Abstract
Based on sparse representations, the problem of two-dimensional (2-D) direction of arrival (DOA) estimation is addressed in this paper. A novel sparse 2-D DOA estimation method, called Dimension Reduction Sparse Reconstruction (DRSR), is proposed with pairing by Spatial Spectrum Reconstruction of Sub-Dictionary (SSRSD). By utilizing the angle decoupling method, which transforms a 2-D estimation into two independent one-dimensional (1-D) estimations, the high computational complexity induced by a large 2-D redundant dictionary is greatly reduced. Furthermore, a new angle matching scheme, SSRSD, which is less sensitive to the sparse reconstruction error with higher pair-matching probability, is introduced. The proposed method can be applied to any type of orthogonal array without requirement of a large number of snapshots and a priori knowledge of the number of signals. The theoretical analyses and simulation results show that the DRSR-SSRSD method performs well for coherent signals, which performance approaches Cramer–Rao bound (CRB), even under a single snapshot and low signal-to-noise ratio (SNR) condition.
Highlights
Direction of Arrival (DOA) estimation methods, especially those of high accuracy and high resolution, have been rapidly developed in recent years, many of which can be found in applications of radar, sonar, communications, etc. [1]
A novel DOA estimation method based on dimension reduction sparse reconstruction and
A novel DOA estimation method based on dimension reduction sparse reconstruction and Spatial Spectrum Reconstruction of Sub-Dictionary (DRSR-SSRSD) has been proposed to realize
Summary
Direction of Arrival (DOA) estimation methods, especially those of high accuracy and high resolution, have been rapidly developed in recent years, many of which can be found in applications of radar, sonar, communications, etc. [1]. DOA estimation with high accuracy and resolution under the strict constrains of large snapshots, independent signals, uncorrelated white noise, etc The advantages of the proposed method are mainly in the following aspects respects: (1) the coherent DOA estimation can be executed directly without decoherence process such as spatial smoothing; (2) the computational complexity and execution time are greatly reduced by transforming the 2-D DOA estimation into parallel computations of two independent 1-D DOAs; (3) the requirement of large number of snapshots is relaxed such that the 2-D DOA estimation performs well in any number of snapshots; and (4) prior knowledge of the number of signals is no longer a requirement.
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