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PIER PIER B PIER C PIER M PIER Letters
2012-02-06
Sparsity-Based Multi-Target Direct Positioning Algorithm Based on Joint-Sparse Recovery
By
Wei Ke,

    Dr. Wei Ke

    School of Physics Science and Technology

    Nanjing Normal University

    China

    Homepage

Lenan Wu

    Dr. Lenan Wu

    School of Information Science and Engineering

    Southeast University

    China

    Homepage

Progress In Electromagnetics Research C, Vol. 27, 99-114, 2012
doi:10.2528/PIERC11110704
Abstract
The direct position determination (DPD) method can improve the location accuracy compared with the traditional two-step location methods due to omitting the intermediate procedure of estimating the measurement parameters. However, the DPD methods presented so far are significantly more complex than the two-step approach. To overcome the shortcomings of the published DPD algorithms, a novel multi-target direct localization approach is firstly proposed by exploiting the jointly sparse property in the discrete spatial domain. The main idea of this paper is that the location estimation can be obtained by finding the sparsest solution according to the predefined overcomplete basis. Furthermore, the locations of targets can be obtained from noisy signals, even if the number of targets is not known a priori. Experimental results demonstrate that the proposed algorithm has superior positioning accuracy to other DPD methods and improves computational efficiency greatly.
Citation
Wei Ke, and Lenan Wu, "Sparsity-Based Multi-Target Direct Positioning Algorithm Based on Joint-Sparse Recovery," Progress In Electromagnetics Research C, Vol. 27, 99-114, 2012.
doi:10.2528/PIERC11110704
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