Abstract:
The present invention provides a technique relating to a frame rate conversion which enables display of an image of extended definition by smoothening the movement of the image. Therefore, the invention fixes the direction of interpolation using information on a first frame which appeared before the insertion time of the interpolated frame, a second frame appeared before the first frame, a third frame appeared after the insertion time, and a fourth frame appeared after the third frame, based on the insertion time of the interpolated frame. The interpolated pixel is generated from pixels of the second frame and the third frame located in the direction of interpolation, and generates the interpolated frame. Then, the interpolated frame is inserted into the inputted image signal to convert the frame rate.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     1. Field of the Invention  
         [0002]     The present invention relates to a frame rate converting technique for converting the number of image frames used, for example, for an image display apparatus.  
         [0003]     2. Description of the Related Art  
         [0004]     In the image display apparatus, as a technique for displaying an image after having converted a frame rate (frame frequency) of image signal transmitted through a television broadcast into a desired frame rate, for example, a technique described in JP-A-2001-111968 is known.  
         [0005]     In the related art described above, when increasing the frame rate of the image signal as a conversion process, a process to repeat the same frame a plurality of times is performed. For example, when doubling the frame rate of an image signal having a frame row of (F1, F2 . . . ), a process to repeat each frame two times each, such as (F1, F1, F2, F2 . . . ) is performed. Therefore, in the image signal after conversion, the position of an object which moves within the display is the same between the repeated two frames. Therefore, in the related art, it is difficult to achieve smooth movement of the image after the frame rate conversion.  
         [0006]     The above described problem is obvious when a 2-3 pulldowned interlace image signal is displayed by 60 frames per second. The 2-3 pulldown system image signal is converted into the image signal of 24 frames per second once by reverse pulldown process in the image display apparatus, and then is converted into an image signal of 60 frames per second by repeating the same frame image in the order of two frames, three frames, two frames, three frames . . . . Therefore, since the image after conversion is switched in its image contents every 2/60, 3/60 seconds, even when it is an image in which an object moves in the screen at a constant velocity, the amount of movement of the object per unit time is no longer constant after conversion. Also, since the time period in which the same frame is displayed is increased, achievement of smooth movement is further difficult.  
       SUMMARY OF THE INVENTION  
       [0007]     In view of such a problem described above, it is an object of the invention to provide a technology relating to frame rate conversion which makes the movement of image smoother and enables display of extended definition image.  
         [0008]     The invention is characterized in that when the frame rate is converted by inserting an interpolated frame in the image signal, the interpolated frame is generated by using information on at least three frames of the image signal. The three frames are previous and subsequent frames interposing a position where the interpolated frame is inserted and a frame adjacent to any one of the previous and subsequent frames. The interpolated frame preferably uses information on four frames. The four frames include a first frame which appeared before the insertion time of the interpolated frame, a second frame appeared before the first frame, a third frame appeared after the insertion time, and a fourth frame appeared after the third frame.  
         [0009]     Specifically, the frame rate conversion according to the invention includes the steps of: setting a plurality of straight lines passing through the first to fourth frames based on a certain interpolated pixel in the interpolated frame, and obtaining, for each of the plurality of the straight lines, a sum of the difference between the pixel on the first frame and the pixel on the second frame located on each of the plurality of straight line, the difference between the pixel on the second frame and the pixel on the third frame located on the straight line, the difference between the pixel on the third frame and the pixel on the fourth frame on the straight line. The sum value is used as information for generating the interpolated frame, that is, as information on movement of the image. Then, the straight line whereof the sum value of the difference is the smallest is determined as a reference of the direction in which the movement of image, that is, the direction of interpolation for generating the aforementioned certain interpolated pixel, and the interpolated pixel is generated using the pixel information on the first frame and the third frame located in the direction of interpolation (that is, the previous and subsequent frames adjacent to the interpolated frame). The direction of interpolation may be the direction of the straight line whereof the sum of the differences is the smallest, or may be determined by using this straight line and the direction of interpolation of at least one interpolated pixel generated before the aforementioned certain interpolated pixel and/or one or more directions of interpolation of the interpolated frame generated before the interpolated frame in question.  
         [0010]     As described above, according to the invention, the movement of the image after converting the frame rate is smoothened, and hence an extended definition image can be obtained. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0011]      FIG. 1  is a drawing showing a circuit block in a first embodiment of the invention;  
         [0012]      FIG. 2  is an explanatory drawing showing a process of a correlation detection/interpolated pixel generation unit in the first embodiment;  
         [0013]      FIG. 3  is a drawing showing a circuit block in a second embodiment of the invention;  
         [0014]      FIG. 4  is an explanatory drawing showing a process of a correlation detection/interpolated pixel generation unit in the second embodiment;  
         [0015]      FIG. 5  is an explanatory drawing showing a process of the correlation detection/interpolated pixel generation unit in the second embodiment; and  
         [0016]      FIG. 6  is a drawing showing a process when a scene change is occurred in the second embodiment. 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0017]     Referring now to the drawings, preferred embodiment for carrying out the invention will be described.  
       First Embodiment  
       [0018]     Referring now to  FIG. 1  and  FIG. 2 , the first embodiment of the invention will be described.  FIG. 1  is a block diagram showing the first embodiment of a frame rate conversion unit used in an image display apparatus. In the first embodiment, a case in which an image signal of sequential scanning system of 60 frames per second is inputted, and the frame rate of this image signal is converted into the image signal of double frames, that is, of 120 frames per second will be described as an example. As a matter of course, the frame frequency of the aforementioned inputted image signal may be other frequencies. Needless to say that this embodiment can be applied to the case in which the frame rate is converted in a multiplying factor different from twice (for example, the frequency of 1.5 times or three times) in the same manner. In the following description, it is assumed that the inputted image signal has a digital format. Therefore, when the image display apparatus received an analogue image signal, the analogue image signal is converted into a digital image signal and supplied to a circuit shown in  FIG. 1 .  
         [0019]     The frame rate conversion unit according to this embodiment includes frame memories  22 - 24  and  25 , a correlation detection/interpolated pixel generation unit  11  and a switching circuit  31 . An image signal inputted to an input terminal  1  of the image signal is supplied to the correlation detection/interpolated pixel generation unit  11  and the frame memory  22 . The frame memory  22  delays the image signal by one frame by retaining the image signal for a time period corresponding to one frame. The signal delayed by one frame is supplied to the correlation detection/interpolated pixel generation unit  11  and the frame memory  23 . The frame memory  23  delays the image signal by another one frame by retaining the image signal for the time period corresponding to one frame like the frame memory  22 . Therefore, the output signal of the frame memory  23  is delayed by two frames with respect to the image signal at the signal input terminal  1 . The image signal delayed by two frames is supplied to the correlation detection/interpolated pixel generation unit  11 , the frame memory  24 , and the switching circuit  31 . The frame memory  24  delays the image signal by one frame as in the case of the frame memories  22  and  23  by retaining the image signal for a time period corresponding to one frame. Therefore, the output signal of the frame memory  23  is delayed by three frames with respect to the image signal at the signal input terminal  1 . The signal delayed by three frames is also supplied to the correlation detection/interpolated pixel generation unit  11 .  
         [0020]     When the image signal corresponding to four frames in the signal input terminal  1  and the frame memories  22 - 23  is inputted to the correlation detection/interpolated pixel generation unit  11 , the correlation detection/interpolated pixel generation unit  11  generates the interpolated frame using upon reception thereof. In this first embodiment, the interpolated frame is inserted temporally between the signal delayed by one frame by the frame memory  22  and the signal delayed by two frames by the frame memory  23 . Therefore, since the signal delayed by two frames by the frame memory  23  exists temporally before the interpolated frame, this is referred to as a previous frame  113 . Since the signal delayed by three frames by the frame memory  24  exists temporally before the previous frame  113 , that is, two frames before the interpolated frame, this is referred to as a pre-previous frame  114 . On the other hand, since the signal delayed by one frame by the frame memory  22  exists temporally after the interpolated frame, this is referred to as a subsequent frame  112 . Since the signal from the signal input terminal  1 , which is not delayed, exists temporally after the subsequent frame  112 , that is, two frames after the interpolated frame, this is referred to as a post-subsequent frame  111 . The aforementioned four frames of the post-subsequent frame  111 , the subsequent frame  112 , the previous frame  113 , the pre-previous frame  114  are consecutive frames.  
         [0021]     The correlation detection/interpolated pixel generation unit  11  detects a direction having stronger correlation about a certain interpolated pixel (a pixel to be interpolated) in an interpolated frame to be generated, that is, the direction of movement of the interpolated pixel in question, from four frames of the aforementioned post-subsequent frame  111 , the subsequent frame  112 , the previous frame  113 , and the pre-previous frame  114 . Then, the interpolated pixel is generated using data of the pixels in the previous frame  113  and the subsequent frame  112  located in this direction of movement. Detection of the direction of movement and generation of the interpolated pixel is performed for all the pixels in one interpolated frame. For example, when the number of pixels in one frame is 640×480, detection of the direction of movement and generation of the interpolated pixel are performed by the number of times corresponding to the number of the pixels, and consequently, one interpolated frame is generated.  
         [0022]     The interpolated frame generated in the correlation detection/interpolated pixel generation unit  11  in this manner is supplied to the frame memory  25 . The frame memory  25  retains the interpolated frame obtained from the correlation detection/interpolated pixel generation unit  11  for the time period corresponding to one frame, and supplies the same to the switching circuit  31 . The switching circuit  31  switches the interpolated frame from the frame memory  25  and the previous frame  113  from the frame memory  23  in cycle of 1/120 second. Accordingly, the interpolated frame is inserted between the adjacent two frames of the input image signal, and the input image signal is converted in frame rate to a doubled frame frequency, that is, to an image signal having a frame frequency of 120 Hz (that is, converted to a doubled speed). The image signal converted in frame rate from the switching circuit  31  is supplied to a display panel, not shown, and the image converted in frame rate is displayed. It is assumed that the display panel is a flat-type display device such as a plasma display panel (PDP), a liquid crystal panel or a field emission display (FED). However, in this embodiment, a non-panel type display device such as a CRT may be employed instead of the display panel. Subsequently, referring to  FIG. 2 , detection of correlation (direction of movement) in the aforementioned correlation detection/interpolated pixel generation unit  11  and generation of interpolated pixel will be described in detail. As shown in  FIG. 2 , the correlation detection/interpolated pixel generation unit  11  sets a next correlation search window for a certain interpolated pixel  101  on an interpolated frame  100 . For the previous frame image  113  and the subsequent frame image  112 , search windows  123 ,  122  each having a range of laterally 2M+1 pixels and vertically 2N+1 pixels (M and N represent natural numbers) respectively on the basis of the position of the interpolated pixel  101  in the frame. In this case, it is assumed that M=2 and N=1. For the pre-previous frame image  114  and the post-subsequent frame image  111 , search windows  124 ,  121  each having a range of laterally 6M+1 pixels and vertically 6N+1 pixels are set on the basis of the position of the interpolated pixel  101  in the frame, respectively. On these search windows, the position of the interpolated pixel is determined to be (0, 0). Then, on the basis of the interpolated pixel, a plurality of straight lines passing the interpolated pixel and passing through the post-subsequent frame  111 , the subsequent frame  112 , the previous frame  113 , and the pre-previous frame  114  are set. In this embodiment, fifteen straight lines described below are set as the plurality of the straight lines. In the following description, numerals before parentheses represent reference numerals of the respective search windows, and numerals in parentheses represent a coordinate (X, Y) on the search window. In other words, the respective straight lines shown below are straight lines passing through the respective pixels located at the respective coordinates. All of the respective straight lines pass through the interpolated pixel  101 .  
         [0023]     (a) 124(−6,3)−123(−2,1)−122(2,−1)−121(6,−3)  
         [0024]     (b) 124(−3,3)−123(−1,1)−122(1,−1)−121(3,−3)  
         [0025]     (c) 124(0,3)−123(0,1)−122(0,−1)−121(0,−3)  
         [0026]     (d) 124(3,3)−123(1,1)−122(−1,−1)−121(−3,−3)  
         [0027]     (e) 124(6,3)−123(2,1)−122(−2,−1)−121(−6,−3)  
         [0028]     (f) 124(−6,0)−123(−2,0)−122(2,0)−121(6,0)  
         [0029]     (g) 124(−3,0)−123(−1,0)−122(1,0)−121(3,0)  
         [0030]     (h) 124(0,0)−123(0,0)−122(0,0)−121(0,0)  
         [0031]     (i) 124(3,0)−123(1,0)−122(−1,0)−121(−3,0)  
         [0032]     (j) 124(6,0)−123(2,0)−122 (−2,0)−121 (−6,0)  
         [0033]     (k) 124(−6,−3)−123(−2,−1)−122(2,1)−121(6,3)  
         [0034]     (l) 124(−3,−3)−123(−1−1)−122(1,1)−121(3,3)  
         [0035]     (m) 124(0,−3)−123(0,−1)−122(0,1)−121(0,3)  
         [0036]     (n) 124(3,−3)−123(1,−1)−122(−1,1)−121(−3,3)  
         [0037]     (o) 124(6,−3)−123(2,−1)−122(−2,1)−121(−6,3)  
         [0038]     Then, for each of the aforementioned fifteen straight lines shown above in (a) to (o), the following parameters relating to the correlation with respect to the interpolated pixel  101  are calculated and obtained. (1) an absolute value of the difference between a pixel at a coordinate (X, Y) in the subsequent frame search window  122  and a pixel at a coordinate (−X, −Y) in the previous frame search window  123 ; (2) an absolute value of the difference between a pixel at a coordinate (−X, −Y) in the previous frame search window  123  and a pixel at a coordinate (−3X, −3Y) in the pre-previous frame search window  124 ; (3) an absolute value of the difference between a pixel at a coordinate (X, Y) in the subsequent frame search window  122  and a pixel at a coordinate (3X, 3Y) in the post-subsequent frame search window  121 .  
         [0039]     For example, in the case of the straight line (a), an absolute value of the difference between a pixel at a coordinate (2, −1) on the search window  122  and a pixel at a coordinate (−2, 1) on the search window  123 , an absolute value of the difference between a pixel at a coordinate (−2, 1) on the search window  123  and a pixel at a coordinate (−6, 3) on the search window  124 , and an absolute value of the difference between a pixel at a coordinate (2, −1) on the search window  122  and a pixel at a coordinate (6, −3) on the search window  121  are obtained. The reason why the coordinate in the previous frame search window  123  is represented by (−X, −Y) is to indicate that when the coordinate in the subsequent frame search window  122  is assumed to be (X, Y), the coordinate on the search window  123  is located in the opposite direction from the coordinate on the search window  122  both in the X-direction and Y-direction. The reason why the coordinate on the pre-previous frame search window  124  is represented by (−3X, −3Y) is to indicate that when the coordinate on the post-subsequent frame search window  122  is assumed to be (X, Y), the coordinate on the search window  124  is triple of the coordinate on the search window  122  both in the X-direction and Y-direction.  
         [0040]     The correlation detection/interpolated pixel generation unit  11  scans X from −M to M and Y from −N to N in the subsequent frame search window  122 , respectively. Accordingly, calculation shown in (1) to (3) is performed for each of the aforementioned fifteen straight lines, and the sum of the absolute value of the respective difference obtained by the calculation (1) to (3) is calculated for each straight line. It is determined that the smaller the sum value is, the stronger the correlation is in that direction. In other words, it is determined to be the direction of movement. In this embodiment, the straight line whereof the sum of (1) to (3) is the smallest is determined to be the direction of movement of an object. In this case, a straight line passing through a pixel shown in gray color in  FIG. 2 , that is, the straight line (b) is the straight line whereof the sum value is the smallest. In other words, the direction indicated by the straight line (b) is the direction of movement of the object passing through the interpolated pixel  101 . The correlation detection/interpolated pixel generation unit  11  generates the interpolated pixel  101  using a pixel on the subsequent frame  112  located on the straight line (b) whereof the aforementioned sum value is the smallest and a pixel on the previous frame  113 . In other words, the correlation detection/interpolated pixel generation unit  11  determines the straight line (b) as the direction of interpolation for generating the interpolated pixel  101 , and uses the pixels on the previous frame and the subsequent frame located in the direction of interpolation as data for generating the interpolated pixel  101  as a pixel set having the strongest correlation with respect to the interpolated pixel  101 . In this case, since the direction of interpolation is the direction of the straight line (b), the interpolated pixel  101  is generated by using a pixel at a coordinate (−1, 1) on the previous frame located on the straight line (b) (the gray pixel in the search window  123 ) and a pixel at a coordinate (1, −1) on the subsequent frame (a gray pixel in the search window  122 ). Here, the interpolated pixel  101  can be obtained, for example, by a following expression. 
 
γ=(α+β)/2  (Expression 1) 
 
 where α represents a pixel data (level) in the previous frame, β represents a pixel data in the subsequent frame, and γ represents data of the interpolated pixel  101 . 
 
         [0041]     In other words, the interpolated pixel  101  is generated by calculating an average (intermediate value) between the pixel data in the previous frame and the pixel data in the subsequent frame.  
         [0042]     By performing detection of the direction of movement and generation of the interpolated pixel entirely for the current interpolated frame  100 , a single piece of the interpolated frame  100  is generated. In other words, such a process is performed by the number of times corresponding to the number of pixels which constitutes the frame. The generated interpolated frame  100  is written in the frame memory  25  as described above, and is inserted between two frames of the inputted image signal by the switching circuit  31 . Accordingly, conversion of the frame rate is effected, and finally, an image signal having a frame frequency of 120 Hz is generated. The image signal having the frame rate of 120 Hz is particularly effective for the display device using the liquid crystal panel as the display panel. In other words, although the liquid crystal panel has a tendency to bring down an after-image, by converting the frame rate of the image signal into 120 Hz, the after image can be put into the shade. In this embodiment, the frame rate is converted by switching the output of the frame memory  23 , that is, the previous frame  113  and the interpolated frame  100  by the switching circuit  31 . However, it is also possible to convert the frame rate by switching the subsequent frame  112  and the interpolated frame.  
         [0043]     In this embodiment, the values of M and N employed for determining the size of the search window are M=2 and N=1. However, these values are arbitrary, and may be defined according to the effect of interpolation, the amount of calculation, or the scale of the circuit. For example, when M=7 and N=3 are employed, a hundred-and-five straight lines are set. Although the straight line whereof the sum of the aforementioned differences is the smallest is determined as the direction of interpolation in this embodiment, it is not limited thereto. For example, it is also possible to determine the direction of interpolation finally by combining other conditions based on the straight line whereof the aforementioned sum value is the minimum. As methods of determination of the direction of interpolation, examples will be shown below.  
         [0044]     First Method: Points are provided for the respective straight lines from (a) to (o) based on the sum values calculated for the respective fifteen straight lines passing through the interpolated pixel  101 . The smaller the sum value, the larger points are provided. Then, the directions of interpolation of the plurality of other interpolated pixels which are already generated before the interpolated pixel  101  are used for final determination of the direction of interpolation. The plurality of other interpolated pixels are preferably those adjacent to the interpolated pixel  101 . To which one of the aforementioned straight lines from (a) to (o) the directions of interpolation of those other interpolated pixels correspond is determined, and a predetermined point is added to the corresponding straight line. As a result of this addition, the straight line having the highest point is fixed to be the direction of interpolation. For example, it is assumed that 15 points, 14 points, 13 points, 12 points, and 11 points are added to the straight lines (b), (c), (f), (b), and (e), respectively according to the aforementioned sum value (here, for the sake of simplification of description, only five straight lines from the top are exemplified). If the direction of interpolation of the interpolated pixel at the immediate left of the interpolated pixel  101  is (c), the direction of interpolation of the interpolated pixel at the upper left thereof is (c), the direction of interpolation of the interpolated pixel immediately above is (a), and the direction of interpolation of the interpolated pixel at the upper right thereof is (b), for example, 5 points each is added to the straight lines (a), (b) and (c). Consequently, since the straight line (c) has 24 points, which are the highest points, the direction of the straight line (c) is fixed to be the direction of interpolation. Although the number of the aforementioned other interpolated pixels are four in the description, it may be one, or two, or three. When there is only one, only the interpolated pixel at the immediate left is used, and when there are two, the interpolated pixels at the immediate left and immediately above are used.  
         [0045]     Second Method: Addition of the points to the respective straight lines is the same as the first method. The directions of interpolation used for the interpolated frame, which is already generated before the interpolated pixel  101  by one frame, are counted for each sort. Then, the predetermined points are added to the straight lines corresponding to the top three directions in terms of the enumerated value. As a matter of course, the larger the enumerated value, the higher point is added. As a result of addition, the direction of the highest point is fixed to be the direction of interpolation. For example, it is assumed that the points of the respective straight lines based on the aforementioned sum values are the same as the first method, and the descending order of the enumerated values of the directions of interpolation used for the previous interpolated frame are the straight line (f), the straight line (c) and the straight line (a). In this case, 5 points, 3 points and 1 point are added to the straight lines (f), (c) and (a) respectively. Consequently, since the point of the straight line (f) is 18 points, which is the highest, the direction of the straight line (f) is fixed to be the direction of interpolation.  
         [0046]     The first and second methods may be used independently, or may be used in combination thereof. Which method to be used is determined by the requirement relating to improvement of accuracy of decision of the direction of interpolation.  
         [0047]     In this manner, in this embodiment, the direction of interpolation is fixed based on the movement of the image, and the interpolated frame is generated by interpolated pixels based on the direction of interpolation instead of simply inserting the same frame in the image signal as the previous frame as the interpolated frame as in the related art. Therefore, the movement of the image after conversion of the frame rate can be smoothened. In this embodiment, four frames are used when detecting the direction of movement. Therefore, the direction of movement can be detected with higher degree of accuracy in comparison with the case of detecting the same from two frames. Although the four frames of the previous frame, the subsequent frame, the pre-previous frame, and the post-subsequent frame are used for detecting the movement in this embodiment, it may be detected using three frames. At this time, as the three frames used for detecting the direction of movement, one of the pre-previous frame or the post-subsequent frame is used in addition to the previous frame and the subsequent frame. In other words, the detection accuracy of the direction of movement can be improved by using at least three frames. Although it is preferable to use four frames as this embodiment in order to further improve accuracy of detection of movement, when it is difficult to use many frame memories by being bound by the scale of the circuit or the cost, it is possible to use three frames. In this case as well, the invention is implemented as described above. In this case, one of the post-subsequent frame search window  121  or the pre-previous frame search window  124  is deleted as the search window used for detecting the movement.  
       Second Embodiment  
       [0048]     Referring now to  FIG. 3  to  FIG. 6 , a second embodiment of the invention will be described. This embodiment is described about the case in which the 2-3 pulldowned interlace signal of 60 fields per second (hereinafter referred simply as “2-3 signal”) is inputted, and this signal is converted into an image of 60 frames per second as an example.  
         [0049]      FIG. 3  is a circuit block diagram showing the second embodiment of the invention. A point significantly different from the first embodiment shown in  FIG. 1  is that a sequential scanning conversion unit  2  is added. This sequential scanning conversion unit includes field memories  41  and  42 , a subtracter  81 , a controller  61 , line memories  51  and  52 , and a selector  32 . The image signal (2-3 signals) inputted from the signal input terminal  1  is supplied to the field memory  41  and the subtracter  81 . The field memory  41  retains and delays the inputted image signal by one field and outputs the same to the field memory  42  and the line memory  51 . The field memory  42  retains the output signal from the field memory  41  to delay the same by another one field, and then outputs the same to the line memory  52  and the subtracter  81 . Therefore, the output from the field memory  42  is delayed by two fields (one frame) with respect to the inputted image signal. The line memories  51  and  52  retains the image signals outputted from the field memories  41  and  42  respectively for the time period corresponding to one line, and outputs the same to the selector  32 .  
         [0050]     On the other hand, the subtracter  81  subtracts the image signal inputted to the signal input terminal  1  and the image signal delayed by two fields and outputted from the field memory  42 , and outputs the result of subtraction to the controller  61 . As indicated by “input signal” in  FIG. 4 , images  201 - 243  of the 2-3 signal are of an interlace image signal of 60 fields per second, and odd numbers represent an image signal of the top field and even numbers represent an image signal of the bottom field. The images having the same number in tenth digit indicates that they are the image signals generated from the same original 24 frames per second. Therefore, the images  201  and  203  are the same. In the same manner, the images  222  and  224 , the images  241 ,  243  are the same, respectively. In this manner, in the 2-3 signal, the image contents in two fields with the intermediary of one field are the same with a period of five fields. Therefore, the difference between the inputted image signal and the image signal delayed by two fields (frame difference) becomes substantially zero once at every five fields. The aforementioned controller  61  detects that the inputted image signal is 2-3 signal when the sequence in which the difference becomes zero once at every five fields (a series of flow in which the difference appears in the sequence of present-present-present-absent (zero)-present) appears consecutively at least by a predetermined number of times (for example, 3 times). When the inputted image signal is determined to be 2-3 signal, the controller  61  outputs the control signal with respect to the selector  32 . The control signal controls the selector  32  so as to output the signal from the line memory  51  and the signal from the line memory  52  alternately by switching between them periodically. Therefore, from the selector  32 , the first line of the first field stored in the field memory  41 , the first line of the second field stored in the field memory  42 , the second line of the first field, and the second line of the second field are outputted in this order. Consequently, the sequential scanning-signal (signal one frame) as shown in the middle stage in  FIG. 4  is generated from the two fields of the 2-3 signal. For example, as shown in  FIG. 4 , an image  301  is generated when the images  203  and  202  are retained in the field memory  41  and  42  respectively, and an image  311  is generated when the images  212 ,  213  are retained respectively. The control signal from the controller  61  to the selector  32  is outputted at such timing as to generate two frames from five fields of the 2-3 signal. In this manner, the sequential scanning conversion unit  2  performs the process of converting the 2-3 pulldowned interlace signal of 60 fields per second into a non-interlace (sequentially scanning) signal of 24 frames per second.  
         [0051]     The non-interlace signal of 24 frames per second outputted from the sequential scanning conversion unit  2  is supplied to the frame memory  21 . Unlike with the first embodiment, the frame memory  21  is newly added in the second embodiment. The reason will be described referring to  FIG. 4 . The first embodiment is a process for converting the number of frames of the image signal into double. However, since this embodiment is a process for converting the image of 24 frames per second to the image of 60 frames per second, two types of images must be generated from the images of the same combination. For example, it is necessary to generate two types of images, that is, an image  404  and an image  405  between the image  311  and the image  321  from four frames of the image  301 , the image  311 , the image  321 , and the image  331  in  FIG. 4 . Therefore, there is a necessity to perform processing twice in a correlation detection/interpolated pixel generation unit  12 . In the first embodiment, the processing is performed only once, and hence the signal inputted from the outside can be used as is. However, in this embodiment, it is necessary to use the signal from the selector  32  twice. Therefore, in this embodiment, the frame memory  21  is newly added, and the signal from the selector  32  is written and read out twice in this frame memory  21 .  
         [0052]     Subsequently, referring also to  FIG. 5 , the interpolation process for generating, for example, the image  405  in  FIG. 4  will be described in detail. The frame memories  21 - 24  in  FIG. 3  are frame memories which are similar to those in the first embodiment, and retain the image for the time period corresponding to one frame. The frame memory  21  retains the signal from the selector  32  for the time period corresponding to one frame, and outputs the image data  331  which corresponds temporally to the post-subsequent frame  111  with respect to the interpolated frame  100  to the correlation detection/interpolated pixel generation unit  12 . The frame memories  22 ,  23  and  24  retain data corresponding to one frame as in the first embodiment, and output the image  321 , which is the subsequent frame  112 , the image  311  which is the previous frame  113 , and the image  301  which is the pre-previous frame  114 . The correlation detection/interpolated pixel generation unit  12  performs detection of the direction of interpolation and generation of interpolated pixel and the interpolated frame using four frames data outputted from the frame memories  21 - 24  as in the first embodiment. However, unlike with the first embodiment, in this embodiment, the temporal distance between the interpolated frame  100  to be generated and the previous frame  113 , and the temporal distance between the interpolated frame  100  and the subsequent frame  112  are different from each other. For example, when generating the image  405  in  FIG. 4 , the ratio of the temporal distance of the image  311  which is the previous frame  113  and the image  321  which is the subsequent frame  112  with respect to the image  405  is 3:2. Accordingly, the rate of the temporal distance of the pixels which correlates to the interpolated pixel  101  must also be 3:2, and hence the size of the search window must be changed correspondingly. Therefore, in this embodiment, the following parameters relating to the correlation with the interpolated pixel  101  are obtained for each of the plurality of the straight lines passing through the aforementioned four frames on the basis of the interpolated pixel  101 . (1) an absolute value of the difference between the pixel at the coordinate (X, Y) on the subsequent frame search window  122  and the pixel at the coordinate (−1.5X, −1.5Y) on the previous frame search window  123 ; (2) an absolute value of the difference between the pixel at the coordinate (−1.5X, −1.5Y) on the previous frame search window  123  and the pixel at the coordinate (−4X, −4Y) on the pre-previous frame search window  124 ; (3) an absolute value of the difference between the pixel at the coordinate (X, Y) on the subsequent frame search window  122  and the pixel at the coordinate (3.5X, 3.5Y) on the post-subsequent frame search window  121 .  
         [0053]     When the position of the pixel does not become an integer number and hence is a position where the actual pixel does not exist, a weighted mean of the peripheral pixels is used as the pixel value of that position. For example, when the gray position on the previous frame search window  123  shown in  FIG. 5  is the position of the pixel, this position of the pixel is located at the center of peripheral four pixels, and hence data of the position of this pixel is obtained by dividing the sum of the four pixel data on the periphery thereof by four. Then, the direction of interpolation of the interpolated pixel  101  is fixed from the straight line whereof the sum of the aforementioned (1) to (3) is the smallest, or based on that straight line in the same process as described in conjunction with the first embodiment. Then, the pixel on the previous frame  113  and the pixel on the subsequent frame  112  located in this direction of interpolation are used to generate the interpolated pixel  101 . Here, since the temporal distance between the interpolated frame  100  and the previous frame  113  and the temporal distance between the interpolated frame  100  and the subsequent frame  112  are different, the weighted mean of the two pixels located in the direction of interpolation is obtained according to the ratio of those temporal distances. In this embodiment, since the ratio of the temporal distances is 3:2, the interpolated pixel  101  can be obtained, for example by the following expression 
 
γ=(2α+3β)/5  (Expression 2) 
 
 where α represents the pixel data of the previous frame, β represents the pixel data of the subsequent frame, and γ represents data of the interpolated pixel  101 . 
 
         [0054]     Since the pixel used for interpolation, the pixel data α, and the pixel data β have strong correlation, these values are in the similar level. Therefore, it is also possible to obtain data of the interpolated pixel γ from the average between the pixel data α and the pixel data β (for example, from calculation using Expression 1) for reducing the amount of calculation or the scale of the circuit.  
         [0055]     Although the ratio between the temporal distance between the image  311 , which is the previous frame  113 , and the image  405 , and the temporal distance between the image  321 , which is the subsequent frame  112  and the image  405  is 3:2 in  FIG. 5 , the ratio may change according to the temporal position of the image to be interpolated. In this embodiment, the case in which the 2-3 signal is converted into the signal of 60 frames per second has been described as an example. However, the same processing is performed also when it is converted into 72, 96 or 120 frames per second. In this case, although the ratio of the temporal distance changes, the same processing is performed except for the points that the image signal is read from the frame memories  21 - 24  and the number of times of generating the interpolated image changes.  
         [0056]     The correlation detection/interpolated pixel generation unit  12  uses the signal from the frame memories  21 ,  22  for detecting the scene change in addition to the processing described above. As shown in  FIG. 6 , it is assumed that the image  501  is retained in the frame memory  24 , the image  502  is retained in the frame memory  23 , the image  503  is retained in the frame memory  22 , and the image  504  is retained in the frame memory  21  at a certain moment. At this time, it is assumed that the images  501 - 503  are the same scene, and are A, B, C which have small differences from each other. On the other hand, the image  504  is a different scene, and is an image d which is significantly different from A to C. In this state, the correlation detection/interpolated pixel generation unit  12  calculates the difference between the signal from the frame memory  21  and the signal from the frame memory  22 . This difference is the difference between the same positions (the pixels at the same coordinate) between these frames. This calculation is performed for all the pixels in one frame, or for all the pixels in the preset area (for example, 80% of the entire display, which is preset on the basis of the center of the screen). Then, the difference between the respective pixels in one frame is accumulated, and when the accumulated value exceeds the predetermine value, it is determined that the scene change has occurred. Information on the scene change is retained in the correlation detection/interpolated pixel generation unit  12 . When the time is elapsed, the image  502  is retained in the frame memory  24 , the image  503  is retained in the frame memory  23 , the image  504  is retained in the frame memory  22 , and the image  505  is retained in the frame memory  21 . At this time, since information on scene change is retained in the correlation detection/interpolated pixel generation unit  12 , the direction of interpolation is changed using this information. In other words, in this embodiment, information on the detected scene change is not reflected to the interpolation process at the time point of detection, but reflected to the subsequent interpolating process. The method of interpolation is changed in the following manner. In other words, before scene change, the direction of interpolation is detected and interpolated from data of four frames as in the first embodiment, while after scene change, such detection of the direction of interpolation is not performed and the interpolated pixel is generated from the weighted mean between the images  503  and  504 . At this time, it is also possible to perform the interpolation processing using data of the image  503  or  504  as is. In the above-described description, accumulation of differences between the pixels for one frame is used for detecting the scene change. However, it is also possible to integrate the number of pixels whereof the value of difference is at least a predetermined constant value over one frame, and determine that the scene change has occurred when the integrated value is equal to or larger than a predetermined value.  
         [0057]     The frame memory  25  stores the image of the interpolated frame generated in the manner described above and outputs the same to the switching circuit  31 . The switching circuit  31  switches the interpolated frame from the frame memory  25  and the previous frame  113  from the frame memory  23  periodically, and outputs the image signal of 60 frames per second. At this time, the selected time for the interpolated frame and the selected time for the previous frame in the switching circuit  31  are not the same. In other words, as shown in “OUTPUT SIGNAL” in  FIG. 4 , the switching circuit selects the signal from the frame memory  23  when outputting the images  401 ,  406 ,  411 , and selects the signal from the frame memory  25  when outputting the images  402 - 405  and the images  407 - 410 . In other words, the switching circuit  31  selects the signal from the frame memory  23  at the timing where the images  301 ,  321  and  341  are generated in the sequential scanning conversion unit and selects the signal from the frame memory  25  at other timings.  
         [0058]     In this embodiment, the actions of the frame memory  25  and the switching circuit  31  are described by exemplifying a process for the image of 60 frames per second. Even when the output frame frequency of the image is changed, the same processing is performed other than a point that the operation speed and/or the order of the frame memories to be read out are changed.  
         [0059]     A voice delay unit  71  has a function to delay a voice signal which is inputted together with the image signal. In the aforementioned frame rate conversion process, the image delays since it uses the field memory and the frame memory, while there occurs no delay in voice. Therefore, there occurs a time lag between the image and the voice. The voice delay unit  71  is intended for compensating this time lag. The voice delay unit  71  processes the voice in digital form, and compensates the time lag between the image and the voice by providing a delay as much as the image to the voice by, for example, FIFO.  
         [0060]     As described above, the invention is applied to the image device for performing the frame rate conversion process (image signal output devices such as a DVD player or a set-top box, or image display apparatus such as a television receiving set) In particular, it is effective when smoothening of the movement of the image after the frame rate conversion is desired.