Robust Sampling and Reconstruction Methods for Sparse Signals in the Presence of Impulsive Noise

• Published in: IEEE journal of selected topics in signal processing Vol. 4; no. 2; pp. 392 - 408
• Main Authors: Carrillo, R.E., Barner, K.E., Aysal, T.C.
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.04.2010; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Algorithms; Compressed sensing; Compressed sensing (CS); Current measurement; Data acquisition; Detection; Error analysis; Gaussian noise; impulse noise; Mathematical analysis; Mathematical models; Methods; Noise; Noise measurement; Noise robustness; nonlinear estimation; Operators; Reconstruction; Reconstruction algorithms; Sampling; Sampling methods; signal reconstruction; Signal sampling; Studies; Working environment noise
• ISSN: 1932-4553; 1941-0484
• DOI: 10.1109/JSTSP.2009.2039177

Recent results in compressed sensing show that a sparse or compressible signal can be reconstructed from a few incoherent measurements. Since noise is always present in practical data acquisition systems, sensing, and reconstruction methods are developed assuming a Gaussian (light-tailed) model for the corrupting noise. However, when the underlying signal and/or the measurements are corrupted by impulsive noise, commonly employed linear sampling operators, coupled with current reconstruction algorithms, fail to recover a close approximation of the signal. In this paper, we propose robust methods for sampling and reconstructing sparse signals in the presence of impulsive noise. To solve the problem of impulsive noise embedded in the underlying signal prior the measurement process, we propose a robust nonlinear measurement operator based on the weighed myriad estimator. In addition, we introduce a geometric optimization problem based on L 1 minimization employing a Lorentzian norm constraint on the residual error to recover sparse signals from noisy measurements. Analysis of the proposed methods show that in impulsive environments when the noise posses infinite variance we have a finite reconstruction error and furthermore these methods yield successful reconstruction of the desired signal. Simulations demonstrate that the proposed methods significantly outperform commonly employed compressed sensing sampling and reconstruction techniques in impulsive environments, while providing comparable performance in less demanding, light-tailed environments.