Yimin D. Zhang scite author profile

A coprime array uses two uniform linear subarrays to construct an effective difference coarray with certain desirable characteristics, such as a high number of degrees-of-freedom for direction-of-arrival (DOA) estimation. In this paper, we generalize the coprime array concept with two operations. The first operation is through the compression of the inter-element spacing of one subarray and the resulting structure treats the existing variations of coprime array configurations as well as the nested array structure as its special cases. The second operation exploits two displaced subarrays, and the resulting coprime array structure allows the minimum inter-element spacing to be much larger than the typical half-wavelength requirement, making them useful in applications where a small interelement spacing is infeasible. The performance of the generalized coarray structures is evaluated using their difference coarray equivalence. In particular, we derive the analytical expressions for the coarray aperture, the achievable number of unique lags, and the maximum number of consecutive lags for quantitative evaluation, comparison, and design of coprime arrays. The usefulness of these results is demonstrated using examples applied for DOA estimations utilizing both subspace-based and sparse signal reconstruction techniques.

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Dual-Function Radar-Communications: Information Embedding Using Sidelobe Control and Waveform Diversity

Hassanien

Amin

Zhang

et al. 2016

IEEE Trans. Signal Process.

515

306

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Sparsity-based DOA estimation using co-prime arrays

2013

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In this paper, we propose co-prime arrays for effective direction-of-arrival (DOA) estimation. To fully utilize the virtual aperture achieved in the difference co-array constructed from a co-prime array structure, sparsity-based spatial spectrum estimation technique is exploited. Compared to existing techniques, the proposed technique achieves better utilization of the co-array aperture and thus results in increased degrees-of-freedom as well as improved DOA estimation performance.

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Direction-of-Arrival Estimation for Coprime Array via Virtual Array Interpolation

Zhou

Fan

et al. 2018

IEEE Trans. Signal Process.

467

204

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Radar Signal Processing for Elderly Fall Detection: The future for in-home monitoring

Amin

Zhang

Ahmad

et al. 2016

IEEE Signal Process. Mag.

344

147

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Yimin D. Zhang

Generalized Coprime Array Configurations for Direction-of-Arrival Estimation

Dual-Function Radar-Communications: Information Embedding Using Sidelobe Control and Waveform Diversity

Sparsity-based DOA estimation using co-prime arrays

Direction-of-Arrival Estimation for Coprime Array via Virtual Array Interpolation

Radar Signal Processing for Elderly Fall Detection: The future for in-home monitoring

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