JP4226939B2 - Progressive scan conversion apparatus and progressive scan conversion method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a progressive scan conversion apparatus and a progressive scan conversion method for converting, for example, a 2: 1 interlace video signal into a progressive scan video signal.
[0002]
[Prior art]
When converting an interlaced video signal to a progressive scan video signal, a progressive scan conversion technique that detects the motion of the video signal and generates an interpolated signal based on it is common to prevent image quality degradation in the moving image part. Has been implemented.
One of the progressive scan conversion techniques is a motion adaptive progressive scan conversion technique. In this technique, when a video is a still image, so-called inter-field interpolation is used to add the preceding and succeeding fields as they are, and the video moves. If so, so-called intra-field interpolation is used in which interpolation is performed by specifying an interpolated pixel based on upper and lower pixels in the field.
[0003]
For this reason, a high-resolution video with little aliasing distortion can be obtained for a still image, but only a picture with much aliasing distortion and degraded resolution can be obtained in a moving image portion.
As described above, in the progressive scan conversion technique, the resolution of the moving image part is inevitably deteriorated, but the video signal frame or field is a special video signal composed of a certain pattern. It is known that progressive scan conversion is possible without degrading resolution.
[0004]
That is, there is a technique for generating a 2: 1 interlace signal by distributing each frame of a video signal of 30 frames / second into two fields, which is called a so-called 2-2 pull-down method. The interlaced video signal generated by the 2-2 pull-down method has a pattern in which two fields generated from the same frame are continuous and two fields generated from the next frame are continuous.
[0005]
Furthermore, a conversion method called a 3-2 pull-down method is also known, and is used when converting a movie image into a television signal. In the 3-2 pull-down method, a continuous field of 3 fields is generated from one frame, a continuous field of 2 fields is generated from the next frame, and then 3 fields and 2 fields are alternately generated from each frame. A signal is generated.
[0006]
Therefore, if the pattern is understood, it can be converted into sequential scanning by field interpolation regardless of still images and moving images using continuous fields generated from the same frame. High progressive scanning image can be obtained.
[0007]
FIG. 8 is a timing chart for explaining the processing of the 2-2 pull-down method. A continuous field a, a ′ is generated from the frame A, a continuous field b, b ′ is generated from the next frame B, and thereafter, similarly, two fields of video c, c ′ are generated from each frame C, D. And d, d ′...
[0008]
FIG. 9 is a timing chart for explaining the 3-2 pull-down process. In the 3-2 pull-down method, three continuous fields a, a ′, a are generated from the frame A, two continuous fields b ′, b are generated from the next frame B, and the next frame C is generated. Three consecutive fields c ′, c, and c ′ are generated, and thereafter, similarly, three fields and two fields are alternately generated from each frame.
[0009]
For example, Patent Document 1 discloses a technique for converting a video signal converted into an interlace signal by a 3-2 pull-down method into a sequentially scanned video signal.
The sequential scanning conversion device disclosed in this patent document generates an intra-field interpolation signal from a scanning line that is spatially positioned above and below the interpolated scanning line in the current field, and generates the intra-field interpolation signal and the current field. The difference between the current field and the subsequent field is generated by generating a difference of the low frequency component in the vertical direction between the subsequent field signal which is located behind the time line and is the same scanning line as the interpolated scanning line. A first matching signal representing the matching is generated.
[0010]
Furthermore, a difference of a low frequency component in the vertical direction is generated between the intra-field interpolation signal and the previous field signal which is located temporally before the current field and is the same position as the interpolated scanning line. As a result, a second matching signal representing the matching between the current field and the previous field is generated.
[0011]
Then, by generating a difference between the first matching signal and the second matching signal, a first mixing coefficient of the rear field signal and the previous field signal is generated, and according to the first mixing coefficient, The field interpolation signal is generated by mixing the rear field signal and the previous field signal.
[0012]
As a result, the video signal converted into the interlace by the 3-2 pull-down or the 2-2 pull-down can be converted into the sequential scanning without causing the image quality deterioration without performing the field interpolation in the wrong field.
Certainly, if the input signal is limited to those interlaced by 3-2 pull-down or 2-2 pull-down, the targeted effect can be exhibited as it is, but 3-2 pull-down or 2-2 pull-down. If a signal that is not an interlace-converted video signal is input, it may be possible that a malfunction occurs.
[0013]
That is, when the vertical motion of the video is ± 2n (intra-frame scanning line / field, hereinafter abbreviated as line / field), the inter-field difference is the same as the 2-2 pull-down signal. That is, in the NTSC (National Television System Committee) signal, the inter-field difference has a pattern that repeats the magnitude in a 1/60 second cycle. There is a problem that it is impossible to distinguish whether there is an image having a motion of ± 2n (line / field) in the vertical direction, leading to a malfunction.
[0014]
This will be described in detail based on a specific example. FIG. 10 shows an example in which the vertical movement is 2 (line / field). FIG. 10 schematically shows the relationship between a field and a scanning line (pixel), where time t is taken on the horizontal axis and position y in the screen vertical direction is taken on the vertical axis. The circles arranged in three columns in the y-axis direction schematically indicate the scanning lines of the respective fields with pixels representing them, the middle column indicates the current field (n), and the right column indicates the current column. The subsequent field (n + 1) following the field is shown, and the left column shows the previous field (n-1) of the current field. The pixels e and f in the previous field (n−1) correspond to the pixels v and w in the subsequent field (m + 1), and indicate that the scanning line has moved by two scanning lines between frames.
[0015]
FIG. 11 shows a situation where the video shown in FIG. 10 is inter-field interpolated and intra-field interpolated. 11 indicates that the current field (n) is inter-field interpolated, and the previous field (n−1) and the subsequent field (n + 1) are inter-field interpolated in the current field. In the current field (n), pixels M to T indicated by triangles are pixels subjected to intra-field interpolation, and pixels a to z are transmitted pixels. Of the interpolated pixels in the field, a pixel with a dotted line in the triangle represents a gray pixel formed from a white pixel and a black pixel.
[0016]
In FIG. 11, the difference between (c−P), (d−Q), and (e−R) occurs in the subtraction between the intra-field interpolation signals of the previous field (n−1) and the current field (n). To do. Further, in the subtraction between the intrafield interpolation of the subsequent field (n + 1) and the current field (n), a difference is generated between (Pv) and (Rx).
[0017]
Since the difference of (P−v) is equal to the difference of (e−R) and the difference of (R−x) is equal to (c−P), the difference between the previous field (n−1) and the interpolation signal in the current field The subtraction signal becomes larger by the difference signal (d−Q).
In the technique disclosed in Patent Document 1, first and second matching signals are generated from the difference between the current field signal and the previous field signal and the difference between the current field signal and the subsequent field signal, respectively. The matching signal is obtained by subtracting the second matching signal from the matching signal. However, as described above, the first matching signal and the second matching signal are equal in an image having a movement of 2 lines / field as described above. Since a difference is generated instead of a value, if a mixing coefficient is generated from a matching signal obtained by subtraction, interpolation by field interpolation is performed, resulting in a double image and deterioration in image quality.
[0018]
[Patent Document 1]
JP 2000-78535 A (Pages 7 to 8 [0045] to [0052], FIGS. 1, 2, 6, and 7)
[0019]
  As described above, in the conventional progressive scan converter,For example a rectangular areaWhen the vertical motion of the video is ± 2n (line / field), the difference signal between fields is a 2-2 pull-down signal.The same pattern as the detection signalAs a 2-2 pull-down signal even though it is not a 2-2 pull-down signalJudgment by mistakeAs a result, there is a problem that the image quality deteriorates.
[0020]
The present invention has been made in response to the above points. When a motion vector in the vertical direction of an image is detected and this is an even line / field, a 2-2 pull-down signal is sequentially scanned. By configuring so as to perform progressive scan conversion by motion compensation or motion adaptive progressive scan conversion without following the conversion sequence, an even line / field video can be converted into a video signal generated by the 2-2 pull-down method. It is intended to prevent image quality deterioration due to erroneous determination of being present.
[0021]
[Means for Solving the Problems]
In the progressive scan converter of the present invention, the input interlaced video signal is2-2 Telecine converted by pull-down methodFirst determination means for determining whether or not an image signal;
  Second determination means for determining whether or not the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields. When,
  In the first determination means, the input video signal is2-2 Telecine converted by pull-down methodWhen it is determined that the signal is an image signal, an interpolated signal of the input interlace video signal is generated in accordance with a telecine conversion sequence, and ± 2n (intraframe scanning line in the vertical direction) is generated by the second determining means. / Field) Interpolation signal generation for generating an interpolation signal by motion adaptive interpolation or motion compensation interpolation regardless of the determination result of the first determination means when it is determined that the motion vector has (n is an integer). Means,
  Interpolating means for interpolating the interlaced video signal with the interpolation signal generated by the interpolation signal generating means.
[0022]
  According to the present invention, when motion of even lines / fields in the vertical direction is detected, interpolation is performed using an interpolation signal generated by motion adaptive interpolation or motion compensation interpolation. A video2-2 Pull-down methodAppropriate sequential scanning conversion can be performed without erroneously distinguishing the telecine-converted video signal.
[0023]
  In the progressive scan converter of the present invention, the input interlace video signal is2-2 Telecine converted by pull-down methodFirst determination means for determining whether or not an image signal;
  Second determination means for determining whether or not the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields. When,
  First interpolation signal generating means for generating an interpolated video signal of the input interlace video signal according to a telecine conversion sequence;
  Second interpolation signal generating means for generating a motion adaptive interpolation signal or a motion compensated interpolation signal according to at least the motion between fields of the video related to the input interlace video signal;
  When the second determination means determines that the motion vector has a vertical motion vector of ± 2n (intra-frame scanning line / field) (n is an integer), the determination result of the first determination means Regardless, the input interlaced video signal is interpolated with the interpolation signal generated by the second interpolation signal generation means, and the vertical determination ± 2n (intraframe scanning line / field) by the second determination means. (N is an integer) motion vector is not determined, and the interlaced video signal input by the first determination means is2-2 Telecine converted by pull-down methodAnd interpolating means for interpolating the input interlaced video signal with the interpolation signal generated by the first interpolation signal generating means when it is determined to be an image signal.
[0024]
According to the present invention, when motion of even lines / fields in the vertical direction is detected, interpolation is performed using an interpolation signal generated by motion adaptive interpolation or motion compensation interpolation. Appropriate sequential scanning conversion can be performed without erroneously discriminating a certain video from a telecine conversion video signal.
[0025]
  In the progressive scan converter of the present invention, the input interlaced video signal is2-2 Pull-down methodA telecine detection circuit for detecting a video signal generated by telecine conversion;
  A motion vector detecting means for detecting a motion between at least fields of the video related to the input interlaced video signal;
  Telecine interpolation signal generating means for generating an interpolation signal according to a telecine conversion sequence;
  Motion compensated interpolation signal generating means for generating an interpolation signal according to the motion vector detected by the motion vector detecting means;
  When the motion vector detection means detects a motion vector of ± 2n in the vertical direction (intra-frame scanning line / field) (n is an integer), the telecine is detected.circuitRegardless of the detection result, the interpolation signal generated by the motion compensation interpolation signal generation means is used, and the motion vector detection means uses ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction. Is detected, and the input interlace signal is detected by the telecine detection circuit.2-2 Pull-down methodWhen it is determined that the video signal is generated by telecine conversion, the interlace signal is converted using the interpolation signal generated by the telecine interpolation signal generation means.interpolationInterpolation means to perform,
It is characterized by comprising.
[0026]
According to the present invention, when motion of even lines / fields in the vertical direction is detected, interpolation is performed using an interpolation signal generated by motion adaptive interpolation or motion compensation interpolation. Appropriate sequential scanning conversion can be performed without erroneously discriminating a certain video from a telecine conversion video signal.
[0027]
  In the progressive scan converter of the present invention, the input interlaced video signal is2-2 Pull-down methodA telecine detection circuit for detecting a video signal generated by telecine conversion;
  First motion vector detection for detecting a motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction for every predetermined block or every predetermined pixel between video fields related to the input interlaced video signal Means,
  Second motion vector detecting means for detecting a motion vector between fields or frames of a video related to the interlaced video signal;
  Telecine interpolation signal generating means for generating an interpolation signal according to a telecine conversion sequence;
  Motion compensated interpolation signal generating means for generating an interpolation signal according to the motion vector detected by the second motion vector detecting means;
  Whether the field in which the first motion vector detection means detects a motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction equal to or more than a predetermined number of blocks or more than a predetermined number of pixels is continuous. Determining means for determining
  A field in which ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction is detected by the motion vector detection unit by the motion vector detection unit more than a predetermined number of blocks or more than a predetermined pixel is continuous for 2 fields or more. When it is determined that the telecine is detectedcircuitAnd interpolating means for interpolating the input interlaced video signal using the interpolation signal generated by the motion compensated interpolation signal generating means.
[0028]
According to the present invention, when motion of even lines / fields in the vertical direction is detected, interpolation is performed using an interpolation signal generated by motion adaptive interpolation or motion compensation interpolation. Appropriate sequential scanning conversion can be performed without erroneously discriminating a certain video from a telecine conversion video signal.
[0029]
  In the progressive scan conversion method of the present invention, an input interlaced video signal is2-2 Telecine converted by pull-down methodDetermining whether it is an image signal;
  Determining whether the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields;
  The input video signal is2-2 Telecine converted by pull-down methodWhen it is determined that the signal is an image signal, an interpolation signal of the input interlaced video signal is generated according to a telecine conversion sequence, and ± 2n (intraframe scanning line / field) in the vertical direction (n is an integer) ) Is input, the input interlaced video signal is2-2 Telecine converted by pull-down methodRegardless of the determination result of the step of determining whether or not it is an image signal, generating an interpolation signal by motion adaptive interpolation or motion compensation interpolation;
  Interpolating the interlaced video signal with the generated interpolation signal.
[0030]
Interpolating the interlaced video signal with the generated interpolation signal.
According to the present invention, when motion of even lines / fields in the vertical direction is detected, interpolation is performed using an interpolation signal generated by motion adaptive interpolation or motion compensation interpolation. Appropriate sequential scanning conversion can be performed without erroneously discriminating a certain video from a telecine conversion video signal.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a circuit block diagram of a progressive scan converter 10 of the present invention. In FIG. 1, an input terminal 11 is supplied with a 2: 1 interlace video signal. The input terminal 11 is connected to the first field delay circuit 12, and the first field delay circuit 12 is further connected to the second field delay circuit 13.
[0032]
The input terminal and the output terminal of the second field delay circuit 13 are connected to an MV (Moving Vector) detection circuit 14, respectively. The MV detection circuit 14 receives a delay signal (interpolated field) generated by the first field delay circuit 12. The motion vector between fields is detected from the delayed signal by the second field delay circuit 13, and even (field scanning line / field) (hereinafter abbreviated as line / field) motion vectors are detected continuously for two fields. The video signal is determined not to be 2-2 pull-down conversion, and the result is output. The line / field motion vector is a vector in the so-called vertical direction of the screen (Y direction), and may be expressed as Vy hereinafter.
[0033]
The telecine detection circuit 15 is a signal obtained by converting the video signal supplied to the input terminal 11 from the input video signal and the signal delayed by the first field delay circuit 12 by the 2-2 pull-down method by the telecine. If it is a signal converted by the 2-2 pull-down method, the conversion pattern is detected.
[0034]
The telecine interpolation circuit 16 performs a telecine interpolation process on the video signal supplied to the input terminal 11 and the output of the second field delay circuit 13 according to the conversion pattern detected by the telecine detection circuit 15. That is, a signal in the previous field and a signal in the subsequent field with respect to the interpolation field are selected and output according to the conversion pattern. In the example of FIG. 8, when the interpolation field is a ', the previous field a is selected, and when the interpolation field is b, the subsequent field b' is selected and output.
[0035]
The motion adaptive interpolation circuit 17 is controlled by the motion detection circuit 19 and interpolates from the signal delayed by one field by the first field delay circuit 12 and the signal delayed by one field by the second field delay circuit 13. The motion detection circuit 19 subtracts the difference between the signal input to the input terminal 11 and the output of the second field delay circuit 13, which is a signal delayed by two fields, by the subtractor 18. The motion is detected based on the obtained signal, that is, the inter-frame difference signal.
[0036]
The selector control circuit 20 controls the selector 21 based on the motion vector detection result of the MV detection circuit 14 and the detection result of the telecine detection circuit 15, and the telecine detection circuit 15 is a 2-2 pull-down conversion signal. If the MV detection circuit 14 detects an even-numbered (line / field) motion vector in the vertical direction, the selector 21 selects the output of the telecine interpolation circuit 16 and outputs it to the double speed conversion circuit 22. To control.
[0037]
When the MV detection circuit 14 detects even-numbered motion (line / field) in the vertical direction, the selector selects the output of the motion adaptive interpolation circuit 17 regardless of the detection result of the telecine detection circuit 15. 21 is controlled. Further, when the MV detection circuit 14 does not detect even-numbered motion (line / field) in the vertical direction and the telecine detection circuit 15 does not detect the 2-2 pull-down conversion signal, the motion adaptive interpolation circuit The selector 21 is controlled so that 17 outputs are selected.
[0038]
The double speed conversion circuit 22 outputs the output of the first field delay circuit 12 that is an interpolation field signal and the output of the telecine interpolation circuit 16 selected by the selector 21 or the output of the motion adaptive interpolation circuit 17, respectively, in the horizontal scanning period. The time is compressed to ½, and each scanning line is alternately selected and sequentially output to the output terminal 23 as a scanning conversion signal.
[0039]
A specific circuit configuration of the MV detection circuit 14 is shown in FIG. The input terminal 31 is connected to the output terminal of the second field delay circuit 13 in FIG. 1, and the input terminal 32 is connected to the output terminal of the first field delay circuit 12. The two-field delay signal supplied from the input terminal 31 is supplied to the vector detection circuit 34 via a line (horizontal scanning line) delay train 33. The 1-field delay signal supplied from the input terminal 32 is subjected to scanning line interpolation processing by the scanning line interpolation circuit 35 and then supplied to the vector detection circuit 34 via the line delay string 36.
[0040]
The scanning line interpolation circuit 35 performs intra-field interpolation processing, adds a signal obtained by delaying the video signal supplied to the input terminal 32 by one horizontal scanning period and a signal not delayed, and outputs a 1/2 coefficient to the added output. The output is multiplied by.
The line delay trains 33 and 36 are obtained by cascading line delay circuits, and output a delay signal in the line direction corresponding to the vector search range.
The vector detection circuit 34 receives a plurality of pairs of signals having a 2n (even) line difference from the line delay trains 33 and 36, and specifies a block constituted by a predetermined pixel unit in the horizontal direction for each pair of signals. The error value is obtained for each specified block, the smallest error value among all the signal pair blocks is calculated and output, and the vertical vector value corresponding to the minimum error value is obtained. Output.
[0041]
A specific configuration example of the vector detection circuit 34 is shown in FIG. The input terminal 51 is supplied with the output of the line delay string 33 shown in FIG. 2, and the input terminal 52 is supplied with the output of the line delay string 36 shown in FIG. The +8 line block error calculation circuit 53 is supplied with the output of the line delay string 36 and the output of the line delay string 33 in such a relationship that the output of the line delay line 33 is advanced by 8 lines with respect to the output of the line delay string 36. The
[0042]
Similarly, in the +6 line block error calculation circuit 54, the +4 line block error calculation circuit 55, and the +2 line block error calculation circuit 56, the output of the line delay line 33 corresponds to the output of the line delay string 36, respectively. It is supplied in a relationship advanced by 4 lines and 2 lines.
[0043]
The 0-line block error calculation circuit 57 is supplied with the output of the delay line delay string 36 and the output of the line delay string 33 as signals on the same line. In the error calculation circuit 59, the -6 line block error calculation circuit 60, and the -8 line block error calculation circuit 61, the output of the line delay line 33 with respect to the output of the line delay string 36 is 2 lines, 4 lines, 6 Lines are supplied with a delay of 8 lines.
[0044]
Each of the line block error calculation circuits 53 to 61 specifies a block in a predetermined pixel unit in the horizontal direction of each input signal, and further, for each block, generates an error between the signal moved one pixel in the horizontal direction and the signal not moved. The smallest error value and the vertical vector value corresponding to the error value are output to the vertical correlation detection circuit 62.
[0045]
The vertical correlation detection circuit 62 specifies the smallest error value among the error values supplied from the line block error calculation circuits 53 to 61, outputs it to the output terminal 63, and corresponds to the error value. The vertical vector value is output to the output terminal 64.
Returning to FIG. 2, the description will be continued. The line block error calculation output output from the vector detection circuit 34 is supplied to the reliability determination circuit 37 and compared with a predetermined value (ref). If the output is smaller than the predetermined value, the motion vector detected in the block is calculated. It is determined that the reliability is high, and the count circuit 38 counts the number of times the vector value is output each time it is determined. When the block error output output from the vector detection circuit 34 is larger than a predetermined value, the reliability determination circuit 37 determines that the reliability of the motion vector detected in the block is low, and the counting circuit 38 Control is performed so as not to execute the counting process. That is, when there is no correlated image block in the search range, the block calculation error becomes large. In this case, counting by the counting circuit 38 is prevented.
[0046]
The counting circuit 38 outputs a vertical vector (for example, Vy = 2) once when a vertical vector determined to be reliable is output from the vector detection circuit 34 based on the determination result from the reliability determination circuit 37. It counts that it was done. The count is performed for each vertical vector, and the count value of the vertical vector having the largest count value is output to the comparison circuit 39.
[0047]
In the comparison circuit 39, the output of the counting circuit 38 is compared with the block number comparison value, and when the output of the counting circuit 38 is large, a signal having a logical value “H” is output to the field continuity determination circuit 40. That is, in the comparison circuit 39, when a predetermined number or more of the same vertical vectors are detected with respect to the number of blocks specified by the vector detection circuit 34, it is determined that there is motion between fields, and a logical value “H” is set. Output.
[0048]
The field continuity determination circuit 40 includes a latch circuit 41 that latches the output of the comparison circuit 39 with a field pulse, and a logical product circuit 42 that takes the logical product of the output of the comparison circuit 39 and the output of the latch circuit 41. When the output of the circuit 39 is the logical value “H” for two consecutive fields, the signal of the logical value “H” is output from the output terminal 43. In other words, when there is motion in the image for two consecutive fields, a signal of logical value “H” is output from the output terminal 43.
[0049]
The operation of the vector detection circuit 34 will be further described with reference to FIG.
In each field (n−1) (n) (n + 1), a to g, m, n, and p to z indicated by circles are transmitted scanning lines, and pixels represented by the images of the respective scanning lines are as follows: It is represented by white circles and black circles. Further, in the (n) field that is an interpolation field, scanning lines M, N, and P to T indicated by triangles are scanning lines interpolated in the field, and are output from the scanning line interpolation circuit 35 illustrated in FIG. Is. Of the scanning lines indicated by triangles, hatched scanning lines P and R are scanning lines generated from a white circle scanning line and a black circle scanning line, and have a gray concept.
[0050]
In FIG. 11, a case where a motion vector is detected in a block of 4 lines will be described as an example. Since motion vectors between fields are limited to even lines / fields, Vy = 0 (0 line block error calculation circuit 57 In the calculation, the accumulation of the inter-field difference signal is (b−N), (c−P), (d−Q), and (e−R).
[0051]
Further, when the vertical vector is Vy = 2 lines / field (calculation of the two-line block error calculation circuit 56), the accumulation of inter-field differences is (c−N), (d−P), (e−Q), (f −R), and when Vy = 4 lines / field (operation of the 4-line block error calculation circuit 55), the accumulation of inter-field differences is (d−N), (e−P), (f−Q), (g -R).
[0052]
The difference signal (e−R) at Vy = 0 is equal to the difference signal (f−R) of motion at Vy = 2 and the difference signal (e−P) of motion at Vy = 4, and the difference signal (e−P) of Vy = 0 b−N) is equal to the motion differential signal (c−N) of Vy = 2 and the motion differential signal (d−N) of Vy = 4. Further, the difference signal (c−P) at Vy = 0 is equal to the difference signal (d−P) of motion at Vy = 2 and the difference signal (g−R) of motion at Vy = 4.
[0053]
Therefore, the differential signal (d−Q) at Vy = 0 is larger than the differential signal (e−Q) of motion at Vy = 2 and the differential signal (f−Q) of motion at Vy = 4.
Thus, in the example shown in FIG. 11, the vector detection circuit 34 outputs Vy = 2 lines / field or Vy = 4 lines / field as a vertical vector having the smallest error value. The counting circuit 38 adds 1 to the count of Vy = 2 or Vy = 4 based on the output of the vector detection circuit 34.
[0054]
When the number of the same motion vectors detected in one field is equal to or greater than a predetermined number in the comparison circuit 39, it is determined that there is motion between the fields, and further, the field continuity determination circuit 40 further determines between the fields. It is determined whether or not the motion is continuous for two fields and output.
[0055]
In the example of FIG. 11, since the motion is continuous for two fields, the MV detection circuit 14 drives the selector control circuit 20 and outputs a control signal for selecting the output of the motion adaptive interpolation circuit 17 to the selector 21. Let
Returning to FIG. 1, the telecine detection circuit 15 identifies whether the state in which there is no motion between fields as described above occurs in units of one frame, and identifies the video signal converted by 2-2 pull-down. A specific example is shown in FIG. In FIG. 4, a signal supplied to the input terminal 11 of FIG. 1 is added to the input terminal 71, and the output of the first field delay circuit 12 is supplied to the input terminal 72.
[0056]
The signal supplied to the input terminal 71 is supplied to a subtracter 74 after a horizontal high-frequency component is removed as noise by a horizontal LPF (Low Pass Filter) 73. The signal supplied to the input terminal 72 is subjected to scanning line interpolation processing by the scanning line interpolation circuit 75 and is supplied to the subtracter 74 via the horizontal LPF 76. Similarly to the scanning line interpolation circuit 35 shown in FIG. 2, the scanning line interpolation circuit 75 adds a signal delayed by one horizontal scanning period and a signal not delayed, and outputs the result by multiplying by a ½ coefficient. The output signal is the same as the signal supplied to the input terminal 71 at the position of the scanning line on the screen. Similarly to the horizontal LPF 72, the horizontal LPF 76 removes a high-frequency component in the horizontal direction as noise.
[0057]
The subtracter 74 takes the difference between the signal supplied to the input terminal 11 and the signal delayed by the first one-field delay circuit 12 and outputs the difference to the absolute value circuit 77. The absolute value circuit 77 calculates the absolute value of the output of the subtracter 74 and outputs it to the non-linear processing circuit 78.
The non-linear processing circuit 78 performs rounding processing on the output of the absolute value circuit 77 to limit the amount of information, and outputs it to the cumulative addition circuit 79. The cumulative addition circuit 79 cumulatively adds the output of the non-linear processing circuit 78 in one field period and outputs the result to the comparison circuit 80.
[0058]
In the comparison circuit 80, when the output of the cumulative addition circuit 79 is smaller than a predetermined value (ref), it is determined that the video does not move between fields, and a signal having a logical value “L” is output via the output terminal 81. This is supplied to the telecine interpolation circuit 16 and also supplied to the period detection circuit 82. If the output of the cumulative addition circuit 79 is larger than a predetermined value (ref), it is determined that there is movement between fields, and a signal of logical value “H” is supplied to the telecine interpolation circuit 16 via the output terminal 81. At the same time, it is supplied to the cycle detection circuit 82.
[0059]
When the signal supplied to the input terminal 11 is a 2-2 pull-down conversion signal, if there is movement between frames, the comparison circuit 80 alternately outputs logical values “L” and “H”. The period detection circuit 82 is such that the state in which the comparison circuit 80 alternately outputs logical values “L” and “H” continues for a predetermined period, so that the signal supplied to the input terminal 11 is a 2-2 pull-down conversion signal. It is determined that there is, and the detection result is output to the selector control circuit 20 via the output terminal 83.
[0060]
As described above, according to the progressive scan conversion apparatus of the present invention, when the motion vector in the vertical direction of the video is detected and this is an even line / field, the sequential scan conversion of the signal of 2-2 pull-down method is performed. This is a video signal generated by 2-2 pull-down method for even line / field video by performing sequential scan conversion by motion compensation or motion adaptive progressive scan conversion without following the sequence for Image quality deterioration due to erroneous determination.
[0061]
FIG. 5 shows another embodiment of the progressive scan converter 90 of the present invention. In FIG. 5, the same circuit blocks as those in FIG. The embodiment of FIG. 5 differs from the circuit of FIG. 1 in that an interpolation signal is generated by the motion compensation circuit 92 according to the motion vector detected by the MV detection circuit 91.
[0062]
The MV detection circuit 91 detects a motion vector between the previous field signal that is the output of the second field delay circuit 13 and the interpolated field that is the output of the first field delay circuit 12. And a horizontal motion vector is detected. (The MV detection circuit 14 in FIG. 1 outputs only a vertical motion vector)
[0063]
The motion vector detected by the MV detection circuit 91 is supplied to the motion compensation interpolation circuit 92. The motion compensation interpolation circuit 92 moves the position of the image in the previous field in accordance with the motion vector supplied from the MV detection circuit 91. Thus, an interpolation signal is generated. Further, the MV detection circuit 91 has a function of detecting the motion of even lines / fields in the vertical direction and supplying the detected motion to the selector control circuit 20, and the function is the same as that of the MV detection circuit 14 of FIG.
[0064]
When the motion of even lines / fields in the vertical direction is detected by the MV detection circuit 91, the interpolation signal generated by the motion compensation interpolation circuit 92 is selected by the selector 21 regardless of the detection result by the telecine detection circuit 15. And supplied to the double speed conversion circuit 22.
If the MV detection circuit 91 does not detect even line / field motion and the telecine detection circuit 15 determines that the signal is a 2-2 pull-down conversion signal, the output of the telecine interpolation circuit 16 is used as an interpolation signal. If the even line / field motion is not detected by the MV detection circuit 91 and the telecine detection circuit 15 does not determine that it is a 2-2 pull-down conversion signal, the output of the motion compensation interpolation circuit 92 is used as the interpolation signal. It is what.
[0065]
In this embodiment, the motion compensation interpolation circuit 92 is controlled by the motion vector detected by the MV detection circuit 91, and the circuit can be shared and the configuration is simplified.
Further, FIG. 6 shows another embodiment of the progressive scan conversion apparatus of the present invention. In the progressive scan conversion apparatus 100 shown in FIG. 6, a second MV circuit 101 that detects a motion vector between fields or frames from the interpolated field signal and the signals of fields before and after the circuit shown in FIG. 1. A motion compensation interpolation circuit 102 that moves the position of the image of the previous field signal according to the motion vector detected by the second MV circuit 101, a field interpolation circuit 103 that generates an intra-field interpolation signal, The difference is that a mixer 104 that mixes the outputs of the compensation interpolation circuit 102 and the field interpolation circuit 103 and outputs the mixture to the selector 21 is provided.
[0066]
In the mixer 104, the mixing ratio of the motion compensation interpolation circuit 102 and the field interpolation circuit 103 is controlled according to the motion coefficient output from the motion detection circuit 19.
The MV detection circuit 14 can be limited to a circuit that detects even lines / fields, similarly to the progressive scan converter 10 shown in FIG. When even line / field motion is detected by the MV detection circuit 14, the selector control circuit 20 selects the output of the mixer 104 as an interpolation signal regardless of the detection result of the telecine detection circuit 15. 21 is controlled. When the even line / field motion is not detected by the MV detection circuit 14 and the input signal is detected as the telecine conversion signal by the telecine detection circuit 15, the telecine interpolation signal is selected as the interpolation signal. When it is determined that the signal is not a telecine conversion signal, the output of the mixer 104 is selected as an interpolation signal.
[0067]
According to this embodiment, when it is not a telecine conversion video, the image quality of the moving image can be improved by performing motion compensation interpolation.
FIG. 7 shows a flowchart for explaining the operation of the progressive scan converter of FIG. In FIG. 7, the process starts in step 7a, and in step 7b, the input interlace signal is delayed by one field to obtain an interpolated field signal. In step 7c, the interpolated field signal is delayed by one field to obtain the previous field signal.
[0068]
Next, in step 7d, a motion vector between fields is detected from the interpolated field signal and the previous field signal. Next, in step 7e, it is determined whether or not an even line / field vector is present in the motion vectors detected in step 7d, and if it is determined that an even line / field motion vector is detected. In step 7f, the motion adaptive interpolation signal generated from the interpolation field signal and the previous field signal is selected as the interpolation signal.
[0069]
Next, the interpolation signal selected in step 7f is interpolated with respect to the interpolation field signal in step 7g, and the processing is ended in step 7h.
If it is determined in step 7e that an even line / field motion vector has not been detected, it is determined in step 7i whether or not the input signal is a telecine conversion signal from the input interlace signal and the interpolation field signal. In step 7j, the determination in step 7i is made. If the signal is a telecine conversion signal, the signal generated by selecting the input signal and the previous field signal in accordance with the telecine conversion pattern in step 7k is used as an interpolation signal. select. Next, the process proceeds to step 7g, where the selected interpolation signal is interpolated into the interpolation field signal, and the process ends in step 7h.
[0070]
If it is not determined as the telecine conversion signal in step 7j, the process moves to step 7f to select the motion adaptive interpolation signal generated from the interpolation field signal and the previous field signal as the interpolation signal, and then in step 7g. The interpolation signal selected in step 7f is interpolated with respect to the interpolation field signal, and the process ends in step 7h.
[0071]
As described above, according to the progressive scan conversion apparatus of the present invention, the detection circuit that detects the motion of the even-numbered line / field in the vertical direction includes the detection circuit of the telecine detection circuit when the motion of the even-numbered line / field is detected. Regardless of the result, since the interpolation is performed with the interpolation signal obtained from the motion adaptive interpolation circuit or the interpolation signal obtained from the motion compensation interpolation circuit, it is possible to prevent malfunction due to erroneous determination of the 2-2 pull-down converted video signal. It is something that can be done.
[0072]
【The invention's effect】
As described above, the progressive scan conversion apparatus according to the present invention relates to the detection result of the telecine detection circuit when the motion of the even line / field is detected by the detection circuit that detects the motion of the even line / field in the vertical direction. Since the interpolation is performed using the interpolation signal obtained from the motion adaptive interpolation circuit or the interpolation signal obtained from the motion compensation interpolation circuit, it is possible to prevent malfunction due to erroneous determination of the 2-2 pull-down converted video signal. It is.
[Brief description of the drawings]
FIG. 1 is a circuit block diagram showing an embodiment of a progressive scan converter according to the present invention.
FIG. 2 is a circuit block diagram showing an embodiment of a main part of the apparatus shown in FIG.
3 is a circuit block diagram showing an embodiment of the main part of the circuit block shown in FIG. 2;
4 is a circuit block diagram showing an embodiment of another main part of the apparatus shown in FIG. 1;
FIG. 5 is a circuit block diagram showing another embodiment of the progressive scan converter according to the present invention.
FIG. 6 is a circuit block diagram showing still another embodiment of the progressive scan conversion apparatus according to the present invention.
7 is a flowchart for explaining the operation of the apparatus shown in FIG.
FIG. 8 is a timing chart for explaining a 2-2 pull-down conversion method.
FIG. 9 is a timing chart for explaining a 2-3 pull-down conversion method.
FIG. 10 is a diagram for explaining the operation of a conventional progressive scan converter.
FIG. 11 is a diagram for explaining the operation of a conventional scanning conversion device according to the related art and the present invention.
[Explanation of symbols]
10, 90, 100 ... sequential scanning conversion device
11 ... Input terminal
12: First field delay circuit
13: Second field delay circuit
14, 91 ... MV detection circuit
15 ... Telecine detection circuit
16 ... Telecine interpolation circuit
17, 92 ... motion adaptive interpolation circuit
18 ... Subtractor
19 ... Motion detection circuit
20 ... Selector control circuit
21 ... Selector
22 ... Double speed conversion circuit
23 ... Output terminal
40. Field continuity determination circuit
92, 101 ... motion compensation interpolation circuit
102. Second MV detection circuit
103: Field interpolation circuit
104 ... Mixer

Claims (7)

Video signal input interlaced, the first determination unit determines whether the movies image signal telecine converted by the 2-2 pull-down scheme,
Second determination means for determining whether or not the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields. When,
In the first determination means, when said input video signal is determined to be a Film image signal telecine converted by the 2-2 pull-down scheme, the video signal of interlace scheme, as the input in accordance with telecine conversion sequence An interpolation signal is generated, and when the second determination means determines that the motion vector has ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction, the first determination Interpolation signal generating means for generating an interpolation signal by motion adaptive interpolation or motion compensation interpolation regardless of the determination result of the means;
Interpolating means for interpolating the interlaced video signal with the interpolation signal generated by the interpolation signal generating means;
A progressive scan conversion device comprising: The interpolation signal generation means does not detect a vertical motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) by the second determination means, and is input by the first determination means. claims video signal is when it is not determined that the movies image signal telecine converted by 2-2 pulldown scheme, characterized in that for generating an interpolation signal by said motion adaptive interpolation or motion compensated interpolation Item 4. The progressive scan conversion device according to Item 1. Video signal input interlaced, the first determination unit determines whether the movies image signal telecine converted by the 2-2 pull-down scheme,
Second determination means for determining whether or not the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields. When,
First interpolation signal generating means for generating an interpolated video signal of the input interlace video signal according to a telecine conversion sequence;
Second interpolation signal generating means for generating a motion adaptive interpolation signal or a motion compensated interpolation signal according to at least the motion between fields of the video related to the input interlace video signal;
When the second determination means determines that the motion vector has a vertical motion vector of ± 2n (intra-frame scanning line / field) (n is an integer), the determination result of the first determination means Regardless, the input interlaced video signal is interpolated with the interpolation signal generated by the second interpolation signal generation means, and the vertical determination ± 2n (intraframe scanning line / field) by the second determination means. If (n is an integer) is not determined motion vectors, it is determined to be a Film image signal telecine converted by the video signal of the input interlaced manner in the first determining means 2-2 pull-down scheme Interpolating means for interpolating the input interlace video signal with the interpolation signal generated by the first interpolation signal generating means;
A progressive scan conversion device comprising: Said interpolation means, said first of said input video signal by judging means is determined not to be Film image signal telecine converted by the 2-2 pull-down scheme, and ± 2n (frame in the vertical direction by the second determination means Interpolate the input interlaced video signal with the interpolation signal generated by the second interpolation signal generation means when the motion vector of (inner scanning line / field) (n is an integer) is not detected The progressive scanning conversion apparatus according to claim 3 , wherein: A telecine detection circuit for detecting that the input interlaced video signal is a video signal generated by 2-2 pull-down telecine conversion;
A motion vector detecting means for detecting a motion between at least fields of the video related to the input interlaced video signal;
Telecine interpolation signal generating means for generating an interpolation signal according to a telecine conversion sequence;
Motion compensated interpolation signal generating means for generating an interpolation signal according to the motion vector detected by the motion vector detecting means;
When a motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction is detected by the motion vector detection means, the motion compensation interpolation signal is used regardless of the detection result of the telecine detection circuit. Using the interpolation signal generated by the generation unit, the motion vector detection unit does not detect a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction, and the telecine detection circuit Interpolating means for interpolating the interlaced signal using the interpolation signal generated by the telecine interpolation signal generating means when it is determined that the input interlace signal is a video signal generated by 2-2 pull-down type telecine conversion When,
A progressive scan conversion device comprising: A telecine detection circuit for detecting that the input interlaced video signal is a video signal generated by 2-2 pull-down telecine conversion;
First motion vector detection for detecting a motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction for every predetermined block or every predetermined pixel between video fields related to the input interlaced video signal Means,
Second motion vector detecting means for detecting a motion vector between fields or frames of a video related to the interlaced video signal;
Telecine interpolation signal generating means for generating an interpolation signal according to a telecine conversion sequence;
Motion compensated interpolation signal generating means for generating an interpolation signal according to the motion vector detected by the second motion vector detecting means;
Whether the field in which the first motion vector detection means detects a motion vector of ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction equal to or more than a predetermined number of blocks or more than a predetermined number of pixels continues Determining means for determining
A field in which ± 2n (intra-frame scanning line / field) (n is an integer) in the vertical direction is detected by the motion vector detection unit by the motion vector detection unit more than a predetermined number of blocks or more than a predetermined pixel is continuous for 2 fields or more. Interpolating means for interpolating the input interlaced video signal using the interpolation signal generated by the motion compensated interpolation signal generating means regardless of the detection result of the telecine detection circuit ,
A progressive scan conversion device comprising: Video signal input interlaced, determining whether a telecine converted movies image signal by the 2-2 pull-down scheme,
Determining whether the video related to the input interlaced video signal has a motion vector of ± 2n (intraframe scanning line / field) (n is an integer) in the vertical direction between fields;
When the input video signal is determined to be a Film image signal telecine converted by the 2-2 pull-down scheme, generates an interpolation signal of a video signal of the inputted interlace method according to telecine conversion sequence, the vertical The input interlace video signal was telecine-converted by the 2-2 pull-down method when it was determined that the motion vector had a direction ± 2n (intraframe scanning line / field) (n is an integer) . regardless of the determination result of whether a Film image signal or determining, a step of generating an interpolation signal by the motion adaptive interpolation or motion compensated interpolation,
Interpolating the interlaced video signal with the generated interpolation signal;
A progressive scan conversion method characterized by comprising:

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