Research PaperNo Access

Fast motion estimation algorithm based on geometric wavelet transform

Leyla Cheriet

Electronics Department, Badji Mokhtar University of Annaba, Algeria

E-mail Address: l.cheriet@yahoo.fr

Search for more papers by this author

Salah Chenikher

LABGET Laboratory, Department of Electrical Engineering, Larbi Tebessi University of Tebessa, 12000 Tebessa, Algeria

Search for more papers by this author

, and

Karima Boukari

Electronics Department, Badji Mokhtar University of Annaba, Algeria

Search for more papers by this author

https://doi.org/10.1142/S0219691319500188Cited by:2 (Source: Crossref)

Abstract

Motion estimation is a means, which consists in studying the displacement of objects in a video sequence, seeking the correlation between two successive frames, to predict the change in the contents position. Motion estimation is becoming a progressively significant requirement in a variety of applications such as medicine, robotics and video compression. In recent years, wavelets are effective tools for motion estimation, but the DWT (Discrete Wavelet Transform) will suffer from problems like translation sensitivity, poor directionality and absence of phase information. These three disadvantages make classical wavelets incapable of calculating motion in complex sequences (contain several directions.). In order to improve these negative aspects, we will choose geometric wavelet. Therefore, our objective is to propose a method capable of estimating the motion in terms of performance (speed and accuracy). This method will be based on the geometric wavelet transform and more precisely on the Contourlet transform. This work consists of two parts: in the first stage, the denoising process is examined by the Contourlet transform to ensure the precision of motion; in the second phase, we applied the iterative method of Horn and Schunck to calculate the motion in order to guarantee good speed. Comparative experimental results of artificial sequences show that the proposed algorithm obtains considerably better performance than several state-of-the-art methods.

Keywords:

AMSC: 62H35, 42C40

References

1. F. Abdolalia, R. Aghaeiza, D. Zoroofia, Y. Otakeb and Y. Satob, Automated classification of maxillofacial cysts in cone beam CT images using Contourlet transformation and Spherical Harmonics, Comput. Meth. Prog. Biomed. 139 (2017) 197–207. Crossref, Web of Science, Google Scholar
2. S. Bachu and K. M. Char, A review on motion estimation in video compression, Int. Conf. Signal Processing and Communication Engineering Systems (2015). Crossref, Google Scholar
3. J. L. Barron and N. A. Thacker, Tutorial: Computing 2D and 3D optical flow, Tina Memo No. 2004-012, Int. Document of Imaging Science and Biomedical Engineering Division, Medical School, University of Manchester (2004). Google Scholar
4. Barron, Performance of optical flow technique, Int. J. Comput. Vision 12(1) (1994) 43–77. Crossref, Web of Science, Google Scholar
5. S. S. Beauchemin and J. L. Barron, The computation of optical flow, ACM Comput. Surv. 27(3) (1995) 433–466. Crossref, Web of Science, Google Scholar
6. G. Bhatnagar, Q. M. J. Wu and B. Raman, Discrete fractional wavelet transform and its application to multiple encryption, Inform. Sci. 223(2013) (2013) 297–316. Crossref, Web of Science, Google Scholar
7. T. Bruylants, A. Munteanu and P. Schelkens, Wavelet-based volumetric medical image compression, Signal Process. Image Commun. 31 (2015) 112–133. Crossref, Web of Science, Google Scholar
8. R. Budinich, A region based easy path wavelet transform for sparse image representation, Int. J. Wavelets, Multiresolution Inf. Process. 12 (2017) 16–28. Google Scholar
9. M. Chuia, Y. Fengb, W. Wanga, Z. Lic and X. Xua, Image denoising method with adaptive Bayes threshold in nonsubsampled contourlet domain, 2012 AASRI Conf. Computational Intelligence and Bioinformatics (Published by Elsevier B. V. Selection and/or peer review under responsibility of American Applied Science Research Institute, 2012), pp. 512–518. Google Scholar
10. M. Do and M. Vetterli, The finite ridgelet transform for image representation, IEEE Trans. Image Process. (2003). Crossref, Web of Science, Google Scholar
11. M. N. Do and M. Vetterli, The Contourlet transform: An efficient directional multiresolution image representation, IEEE Trans. Image Process. 14(12) (2003) 2091–2106. Crossref, Web of Science, Google Scholar
12. M. N. Do and M. Vetterli, Contourlets, Beyond Wavelets (Academic Press, New York, 2003). Crossref, Google Scholar
13. D. L. Donoho and M. R. Duncan, Digital curvelet transform: Strategy, implementation, and experiments, Wavelet Applications VII (2000). Crossref, Google Scholar
14. M. Drulea and S. Nedevschi, Motion estimation using the correlation transform, IEEE Trans. 22(8) (2013) 3260–3270. Google Scholar
15. L. Gao, G. Wang and J. Liu, Image denoising based on edge detection and prethresholding Wiener filtering of multi-wavelets fusion, Int. J. Wavelets, Multiresolution Inf. Process. (2015). Link, Web of Science, Google Scholar
16. S. Gujjunoori and S. Reddy, Tracking and size estimation of objects in motion, Machine Vision (Singapore, 2017), pp. 87–92. Google Scholar
17. M. Hossen and S. Tuli, A surveillance system based on motion detection and motion estimation using optical flow, Electronics and Vision (ICIEV) (IEEE, 2016), pp. 646–651. Crossref, Google Scholar
18. A. Jaiswal, J. Padhyay and A. Somkuwar, Image denoising and quality measurements by using filtering and wavelet based techniques, Int. J. Electron. Commun. 68 (2014) 699–705. Crossref, Web of Science, Google Scholar
19. A. B. Jambek and A. A. Juri, Low-energy motion estimation architecture using quadrant-based multi-octagon (QBMO) algorithm, J. Real-Time Image Process. 12 (2016) 623–632. Crossref, Google Scholar
20. C. Liu, Introduction to dense optical flow, Dense Image Correspondences for Computer Vision (Springer, 2016). Crossref, Google Scholar
21. W. I. Liu and W. Lin, Senior member, IEEE, additive white Gaussian noise level estimation in SVD domain for images, IEEE Trans. Image Process. 22(3) (2013) 872–883. Crossref, Web of Science, Google Scholar
22. J.-C. Liu and W.-L. Hwang, Active contour model using wavelet modulus for object segmentation and tracking in video sequences, Int. J. Wavelets, Multiresolution Inf. Process. 1 (2003) 93–113. Link, Google Scholar
23. I. Mehra and N. K. Nishchal, Wavelet-based image fusion for securing multiple images through asymmetric keys, Opt. Commun. 335 (2015) 153–160. Crossref, Web of Science, Google Scholar
24. D. D. Y. Po and M. N. Do, Directional multiscale modeling of images using the Contourlet transform, IEEE Trans. Image Process. 15 (2006) 1610–1620. Crossref, Web of Science, Google Scholar
25. N. Rajpal and R. Purwar, A fast block motion estimation algorithm using dynamic pattern search, Signal Image Video Process. 7 (2013) 151–161. Crossref, Web of Science, Google Scholar
26. D. Rfenacht and R. Mathew, A novel motion field anchoring paradigm for highly scalable wavelet-based video coding, IEEE Trans. Image Process. 25(1) (2016) 39–52. Crossref, Web of Science, Google Scholar
27. T. Schps, T. Sattler and C. Hne, 3D modeling on the go: Interactive 3D reconstruction of large-scale scenes on mobile devices, Int. Conf. 3D Vision (Lyon, France, 2015), pp. 291–299. Crossref, Google Scholar
28. G. Selvi and R. Nadarajan, CT and MRI image compression using wavelet-based Contourlet transform and binary array technique, J. Real-Time Image Process. 13 (2017) 261–272. Crossref, Google Scholar
29. P. Shah, S. N. Merchant and U. B. Desai, Fusion of surveillance images in infrared and visible band using curvelet, wavelet and wavelet packet transform, Int. J. Wavelets, Multiresolution Inf. Process. 8(2) (2010) 271–292. Link, Web of Science, Google Scholar
30. N. Terki, D. Saigaa, L. Cheriet and N. Doghmane, Fast motion estimation algorithm based on complex wavelet transform, J. Signal Proces. Syst. 72 (2013) 99–105. Crossref, Web of Science, Google Scholar
31. Ch. Wu and H. Jiang, Catenary image denoising method using lifting wavelet based Contourlet transform with cycle shift-invariance, Int. J. Wavelets, Multiresolution Inf. Process. 17 (2019) 1850060. Link, Web of Science, Google Scholar
32. Q. Xie, Q. Long and S. Mita, Integration of optical flow and Multi-Path-Viterbi algorithm for stereo vision, Int. J. Wavelets, Multiresolution Inf. Process. (2017) 1–24. Web of Science, Google Scholar
33. X. You, L. Du, Y. Cheung and Q. Chen, A blind watermarking scheme using new nontensor product wavelet filter banks, IEEE Trans. Image Process. 19(12) (2010) 3271–3284. Crossref, Web of Science, Google Scholar
34. S. Yu, Y. Mou, D. Xu, X. You, L. Zhou and W. Zeng, A new algorithm for shoreline extraction from satellite imagery with non-separable wavelet and level set method, Int. J. Machine Learning Comput. 3(1) (2013) 158. Crossref, Google Scholar