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On Interpolation Methods using Statistical Models

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Title: On Interpolation Methods using Statistical Models


1
On Interpolation Methods using Statistical Models
  • RONEN SHER
  • Supervisor MOSHE PORAT

2
Outline
  • Black White image interpolation
  • Motivations
  • Concepts
  • Flow
  • Results
  • 1D Signal interpolation
  • CCD Demosaicing
  • Structure
  • Methods Overveiw
  • Components correlation
  • Statistical extension
  • Results
  • Summary

3
The Interpolation Problem
  • Factor of 2

Input
Output
4
Image Interpolation Methods
  • Nearest Neighbor
  • Bilinear
  • Bi-Cubic
  • Spline

5
Motivations 1 Pixels Correlation
  • Normalized histograms of Lena (gray Levels)
  • 256x256-dashed 512x512-solid

6
Motivations 2 Image Compression Results
Compression rates in bits/sample
7
Proposed Approach
8
Approaching the problem
Near Lossless Compression Scheme
9
Lossless Compression predictors
10
Lossless Compression - Context modeling
  • The error value is subtracted from the average
    error in a given context

Horizontal edge
Vertical edge
11
Outline
  • Black White image interpolation
  • Motivations
  • Concepts
  • Flow
  • Results
  • 1D Signal interpolation
  • CCD Demosaicing
  • Structure
  • Methods Overview
  • Components correlation
  • Statistical extension
  • Results
  • Summary

12
Image Regions
  • In regions of edges, averaging will result in a
    smoothing effect.
  • The edge must be preserved.
  • The edges exist in the input image and the same
    distribution is assumed in the larger
    interpolated image.

13
Image Regions
  • In case of a horizontal edge

14
Pixels fitting
From Lena 256x256
15
Image Regions
  • In each region a different weighted sum is valid
    for the prediction
  • The coefficients
  • are learned from the input image

16
Outline
  • Black White image interpolation
  • Motivations
  • Concepts
  • Flow
  • Results
  • 1D Signal interpolation
  • CCD Demosaicing
  • Structure
  • Methods Overveiw
  • Components correlation
  • Statistical extension
  • Results
  • Summary

17
Step 1 Coefficients calculation
  • Scanning the Input Image
  • for the x type pixel we determine its
    permutation from its four neighbors and save its
    value and its neighbors values in VMx
  • Modeling only the regions
  • with significant changes
  • in gray levels
  • Same treatment for the type pixels

18
Step 1 Coefficients calculation
  • For each permutation we find the four
    coefficients using the Least Square solution
  • Same technique for the coefficients

19
Step 2a x type Reconstruction
  • Scanning the sparse Image, for each pixel we
  • determine its matching
  • permutation (coefficients)
  • from its four neighbors and predict its value
  • using

20
Step 2b type Reconstruction
  • The Input is Ix, for each pixel
    we find its matching permutation
    (coefficients) and calculate
    its prediction by

21
Experiments - Lena
  • The 4 coefficients in 24 cases of x-type

a2
a1
a4
a3
Errors
  • Lena size 512x512
  • Lena size 256x256

22
Example 1 - BW images (128x128-gt256x256)
Original
Bilinear
Nearest neighbor (Input)
Proposed
Bi-Cubic Spline
Bi-Cubic
23
Example 2 - BW images (128x128-gt256x256)
Original
Bilinear
Nearest neighbor (Input)
Proposed
Bi-Cubic Spline
Bi-Cubic
24
Outline
  • Black and White image interpolation
  • Motivations
  • Concepts
  • Flow
  • Results
  • 1D Signal interpolation
  • CCD Demosaicing
  • Structure
  • Methods Overveiw
  • Components correlation
  • Statistical extension
  • Results
  • Summary

25
One-Dimensional Interpolation
Interpolating yd, using NR. Its adjacent samples
serve as the four neighbors for the coefficients
calculation.
26
Synthetic Test Signal
  • y1sin(r.(53.sin(2.(r0.7)))).sin(7.(r0.9))
  • t11,2..N1
  • r(t1OS1)/100
  • N12400
  • f11
  • Ts2
  • OS13000
  • L2

27
1D Interpolation result 1
28
1D Interpolation result 2
Voice signal the word Diskette
29
Outline
  • Black and White image interpolation
  • Motivations
  • Concepts
  • Flow
  • Results
  • 1D Signal interpolation
  • CCD Demosaicing
  • Structure
  • Methods Overveiw
  • Components correlation
  • Statistical extension
  • Results
  • Summary

30
CCD structure
31
CCD Demosaicing Methods
  • Bilinear
  • Kimmel - gradient based function and hues
    R/G,B/G.
  • Gunturk data consistency and similarity between
    the high-frequency components.
  • Muresan - interpolates R-G,B-G.
  • Not Linear
  • Changing the Input

32
Basic Method
  • Treating each color component as an individual
    BW image

Original
Bilinear
Proposed
33
Basic Method Aliasing Effect
Original
Bilinear
Basic Method
34
Components method
  • Using all colors neighbors for the green
    reconstruction.
  • Reconstructing the difference of the colors
    components Hues (R-G, B-G, R-B). Processing
    smoother signals.

35
Statistical generalization
  • Separating each case to sub-regions for better
    characterization.
  • Using the mean and the standard deviation of each
    neighbors set for the division (size invariant).
  • Each Sub-region will have its own coefficients
    better representation of the region.

36
Case Study
From Light-House
  • Maximal Size Region

37
Case Study 2
  • 1 Region
  • 14 Sub-Regions
  • 98 Sub-Regions
  • 140 Sub-Regions
  • 196 Sub-Regions

38
Results 1 (384x256)
Original
Bi-Linear
Gunturk
Optimal Numeric Values s 2 divisions E 7
divisions
Optimal recovery
Kimmel
Neighbors Rule
39
Results 2 (384x256)
Original
Bi-Linear
Gunturk
Optimal recovery
Kimmel
Neighbors Rule
40
Summary
  • A new interpolation method has been presented for
    1D signals, BW images and CCD color demosaicing
    based on the correlation between low and high
    resolution versions.
  • A non linear localized method was developed to
    overcome the artificial effects caused from under
    sampling.
  • The proposed method outperforms the traditional
    scheme in terms of MSE.
  • Good results has been achieved in 2D
    interpolation and CCD demosaicing.

41
Appendix
42
Comparison Basic vs. Components
43
Mean and STD histograms
Mean
STD
Green
-- 192x128 -- 384x256
From Light-House
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