Quantitative Robust Uncertainty Principles and Optimally Sparse Decompositions
Foundations of Computational Mathematics
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IEEE Transactions on Knowledge and Data Engineering
Compressed Sensing and Redundant Dictionaries
IEEE Transactions on Information Theory
Consistent image decoding from multiple lossy versions
Proceedings of the 2010 ACM workshop on Advanced video streaming techniques for peer-to-peer networks and social networking
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In this paper, following the Compressed Sensing (CS) paradigm, we study the problem of recovering sparse or compressible signals from uniformly quantized measurements. We present a new class of convex optimization programs, or decoders, coined Basis Pursuit DeQuantizer of moment p (BPDQp), that model the quantization distortion more faithfully than the commonly used Basis Pursuit DeNoise (BPDN) program. Our decoders proceed by minimizing the sparsity of the signal to be reconstructed while enforcing a data fidelity term of bounded lp-norm, for 2 p ≤ ∞. We show that in oversampled situations, i.e. when the number of measurements is higher than the minimal value required by CS, the performance of the BPDQp decoders outperforms that of BPDN, with reconstruction error due to quantization divided by √p + 1. This reduction relies on a modified Restricted Isometry Property of the sensing matrix expressed in the lp-norm (RIPp); a property satisfied by Gaussian random matrices with high probability. We conclude with numerical experiments comparing BPDQp and BPDN for signal and image reconstruction problems.