CN103763500A - De-interlacing image processing device and method achieving motion compensation - Google Patents
De-interlacing image processing device and method achieving motion compensation Download PDFInfo
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Abstract
The invention discloses a de-interlacing image processing device achieving motion compensation. The device comprises a motion compensation module, a static compensation module, a motion detection module and a de-interlacing blending module, wherein the motion compensation module is used for producing a motion compensation pixel at least according to the current field, a former field and a later field of a pixel to be interpolated; the static compensation module is used for producing a static compensation pixel according to the former field and the later field of the pixel to be interpolated; the motion detection module is used for producing a motion index according to the former field and the later field of the pixel to be interpolated; the de-interlacing blending module is used for producing the pixel to be interpolated by conducting weighted average calculation on the motion compensation pixel and the static compensation pixel according to the motion index.
Description
The application is the application number of on January 4th, the 2011 application Chinese invention patent application that is 201110021616.3
Divide an application
Technical field
The present invention refers to a kind of Deinterlacer processing unit, espespecially a kind of release of an interleave image processor and correlation technique thereof with motion compensation.
Background technology
Along with Digital Television period arrives, TV not only can teleview, and can also use the internet application such as TV browsing page simultaneously.And Digital Television can provide the audio-visual quality that surmounts traditional analog television to serve with individualized use.According to the standard of existing various countries Digital Television, television format signal comprises the signal format of formula (Progressing) and interlacing (Interlacing) scanning in proper order.The signal format of these two kinds of scannings respectively has its pluses and minuses.Wherein, interleaved great advantage is that the data volume of required transmission is less, and the in bright gay color degree of dynamic image and contrast are also relatively good.Therefore, be particular about under the occasion of high-resolution and large frame TV, particularly, in the situation of 1080 scan lines, interleaved signal format is used more extensive, and its transinformation is also fewer, saves the frequency range of transmission.
In detail, please refer to Fig. 1, interleaved signal format transmits each frame (Frame) is resolved into an odd field (Odd Field) and an even field (Even Field), wherein odd field only comprises the pixel of odd-numbered line in this frame (Odd Line), and even field only comprises the pixel that this frame rushes even number line (Even Line).When transmission, odd field and even field alternately transmit, and the volume of transmitted data in the unit interval can reduce by half.But the received image data of image receiving terminal is odd field or Even Fields number, one of incomplete frame picture, need to see through the processing of release of an interleave (De-Interlace), supply at point at the same time, the even number line not transmitting or the pixel data of odd-numbered line, to produce complete frame picture, and then be presented on video display.Meaning is inputted in odd field (Odd Field) only the 1st, 3,5,7,9 ... the pixel data of row, only has 2,4,6,8,10 in input even field ... the pixel data of row; But when image output, be all necessary for the frame of form in proper order, the 1st, 2,3,4,5,6,7,8,9,10 ... in row, all there is pixel data.
The have living space mode of processing of release of an interleave or time release of an interleave of the processing of common release of an interleave.Space Solutions is staggered processes the interpolation of pixel row pixel to be mended of the up-downgoing par shaft position of the field of using same time point, usings the pixel average of upper and lower 2 as the pixel value of interpolation, also can use the more direct pixel value as interpolation.For instance, in the first figure, the pixel A of odd field Fn is a pixel for the treatment of in interpolation row, the staggered pixel value of processing the pixel average of the pixel C of the pixel B of lastrow and next line as pixel A of Space Solutions, or direct pixel value of usining pixel A or pixel B is as the pixel value of pixel A.In addition, the interpolation of the pixel row pixel to be mended of a same position before and after time release of an interleave process to be used, usings the pixel average of two the middle same positions in front and back as the pixel value of interpolation.For instance, in Fig. 1, the pixel A of odd field Fn is a pixel for the treatment of in interpolation row, and time release of an interleave is processed the pixel value using the mean value of the pixel E of same position in the pixel D of same position in last even field Fn-1 and a rear even field Fn+1 as pixel A.But Space Solutions is staggered or the processing of time release of an interleave, for dynamic picture interpolation, cannot interpolation go out real pixel, can cause image distortion.Therefore, the present invention proposes to utilize the estimation of motion-vector, and with correct interpolation, goes out real pixel according to this, to promote the quality of image.
Summary of the invention
Therefore, one of object of the present invention is to provide a kind of release of an interleave image processor and correlation technique thereof with motion compensation, to solve the above problems.
According to embodiments of the invention, disclose a kind of release of an interleave image processor with motion compensation, this device includes a time motion compensation module, a space motion compensation module, a space motion compensation module and a motion compensation mixing module.Wherein, time motion compensation module, for according to previous field and a Hou Yichang who treats inter polated pixel, produces a time interpolator pixel and a time motion-vector quality index; Space motion compensation module, for treat the field of inter polated pixel according to this, produces a space inter polated pixel and a sawtooth index; And motion compensation mixing module, for according to this time interpolator pixel, this space inter polated pixel, this time motion-vector quality index and this sawtooth index, produce this and treat inter polated pixel.
According to embodiments of the invention, it separately discloses a kind of release of an interleave image treatment method with motion compensation, and the method includes previous field and the Hou Yichang that foundation one is treated inter polated pixel, produces a time interpolator pixel and a time motion-vector quality index; The field for the treatment of inter polated pixel according to this, produces a space inter polated pixel and a sawtooth index; And according to this time interpolator pixel, this space inter polated pixel, this time motion-vector quality index and this sawtooth index, produce this and treat inter polated pixel.
According to embodiments of the invention, it separately discloses a kind of release of an interleave image processor with motion compensation.This device includes a motion compensation module, a static compensation module, moves detection module and a release of an interleave mixing module.Wherein, motion compensation module, according on the scene, the previous field of institute and a Hou Yichang who treats inter polated pixel, produces a motion compensation pixel at least; Static compensation module, for treat previous field and the Hou Yichang of inter polated pixel according to this, produces a static compensation pixel; Mobile detection module, for treat previous field and the Hou Yichang of inter polated pixel according to this, produces one and moves index; And release of an interleave mixing module, for moving index according to this, this motion compensation pixel and this static compensation pixel are weighted to average computation, produce this and treat inter polated pixel.
According to embodiments of the invention, it separately discloses a kind of release of an interleave image treatment method with motion compensation, and the method includes at least according to one treating that the institute of inter polated pixel is on the scene, previous field and Hou Yichang, produces a motion compensation pixel; According to this, treat previous field and the Hou Yichang of inter polated pixel, produce a static compensation pixel; According to this, treat previous field and the Hou Yichang of inter polated pixel, produce one and move index; And move index according to this, and this motion compensation pixel and this static compensation pixel are weighted to average computation, produce this and treat inter polated pixel.
According to embodiments of the invention, it separately discloses a kind of release of an interleave image processor with motion compensation.This device includes a time motion compensation module, for according to one after a previous field and of inter polated pixel one, produces a time interpolator pixel and a time motion-vector quality index; One space motion compensation module, for treat of inter polated pixel place according to this, produces a space inter polated pixel; And a motion compensation mixing module, for according to this time interpolator pixel, this space inter polated pixel and this time motion-vector quality index, produce this and treat inter polated pixel.
According to embodiments of the invention, it separately discloses a kind of release of an interleave image processor with motion compensation.This device includes a time motion compensation module, for according to one after a previous field and of inter polated pixel one, produces a time interpolator pixel; One space motion compensation module, for treat of inter polated pixel place according to this, produces a space inter polated pixel and a sawtooth index; And a motion compensation mixing module, for according to this time interpolator pixel, this space inter polated pixel and this sawtooth index, produce this and treat inter polated pixel.
The estimation of the use of advantage motion-vector of embodiments of the invention, and with correct interpolation, go out real pixel according to this, to promote the quality of image.
Accompanying drawing explanation
Fig. 1 is the schematic diagram of release of an interleave image processing.
Fig. 2 is the functional block diagram of the release of an interleave image processor with motion compensation of a preferred embodiment of the present invention.
Fig. 3 is the flow chart of the release of an interleave image treatment method with motion compensation of a preferred embodiment of the present invention.
Fig. 4 is the operation workflow figure of time motion compensation module.
Fig. 5 A is the schematic diagram of decision time motion-vector.
Fig. 5 B is the schematic diagram of decision time motion-vector quality index.
Fig. 6 is for producing the flow chart of space compensation pixel.
Fig. 7 is for determining the flow chart of sawtooth index.
Fig. 8 is the flow chart of image treatment method of the present invention.
Fig. 9 is the functional block diagram of the release of an interleave image processor with motion compensation of another preferred embodiment of the present invention.
Figure 10 is the flow chart of the release of an interleave image processing with motion compensation of another preferred embodiment of the present invention.
Figure 11 moves the flow chart of index for producing a static compensation pixel and.
Primary clustering symbol description
10 release of an interleave image processors
100 time motion compensation modules
110 time mobile estimating unit
120 time pixel interpolation unit
130 time motion-vector quality index generation units
200 space motion compensation modules
210 mobile estimating unit, spaces
220 pixel interpolation unit, spaces
230 sawtooth detecting units
300 motion compensation mixing modules
90 release of an interleave image processors
910 motion compensation modules
920 static compensation modules
930 move detection module
940 release of an interleave mixing modules
Embodiment
Please refer to Fig. 2, it has illustrated the functional block diagram of the release of an interleave image processor 10 with motion compensation of a preferred embodiment of the present invention.Release of an interleave image processor 10 is for converting the field of interlacing (interlaced scan) to the frame of P-SCAN (progressive scan), the even number line lacking in the odd field of soon staggered processing of meaning or even field or the pixel interpolation of odd-numbered line generate, and are reduced into a complete frame.Release of an interleave image processor 10 comprises time motion compensation module (time-domain motion compensation unit) 100, space motion compensation module (space-domain motion compensation unit) 200 and motion compensation mixing module (motion compensation blending unit) 300.For more clearly demonstrating the present invention's running, please separately with reference to Fig. 3, it has illustrated the flow chart of the release of an interleave image processing with motion compensation of a preferred embodiment of the present invention.First, in step 310, time motion compensation module 100 for according to when the previous field Fn-1 of front court Fn and after a Fn+1, produce time interpolator pixel P3di and corresponding time motion-vector quality index I3di in a Fn, comprise time mobile estimating unit 110, time pixel interpolation unit 120 and time motion-vector quality index generation unit 130.Then, in step 320 and 330, space motion compensation module 200 is for lastrow Ln-1 and a next line Ln+1 according to field Fn row Ln to be compensated, produce inter polated pixel P2di and corresponding sawtooth index (Jaggy Index) Ij between row Ln hollow, comprise mobile estimating unit, space 210, pixel interpolation unit, space 220 and sawtooth detecting unit 230.Finally, in step 340, motion compensation mixing module 300, for according to time interpolator pixel P3di, space inter polated pixel P2di, time motion-vector quality index I3di and sawtooth index Ij, produces motion compensation pixel PMCDi.
Please refer to Fig. 4, further illustrate the operation workflow of time motion compensation module 100.In step 312, the previous field Fn-1 of 110 pairs one of time mobile estimating unit until inter polated pixel Pxy and after a Fn+1 carry out block comparison calculation, to determine according to time motion-vector MV3D.Separately, with reference to Fig. 5 A, it is the schematic diagram of decision time motion-vector.In the Fn of front court, pixel Pxy treats inter polated pixel, and block 520,540 is a comparison blocks size, and region 510,530 is a comparison region.In the time that determines pixel Pxy, during motion-vector, in region 510,530, with the size of block 520,540, carry out block comparison.The mode that this motion-vector estimation is processed time can be looks for previous field Fn-1 and block the most similar in a rear Fn+1, and search area can be whole or part field.Consider under the situation of operand, preferred embodiment of the present invention adopts absolute value error summation (Sum of Absolute Difference; SAD) algorithm, when the absolute value error summation of certain two block is minimum, this two block is Best similarity block, and its corresponding vector is the time motion-vector of pixel Pxy, and algorithm is as follows:
Motion-vector is (m, n), makes i=m, and SAD during j=n is minimum, wherein
(1) N represents the length of block and wide;
(2) C (x+k, y+l) represents in target image field, the point in target image block;
(3) R (x+i+k, y+j+l) representative is in reference to image fields, with reference to the point in image block;
(4) p represents search area.
This case invention preferred embodiment of take is example, for reducing complexity and cost-effective consideration, selects the one-dimensional area that block 520,540 is 1*5, and the region that region 510,530 is 5*10.The SAD that supposes the block 540 in block in comparative result previous field Fn-1 520 and a rear Fn+1 is minimum, and motion-vector MV3D is the time motion-vector MV3D of pixel Pxy.Large I that it should be noted that block 520,540 and region 510,530 is different in response to the demand of implementation, non-restrictive condition of the present invention.
Then, in step 314, time pixel interpolation unit 120 is according to time motion-vector MV3D, first finds in previous field Fn-1 pixel Pn+1 in pixel Pn-1 and a rear Fn+1, then produces according to this time interpolator pixel P3di to pixel Pxy.The production method of this time interpolator pixel P3di, can select pixel Pn-1 or pixel Pn+1 one of them, or the pixel value that pixel Pn-1 and pixel Pn+1 weighted average are produced.
Then,, in step 316, please separately with reference to Fig. 5 B, it is the schematic diagram of decision time motion-vector quality index.Time motion-vector quality index generation unit 130 is treated the time motion-vector MV3D of inter polated pixel Pxy and the motion-vector MV1~MV3 of this lastrow, next line and previous field respective pixel according to this, produce a time motion-vector quality index I3di, for the confidence level of motion compensation mixing module 300 judgement time interpolator pixel P3di is provided.The formula that the time motion-vector quality index I3di of preferred embodiment of the present invention determines is as follows:
I3di=|MV3D-MV1|+|MV3D-MV2|+|MV3D-MV3|
The formula that the time motion-vector quality index I3di of another embodiment of this case determines also can be as follows:
I3di=Max(|MV3D-MV1|,|MV3D-MV2|,|MV3D-MV3)|
As time motion-vector quality index I3di hour, represent this treat the time motion-vector MV3D of inter polated pixel Pxy with around and the motion-vector of pixel corresponding to previous field close, also mean mobile trend close, therefore the confidence level of time motion-vector MV3D and time interpolator pixel P3di is very high; Contrary, when the time, motion-vector quality index I3di was large, represent this treat the time motion-vector MV3D of inter polated pixel Pxy from around and the motion-vector of pixel corresponding to previous field different, also mean and there is no identical mobile trend, therefore the confidence level of time motion-vector MV3D and time interpolator pixel P3di is very low.
Next, further space motion compensation is processed, and please also refer to Fig. 6, it is for producing the flow chart of space compensation pixel.In step 322, between at least lastrow and next line for the treatment of inter polated pixel Pxy in 210 pairs of mobile estimating unit, space current figure field Fn, (this case invention preferred embodiment is between row Ly-3~Ly+3) carries out block comparison, produces a space move angle.Then, please refer to Fig. 8, Pxy treats inter polated pixel, and block 820 is a comparison blocks size, and region 810 is a comparison region.In this case invention preferred embodiment, for reducing complexity and cost-effective consideration, select the one-dimensional area that block 820 is 1*5, and the region that region 810 is 7*10 (between row Ly-3~Ly+3).And block comparison also adopts absolute value error summation (Sum of Absolute Difference; SAD) algorithm, according to lastrow Ln-1 and next line Ln+1, two blocks of the SAD minimum producing, determine the space move angle of this pixel Pxy.Large I that it should be noted that block 820 and region 810 is different in response to the demand of implementation, non-restrictive condition of the present invention.Then,, in step 324, pixel interpolation unit, space 220, according to the space move angle of this pixel Pxy, first finds two pixels corresponding in lastrow Ln-11 and next line Ln+1, then produces according to this space inter polated pixel P2di to pixel Pxy.The production method of this space inter polated pixel P2di, can select this two pixel one of them, the pixel value maybe this two pixels weighted average being produced.
Then, please refer to Fig. 7, it is for determining the flow chart of sawtooth index.In step 332, mobile estimating unit 210, space, in the process of block comparison, produces a high specific to difference Max SAD and a minimum comparison difference Min SAD.Then, sawtooth detecting unit 230 to difference Max SAD and this minimum comparison difference Min SAD, produces a sawtooth index Ij according to this maximum, for providing motion compensation mixing module 300 judgement spaces to move the confidence level of inter polated pixel P2di.The formula that the sawtooth index Ij of this case preferred embodiment determines is as follows:
Ij=Max?SAD–Min?SAD
As sawtooth index Ij hour, represent the lastrow Ln-11 that this treats inter polated pixel Pxy and next line Ln+1 is non-is in edge zone (edge), therefore the with a high credibility of inter polated pixel P2di moved in space; On the contrary, when sawtooth index Ij is large, represent that lastrow Ln-11 and next line Ln+1 that this treats inter polated pixel Pxy are in edge zone (edge), therefore the with a low credibility of inter polated pixel P2di moved in space.
Finally, in step 340, motion compensation mixing module 300, for according to time interpolator pixel P3di, space inter polated pixel P2di, time motion-vector quality index I3di and sawtooth index Ij, produces a motion compensation pixel PMCDi to this pixel Pxy to be compensated.Motion compensation mixing module 300 can be according to time motion-vector quality index I3di and sawtooth index Ij, be chosen to be time interpolator pixel P3di or space inter polated pixel P2di one of them as this motion compensation pixel PMCDi; Or can determine a weighted number α by time motion-vector quality index I3di and sawtooth index Ij, time interpolator pixel P3di and space inter polated pixel P2di are weighted to average computation, to produce this motion compensation pixel PMCDi.So the motion compensation pixel PMCDi of this case invention preferred embodiment determines to adopt the latter's mode, and formula is as follows:
PMCDi=α*P3di+(1-α)*P2di
α=f (I3di, Ij)=min max (a*I3di – b*Ij, 0,1) wherein
The explanation of the invention described above preferred embodiment, is motion compensation release of an interleave image processor and method, is considering the impact of picture moving, for generation of the pixel value of pixel to be compensated in.If but add the mechanism of static compensation, and in the situation of picture still, have better compensation effect, refer to following explanation.
Please refer to Fig. 9, it illustrates the functional block diagram of the release of an interleave image processor 90 with motion compensation of another preferred embodiment of the present invention.Similarly, release of an interleave image processor 90 is for converting the field of interlacing (interlaced scan) to the frame of P-SCAN (progressive scan), the odd-numbered line lacking in the odd field of soon staggered processing of meaning or even field or the pixel interpolation of even number line generate, and are reduced into a complete frame.Release of an interleave image processor 90 comprises motion compensation module 910, static compensation module 920, mobile detection module 930 and release of an interleave mixing module 940.For more clearly demonstrating the present invention's running, please separately with reference to Figure 10, it illustrates the release of an interleave image processing flow chart with motion compensation of another preferred embodiment of the present invention.First, in step 1010, motion compensation module 910, for generation of a motion compensation pixel PMCDi, comprises any consideration time or space and moves factor, the method for the motion compensation pixel that produces.The devices and methods therefor that this motion compensation pixel PMCDi can be disclosed by earlier figures 2 and Fig. 3 is produced, but is not limited to this mode.Then,, in step 1020, static compensation module 920 and mobile detection module 930 produce respectively a static compensation pixel PSCDi and and move index Im.Finally, in step 1030, release of an interleave mixing module 940, according to motion compensation pixel PMCDi, static compensation pixel PSCDi and mobile index Im, produces a release of an interleave pixel PDi.
In more detail, please refer to 1 Figure 11, it has illustrated and has produced the detail flowchart that a static compensation pixel PSCDi and moves index Im.In step 1022, static compensation module 920 select this wait mend pixel Pxy previous field Fn-1 or after the pixel of a Fn+1 same position, as this static compensation pixel PSCDi; Or the pixel average of calculating previous field Fn-1 and a rear Fn+1 same position, as this static compensation pixel PSCDi.In step 1024, mobile detection module 930, according to the related pixel of this pixel Pxy to be mended, moves index Im to produce this.Preferred embodiment of the present invention, for calculating the difference of the pixel of previous field Fn-1 and a rear Fn+1 same position, is moved index Im as this, and calculating formula is as follows:
Im=|Pn-1–Pn+1|
Another embodiment of the present invention is the mobile index being calculated as according to this pixel Pxy to be mended at least one related pixel around and in field, front and back, calculates this and moves index Im.Wherein in the present embodiment, related pixel is this pixel Pxy lastrow to be mended and next line par position surrounding pixel (Pxy-1, n, Px-1y-1, n, Px+1y-1, n, Pxy+1, n, Px-1y+1, n, Px+1y_1, n), and the surrounding pixel (Pxy of previous field and a rear same position, n-1, Px-1y, n-1, Px+1y, n-1, Pxy, n+1, Px-1y, n+1, Px+1y, n+1), calculating formula is as follows:
Ixy,n=β*Ixy,n-2+(1-β)*|Pxy,n-1–P?xy,n+1|
Im,xy,n=avg(Ixy-1,n,Ix-1y-1,n,Ix+1y-1,n,Ixy+1,n,Ix-1y+1,n,Ix+1y+1,n,Ixy,n-1,Ix-1y,n-1,Ix+1y,n,Ixy,n+1,Ix-1y,n+1,Ix+1y,n+1)
As mobile index Im hour, being illustrated in continuous pictures this, to treat that inter polated pixel Pxy is positioned at the possibility of stagnant zone high, therefore static compensation pixel PSCDi's is with a high credibility; On the contrary, when mobile index Im is large, being illustrated in continuous pictures this, to treat that inter polated pixel Pxy is positioned at the possibility of moving area high, therefore static compensation pixel PSCDi's is with a low credibility.
In addition, in preferred embodiment of the present invention, release of an interleave mixing module 940 is when determining release of an interleave pixel, according to mobile index Im, determine a weighted number β, then motion compensation pixel PMCDi and static compensation pixel PSCDi are weighted to average computation, to produce this release of an interleave pixel PDi.Computing formula is as follows:
PDi=γ*PMCDi+(1-γ)*PSCDi
γ=f (Im) wherein
But release of an interleave mixing module 940 can be according to moving hand Im, be chosen to be motion compensation pixel PMCDi or static compensation pixel PSCDi one of them as this release of an interleave pixel PDi.So, the mode of above-mentioned generation release of an interleave pixel PDi, is only two better enforcement aspects, not as restrictive condition of the present invention.
The foregoing is only preferred embodiment of the present invention, all equalizations of doing according to the present patent application the scope of the claims change and modify, and all should belong to covering scope of the present invention.
Claims (8)
1. a release of an interleave image processor with motion compensation, this device includes:
One motion compensation module, according to after one on the scene until of inter polated pixel a, previous field and one one, produces a motion compensation pixel at least;
One static compensation module, for according to this after this previous field of inter polated pixel and this one, produces a static compensation pixel;
One moves detection module, for treat the related pixel of inter polated pixel according to this, produces one and moves index; And
One release of an interleave mixing module, for moving index according to this, is weighted average computation to this motion compensation pixel and this static compensation pixel, produces this and treats inter polated pixel.
2. release of an interleave image processor as claimed in claim 1, is characterized in that, this motion compensation module includes:
One time motion compensation module, for according to this after this previous field of inter polated pixel and this one, produces a time interpolator pixel and a time motion-vector quality index;
One space motion compensation module, on the scene for treat this institute of inter polated pixel according to this, produce a space inter polated pixel and a sawtooth index; And
One motion compensation mixing module, for according to this time interpolator pixel, this space inter polated pixel, this time motion-vector quality index and this sawtooth index, produces this motion compensation pixel.
3. release of an interleave image processor as claimed in claim 1, is characterized in that, this static compensation module select this until this previous field of inter polated pixel or after this same position pixel one of them for this static compensation pixel.
4. release of an interleave image processor as claimed in claim 1, is characterized in that, this moves detection module, and relatively this,, until this previous field of inter polated pixel and the pixel of a same position after this, moves index to produce one.
5. a release of an interleave image treatment method with motion compensation, the method includes:
At least, according to after one on the scene until of inter polated pixel a, previous field and one one, produce a motion compensation pixel;
According to this after this previous field of inter polated pixel and this one, produce a static compensation pixel;
According to this, treat the related pixel of inter polated pixel, produce one and move index; And
According to this, move index, this motion compensation pixel and this static compensation pixel are weighted to average computation, produce this and treat inter polated pixel.
6. release of an interleave image treatment method as claimed in claim 5, is characterized in that, this step that produces this motion compensation pixel also comprises:
According to this after this previous field of inter polated pixel and this one, produce a time interpolator pixel and a time motion-vector quality index;
The field for the treatment of inter polated pixel according to this, produces a space inter polated pixel and a sawtooth index; And
According to this time interpolator pixel, this space inter polated pixel, this time motion-vector quality index and this sawtooth index, produce this motion compensation pixel.
7. release of an interleave image treatment method as claimed in claim 5, is characterized in that, this step that produces this static compensation pixel also comprise select this until this previous field of inter polated pixel or after this same position pixel one of them be this static compensation pixel.
8. release of an interleave image treatment method as claimed in claim 5, is characterized in that, this produces this step until inter polated pixel and also comprises relatively this until this previous field of inter polated pixel and the pixel of a same position after this, to produce one, moves index.
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CN101189871A (en) * | 2005-05-23 | 2008-05-28 | Nxp股份有限公司 | Spatial and temporal de-interlacing with error criterion |
CN101600061A (en) * | 2009-07-09 | 2009-12-09 | 杭州士兰微电子股份有限公司 | De-interlaced method of video motion-adaptive and device |
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