Dequantizing Compressed Sensing: When Oversampling and Non-Gaussian Constraints Combine

Jacques, Laurent; Hammond, David K.; Fadili, Jalal M.

doi:10.1109/tit.2010.2093310

Cited by 181 publications

(245 citation statements)

References 48 publications

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“…One may endeavor to circumvent this problem by considering quantization errors as a source of noise, thereby reducing the quantized compressed sensing problem to the noisy classical compressed sensing problem. Further, in some cases the theory and algorithms of noisy compressed sensing may be adapted to this problem as in [28,11,17,25]; the method of quantization may be specialized in order to minimize the recovery error. As noted in [19] if the range of the signal is unspecified, then such a noise source is unbounded, and so the classical theory does not apply.…”

Section: Introductionmentioning

confidence: 99%

One‐Bit Compressed Sensing by Linear Programming

Plan

Vershynin

2013

Comm Pure Appl Math

333

318

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Abstract. We give the first computationally tractable and almost optimal solution to the problem of one-bit compressed sensing, showing how to accurately recover an s-sparse vector x ∈ R n from the signs of O(s log 2 (n/s)) random linear measurements of x. The recovery is achieved by a simple linear program. This result extends to approximately sparse vectors x. Our result is universal in the sense that with high probability, one measurement scheme will successfully recover all sparse vectors simultaneously. The argument is based on solving an equivalent geometric problem on random hyperplane tessellations.

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Section: Introductionmentioning

confidence: 99%

One‐Bit Compressed Sensing by Linear Programming

Plan

Vershynin

2013

Comm Pure Appl Math

333

318

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“…The optimality is addressed by minimizing the MSE performance measure E[ X − X stress that we use the VQ in its generic form. This is different from the design methods using uniform quantization [9] or 1-bit quantization of CS measurements [12]- [15]. Our contributions include…”

Section: A Backgroundmentioning

confidence: 95%

“…Examples are [6]- [15]. To elaborate, let us consider [9] where CS measurements are uniformly quantized and a convex optimization-based CS reconstruction algorithm, called basis pursuit dequantizing (BPDQ), is developed to suit the effect of uniform quantization. Further, the design of CS reconstruction algorithms and their performance bounds for reconstructing a sparse source from 1-bit quantized measurements have been investigated in [12]- [15].…”

Section: A Backgroundmentioning

confidence: 99%

“…minimizing end-to-end distortion, quantization distortion or ℓ 1 -norm of reconstruction vector. Some examples of system models following Figure 3 include [3], [5], [9], [11] (assuming a noiseless channel) and the conventional nearestneighbor coding of CS measurements. In general, according to this system model, quantizer decoder D outputs the vector Y ∈ R M after receiving channel output.…”

Section: Remark 2 the General System Of Figure 1 And Figure 2 Are Eqmentioning

confidence: 99%

“…• Basis Pursuit DeQuantizing (BPDQ) [9]: Using this method, the encoder uniformly scalar-quantizes CS measurements, and the BPDQ algorithm [9] reconstructs the sparse source (from the quantized measurements) by solving the following convex optimization problem…”

Section: Nearest-neighbor Coding For Cs (Nnc-cs)mentioning

confidence: 99%

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Joint Source-Channel Vector Quantization for Compressed Sensing

2014

IEEE Trans. Signal Process.

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Abstract-We study joint source-channel coding (JSCC) of compressed sensing (CS) measurements using vector quantizer (VQ). We develop a framework for realizing optimum JSCC schemes that enable encoding and transmitting CS measurements of a sparse source over discrete memoryless channels, and decoding the sparse source signal. For this purpose, the optimal design of encoder-decoder pair of a VQ is considered, where the optimality is addressed by minimizing end-to-end mean square error (MSE). We derive a theoretical lower-bound on the MSE performance, and propose a practical encoder-decoder design through an iterative algorithm. The resulting coding scheme is referred to as channeloptimized VQ for CS, coined COVQ-CS. In order to address the encoding complexity issue of the COVQ-CS, we propose to use a structured quantizer, namely low complexity multi-stage VQ (MSVQ). We derive new encoding and decoding conditions for the MSVQ, and then propose a practical encoder-decoder design algorithm referred to as channel-optimized MSVQ for CS, coined COMSVQ-CS. Through simulation studies, we compare the proposed schemes vis-a-vis relevant quantizers.Index Terms-Vector quantization, multi-stage vector quantization, joint source-channel coding, noisy channel, compressed sensing, sparsity, mean square error.

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Compressive Sensing

Lakshminarayanan

Thapa

Raahemifar

et al. 2015

The Optics Encyclopedia

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Compressive sensing (CS) is an emerging sampling theory, which reproduces signals from a much smaller set of samples than that required by the Nyquist‐Shannon criterion. Since its introduction in the mid‐2000s it has attracted considerable research interest and a number of CS‐based architectures have been proposed, built, and examined in the research labs. This article outlines the main theoretical concepts surrounding CS and also discusses some of its applications in the field of optics and image science.

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Dequantizing Compressed Sensing: When Oversampling and Non-Gaussian Constraints Combine

Cited by 181 publications

References 48 publications

One‐Bit Compressed Sensing by Linear Programming

One‐Bit Compressed Sensing by Linear Programming

Joint Source-Channel Vector Quantization for Compressed Sensing

Compressive Sensing

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