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Multi-sensor kernel design for time-frequency analysis of sparsely sampled nonstationary signals | IEEE Conference Publication | IEEE Xplore
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Multi-sensor kernel design for time-frequency analysis of sparsely sampled nonstationary signals

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Yimin D. Zhang; Liang Guo; Qisong Wu; Moeness G. Amin
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Abstract:

In this paper, we examine the sparsity-based time-frequency signal representation (TFSR) of randomly thinned nonstationary signals in a multi-sensor platform to yield imp...Show More

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Abstract:

In this paper, we examine the sparsity-based time-frequency signal representation (TFSR) of randomly thinned nonstationary signals in a multi-sensor platform to yield improved performance with reduced number of samples in each sensor. The property that different sensors share identical auto-term time-frequency regions renders the TFSR a group sparse reconstruction problem, which is effectively solved using the compressive sensing techniques for high-fidelity TFSR reconstruction. We exploit the adaptive optimal kernel (AOK) to effectively preserve signal auto-terms and mitigate cross-terms. High level of noise and artifacts due to missing samples, however, may render AOK ineffective if designed for each sensor separately. We develop a robust multi-sensor AOK design based on data fusion across all sensors so as to enhance the signal auto-terms while effectively mitigating artifacts, cross-terms, and noise. The superior performance of the proposed multi-sensor AOK design is demonstrated through the comparison with its single-antenna counterpart and data-independent kernels.
Published in: 2015 IEEE Radar Conference (RadarCon)
Date of Conference: 10-15 May 2015
Date Added to IEEE Xplore: 25 June 2015
ISBN Information:

ISSN Information:

DOI: 10.1109/RADAR.2015.7131122
Conference Location: Arlington, VA, USA
References is not available for this document.
Contents

I. Introduction

A large class of nonstationary signals, particularly those characterized by their instantaneous frequencies (IFs), are often encountered in practice, including radar, sonar, communications and biomedical applications [1]–[6]. In particular, by exploiting multiple sensors, array processing of nonstationary signals finds broad applications, such as direction finding, source separation, jammer suppression, and source localization [7]–[14].

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