Minimum Mean-Squared-Error Autocorrelation Processing in Coprime Arrays

Coprime arrays enable Direction-of-Arrival (DoA) estimation of an increased number of sources. To that end, the receiver estimates the autocorrelation matrix of a larger virtual uniform linear array (coarray), by applying selection or averaging to the physical array's autocorrelation estimates,...

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Hauptverfasser:	Chachlakis, Dimitris G, Zhou, Tongdi, Ahmad, Fauzia, Markopoulos, Panos P
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Sprache:	eng
Schlagworte:	Computer Science - Information Theory Mathematics - Information Theory
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creator	Chachlakis, Dimitris G Zhou, Tongdi Ahmad, Fauzia Markopoulos, Panos P
description	Coprime arrays enable Direction-of-Arrival (DoA) estimation of an increased number of sources. To that end, the receiver estimates the autocorrelation matrix of a larger virtual uniform linear array (coarray), by applying selection or averaging to the physical array's autocorrelation estimates, followed by spatial-smoothing. Both selection and averaging have been designed under no optimality criterion and attain arbitrary (suboptimal) Mean-Squared-Error (MSE) estimation performance. In this work, we design a novel coprime array receiver that estimates the coarray autocorrelations with Minimum-MSE (MMSE), for any probability distribution of the source DoAs. Our extensive numerical evaluation illustrates that the proposed MMSE approach returns superior autocorrelation estimates which, in turn, enable higher DoA estimation performance compared to standard counterparts.
doi_str_mv	10.48550/arxiv.2010.11073
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title	Minimum Mean-Squared-Error Autocorrelation Processing in Coprime Arrays
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