Oriented Wavelet

1. Oriented Wavelet 國立交通大學電子工程學系 陳奕安 2007.5.9

2. Outline • Background • Beyond Wavelet • Simulation Result • Conclusion

3. Outline • Background • Wavelet Review • The Failure of wavelet • Beyond Wavelet • Simulation Result • Conclusion

4. Wavelet Review • Signal Decomposition: • Equal temporal and spatial resolutions • “Natural” trade-off of temporal and spatial resolutions (Wavelet)

5. Wavelet Review • Wavelet Decomposition: • 1-D wavelet transform • 2-D wavelet transform can be obtained from a • separable extension of 1-D transform

6. The failure of wavelet • 1-D: Wavelets are well adapted to singularities • 2-D: • Separable wavelets are only well adapted to point-singularity • However, in line- and curve-singularities…

7. The inefficiency of wavelet • Wavelet: fails to recognize that boundary is smooth • New: require challenging non-separable constructions

8. Outline • Background • Beyond Wavelet • Curvelet • Contourlet • Bandelet • Oriented Wavelete • Simulation Result • Conclusion

9. Curvelets • Curvelets can be interpreted as a grouping of nearby wavelet basis functions into linearstructures so that they can capture the smooth discontinuity curve more efficiently

10. Curvelets • First, a standard multiscale decomposition is computed, where the low-pass channel is sub-sampled while the high-pass channel is not. • Then, a directional decomposition with a DFB is applied to each high-pass channel.

11. Contourlet

12. Contourlet 3 2 1 0

13. Contourlet 0 1 2 3 4 5 6 7

14. Contourlet 11 12 7 8 9 10 11 12 16 13 5 6 15 1 2 14 10 5 8 7 4 3 0 3 4 7 8 1 9 6 3 4 14 2 15 6 5 13 16 0 2 1 12 11 10 9 14 13 15 16

15. Curvelets & Contourlet • Pros: • They do not require a geometric model of the image. • Cons: • The discrete implementations of curvelet transforms are currently highly redundant.

16. Bandelets • Using separable wavelet basis, if no geometric flow • Using modified orthogonal wavelets in the flow direction, called bandelets • Quad-tree segmentation

17. Bandelets • Bandelets use a geometric model to describe the discontinuities of the image; is theoretically more efficient than curvelets for compression purposes . • They are computationally intensive and have the problem of optimization of the bitrate allocation between the image geometry description and the wavelet coefficients.

18. Oriented Wavelete • Applying the lifting steps of a 1D wavelet transform in the direction of the image contours

19. Oriented Wavelete • Using quincunx multi-resolution sampling, the image is filtered along horizontal and vertical or diagonal and anti-diagonal directions.

20. Oriented Wavelete • Horizontal (red) or vertical (green) filtering directions for the first decomposition level . • Diagonal '/' (blue) or anti-diagonal '\' (yellow) filtering directions for the second decomposition level.

21. Oriented Wavelete • Use quad-tree structure to describe the geometry of the image leading to an efficient representation and a simpler rate-distortion optimization.

22. Outline • Background • Beyond Wavelet • Simulation Result • Image compression • Denoising • Conclusion

23. Image compression • Original lena and JPEG Compression (0.25 bpp) JPEG PSNR 31.8 dB

24. Image compression • Separable wavelets and oriented wavelets (0.25 bpp) Separable waveletsPSNR 34.3 dB Oriented waveletsPSNR 34.3 dB

25. Denoising • Noisy lena and separable wavelets Noisy lena PSNR 20.24 dB DWT PSNR 29.86 dB

26. Denoising • Noisy lena and separable wavelets DWT PSNR 29.86 dB OWT PSNR 30.41 dB

27. Outline • Background • Beyond Wavelet • Simulation Result • Conclusion

28. Conclusion • OWT has similar complexity as the separable wavelet transform while providing better energy compaction and staying critically sampled. • Filtering along the image contours allows to remove the noise more efficiently than anisotropic techniques like the ones based on separable wavelets.

29. Happy Birthday !!

30. Outline • Background • Wavelet Review • Failure of wavelet • Beyond Wavelet • Curvelet • Contourlet • Bandelet • Oriented Wavelete • Simulation Result • Image compression • Denoising • Conclusion