Authors: Mbainaibeye Jérôme, Noureddine Ellouze

Abstract:

Wavelet transforms is a very powerful tools for image compression. One of its advantage is the provision of both spatial and frequency localization of image energy. However, wavelet transform coefficients are defined by both a magnitude and sign. While algorithms exist for efficiently coding the magnitude of the transform coefficients, they are not efficient for the coding of their sign. It is generally assumed that there is no compression gain to be obtained from the coding of the sign. Only recently have some authors begun to investigate the sign of wavelet coefficients in image coding. Some authors have assumed that the sign information bit of wavelet coefficients may be encoded with the estimated probability of 0.5; the same assumption concerns the refinement information bit. In this paper, we propose a new method for Separate Sign Coding (SSC) of wavelet image coefficients. The sign and the magnitude of wavelet image coefficients are examined to obtain their online probabilities. We use the scalar quantization in which the information of the wavelet coefficient to belong to the lower or to the upper sub-interval in the uncertainly interval is also examined. We show that the sign information and the refinement information may be encoded by the probability of approximately 0.5 only after about five bit planes. Two maps are separately entropy encoded: the sign map and the magnitude map. The refinement information of the wavelet coefficient to belong to the lower or to the upper sub-interval in the uncertainly interval is also entropy encoded. An algorithm is developed and simulations are performed on three standard images in grey scale: Lena, Barbara and Cameraman. Five scales are performed using the biorthogonal wavelet transform 9/7 filter bank. The obtained results are compared to JPEG2000 standard in terms of peak signal to noise ration (PSNR) for the three images and in terms of subjective quality (visual quality). It is shown that the proposed method outperforms the JPEG2000. The proposed method is also compared to other codec in the literature. It is shown that the proposed method is very successful and shows its performance in term of PSNR.

Keywords: Image compression, wavelet transform, sign coding, magnitude coding.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1063435

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References:

[1] W.B Pennebaker, and J.L. Mitchel, JPEG Still Image Data Compression Standard, Van Nostrand Reinhold, 1993.
[2] G.K. Walace, "The jpeg still image compression standard", Comm. ACM, vol.34, no.4, pp30-44, Apr. 1994.
[3] K.R. Rao, and P. Yip, Discrete Cosine Transform- Algorithms, Advantages, Applications, Academic Press, 1990.
[4] H.S. Malvar, Signal Processing with Lapped Transforms, Norwood, MA, Artech House, 1992.
[5] R.Grisel et F. Astrade, "Compression d-images par modélisation des coefficients tcd en lois mélange et quantification adaptative dans l-environnement jpeg", Traitement du Signal, vol.14, no.3, pp.301-315, 1997.
[6] S.G. Mallat, "A theory for multi-resolution signal decomposition: The wavelet representation", IEEE Trans. On Pattern Analysis and Machine Intelligence, vol.11, no.7, pp.674-693, Jul. 1989.
[7] J.M. Shapiro, "Embedded image coding using zerotree of wavelet coefficients", IEEE Trans. On Signal Processing, vol.41, no.12, pp.3445-3462, Dec. 1993.
[8] A. Zandi, J.D. Allen, E.L. Schwartz, and M. Boliek, "CREW: Compression with reversible embedded wavelet", IEEE Data Compression Conference, Snowbird, pp.212-221, Mar. 1995.
[9] A. Said, and W.A. Pearlman, "An image multi-resolution representation, for lossless and lossy compression", IEEE Trans. On Image Processing, vol.5, no.6, pp.1303-1310, Sep. 1996.
[10] A. Said, and W.A. Pearlman, "A new fast and efficient image codec based on set partitioning in hierarchical trees", IEEE Trans. On Circuits and Systems for Video Technology, vol.6, no.3, pp.243-250, Jun. 1996.
[11] S.A Martucci, I. Sodager, T.H. Chiang, and Y.Q. Zhang, "A zerotree wavelet coder", IEEE Trans. On Circuits and Systems for Video Technology, vol.7, no.1, pp.109-118, Fev. 1997.
[12] J. Li, P. Cheng, and C. Kuo, "On the improvement of embedded zerotree wavelet coding", Proc. SPIE, Visual Communications and Image Processing, Orlando, pp.1490-1501, Apr. 1995.
[13] P.G. Sherwood, and K. Zeger, "Progressive image coding for noisy channels", IEEE Signal Processing Letters, vol.4, no.7, pp.189-191, Jul. 1997.
[14] H. Man, F. Kossentini, and M. Smith, "Robust EZW image coding for nosy channels, IEEE Signal Processing Letters, vol.4, no.8, pp.227-229, Aug. 1997.
[15] C.D Creusere, "A new method for robust image compression based on the embedded zerotree wavelet algorithm", IEEE Trans. On Image Processing Letters, vol.6, no.10, pp.1436-1442, Oct. 1997.
[16] J.K. Rogers, and P.C. Cosman, "Wavelet zerotree image compression with packetization", IEEE Signal Processing Letters, vol.5, no.5, pp.105-107, May. 1998.
[17] Z. Xiong, K. Ramchandran, and M.T. Orchard, "Space frequency quantization for wavelet image coding" IEEE Tran. On Image Processing, vol.6, no.5, pp.677-693, May. 1997.
[18] Z. Xiong, K. Ramchandran, and M.T. Orchard, "Wavelet packets image coding using space frequency quantization", IEEE Trans. On Image Processing, vol.7, pp.892-898, Jun. 1998.
[19] S. Joo, H. Kikuchi, S. Sasaki, and J. Shin, "Flexible zerotree coding of wavelet coefficients", IEICE Trans. Fundamentals, vol.E82-A, no.4, Apr. 1999.
[20] M.W. Marcellin, M.J. Gormis, A. Bilgin and M.P. Boliek, "An overview JPEG2000", Proc. IEEE Data Compression Conference, pp.523-541, 2000.
[21] J.D Villasenor, B. Belzer, and J. Lio, "Wavelet filter evaluation for image compression", IEEE Tran. On Image Processing, vol.6, no.11, pp.289-290, Aug. 1995.
[22] M. Antoni, M. Barlaud, P. Mathieu, and I. Daubechies, "Image coding using wavelet transform", IEEE trans. On Image Processing, vol.1, no.2, pp.205-220, Apr. 1992.
[23] E. Schwartz, A. Zandik, "Implementation of compression with reversible embedded wavelets", SPIE, no. 2564, pp.32-43, 1995.
[24] X. Wu, "High-order context modelling and embedded conditional entropy coding of wavelet coefficients for image compression", Proc. 31th Asilomor Conf. on Signals, Systems and Computers, pp.1378-1382, 1997.
[25] A. Bigin, P. Sementilli, and M. Marcellin, "Progressive image coding using treillis coded quantization", IEEE Tran. On Image Processing, vol.11, no.8, pp.1638-1643, Nov. 1999.
[26] D. Taubman, "High performance scalable image compression with EBCOT", Proc. ICIP, pp.344-348, 1999.
[27] A. Deever, and S.S. Hemami, "What-s your sign: Efficient sign coding for embedded wavelet image coding", Proc. Data Compression Conference, 2000, Snowbird, Utah, March 2000.
[28] C. Tion, and S.S. Hemami, "An embedded image coding system based on tar filter with classification", Proc. ICASSP, Montreal, Quebec, Canada, May 2004.
[29] M. Jér├┤me, "Optimal Image coding based on probability distribution of embedded zerotree wavelet symbols", Tunisian-German Conference on Smart Systems and Devices, pp.666-671, Hammamet, Tunisia, Mar. 27- 30, 2001.
[30] M. Jér├┤me, Compression d-Images par Ondelettes, PhD Thesis, Ecole Nationale d-ingénieurs de Tunis, Jul. 2002.
[31] M. Jér├┤me, and N. Ellouze, "Very low bit rate coding of image sequence using embedded zerotree wavelet and symbol probability distributions", Proc. IEEE 3th Inter. Conf. on Information, Communication & Signal Processing, Singapore, Oct.15-18, 2001.
[32] M. Jér├┤me and N. Ellouze, "Embedded zerotree wavelet coding of image sequence", Proc. Inter. Conf. on Wavelet Analysis and Its Applications, Springer Publisher, Lecture Notes in Computer Science, vol. 2251, ISBN 3-540-43034-2, Hong Kong, pp.65-75, Dec.18-20, 2001.
[33] www.aware/jpeg2000 J2K-Tool, JPEG2000 Compression/Decompression Tool 2 5.1, Aware Inc.