Distributed Compressive Sensing: Performance Analysis With Diverse Signal Ensembles
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TL;DR: This paper introduces two key ingredients, called “Euclidean distances between signals” and “decay rate of signal ensemble,” to conduct a performance analysis of a deterministic signal model under the MMVs framework and designs a new method based on modified SOMP algorithms for a key application known as cooperative spectrum sensing.
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Abstract: Distributed compressive sensing (DCS) is a framework that considers joint sparsity within signal ensembles along with multiple measurement vectors (MMVs). However, current theoretical bounds of the probability of perfect recovery for MMVs are derived to be essentially identical to that of a single MV (SMV); this is because characteristics of the signal ensemble are ignored. In this paper, we introduce two key ingredients, called “Euclidean distances between signals” and “decay rate of signal ensemble,” to conduct a performance analysis of a deterministic signal model under the MMVs framework. We show that, by taking the size of signal ensembles into consideration, MMVs indeed exhibit better performance than SMV. Although our extension can be broadly applied to CS algorithms with MMVs, a case study conducted on a greedy solver, which is commonly known as simultaneous orthogonal matching pursuit (SOMP), will be explored in this paper. When incorporated with our concept by modifying the steps of support detection and signal estimation, we show that the performance of SOMP will be improved to a meaningful extent, especially for short Euclidean distances between signals. Performance of the modified SOMP is verified to meet our theoretical prediction. Moreover, we design a new method based on modified SOMP algorithms for a key application known as cooperative spectrum sensing (CSS). The simulation results demonstrate that our method can benefit from more than one measurement vector, especially when the length of the measurement vectors is smaller than the sparsity of the signals, which is where traditional CS algorithms fail.
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Citations
Maximizing Energy Efficiency in Hybrid Overlay-Underlay Cognitive Radio Networks Based on Energy Harvesting-Cooperative Spectrum Sensing
TL;DR: A novel energy harvesting-distributed cooperative spectrum sensing architecture that allows SUs to acquire from the surrounding environment and radio frequency (RF) signals energy, and an improved distributed Cooperative spectrum sensing scheme based on energy-correlation is proposed.
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A novel subspace pursuit of residual correlation step algorithm for distributed compressed sensing
Mingchi Ju,Man Zhao,Tailin Han,Hong Liu,Bo Xu,Xuan Liu +5 more
TL;DR: In this article , a distributed compressed sensing joint reconstruction algorithm called DCS-SPRCS is proposed for application to WSNs, which is suitable for distributed conditions such as multiple Gaussian sparse signals and shock wave field tests.
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Federated Consensus-Based Algorithm for Stable Recovery of Sparse Signals
TL;DR: In this article , a federated consensus-based algorithm (FCB) was proposed to increase the computational parallelism and accelerate the convergence of sparse recovery. And the authors derived the conditions of exact support recovery and an upper bound of signal recovery error for FCB in the noisy case.
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Distributed Multi-View Sparse Vector Recovery
TL;DR: In this paper , a distributed alternating direction method of multipliers (ADMM) algorithm is proposed to recover the global vector from a partial view of the local masking vector in multi-view compressed sensing problem.
2
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