CN1622614A - Deinterlace method and deinterlace algorithm generating method - Google Patents

Abstract

The interleaving eliminating dynamic modulation algorithm includes the following steps: generating one characteristic difference based on the first segment datan and the second segment data; determining the mixing coefficient based on the characteristic difference; and generating dynamic modulation based on the mixing coefficient to eliminate interleaving. The mixing coefficient decides the proportion of the first interleaving eliminating algorithm in the interleaving eliminating dynamic modulation algorithm, while the different between the mixing coefficient and one constant decides the second interleaving eliminating algorithm in the interleaving eliminating dynamic modulation algorithm. In addition, the interleaving eliminating method executes the interleaving eliminating dynamic modulation algorithm to generate interleaving eliminating processed image.

Description

De-interlacing methods and deinterlace algorithm production method

Technical field

The present invention relates to a kind of de-interlacing methods and deinterlace algorithm production method, particularly a kind ofly can produce the deinterlace algorithm production method of dynamic modulation deinterlace algorithm and the de-interlacing methods that utilizes dynamic modulation deinterlace algorithm.

Background technology

When video industry when simulation is transferred to numeral, present video processing equipment must have the function that analog signal is transferred to digital signal mostly.With the scanning standard (standard) of present simulated television, main adopt two kinds of National Television StandardsCommittee (NTSC) and Phase Alternation by Line (PAL) are arranged.The NTSC mode is to constitute a frame (frame) with 525 scan line, or is called picture, just with 1 second 30 frame (picture) speed repeat to show, and reappear a picture in interleaved mode.In other words, after the 1st scan line finished, be right after and what come is not the 2nd line, but carry out with 3,5,7 order, until the 525th line, and then get back to the 2nd line, repeat with 4,6,8 order then, therefore in fact obtaining smooth and frame (picture) clearly, is that the mode by odd-numbered scan lines, even-line interlace line, odd-numbered scan lines constitutes editor (Format) mode that Here it is " interlacing scan " is also referred to as " interlacing (Interlacing) ".

Interlace video signal is made up of two visual fields (field), and wherein each visual field only comprises the odd-numbered scan lines of image or the even-line interlace line of image.In the process of carrying out picture catching (imagecapture), the telephotography chance one moment output image odd-numbered scan lines, then after 16.7 milliseconds, the even-line interlace line of output image again.Between the process of the odd-numbered scan lines of output image and even-line interlace line, can produce the displacement (temporalshift) of a time, it must be positioned in the system that handles with frame benchmark (frame based).Yet this mode can produce the image of zigzag (serration) in edge of image for the dynamic image picture with mobile attribute, promptly so-called " burr " phenomenon.In addition, because odd number visual field and even number visual field are made up of the scan line (i.e. 263/262 line) of half, therefore each odd number visual field and even number visual field have only half resolution (resolution) of original image, and each odd number visual field and even number visual field are to show with 1/60 second speed.Such picture is with human eye, though be unlikely to allow the vision of human eye feel not nature (motion artifacts), picture can feel that just scan line is thick in case amplify, even can feel fuzzy pictures.

Aforementioned these shortcomings when carrying out " interlacing " or " interlacing scan " can be solved by the technology of a kind of being called " (progressive scan) lines by line scan " now." line by line scan " is continuously to 525 lines with 1,2,3, once order is depicted all scan lines, and the speed with 1 second 60 picture is reappeared, therefore its sweep speed is the twice of " interlacing scan ", thereby picture is with 525 scan line display frames on display, so picture very thin and clear, this is " lining by line scan " biggest advantage, and therefore advanced at present audio-visual devices has adopted this mode to come scanner uni to show mostly.

Yet, the picture signal of existing NTSC system, up to the present, the mode that is still employing " interlacing " is main, therefore if the picture that interlacing is formed is when the display system of " lining by line scan " shows,, directly goes up and play and when showing at high definition TV (HDTV) for example with a DVD film of compiling via interlacing, therefore the picture that then can only show odd number visual field and even field can make the resolution variation (because of having only half resolution of original image) of image.Be head it off, just must use the technology of " deinterleave (De-interlace) " to overcome, in other words, " deinterleave " is exactly to convert interlacing to line by line scan a kind of method.For example standard definition television (Standard Definition TV:SDTV) is converted to high definition TV (High Definition TV; HDTV) time, it utilizes deinterleave and two steps of taking a sample again, scan line is promoted to 720 line by line scan (720p) by 480 interlacings (480i), and the alignment error the when interlaced image of revising odd-numbered scan lines and even-line interlace line merges is to be created in the sequential picture that visually can make the people satisfied.

As previously mentioned, on progressive-scan system, show the lack of resolution problem that is produced though use the technology of deinterleave can solve the interlacing system, but the situation of can not ignore is arranged equally, be exactly that the image of playing is always moving, if ignore this point, actually the odd number visual field is overlapped with the even number visual field, then the still image part can obtain distinct image, but the part to dynamic image then equally has fuzzy and factitious phenomenon, so high image quality just can not show.For this reason, deinterleave handle technical, have two kinds of rudimentary algorithms to select, promptly do not have motion compensation (non-motion compensated) and motion compensation (motion-compensated).Wherein, no motion compensation deinterlace algorithm comprises two kinds of linear transformation technology the most basic, is respectively braiding (Weave) and swing (Bob); Braiding is imported visual fields overlapping (overlaid) with two or is woven together, to produce a sequence frames, braiding is for tableaux, the image of different visual fields can be aimed at fully, thereby can obtain a not clear deinterleave image of decay, but edge at moving image, but can demonstrate tangible zigzag or burr, this is because dynamic menu can produce displacement along with the time, so when odd number visual field and even number visual field are woven into a frame, will be because of between odd number visual field and the even number visual field time displacement being arranged, thereby when odd number visual field and even number visual field are woven together, will occur having the fuzzy frame of zigzag or burr because of producing the image alignment error, this phenomenon as shown in Figure 1.On the other hand, a wherein visual field (for example only accepting the image of even-line interlace line) of input picture is only accepted in swing, another visual field (being the image of odd-numbered scan lines) then is dropped (discarded), so picture can be reduced to 720 * 243 pixels from 720 * 486 pixels (pixel) in the resolution sizes of vertical direction.This has only the image of a half-resolution, will remove to fill up the void space (voids) of another line by adjacent scanning lines, so that 720 * 486 pixels are got back in image interpolation; The advantage of swing is that it can overcome not the picture of action (motionartifacts) naturally, and less computation requirement is arranged, but its shortcoming be the vertical resolution of picture through after the interpolation, still have only half of original image, therefore the thin portion resolution of order picture has just reduced.

Because existing Video CD (DVD) still is to use the captured picture editting of interlacing system to form, constitute a picture so still must see through staggered the processing during its playing image, therefore when the digit television broadcasting that uses high-fidelity (Hi-Fi) is given out light dish, play for interlacing being converted to progressive scan mode, must on playing device, select to play with the braiding or the method for swing.Yet,, can produce the image alignment error for the image that moves, so the zigzag or the picture of burr can occur when selecting " braiding " when mode is play; And when selecting " swing " when mode is play, though can overcome the image alignment error of mobile image, make the dynamic image can be more clear and natural, but sacrificed the vertical resolution of still image, therefore between the existing video-audio playing system and digital display system, in the process of handling through deinterleave, can't take into account the image quality of dynamic menu and tableaux.

Summary of the invention

Because above-mentioned problem the invention provides a kind of deinterlace algorithm production method that can produce a dynamic modulation deinterlace algorithm, its step comprises: at first, produce a feature difference according to first segment data and second segment data; Then, the size according to feature difference determines a mixed coefficint; Produce dynamic modulation deinterlace algorithm according to mixed coefficint then.In the present invention, mixed coefficint determines the proportion of first deinterlace algorithm in dynamic modulation deinterlace algorithm, and the difference of a mixed coefficint and a constant determines the proportion of second deinterlace algorithm in dynamic modulation deinterlace algorithm.Wherein, first deinterlace algorithm is braiding (Weave) algorithm, and second deinterlace algorithm is swing (Bob) algorithm.

The present invention also proposes a kind of de-interlacing methods, and its step comprises: at first, produce a feature difference according to first segment data and second segment data; Then, the size according to feature difference determines a mixed coefficint; Produce a dynamic modulation deinterlace algorithm according to mixed coefficint again, wherein mixed coefficint determines the proportion of first deinterlace algorithm in dynamic modulation deinterlace algorithm, and the difference of a mixed coefficint and a constant determines the proportion of second deinterlace algorithm in dynamic modulation deinterlace algorithm; Then, carry out dynamic modulation deinterlace algorithm, to produce the image of handling once deinterleave.Wherein, first deinterlace algorithm is the braiding algorithm, and second deinterlace algorithm is the swing algorithm.

From the above, because of producing the adaptive dynamic modulation deinterlace algorithm of tool according to de-interlacing methods of the present invention and deinterlace algorithm production method, so can solve between existing video-audio playing system (for example DVD Player) and the digital display system (for example HDTV or plasma-screen television), in the process that deinterleave is handled, only simple use braiding algorithm or the swing algorithm selected carries out deinterleave, and can't take into account the problem of the image quality of dynamic image and still image, make the output image image quality get a promotion.

Description of drawings

Fig. 1 is a schematic diagram, show known according to the braiding deinterlace algorithm obtained have a jagged sequence frames;

Fig. 2 is a flow chart, shows the flow process according to the de-interlacing methods of preferred embodiment of the present invention;

Fig. 3 A is a schematic diagram, shows the brightness value of the pixel of frame with several line segments and each line segment;

Fig. 3 B is a schematic diagram, shows the characteristic value of each line segment as shown in Figure 3A;

Fig. 3 C is a schematic diagram, shows the feature difference of each line segment shown in Fig. 3 B, and it is the feature difference of two line segments adjacent in the same number of frames;

Fig. 3 D is a schematic diagram, shows the feature difference of each line segment shown in Fig. 3 B, and it is for being positioned at the feature difference of two line segments of same position in the different frame;

Fig. 4 A is a flow chart, shows the flow process that determines the step of mixed coefficint according to the size of feature difference;

Fig. 4 B is a schematic diagram, shows according to the number range of feature difference and the relation of mixed coefficint; And

Fig. 5 is a schematic diagram, shows the dynamic modulation deinterlace algorithm of trying to achieve according to present embodiment and the output valve of each pixel.

The element numbers explanation:

31 frames

311 ~ 318 line segments

32 frames

321 ~ 328 line segments

The step of S01 ~ S04 de-interlacing methods

S11 ~ S12 is according to the step of the size decision mixed coefficint of feature difference

Embodiment

Hereinafter with reference to relevant drawings, de-interlacing methods and deinterlace algorithm production method according to preferred embodiment of the present invention are described.

Please refer to shown in Figure 2, de-interlacing methods according to preferred embodiment of the present invention may further comprise the steps: at first, produce a feature difference (step S01) according to first segment data and second segment data, wherein, first segment data comprises the characteristic value of first line segment, second segment data comprises the characteristic value of second line segment, and feature difference is the difference of the characteristic value of the characteristic value of first line segment and second line segment, at this first line segment and second line segment can be two line segments that are positioned at same position in two line segments adjacent in the same number of frames (intra-frame) or the different frame (inter-frame), and the characteristic value of each line segment can be brightness value (Y value) and/or chromatic value (Cr value according to the pixel that constitutes each line segment, the Cb value) calculating is tried to achieve; For example, as shown in Figure 3A, picture displayed can be odd number visual field or even number visual field in a certain frame 31, and comprising several line segments 311-318, it is made of several pixels respectively, and the Y value in each pixel is shown in the numeral in each line segment, at this moment, the characteristic value of line segment 311-318 can utilize Y value sum to represent, in detail, the characteristic value of line segment 311 be wherein each pixel the Y value and, be shown below:

Characteristic value=the 12+66+72+85=235 of line segment 311

In addition, picture displayed can be odd number visual field or even number visual field (as shown in Figure 3A) equally in another frame 32, comprising several line segments 321-328, it is made of several pixels respectively, and the Y value in each pixel is shown in the numeral in each line segment, and the characteristic value of line segment 321-328 can also utilize Y value sum to represent; At this moment, in frame 31 and the frame 32 characteristic value of each line segment shown in Fig. 3 B.As mentioned above, in step S01, if first line segment and second line segment are two adjacent in same number of frames line segments, for example be the line segment 311 and line segment 312 in the frame 31, then the feature difference that is produced is (235-212)=23 (shown in Fig. 3 C), and the feature difference of other line segment is the numerical value that obtains according to same way as calculating shown in Fig. 3 C in the frame 31; In addition, if first line segment and second line segment are two line segments that are positioned at same position in the different frame, it for example is the line segment 321 in line segment 311 and the frame 32 in the frame 31, then the feature difference that is produced is (235-163)=72 (shown in Fig. 3 D), and the feature difference of other line segment is the numerical value that obtains according to same way as calculating shown in Fig. 3 D in the frame 31.

Then, the size according to feature difference determines a mixed coefficint (step S02); Wherein, mixed coefficint is between 0 and one constant, and the constant of present embodiment is set at 1, so mixed coefficint is between 0 and 1; For example, the size according to feature difference determines the method for mixed coefficint to be based on following principle among the step S02: when feature difference was big more, mixed coefficint was more near 0; When feature difference more hour, mixed coefficint is more near 1 (being constant).For making present embodiment be more prone to clear, shown in Fig. 4 A and 4B, explanation is according to the step of the size decision mixed coefficint of feature difference, comprise and set n threshold value that successively decreases in regular turn, defining continuous n+1 numerical value section (step S11), and determine different compensation characteristic curves by this; And which numerical value section the judging characteristic difference be positioned at, with decision mixed coefficint (step S12) (shown in Fig. 4 A).Then shown in Fig. 4 B, the threshold value that sets in the present embodiment has 8, be respectively 80 in regular turn, 70,60,50,40,30,20,10, so be respectively (greater than 80) by the numerical value section that these threshold values defined, (between 80 and 70), (between 70 and 60), (between 60 and 50), (between 50 and 40), (between 40 and 30), (between 30 and 20), (between 20 and 10), and (less than 10), at this moment, when feature difference was positioned at x numerical value section, the mixed coefficint of being tried to achieve can utilize following formula to calculate:

Wherein n is the quantity of the threshold value that sets, shown in Fig. 4 B, the mixed coefficint of corresponding above-mentioned numerical value section is respectively 0, $\frac{1}{8},\frac{2}{8},\frac{3}{8},\frac{4}{8},\frac{5}{8},\frac{6}{8},\frac{7}{8},$ 1。

Then, produce a dynamic modulation deinterlace algorithm according to mixed coefficint, wherein mixed coefficint determines the proportion of first deinterlace algorithm in dynamic modulation deinterlace algorithm, and the difference of a mixed coefficint and a constant determines the proportion (step S03) of second deinterlace algorithm in dynamic modulation deinterlace algorithm; In the present embodiment, when constant was 1, dynamically the modulation deinterlace algorithm was determined by following formula:

Dynamic modulation deinterlace algorithm=

Mixed coefficint * first deinterlace algorithm

+ (1-mixed coefficint) * second deinterlace algorithm

Wherein, first deinterlace algorithm is braiding (Weave) deinterlace algorithm, and second deinterlace algorithm is swing (Bob) deinterlace algorithm.So the dynamic modulation deinterlace algorithm of being tried to achieve wherein is noted that when mixed coefficint is 0 as shown in Figure 5, second deinterlace algorithm can also be one to have swing (the Bob with interpolation) deinterlace algorithm of interpolation.In addition, if above-mentioned dynamic modulation deinterlace algorithm is represented that with the output valve (comprising brightness value and/or chromatic value) of each pixel then the output valve of each pixel can be determined (as shown in Figure 5) by following formula:

Output valve (the YC of pixel _Out)=

Output valve (the YC of mixed coefficint * try to achieve according to first deinterlace algorithm ₁)

Output valve (the YC of+(1-mixed coefficint) * try to achieve according to second deinterlace algorithm ₂)

In addition, comprise foregoing step S01-S03 according to the deinterlace algorithm production method of preferred embodiment of the present invention, so repeat no more.

At last, carry out dynamic modulation deinterlace algorithm, to produce the image of handling once deinterleave (step S04).

In sum, owing to can produce the adaptive dynamic modulation deinterlace algorithm of tool (as step S01-S03) according to de-interlacing methods of the present invention and deinterlace algorithm production method, so can solve between existing video-audio playing system (for example DVD Player) and the digital display system (for example HDTV or plasma-screen television), in the process that deinterleave is handled, only simple use braiding algorithm or the swing algorithm selected carries out deinterleave, and can't take into account the problem of the picture quality of dynamic image and still image, make the output image image quality get a promotion.

The above only is an illustrative, but not is restrictive.Anyly do not break away from spirit of the present invention and category, and it is carried out equivalent modifications or change, all should comprise in the appended claims.

Claims (10)

1, a kind of de-interlacing methods comprises:

Produce a feature difference according to first segment data and second segment data;

Size according to described feature difference determines a mixed coefficint;

Produce a dynamic modulation deinterlace algorithm according to described mixed coefficint, wherein said mixed coefficint determines the proportion of first deinterlace algorithm in described dynamic modulation deinterlace algorithm, and the difference of a described mixed coefficint and a constant determines the proportion of second deinterlace algorithm in described dynamic modulation deinterlace algorithm; And

Carry out described dynamic modulation deinterlace algorithm, to produce the image of handling once deinterleave.

2, de-interlacing methods as claimed in claim 1, wherein said first segment data comprises the characteristic value of one first line segment, described second segment data comprises the characteristic value of one second line segment, and described feature difference is the difference of the characteristic value of the characteristic value of described first line segment and described second line segment, and described first line segment and described second line segment are two adjacent in same number of frames line segments or for being positioned at two line segments of same position in the different frame.

3, de-interlacing methods as claimed in claim 1, wherein said mixed coefficint is situated between between 0 and 1, and described constant is 1, and described dynamic modulation deinterlace algorithm is determined by following formula:

Described dynamic modulation deinterlace algorithm=

Described mixed coefficint * described first deinterlace algorithm

+ (the described mixed coefficint of 1-) * described second deinterlace algorithm

4, de-interlacing methods as claimed in claim 1, wherein when described mixed coefficint was 0, described second deinterlace algorithm was the swing deinterlace algorithm that a swing deinterlace algorithm or has interpolation.

5, de-interlacing methods as claimed in claim 1, wherein the size according to described feature difference determines the step of described mixed coefficint to comprise:

Set n threshold value that successively decreases in regular turn, to define continuous n+1 numerical value section;

And

Judge which numerical value section described feature difference is positioned at, to determine described mixed coefficint.

6, a kind of deinterlace algorithm production method comprises:

Produce a feature difference according to one first segment data and one second segment data;

Size according to described feature difference determines a mixed coefficint; And

Produce a dynamic modulation deinterlace algorithm according to described mixed coefficint, wherein said mixed coefficint determines the proportion of first deinterlace algorithm in described dynamic modulation deinterlace algorithm, and the difference of a described mixed coefficint and a constant determines the proportion of second deinterlace algorithm in described dynamic modulation deinterlace algorithm.

7, deinterlace algorithm production method as claimed in claim 6, wherein said first segment data comprises the characteristic value of one first line segment, described second segment data comprises the characteristic value of one second line segment, and described feature difference is the difference of the characteristic value of the characteristic value of described first line segment and described second line segment, and described first line segment and described second line segment are two adjacent in same number of frames line segments or for being positioned at two line segments of same position in the different frame.

8, deinterlace algorithm production method as claimed in claim 6, wherein said mixed coefficint is situated between between 0 and 1, and described constant is 1, and described dynamic modulation deinterlace algorithm is determined by following formula:

Described dynamic modulation deinterlace algorithm=

Described mixed coefficint * described first deinterlace algorithm

+ (the described mixed coefficint of 1-) * described second deinterlace algorithm

9, deinterlace algorithm production method as claimed in claim 6, wherein when described mixed coefficint was 0, described second deinterlace algorithm was the swing deinterlace algorithm that a swing deinterlace algorithm or has interpolation.

10, deinterlace algorithm production method as claimed in claim 6, wherein the size according to described feature difference determines the step of described mixed coefficint to comprise:

Set n threshold value that successively decreases in regular turn, to define continuous n+1 numerical value section;

And

Judge which numerical value section described feature difference is positioned at, to determine described mixed coefficint.

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