Abstract
Wideband spectrum sensing is a popular topic in signal processing, especially for many radar and communication applications. What we face is a high sampling rate and a large volume of samples, in which demand of reducing the sampling rate without sacrificing the sensing resolution and quality. The generalized coprime sampling can break the limitation of the Nyquist sampling theorem with both characteristics of sparse sensing and coprime numbers. To fully utilize all the information received of the derived correlation matrix constructed by the different time delays, the matrix completion method is exploited. The theory of matrix completion is an extension of compressive sensing, though, which is not restrained by the sparsity and the restricted isometry property. The interpolation-based method presented via the convex framework of the nuclear norm minimization has no extra fine-tuned parameters, which different from techniques like compressive covariance sampling, positive definite Toeplitz matrix completion, and so on. Moreover, compared to the selection-based method under a continuous set, the proposed method improves the spectral resolution and estimation accuracy to avoid the information losing. The Simulation results indicate the performance of the algorithm.
Highlights
Advances in wideband radio-frequency (RF) technology for many radar and communication applications, the wideband spectrum sensing becomes a popular topic in signal processing
The missing elements of the derived signal based second-order sampled are interpolated by unclear norm minimization to completing a low-rank Toeplitz correlation matrix, which is the main contribution of this paper
The derived correlation matrix completion method for generalized coprime sampling is proposed as an interpolationbased strategy
Summary
Advances in wideband radio-frequency (RF) technology for many radar and communication applications, the wideband spectrum sensing becomes a popular topic in signal processing. The typical method for resolving frequency ambiguities of the multi-rate sampled signal is based on the Chinese remainder theorem (CRT). Compared to the uniformly subsampling scheme and the CRT-based resolution of frequency ambiguities, spectrum estimation using coprime pair of samples improves the resolution and accuracy. In [22], the reconstructed covariance matrix only selects the continuous set of the cross-lags based on the generalized coprime sampling. This method does not take advantage of all the information received, which is caused by an estimation performance lose. The missing elements of the derived signal based second-order sampled are interpolated by unclear norm minimization to completing a low-rank Toeplitz correlation matrix, which is the main contribution of this paper.
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