Authors: Israa Sh. Tawfic, Sema Koc Kayhan

Abstract:

Given a large sparse signal, great wishes are to reconstruct the signal precisely and accurately from lease number of measurements as possible as it could. Although this seems possible by theory, the difficulty is in built an algorithm to perform the accuracy and efficiency of reconstructing. This paper proposes a new proved method to reconstruct sparse signal depend on using new method called Least Support Matching Pursuit (LS-OMP) merge it with the theory of Partial Knowing Support (PSK) given new method called Partially Knowing of Least Support Orthogonal Matching Pursuit (PKLS-OMP). The new methods depend on the greedy algorithm to compute the support which depends on the number of iterations. So to make it faster, the PKLS-OMP adds the idea of partial knowing support of its algorithm. It shows the efficiency, simplicity, and accuracy to get back the original signal if the sampling matrix satisfies the Restricted Isometry Property (RIP). Simulation results also show that it outperforms many algorithms especially for compressible signals.

Keywords: Compressed sensing, Lest Support Orthogonal Matching Pursuit, Partial Knowing Support, Restricted isometry property, signal reconstruction.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1096570

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References:

[1] Wei Dai and Olgica Milenkovic, “Subspace Pursuit for Compressive Sensing: Closing the Gap Between Performance and Complexity”, International Journal of Electronics and Computer Science Engineering 2010.
[2] Entao Liu and V.N. “Orthogonal Super Greedy Algorithm and Applications in Compressed Sensing”, IEEE Trans. Inform. Theory 58 (4), 2040-2047,2011
[3] D. Needel and J. A. Tropp“COSAMP: Iterative Signal Recovery from Incomplete and Inaccurate Samples”, Elsevier applied and Computational Harmonic. Anal. 26 (2009) 301–321 Volume 26, Issue 3,
[4] Wei Dai, and Olgica Milenkovic , “Subspace Pursuit for Compressive Sensing Signal Reconstruction”, IEEE, 5, May (2009).
[5] Parichat Sermwuthisarn, Duangrat Gansawat, “Impulsive noise rejection method for compressed measurement signal in compressed sensing”, EURASIP Journal on advances in signal processing 2012.
[6] Tony TonyCai, Lie Wang, and GuangwuXu, “ Stable Recovery of Sparse Signals and an Oracle Inequality “, IEEE Transactions On Information Theory, Vol. 56, No. 7, July 2010.
[7] Jian Wang and ByonghyoShim , “A Simple Proof of the Mutual Incoherence Condition for Orthogonal Matching Pursuit”, arXiv 1105.4408v1 (cs.It), 23 May (2011).
[8] Richard Baraniuk, “Compressive sensing”, IEEE Signal Processing Magazine, 24(4), pp. 118-121, July 2007.
[9] Joel A. Tropp, and Anna C. Gilber, “Signal Recovery From Random Measurements Via Orthogonal Matching Pursuit”, IEEE Transactions on Theory, vol. 53, NO. 12, DECEMBER 2007
[10] Parichat Sermwuthisarn, Supatana Auethavekiat, ”Robust reconstruction algorithm for compressed sensing in Gaussian noise environment using orthogonal matching pursuit with partially known support and random sub sampling”, EURASIP Journal on Advances in Signal Processing 2012/1/3
[11] Parichat Sermwuthisarn, Supatana Auethavekiat, “Impulsive noise rejection method for compressed measurement signal in compressed sensing ”,EURASIP Journal on Advances in Signal Processing , 2012:68
[12] Jian Wang and Byonghyo Shim , “A Simple Proof of the Mutual Incoherence Condition for Orthogonal Matching Pursuit”, arXiv 1105.4408v1 (cs.It), 23 May (2011).