AN ADAPTIVE MEASUREMENT SCHEME BASED ON COMPRESSED SENSING FOR WIDEBAND SPECTRUM DETECTION IN COGNITIVE WSN 被引量：1

AN ADAPTIVE MEASUREMENT SCHEME BASED ON COMPRESSED SENSING FOR WIDEBAND SPECTRUM DETECTION IN COGNITIVE WSN

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摘要 An Adaptive Measurement Scheme (AMS) is investigated with Compressed Sensing (CS) theory in Cognitive Wireless Sensor Network (C-WSN). Local sensing information is collected via energy detection with Analog-to-Information Converter (AIC) at massive cognitive sensors, and sparse representation is considered with the exploration of spatial temporal correlation structure of detected signals. Adaptive measurement matrix is designed in AMS, which is based on maximum energy subset selection. Energy subset is calculated with sparse transformation of sensing information, and maximum energy subset is selected as the row vector of adaptive measurement matrix. In addition, the measurement matrix is constructed by orthogonalization of those selected row vectors, which also satisfies the Restricted Isometry Property (RIP) in CS theory. Orthogonal Matching Pursuit (OMP) reconstruction algorithm is implemented at sink node to recover original information. Simulation results are performed with the comparison of Random Measurement Scheme (RMS). It is revealed that, signal reconstruction effect based on AMS is superior to conventional RMS Gaussian measurement. Moreover, AMS has better detection performance than RMS at lower compression rate region, and it is suitable for large-scale C-WSN wideband spectrum sensing. An Adaptive Measurement Scheme （AMS） is investigated with Compressed Sensing （CS） theory in Cognitive Wireless Sensor Network （C-WSN）. Local sensing information is collected via energy detection with Analog-to-Information Converter （AIC） at massive cognitive sensors, and sparse representation is considered with the exploration of spatial temporal correlation structure of detected signals. Adaptive measurement matrix is designed in AMS, which is based on maximum energy subset selection. Energy subset is calculated with sparse transformation of sensing information, and maximum energy subset is selected as the row vector of adaptive measurement matrix. In addition, the meas- urement matrix is constructed by orthogonalization of those selected row vectors, which also satisfies the Restricted Isometry Property （RIP） in CS theory. Orthogonal Matching Pursuit （OMP） recon- struction algorithm is implemented at sink node to recover original information. Simulation results are performed with the comparison of Random Measurement Scheme （RMS）. It is revealed that, signal reconstruction effect based on AMS is superior to conventional RMS Gaussian measurement. Moreover, AMS has better detection performance than RMS at lower compression rate region, and it is suitable for large-scale C-WSN wideband spectrum sensing.

作者 Xu Xiaorong Zhang Jianwu Huang Aiping Jiang Bin

机构地区 College of Telecommunication Engineering Institute of Information and Communication Engineering

出处《Journal of Electronics(China)》 2012年第6期585-592,共8页 电子科学学刊（英文版）

基金 Supported by the National Natural Science Foundation of China (No. 61102066, 60972058) the China Postdoctoral Science Foundation (No. 2012M511365) the Scientific Research Project of Zhejiang Provincial Education Department (No. Y201119890)

关键词 Cognitive Wireless Sensor Network (C-WSN) Compressed Sensing (CS) Adaptive Measurement Scheme (AMS) Wideband spectrum detection Restricted Isometry Property (RIP) Orthogonal Matching Pursuit (OMP) Cognitive Wireless Sensor Network （C-WSN） Compressed Sensing （CS） Adaptive Measurement Scheme （AMS） Wideband spectrum detection Restricted Isometry Property （RIP） Orthogonal Matching Pursuit （OMP）

分类号 TN911.7 [电子电信—通信与信息系统]

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