-frequency region on which the frequency of the C signal is multiplexed. Therefore, television sets require YC separation. Imperfect YC separation causes the picture quality to deteriorate in cross color, dot crawl and so on. 
     With development of large-capacity digital memories, there have been proposed various types of signal processing circuits for improving the quality of picture, for example, by using a motion adaptive YC separation which utilizes a delay circuit having a delay time equal to or greater than the vertical scanning frequency of a television signal. 
     FIG. 10 is a block diagram showing one example of the conventional motion adaptive YC separating filters. In FIG. 10, the filter receives, at its input terminal 1, a V signal 101 according to the NTSC system. This signal is shared and input to the respective input terminals of infield YC separation circuit 4, interframe YC separating circuit 5, Y-signal motion detecting circuit 6 and C-signal motion detecting circuit 7. 
     In the infield YC separating circuit 4, the input signal is infield separated into a Y signal 102 and a C signal 103 through an infield filter (not shown). The Y and C signals are then applied respectively to the first inputs of Y-signal mixing circuit 9 and C-signal mixing circuit 10. 
     In the interframe YC separating circuit 5, the input signal is interframe separated into a Y signal 104 and a C signal 105. These Y and C signals are then supplied respectively to the second inputs of the Y-signal and C-signal mixing circuits 9 and 10. 
     On the other hand, a signal 106 indicative of the amount of movement of Y signal detected by the Y-signal motion detecting circuit 6 is applied to one of the inputs of a synthesizer 8 while a signal 107 representative of the amount of movement of C signal detected by the C-signal motion detecting circuit 7 is supplied to the other input of the synthesizer 8. 
     The synthesizer 8 forms a motion detection signal 108 which is shared and input to the respective third inputs of the Y-signal and C-signal mixing circuits 9 and 10. Thus, the Y-signal motion detecting circuit 6, C-signal motion detecting circuit 7 and synthesizer 8 define a motion detecting circuit 80. 
     The output 2 of the Y-signal mixing circuit 9 provides a motion adaptive separated Y signal 109 while the output 3 of the C-signal mixing circuit 10 provides a motion adaptive separated C signal 110. 
     This conventional YC separating circuit will now be described in operation. 
     On YC separation of V signal 101, the motion detecting circuit 80 judges whether the V signal 101 is one indicative of a still or motion picture, based on the output signal from the synthesizer 8 in which the outputs of the Y-signal and C-signal motion detecting circuits 6 and 7 are synthesized. 
     As shown in FIG. 11, the Y-signal motion detecting circuit 6 may comprise a one-frame delay circuit 53, a subtracter 54, a low pass filter 55 (hereinafter referred to as &#34;LPF&#34;), an absolute value circuit 56 and a nonlinear converting circuit 57. V signal 101 inputted to the Y-signal motion detecting circuit 6 at its input 51 is delayed by one frame at the one-frame delay circuit 53. The V signal 101 is also applied directly to the subtracter 54 and then subtracted from the one-frame delayed signal to determine one-frame difference therebetween. The one-frame difference signal is passed through the low pass filter 55 (hereinafter referred to as &#34;LPF&#34;) and is then is applied to the absolute value circuit 56 whereat the absolute value thereof is determined. The determined absolute value is then converted by the nonlinear converting circuit 57 into a signal 106 indicative of the movement of the low frequency component in the Y signal. This signal 106 is outputted from the output 52 of the Y-signal detecting circuit 6. The nonlinear converting circuit 57 serves to convert an absolute value into a data having a magnitude which can be more easily handled by the system. 
     As shown in FIG. 12, the C-signal motion detecting circuit 7 may comprise a two-frame delay circuit 81, a subtracter 82, a band pass filter 83 (hereinafter referred to as &#34;BPF&#34;), an absolute value circuit 84 and a nonlinear converting circuit 85. V signal 101 inputted to the C-signal motion detecting circuit 7 at its input 11 is delayed by one frame at the two-frame delay circuit 81. The V signal 101 is also applied directly to the subtracter 82 and then subtracted from the two-frame delayed signal to determine two-frame difference therebetween. The two-frame difference signal is passed through the band pass filter 83 and then applied to the absolute value circuit 84 whereat the absolute value thereof is determined. The determined absolute value is then converted by the nonlinear converting circuit 85 into a signal 107 indicative of the amount of movement of the C signal. This signal 106 is outputted from the output 89 of the C-signal detecting circuit 6. 
     The synthesizing circuit 8 is adapted to select and output the one of the Y-signal and C-signal movement signals 106 and 107 which is larger than the other movement signal. 
     Such a judgement is represented by a control signal 108 in the form of motion coefficient (0≦k≦1). If a picture is judged to be a complete still picture, the motion coefficient k is equal to zero. If the picture is judged to be a complete motion picture, the motion coefficient k is equal to one. 
     Generally, if a picture is a still picture, the interframe correlation is utilized to perform the interframe YC separation such that Y and C signals are separated from each other. 
     As shown in FIG. 13, the interframe YC separating circuit 5 may comprise a one-frame delay circuit 64, an adder 65 and a subtracter 66. V signal 101 inputted to the interframe YC separating circuit 5 at its input 61 is delayed by one frame at the one-frame delay circuit 64 to form a one-frame delay signal which in turn is added to the V signal directly inputted to the adder 65. The resultant one-frame sum provides a YF signal 104 which is outputted from one output 62 in the interframe YC separating circuit 5. At the same time, the subtracter 66 subtracts the YF signal 104 from the V signal 101 directly applied from the input 61 to the subtracter 66 to extract a CF signal 105. This, in turn is outputted from the output 63 of the interframe YC separating circuit 5. 
     In general, if a picture is a motion picture, the infield correlation is utilized to perform the infield YC separation such that the Y and C signals are separated from each other. 
     As shown in FIG. 14, the infield YC separating circuit 4 may comprise a one-line delay (one horizontal line . . . 1H delay) circuit 74, an adder 75 and a subtracter 76. V signal 101 inputted to the infield YC separating circuit 4 at its input 71 is delayed by one line at the one-line delay circuit 74 to form a one-line delay signal which in turn is added to the V signal directly inputted to the adder 75. The resultant one-line sum provides a Yf signal 102 which is outputted from one output 72 in the infield YC separating circuit 5. At the same time, the subtracter 76 subtracts the Yf signal 102 from the V signal 101 directly applied from the input 71 to the subtracter 76 to extract a Cf signal 103. This, in turn is outputted from the output 73 of the infield YC separating circuit 4. 
     Since the infield and interframe YC separating circuits 4 and 5 are arranged parallel to each other, the motion adaptive YC separation filter can causes the Y-signal mixing circuit 9 to calculate the following equation using the motion coefficient k synthesized by the synthesizer 8: 
     
         Y=kYf+(1-k)YF 
    
     where Yf is an output Y signal 102 from the infield YC separation and YF is an output Y signal 104 from the interframe YC separation. There is thus obtained a motion adaptive YC separation Y signal 109 which in turn is outputted from the motion adaptive YC separation filter at the output 2. 
     Similarly, the control signal 108 is utilized to cause the C-signal mixing circuit 10 to calculate the following equation: 
     
         C=kCF+(1-k)CF 
    
     where Cf is an output signal 103 from the infield YC separation and CF is an output signal 105 from the interframe YC separation. There is thus obtained a motion adaptive YC separation C signal 110 which in turn is outputted from the output 3. 
     The C-signal motion detecting circuit 7 may be arranged as shown in FIG. 15. In this figure, V signal 101 inputted to the circuit 7 at the input 11 is demodulated by a color demodulating circuit 86 into two color difference signals R-Y and B-Y. These color difference signals R-Y and B-Y are then applied to a time division multiplexer 87 in which they are time-division multiplexed at a certain frequency. The output signal from the time division multiplexer 87 is then subjected to subtraction from an output signal from a two-frame delay circuit 81. There is thus obtained a two-frame difference signal. 
     The two-frame difference signal is passed through BPF 83 wherein a Y-signal component is removed therefrom. The output signal of the BPF 83 is then applied to an absolute value circuit 84 to extract an absolute value therefrom. The absolute value is then applied to a nonlinear converter 85 wherein it is nonlinearly converted into a C-signal motion detection signal 107 which in turn is outputted from the output 89 of the C-signal motion detecting circuit 7. 
     It will be apparent from the foregoing that Yf and Cf signals from the infield YC separating circuit 4 and YF and CF signals from the interframe YC separating circuit 5 are respectively mixed with each other. They are mixed based on the amount of movement which is obtained by synthesizing the motion signals from the respective Y-signal and C-signal motion detecting circuits 6 and 7. 
     Therefore, the filter characteristics for the still picture will be completely different from that for the motion picture. If a picture is switched from a still to a motion picture or vice versa, the resolution is subjected to severe change such that the quality of picture will be remarkably degraded on processing the motion picture. 
     SUMMARY OF THE INVENTION 
     In order to overcome the above problem in the prior art, it is therefore an object of the present invention to provide a motion adaptive YC separation filter which can reproduce even such a multi-switched picture as described above with an increased resolution and with a reduced degradation of image quality. 
     To this end, the present invention provides a motion adaptive YC separation filter comprising an inframe YC separation circuit in which, when a motion picture is detected by a motion detecting circuit, an interframe correlation is locally detected with the detected result being utilized to adaptively select one inframe processing from a plurality of inframe processings including interfield operations and infield color signal band limitations, whereby output Y and C signals can be inframe separated from each other. 
     In another aspect of the present invention, the motion adaptive YC separation filter may comprise an inframe YC separation circuit in which when a motion picture is detected by a motion detecting circuit, an interframe correlation is locally detected with the detected result being utilized to adaptively select one inframe processing from a plurality of inframe processings, including interfield operations and infield luminance signal band limitations, whereby output Y and C signals can be inframe separated from each other. 
     When a motion picture is detected by a motion detecting circuit, the motion adaptive YC separation filter determines a correlation between frames. Depending on this correlation, one of three inframe YC separation circuits is selected to output Y and C signals from the inframe YC separation. 
     It will be apparent from the foregoing that when a motion picture is detected by the motion detecting circuit, the motion adaptive YC separation filter can cause the inframe YC separating circuits to detect a local correlation between frames to perform YC separation in three or four types of frames, including interfield operations and infield color signal band limitations. Upon processing any motion picture, therefore, the correlation in the picture can be utilized to perform an optimum YC separation with a reduced degradation of resolution. 
     Upon detection of a motion picture, furthermore, the motion adaptive YC separation filter of the present invention can cause the inframe YC separating circuits to detect a local correlation between frames to perform YC separation in three or four types of frames including interfield operations and infield luminance signal band limitations. Upon processing any motion picture, therefore, the correlation in the picture can be utilized to perform an optimum YC separation with a reduced degradation of resolution. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram of one embodiment of a motion adaptive YC separating filter constructed in accordance with the present invention. 
     FIG. 2 is a block diagram of the details of an inframe YC separating circuit used in the embodiment of the present invention shown in FIG. 1. 
     FIG. 3 is a block diagram of the detail of another inframe YC separating circuit usable in the embodiment of the present invention shown in FIG. 1. 
     FIG. 4 is a block diagram of the detail of still another inframe YC separating circuit usable in the embodiment of the present invention shown in FIG. 1. 
     FIG. 5A is a plan view illustrating the arrangement of a V signal represented by the use of t-axis and y-axis, the V signal being digitized at a frequency four times as high as that of a chrominance subcarrier in a three-dimensional time space. 
     FIGS. 5B and 5C are plan views illustrating the arrangement of the same V signal represented by the use of x-axis and y-axis. 
     FIG. 6A is an oblique view of the spectrum distribution of the V signal in a three-dimensional frequency space. 
     FIG. 6B is a view of the spectrum distribution of FIG. 6A as viewed along the f-axis from the negative side. 
     FIG. 6C is a view of the spectrum distribution of FIG. 6A as viewed along the μ-axis from the positive side. 
     FIG. 7A is an oblique view of the spectrum distribution of Y and C signals obtained from the first interfield YC separation according to the present invention in a three-dimensional frequency space. 
     FIG. 7B is a view of the spectrum distribution of FIG. 7A as viewed along the f-axis from the negative side. 
     FIG. 7C is a view of the spectrum distribution of FIG. 7A as viewed along the μ-axis from the positive side. 
     FIG. 8A is an oblique view of the spectrum distribution of Y and C signals obtained from the second interfield YC separation according to the present invention in a three-dimensional frequency space. 
     FIG. 8B is a view of the spectrum distribution of FIG. 8A as viewed along the f-axis from the negative side. 
     FIG. 8C is a view of the spectrum distribution of FIG. 8A as viewed along the μ-axis from the positive side. 
     FIG. 9A is an oblique view of the spectrum distribution of Y and C signals obtained from the third interfield YC separation according to the present invention in a three-dimensional frequency space. 
     FIG. 9B is a view of the spectrum distribution of FIG. 9A as viewed along the f-axis from the negative side. 
     FIG. 9C is a view of the spectrum distribution of FIG. 9A as viewed along the μ-axis from the positive side. 
     FIG. 10 is a block diagram of a conventional motion adaptive YC separation filter. 
     FIG. 11 is a block diagram of the details of a Y-signal motion detecting circuit in the conventional motion adaptive YC separation filter shown in FIG. 10. 
     FIG. 12 is a block diagram of the details of a C-signal motion detecting circuit in the conventional motion adaptive YC separation filter shown in FIG. 10. 
     FIG. 13 is a block diagram of the details of an interframe YC separating circuit in the conventional motion adaptive YC separation filter shown in FIG. 10. 
     FIG. 14 is a block diagram of the details of an infield YC separating circuit in the conventional motion adaptive YC separation filter shown in FIG. 10. 
     FIG. 15 is a block diagram illustrating another example of the conventional C-signal motion detecting circuits. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Several embodiments of a motion adaptive YC separation filter constructed in accordance with the present invention will now be described in connection with the drawings. FIG. 1 shows a block diagram of one embodiment of the present invention, wherein the infield YC separating circuit 4 shown in FIG. 10 is replaced by an inframe YC separating circuit 50. The remaining components are similar to those of FIG. 10 and will not be further described. 
     The details of the inframe YC separating circuit 50 shown in FIG. 1 is illustrated in FIG. 2 by a block diagram. 
     Referring now to FIG. 2, the inframe YC separating circuit 50 receives a V signal 101 at its input terminal 11. This V signal 101 is applied to the respective inputs of a 263-line (263H) delay circuit 14, one-line (1H) delay circuit 23 and two-pixel (2D) delay circuit 25. 
     The V signal is delayed by 263 lines (one field) at the 263H delay circuit 14 and is then provided to a two-pixel (2D) delay circuit 15 and a 262-line (262H) delay circuit 16 at the respective inputs. 
     The V signal is delayed by two pixels at the 2D delay circuit 15 and then applied to the first inputs of subtracters 20, 21, 22 and 37, respectively. The V signal is delayed by 262 lines at the 262H delay circuit 16 and then supplied to the inputs of a four-pixel (4D) delay circuit 17 and one-line (1H) delay circuit 18, the first input of a subtracter 26 and the second input of the subtracter 20, respectively. The V signal delayed by four pixels at the 4D delay circuit 17 is inputted to the second input of the subtracter 21 and the first input of a subtracter 27. The V signal delayed by one line at the 1H delay circuit 18 is provided to the input of two-pixel (2D) delay circuit 19. The V signal is delayed by two pixels at the 2D delay circuit 19 and then applied to the second input of the subtracter 22 and the first input of a subtracter 28. 
     The output signal of the subtracter 20 is applied to a one-half multiplier 1001, and the output of one-half multiplier 1001 is applied to a signal selection circuit 33 at its first input. The output signal of the subtracter 21 is provided to a one-half multiplier 1002, and the output of one-half multiplier 1002 is applied to the second input of the signal selection circuit 33. The output signal of the subtracter 22 is supplied to a one-half multiplier 1003, and the output of one-half multiplier 1003 is applied to the third input of the signal selection circuit 33. 
     The V signal is delayed by one line at the 1H delay circuit 23 and is then applied to the input of a 4D delay circuit 24 and the second input of the subtracter 27. The V signal is further delayed by four pixels at the 4D delay circuit 24 and is then applied to the second input of the subtracter 26. The V signal delayed by two pixels at the 2D delay circuit 25 is provided to the second input of the subtracter 28. 
     The output of the subtracter 26 is provided to the input of an absolute value (ABS) circuit 29; the output of the subtracter 27 to the input of ABS circuit 30; and the output of the subtracter 28 to the input of ABS circuit 31. 
     The output of the ABS circuit 29 is applied to the first input of a minimum value selection circuit (MIN) 32; the output of the ABS circuit 30 to the second input of the MIN 32; and the output of the ABS circuit 31 to the third input of the MIN 32. 
     The output of the MIN 32 is supplied to the fourth input of the signal selection circuit 33, by which one of the first to third inputs will be selected in the circuit 33. 
     The output of the signal selection circuit 33 is applied to the input of a one-line (1H) delay circuit 34 and the first input of a subtracter 35, respectively- The output of the one-line (1H) delay circuit 34 is provided to the second input of the subtracter 35. The output of the subtracter 35 is applied to a one-half multiplier 1004, and the output of one-half multiplier 1004 is applied to the input of BPF 36. 
     The output of BPF 36 is provided to the second input of a subtracter 37 and also outputted through an output 13 as C signal 113 from the inframe YC separation. The output of the subtracter 37 is outputted through another output 12 as Y signal 112 from the inframe YC separation. 
     The operation will be described below: 
     Assuming that a scene includes a horizontal x-axis, a vertical y-axis, extending perpendicular to the x-axis in the same scene, and a time t-axis extending perpendicular to a plane defined by the x- and y-axes, it can be believed that a space defined by the three x-, y- and t-axes is a three-dimensional time space. 
     FIG. 5 shows such a three-dimensional time space. FIG. 5A shows a plane defined by the t- and y-axes while FIGS. 5B and 5C show a plane defined by the x- and y-axes. FIG. 5A also shows interlacing scan lines with a broken line illustrating one field. Solid lines depict that chrominance subcarriers are in phase. 
     In FIG. 5B, solid and broken lines represent scan lines in n and (n-1) fields, respectively. Four marks &#34;◯&#34;, &#34;&#34;, &#34;.increment.&#34; and &#34;▴&#34; on each scan line represent sample points at which chrominance subcarriers are in phase when the V signal is digitized with a sampling frequency four times as high as the frequency fsc (=3.58 MHz) of the chrominance subcarrier. 
     In FIG. 5C, solid and broken lines represent scan lines in (n+1) and n fields, respectively. Four marks &#34;◯&#34;, &#34;&#34;, &#34;.increment.&#34; and &#34;▴&#34; on each scan line are similar to those of FIG. B. The sample points &#34;◯&#34;, &#34;.increment.&#34;, &#34;&#34;, and &#34;▴&#34; have chrominance subcarriers which are out of phase by each 90° in such an order as described. 
     If it is assumed that an objective sample point is represented by a mark &#34;⊚&#34;, the chrominance subcarriers are out of phase by 180° at four points a, b, c and d, which are at the respective second sample points measured forward and backward from the objective sample point &#34;⊚&#34; and on the respective first scan line spaced vertically away from the scan line of the objective sample point in the same field. 
     Therefore, by a digital circuit, there can be constructed a line comb filter or an adaptive YC separation filter, such as that disclosed in Japanese Patent Laid-Open No. 58-242367 and so on. 
     Since the chrominance subcarriers are out of phase by 180° at the identical sample points spaced away from each other by one frame as shown in FIG. 5A, the present invention can provide an inframe YC separating filter. 
     As can be seen from FIG. 5B, the phase of the chrominance subcarrier is reversed in (n-1) field spaced by one field apart from an objective sample point at a sample point on a line immediately above the scan line on which the objective sample point is located, or at two sample points on a line immediately below that scan line. Therefore, interfield YC separation can be achieved from an arithmetic operation between any one of these three points e, f and g and the objective point . 
     If it is assumed that a horizontal frequency axis corresponding to the x-axis is μ-axis, a vertical frequency axis corresponding to the y-axis is ν-axis and a time frequency axis corresponding to the t-axis is f-axis, it can be believed that there is a three-dimensional frequency space defined by these μ-, ν- and f-axes perpendicular to each other. 
     FIG. 6 depicts such a three-dimensional frequency space in projection. FIG. 6A is an oblique view of the three-dimensional frequency space; FIG. 6B is a view of the three-dimensional frequency space as viewed along the f-axis from the negative side; and FIG. 6C is a view of the three-dimensional frequency space as viewed along the μ-axis from the positive side. 
     FIGS. 6A, 6B and 6C represent the spectrum distribution of a V signal in the three-dimensional frequency space. As seen from these figures, the spectrum of Y signal extends around the origin of the three-dimensional frequency space. C signal has four spectrums located in the three-dimensional frequency space at four points as shown in FIGS. 6A to 6C since I and Q signals are modulated into two quadrature phases at the frequency fsc of the chrominance subcarrier. 
     If the V signal is observed on the μ-axis as shown in FIG. 6C, however, the spectrums of the C signal will be only on the second and fourth quadrants. 
     This corresponds to the fact that solid lines representing the in-phase state of the chrominance subcarrier extend upwardly with the passage of time as shown in FIG. 5A. 
     The conventional motion adaptive YC separating filters performed YC separation by the use of infield correlation when a motion picture was detected. Therefore, although the conventional filters could carry out the band limitations in the directions of μ-axis and ν-axis, they could not take the band limitation in the direction of f-axis. This will cause a frequency space originally including Y signal to be separated as C signal, so that the band of Y signal in the motion picture will be decreased. 
     If the YC separation is made according to the aforementioned interfield processing operation, the band of Y signal in the motion picture can be increased. 
     Referring again to FIG. 5B, the (n-1) field includes three sample points &#34;&#34; e, f and g which are near the objective sample point &#34;⊚&#34;  and have chrominance subcarriers angularly spaced away from one another by 180°. Calculation for any one of the three sample points and the objective sample point permits the interfield YC separation. 
     First of all, high-frequency components including C signals in the three-dimensional frequency space can be taken out from a difference between the objective sample point &#34;⊚&#34; and the sample point &#34;&#34; e in FIG. 5B. When the resulting difference signal is passed through the two-dimensional BPF defined by the 1H delay circuit 34, subtracter 35, one-half multiplier 1004 and BPF 36 as shown in FIG. 2, C signal 113 is obtained. When the C signal is subtracted from the V signal at the subtracter 37, Y signal 112 is obtained. This is referred to as &#34;the first interfield YC separation&#34;. 
     FIGS. 7A, 7B and 7C are respectively similar to FIGS. 6A, 6B and 6C and illustrate a three-dimensional frequency space including the Y and C signals which have been obtained from the first interfield YC separation. 
     Secondly, high-frequency components including C signals in the three-dimensional frequency space can be taken out from a difference between the objective sample point &#34;⊚&#34;  and the sample point &#34;&#34; f in FIG. 5B. When the resulting difference signal is passed through the aforementioned two-dimensional BPF, C signal 113 is obtained. When the C signal 113 is subtracted from the V signal at the subtracter 37, Y signal 112 is obtained. This is referred to as &#34;the second interfield YC separation&#34;. 
     FIGS. 8A, 8B and 8C similarly illustrate a three-dimensional frequency space including Y and C signals which have been obtained from the second interfield YC separation. From these figures, it appears that the C signals are partially included within the separated Y signal. However, there is an extremely small possibility that the C signals are contained in the Y signal, since great correlation exists between the Y and C signals. 
     Thirdly, high-frequency components including C signals in the three-dimensional frequency space can be taken out from a difference between the objective sample point &#34;⊚&#34;  and the sample point &#34;&#34; g in FIG. 5B. When the resulting difference signal is passed through the aforementioned two-dimensional BPF, C signal is obtained. When the C signal is subtracted from the V signal, Y signal is obtained. This is referred to as &#34;the third interfield YC separation&#34;. 
     FIGS. 9A, 9B and 9C similarly illustrate a three-dimensional frequency space including Y and C signals which have been obtained from the third interfield YC separation. From these figures, it appears that the C signals are partially included within the separated Y signal. However, there is an extremely little possibility that the C signals are contained in the Y signal, for the same reason as in FIG. 8. 
     In order to adaptively select one of the three, first, second and third interfield YC separations, it is required that correlations in the picture is detected in the directions of connection between the objective sample point &#34;⊚&#34;  and the respective one of the sample point e, f, and g. The correlations of the picture in the respective directions may be detected by calculating the sample points &#34;&#34; e, f and g in the (n-1) field and the sample points &#34;&#34; h, i and j in the (n+1) field, the objective sample point &#34;⊚&#34;  being located between the (n-1) and (n+1) fields. In such a manner, control signals can be obtained. 
     The inframe YC separation circuit shown in FIG. 2 will be described in operation below: 
     The present invention is characterized by, when a motion picture is detected by the motion detecting circuit 80, the motion picture is processed by the optimum selected one of the inframe YC separations including the aforementioned first, second and third interfield calculations, in place of the infield YC separation. 
     Referring again to FIG. 2, a V signal 101 inputted through the input 11 is delayed by 263 lines at the 263H delay circuit 14 and further delayed by two pixels at the 2D delay circuit 15. The V signal is further delayed by 262 lines at the 262H delay circuit 16. 
     The V signal delayed by two pixels at the 2D delay circuit 15 is subtracted from the output of the 262H delay circuit 16 at the subtracter 20 to provide an interfield difference for the third interfield YC separation which corresponds to the difference between the objective sample point and the (n-1) field sample point g. 
     The V signal delayed by two pixels at the 2D delay circuit 15 is subtracted from the output of the 4D delay circuit 17 at the subtracter 21 to provide an interfield difference for the second interfield YC separation which corresponds to the difference between the objective sample point  and the (n-1) field sample point f. 
     The V signal delayed by two pixels at the 2D delay circuit 15 is subtracted from the output of the 2D delay circuit 19 at the subtracter 22 to provide an interfield difference for the first interfield YC separation which corresponds to the difference between the objective sample point  and the (n-1) field sample point e. 
     The three interfield differences thus obtained are then applied to the signal selection circuit 33 via one-half multipliers 1001-1003 and selected depending on the output of the minimum value selection circuit 32. 
     The outputs of the 262H and 4D delay circuits 16 and 24 are subjected to subtraction from each other at the subtracter 26, the resulting value being converted into an absolute value by the ABS circuit 29. Thus, the correlation between the sample points &#34;&#34; g and j in FIGS. 5B and 5C can be detected. The outputs of the 4D and 1H delay circuits 17 and 23 are subjected to subtraction from each other at the subtracter 27, the resulting value being converted into an absolute value by the ABS circuit 30. Thus, the correlation between the sample points &#34;&#34; f and i in FIGS. 5B and 5C can be detected. The outputs of the 2D delay circuits 19 and 25 are subjected to subtraction from each other at the subtracter 28, the resulting value being converted into an absolute value by the ABS circuit 31. Thus, the correlation between the sample points &#34;&#34; e and h in FIGS. 5B and 5C can be detected. 
     The minimum value selection circuit 32 selects the minimum one of the three absolute values to control the signal selection circuit 33. The minimum absolute value is one which is minimum in differential absolute value but maximum in detection of correlation. 
     More particularly, the signal selection circuit 33 is adapted to select the output of the subtracter 20 via one-half multiplier 1001 if the output of the ABS circuit 29 is minimum; the output of the subtracter 21 via one-half multiplier 1002 if the output of the ABS 30 is minimum; and the output of the subtracter 22 via one-half multiplier 1003 if the output of the ABS circuit 31 is minimum. 
     The output of the signal selection circuit 33 is passed through the 1H delay circuit 34 and subtracter 35 to separate only the vertical high-frequency component therefrom. Further, the output of the subtracter 35 is passed via one-half multiplier 1004 through the BPF 36 to separate only the horizontal high-frequency component therefrom. Namely, the output of the signal selection circuit 33 is subjected to the two-dimensional band limitation by the two-dimensional BPF to provide C signals 113 from the inframe YC separation. 
     The subtracter 37 can subtract the C signals 113 of the inframe YC separation from the V signal which is the output of the 2D delay circuit 15 to provide a Y signal 112 of the inframe YC separation. 
     Although the arrangement of FIG. 2 has been described as to the use of the 1H delay circuit 34 and subtracter 35 for permitting only the vertical high-frequency component to pass therethrough, similar advantages may be attained by utilizing a plurality of 1H delay circuits in place of the 1H delay circuit 34 and subtracter 35. 
     FIG. 3 is a block diagram of the second embodiment of the inframe YC separation filter 50 constructed in accordance with the present invention and shown in FIG. 1. 
     The second embodiment of FIG. 3 is distinguished from the arrangement of FIG. 2 only in the manner of infield band limitation. Therefore, the following description will be made only in connection with an infield band limitation in the inframe YC separation circuits of FIG. 3, which is different from that of FIG. 2. It is to be noted that parts of FIG. 3 similar to those of FIG. 2 are designated by similar reference numerals. 
     The output of the signal selection circuit 33 is a high-frequency component in the three-dimensional frequency space which is obtained from any one of the three interfield calculations. Thus, the output of the signal selection circuit 33 is subtracted, at the subtracter 38, from the V signal which is the output of the 2D delay circuit 15, so as to provide a low-frequency component in the three-dimensional frequency space in the direction wherein the correlation is detected. The low-frequency component thus obtained is applied to the first input of the adder 42. The output of the signal selection circuit 33 is passed through the 1H delay circuit 34 and adder 39 to separate only its vertical low-frequency component and also passed through the 1H delay circuit 34 and subtracter 35 to separate only its vertical high-frequency component. The output of the subtracter 35 is applied to the LPF 40 via multiplier 1004 whereat only the horizontal low-frequency component thereof is separated, and then provided to the first input of the adder 41. On the other hand, the output of the adder 39 is applied to the second input of the adder 41, the output of the adder 41 providing a signal in which C signals are removed from the high-frequency component in the three-dimensional frequency space. At the adder 42, this signal is added to the low-frequency component in the three-dimensional frequency space to provide a Y signal 112 from the inframe YC separation. 
     The subtracter 43 subtracts the Y signal 112 from the output Y signal of the 2D delay circuit 15 to provide C signals 113 from the inframe YC separation. 
     FIG. 4 is a block diagram of the third embodiment of the inframe YC separation circuit 50 shown in FIG. 1. 
     The arrangement of FIG. 4 is distinguished from that of FIG. 2 only in that in addition to the inframe YC separation circuits including three different interfield calculations and infield color signal band limitations there is a inframe YC separation circuit using only infield color signal band limitation. The optimum one of the four inframe YC separation circuits is selected and utilized. There will be described only an interframe correlation detecting circuit in the inframe YC separating circuits of FIG. 4, which is different from those of FIG. 2. Parts similar to those of FIG. 2 are designated by similar reference numerals. 
     The output of the 2D delay circuit 15 is applied to the first inputs of the subtracters 20, 21, 22, 37 and also to the first input of a signal selection circuit 45. The output of the subtracters 20, 21 and 22 are respectively provided to the second, third and fourth inputs of the signal selection circuit 45 via one-half multipliers 1001-1003, respectively. The output of the ABS circuit 29 is respectively applied to the first inputs of maximum and minimum value selection circuits 43 and 32. The output of the ABS circuit 30 is applied to the second inputs of the maximum and minimum value selection circuits 43 and 32, respectively. The output of the ABS circuit 31 is applied to the third inputs of the maximum and minimum value selection circuits 43 and 32, respectively. The output of the maximum value selection circuit 43 is applied to the first input of a threshold discriminating circuit 44. The output of the minimum value selection circuit 32 is provided to the second input of the threshold discriminating circuit 44 and also to the fifth input of the signal selection circuit 45. The output of the threshold discriminating circuit 44 is applied to the sixth input of the signal selection circuit 45. The threshold discriminating circuit 44 is adapted to control the signal selection circuit 45 such that it selects the output of the 2D delay circuit 15 if the maximum one of the three interframe correlations is smaller than a first threshold a or if the minimum interframe correlation is larger than a second threshold β. Components following the signal selection circuit 45 are the same as those of FIG. 2. In this case, the YC separation is made only from the infield band limitations. On the other hand, the threshold discriminating circuit 44 is adapted to control the signal selection circuit 45 such that if the maximum of the three interframe correlations is larger than the first threshold α or if the minimum is smaller than the second threshold β, the signal selection circuit 45 selects the output of the subtracter 20 when the output of the ABS circuit 29 is minimum; the output of the subtracter 21 when the output of the ABS circuit 30 is minimum; and the output of the subtracter 21 when the output of the ABS circuit 30 is minimum, in response to the output of the minimum value selecting circuit 32. As in the embodiment of FIG. 2, this arrangement also adaptively performs the inframe YC separations including the interfield calculations and infield color signal band limitations. It is however required to be a relationship, α&lt;β. 
     The embodiment of FIG. 3 can adaptively control the YC separation only due to the infield band limitations and the three inframe YC separations, by using the maximum value selection circuit 43, threshold discriminating circuit 44 and signal selection circuit 45 as shown in FIG. 4. 
     Although all the embodiments of FIGS. 2 to 4 have been described as to the YC separating filter utilizing the interfield calculations between the n field and the (n-1) field, this may be replaced by interfield calculations between the (n+1) and n fields. More particularly, the same inframe YC separating circuits may be provided by calculations between the objective sample point &#34;⊚&#34; and the respective sample points &#34;&#34; h and i in the (n+1) field, depending on the results of three detections of interframe correlation. 
     From the above-described embodiments of the present invention, it is apparent that the present invention may be modified as would occur to one of ordinary skill in the art without departing from the spirit and scope of the present invention, which should be defined solely by the appended claims. Changes and modifications of the system, method, and apparatus contemplated by the present preferred embodiments will be apparent to those of ordinary skill in the art.