Parametric Multichannel Target Detection in Heterogeneous Environment

Shang  Xiu-Qin; Song  Hong-Jun; Xu  Hai-Sheng; Zheng  Jing-Bo

doi:10.3724/SP.J.1146.2010.00949

Volume 33 Issue 5

Jun. 2011

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Shang Xiu-Qin, Song Hong-Jun, Xu Hai-Sheng, Zheng Jing-Bo. Parametric Multichannel Target Detection in Heterogeneous Environment[J]. Journal of Electronics & Information Technology, 2011, 33(5): 1095-1100. doi: 10.3724/SP.J.1146.2010.00949

Citation:

Shang Xiu-Qin, Song Hong-Jun, Xu Hai-Sheng, Zheng Jing-Bo. Parametric Multichannel Target Detection in Heterogeneous Environment[J]. Journal of Electronics & Information Technology, 2011, 33(5): 1095-1100. doi: 10.3724/SP.J.1146.2010.00949

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Parametric Multichannel Target Detection in Heterogeneous Environment

doi: 10.3724/SP.J.1146.2010.00949 cstr: 32379.14.SP.J.1146.2010.00949

Received Date: 2010-09-03
Rev Recd Date: 2010-12-17
Publish Date: 2011-05-19

Abstract

Abstract

Parametric multichannel target detection in heterogeneous environment is studied in this paper, where the disturbances are represented by Vector AutoregRessive (VAR) model with its spatial covariance matrix following complex inverse Wishart distribution with degrees of freedom and mean Q. When Q is unknown, the Neyman-Pearson Parametric Adaptive Matched Filter (NP-PAMF), Bayesian PAMF (B-PAMF) and its normalized version (B-NPAMF) are proposed based on NP detection rule. And when it is known, the maximum a-posteriori PAMF (MAP-PAMF) and its normalized version (MAP-NPAMF) are proposed followed MAP decision rule. It is shown that NP-PAMF and B-PAMF are both dependent onand B-PAMF is convergent to the PAMF when ; B-NPAMF has no relation with and is consistent with the classic NPAMF. In MAP-PAMF, the MAP estimator of the spatial covariance matrix consists of the classic estimator and the prior knowledge, and the weigh of the later is controlled by . Finally, the complex issues and the detection performances are nalyzed, showing that: Bayesian parametric detectors possess good performances and they are better than their normalized counterparts.
- Target detection

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References

Sangston K J, Gini F, and Greco M V, et al.Structures for radar detection in compound Gaussian clutter [J]. IEEE Transactions on Aerospace and Electronic Systems, 1999, 35(2): 445-458.[2] Shuai X, Kong L, and Yang J. Performance analysis of GLRT-based adaptive detector for distributed targets in compound-Gaussian clutter [J]. Signal Processing, 2010, 90(1): 16-23.[3] Roy L P and Kumar R V R. Performance deterioration of the matched filter detector in partially correlated texture based compound-Gaussian clutter environment [C]. IEEE Radar Conference, Pasadena, California, USA, May 2009: 1-5.[4] Wang J, Dogandzic A, and Nehorai A. Maximum likelihood estimation of compound-Gaussian clutter and target parameters [J]. IEEE Transactions on Signal Processing, 2006, 54(10): 3884-3898.[5] McWhorter L T and Scharf L L. Adaptive matched subspace detectors and adaptive coherence estimators [C]. Proceedings of 30th Asilomar Conference on Signals, Systems, and Computers, Pacific Grove, CA, November 1996: 1114-1117.[6] Maio A De, Farina A, and Foglia G. Adaptive radar detection: a Bayesian approach [C]. Proceedings of the 2007 IEEE Int. Conf. Radar, Waltham, MA, April 2007: 624-629.[7] Bidon S Besson O, and Tourneret J-Y. The adaptive coherence estimator is the generalized likelihood ratio test for a class of heterogeneous environments [J]. IEEE Signal Processing Letters, 2008, 15: 281-284.[8] Maio A De, Nicola S D, and Huang Y, et al.Adaptive detection and estimation in the presence of useful signal and interference mismatches [J]. IEEE Transactions on Signal Processing, 2009, 57(2): 436-450.[9] Michels J H. Multichannel detection using the discrete-time model-based innovations approach [D]. [Ph.D. dissertation], Syracuse University, Syracuse, NY, May 1991.[10] Roman J R, Rangaswamy M, and Davis D W, et al.Parametric adaptive matched filter for airborne radar applications [J]. IEEE Transactions on Aerospace and Electronic Systems, 2000, 36(2): 677-692.[11] Wang P, Li H, and Himed B. A Bayesian parametric test for multichannel adaptive signal detection in nonhomogeneous environments [J]. IEEE Signal Processing Letters, 2010, 17(4): 351-354.[12] Ward J. Space-time adaptive processing for airborne radar [R]. Technical Report 1015, Lincoln Laboratory, MIT, December 1994.[13] Kelly E J. An adaptive detection algorithm [J]. IEEE Transactions on Aerospace and Electronic Systems, 1986, 22(1): 115-127.

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