de interlacing techniques
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De-Interlacing Techniques
Ramesh Prasad
Introduction
• De-interlacing is the process of converting interlaced video, such as common analog television signals or 1080i format HDTV signals, into a non-interlaced form.
• Interlaced video frame consists of two sub-fields taken in sequence, each sequentially scanned at odd and even lines of the image sensor; analog television employed this technique because it allowed for less transmission bandwidth and matched the properties of CRT screens.
• However, most current displays are inherently progressive, so the two fields need to be combined to a single frame, which leads to various visual defects which the de-interlacing process should try to avoid.
Introduction
Progressive Frame
Odd Field Even Field
Introduction• Interlacing is a form of “Spatio-temporal” sub sampling• De-interlacing is the reverse operation, aiming at removal of sub-
sampling artifacts• For stationary pictures (no camera or object motion or intensity
changes) the de-interlacing is trivial as alternating even and odd fields completely describe the captured scene
• However, for pictures with camera/object motion and intensity changes (which always is the case with real life scenario); de-interlacing becomes non-trivial and entails processing, as it requires interpolation of picture data that was never transmitted or even captured.
• A good de-interlacing algorithm should try to avoid interlacing artifacts as much as possible and not sacrifice image quality in the process.
Introduction
Techniques for De-Interlacing
• Intra field de-interlacing• Inter field de-interlacing• Spatio-Temporal Interpolation• Motion adaptive de-interlacing• Motion compensated de-interlacing
Intra field de-interlacing - Overview
• Based on Spatial filtering• Exploits the correlation between vertically
neighboring samples in a field when interpolating intermediate pixels
• They have all pass temporal frequency response which guarantees the absence of motion artifacts
• Low computational cost• Loss of vertical details and artifacts when the
object exists in only one parity field
Intra field de-interlacing – Scan line duplication (Bob)
• The missing line is generated by duplicating the line directly above it
• Cons-– Jagged effect will occur
in the oblique line – flicker – Blur
Intra field de-interlacing – Scan line duplication (Bob)
Flicker
Flicker
Jagged Effect
Intra field de-interlacing – Scan line interpolation
• The missing line is generated by taking the average of the lines vertically above and below it
• Less blur, flicker and jagging than scan line duplication method
Intra field de-interlacing – Edge Line Average (ELA)
• Interpolation is done in the direction of edge
• Three pixels in the previous scan line and the next scan line are referenced to determine the obvious edge in the image
• This method can eliminate the blurring effect of the bilinear interpolation and gives sharp/straight edges.
Intra field de-interlacing – Edge Line Average (ELA)
Inter field de-interlacing - Overview
• Based on Temporal filtering• Exploits the correlation between temporally
neighboring samples between fields when interpolating intermediate pixels
• They have all pass spatial frequency response which guarantees the absence of artifacts for stationary pictures
• Low computational cost but require additional field memory
• Artifacts in areas where motion occurs
Inter field de-interlacing – Field Insertion (Weave)
• The two fields are “woven” into one frame
• It is best solution in case of still images as all vertical frequencies are preserved
• If there is motion between the even and odd fields being woven; artifact called serration or mouse teeth occurs because the moving objects are not shown at the same position for even and odd lines of the single output frameOdd Field Even Field
Inter field de-interlacing – Field Insertion (Weave)
Bob Weave
Difference between Bob and Weave
Inter field de-interlacing – Field Insertion (Weave)
Mouse Teeth Artifact
Inter field de-interlacing – Temporal Averaging
• Types -– Mean –
• Display a half-picture that is created as the average of the two original half-pictures• The Mean algorithm simply pairs the original lines, and averages each pair into one output line.
Line 1 of output is the mean of lines 1 and 2 in input, line 2 of output is the mean of lines 3 and 4 in input, and so on.
– Blend – • Each line of the picture is created as the average of a line from the odd and a line from the
even half-pictures. • This ignores the fact that they are supposed to be displayed at different times • The first line of output is copied from the first line of input. For any other output line N, the line
is the mean of input lines N and N-1. That is, the second line of output is the mean of lines 1 and 2 in input, the third line is the mean of lines 2 and 3, ... and finally, the last line of output is the mean of the last two lines in input. The sliding averaging procedure preserves the original vertical resolution.
• Pros – Mouse Teeth artifact is avoided• Cons – Artifact called ghosting is introduced
Inter field de-interlacing – Temporal Averaging
Ghosting Artifact
Spatio-Temporal Interpolation - Overview
• Based on Spatio-Temporal filtering• Exploits the correlation between both spatially and temporally
neighboring samples when interpolating intermediate pixels• The filter is usually designed such that the contribution from
the neighboring fields is limited to the higher vertical frequencies
• Hence, motion artifacts are absent for objects without vertical details that move horizontally
• The vertical detail from the previous field is being combined with the temporally shifted current field, so some motion artifacts may occur.
Spatio-Temporal Interpolation
Motion adaptive de-interlacing - Overview
• It combines the advantages of both intra-field and inter-field interlacing
• It detects the motion first, and then adopts intra field de-interlacing in motion areas and inter-field de-interlacing in static areas
• High resolution and flicker free picture can be realized in motion and static area
• It relies on accurate motion detection; erroneous detection cause artifacts
Motion adaptive de-interlacing
Motion adaptive de-interlacing
• The motion detection block detects the motion between the two fields
• The output of the motion detection block controls the selector switch for the intra or inter interpolated values
• For moving image parts, intra interpolated values are passed and for static image parts inter interpolated values are passed
• Finally an interleaving switch interleaves the current field and the interpolated sample to form the progressive frame
• The intra and inter interpolation mechanism could be any of the techniques described earlier
Motion adaptive de-interlacing
• Instead of a switch, a fade mechanism could be used which combines the intra and inter interpolated samples
• Fst is the result of interpolation for static image parts• Fmot is the result of interpolation for moving image
parts• Motion detector determines the mix factor “alpha”
with “alpha” = 0 for very high motion and “alpha” = 1 in absence of motion
Motion adaptive de-interlacing – Motion Detection
• Same-parity-field detection– For interlaced video, the vertical position of even
field and odd field is slightly different– Same-parity-field detection detects the motion
area by the even-field to even-field or odd-field to odd-field difference
Motion adaptive de-interlacing – Motion Detection
Motion adaptive de-interlacing – Motion Detection
• 4-Field motion detection– To improve the accuracy of motion detection, 4
fields rather than 2 fields are used– The fields are labeled backward, current, forward
and forward-forward– The differences are computed for fields of same
parity; backward-forward and current-forward-forward
Motion adaptive de-interlacing – Motion Detection
Motion adaptive de-interlacing – Motion Detection
Motion adaptive de-interlacing – Implicit Adaptation (Median Filtering)
• Median Filtering adapts implicitly to motion• The simplest version is a 3-tap spatio-temporal filter which uses the
immediate vertical up, down and temporal neighbor in the previous field
• The underlying assumption is that in case of stationarity, the temporal neighbor is likely to have a value between that of the vertical neighbors of the current field
• In case of motion, intra-field interpolation is likely to result, since the correlation between the samples in the current field is likely to be highest
• Hence Median filtering automatically realizes the intra/inter switch• Pros: Superior properties at vertical edges and low hardware cost• Cons: Distortion of vertical details and introduction of alias
Motion adaptive de-interlacing – Implicit Adaptation (Median Filtering)
Motion compensated de-interlacing - Overview
• It’s the most advanced technique for interpolation• Motion compensated method try to interpolate in the direction with highest
correlation; with motion vector available, this is the interpolation along the motion trajectory
• It allows the moving sequences to be converted virtually into stationary ones and use methods which work well on stationary sequences like line insertion etc.
• Motion compensated methods needs to be combined with scene change detection, otherwise it will attempt to find motion between two completely different scenes
• Usually a combination of Edge directed spatial interpolation and motion compensated temporal interpolation is used in practice
• It outperforms other techniques in terms of quality of the de-interlaced frame• It’s the most complex and processing intensive technique as it involves motion
estimation
Motion compensated de-interlacing
Motion compensated de-interlacing
• Motion estimation is performed on the fields of same parity (backward and forward fields) as they have the same sampling grid
• Half pel/quarter pel accuracy can be used for motion estimation• As the backward and forward fields are of different parity than
the current field, the blocks need to be shifted to the sampling grid of the current field
• To obtain the position of the block in the current interpolated field from the previous field, the motion vectors are halved and the blocks of backward, current and forward field moved simultaneously to the sampling grid of the current interpolated field
Motion compensated de-interlacingBlock shifting to match the sampling grid
Pixel value in the current interpolated field
Motion compensated de-interlacing
• To handle scene change detection, the pixel values obtained by motion compensated interpolation are compared with the spatial edge directed interpolated pixel values
• If the difference is beyond the threshold value, its assumed that interpolation based on motion estimation is incorrect
• In such case, directional interpolation is used instead of motion compensated interpolation
• The motion compensated/edge directed interpolated pixels are finally combined to get the progressive frame
References
• Altera White Paper - High-Definition Video Deinterlacing Using FPGAs
• Deinterlacing - An Overview– GERARD DE HAAN, ERWIN B. BELLERS
• Deinterlacing using directional interpolation and motion compensation– Ohjae Kwon, Kwanghoon Sohn, Chulhee Lee
• Motion Adaptive Interpolation with Horizontal Motion Detection for Deinterlacing– Shyh-Feng Lin, Yu-Ling Chang, and Liang-Gee Chen
Thank You
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