[1] 朱埜. 主动声纳检测信息原理[M]. 北京:科学出版社, 2014. Zhu Ye. Active sonar detection principle[M]. Beijing:Science Press, 2014.
[2] Etter P C. Underwater acoustic modeling and simulation[M]. 5th Edi-tion. Boca Raton, FL:Spon Press(Taylor & Francis Group), 2013:299-311.
[3] Abraham D A, Gelb J M, Oldag A W. Background and clutter mixture distributions for active sonar statistics[J]. IEEE Journal of Oceanic Engi-neering, 2011, 36(2):231-247.
[4] Abraham D A, Lyons A P. Novel physical interpretations of K-distribut-ed reverberation[J]. IEEE Journal of Oceanic Engineering, 2002, 27(4):800-813.
[5] Hodgkiss W. An oceanic reverberation model[J]. IEEE Journal of Oce-anic Engineering, 1984, 9(2):63-72.
[6] Etter P C. Underwater acoustic modeling and simulation[M]. London:Spon Press(Tay & Francis Group), 2003.
[7] Kay S M. Fundamentals of statistical signal processing:Detection theo-ry volume Ⅱ[M]. Upper Saddle Rive, NJ:Printice Hall, 1998.
[8] Klemm R. Interrelations between matched-field processing and air-borne MTI radar[J]. IEEE Journal of Oceanic Engineering, 2002, 18(3):168-180.
[9] Klemm R. Detection of slow targets by a moving active sonar acoustic signal processing for ocean exploration[M]. Dordrecht:Springer, 1993:165-170.
[10] 陈小龙, 关键, 黄勇, 等. 雷达低可观测目标探测技术[J]. 科技导报, 2017, 35(11):30-38. Chen Xiaolong, Guan Jian, Huang Yong, et al. Radar low-observable target detection[J]. Science & Technology Review, 2017, 35(11):30-38.
[11] 陈小龙, 关键, 何友, 等. 高分辨率系数表示及其在雷达动目标检测中的应用[J]. 雷达学报, 2017, 6(3):239-251. Chen Xiaolong, Guan Jian, He You, et al. High-resolution sparse rep-resentation and its applications in radar movin target detection[J]. Jour-nal of radars, 2017, 6(3):239-251.
[12] Cox H and Lai H. Geometric comb waveforms for reverberation sup-pression[C]//Proceedings of 199428th Asilomar Conference on Sig-nals, Systems and Computers. Piscataway, NJ:IEEE, 1995:1185-1189.
[13] Collins T, Atkins P. Doppler-sensitive active sonar pulse designs for reverberation processing[J]. IEE Proceedings-Radar, Sonar and Navi-gation, 1998, 145(6):347-353.
[14] 鄢社锋, 马远良. 传感器阵列波束优化设计及应用[M]. 北京:科学出版社, 2009. Yan Shefeng, Ma Yuanliang. Sensor array beampattern optimization:Theory with applications[M]. Beijing:Science Press, 2009.
[15] Capon J. High-resolution frequency-wavenumber spectrum analysis[J]. Proceedings of the IEEE, 2005, 57(8):1408-1418.
[16] Cox H, Zeskind R M, Owen M M. Robust adaptive beamforming[J]. IEEE Transactions on Acoustics Speech & Signal Processing, 2008, 35(10):1365-1376.
[17] North D O. Analysis of the Factors which Determine Signal/Noise Dis-crimination in Radar[R]. Princeton, NJ:RCA Laboratories, 1943.
[18] Turin G L. An introduction to matched filters[J]. IRE Transactions on Information Theory, 1960, 6(3):311-329.
[19] Li W, Ma X, Zhu Y, et al. Detection in reverberation using space time adaptive prewhiteners[J]. Journal of the Acoustical Society of America, 2008, 124(4):EL236-242.
[20] 陈鹏, 侯朝焕, 马晓川, 等. 基于匹配滤波和离散分数阶傅里叶变换的水下动目标LFM回波联合检测[J]. 电子与信息学报, 2007, 29(10):2305-2308. Chen Peng, Hou Chaohuan, Ma Xiaochuan, et al. The joint detection to underwater moving target's LFM echo based on matched filter and discrete fractional Fourier transform[J]. Journal of Electronics & Infor-mation Technology, 2007, 29(10):2305-2308.
[21] Scharf L L, Friedlander B. Matched subspace detectors[J]. IEEE Trans-actions on Signal Processing, 1994, 42(8):2146-2157.
[22] Barbarossa S. Analysis of multicomponent LFM signals by a combined wigner-hough transform[J]. IEEE Transactions on Signal Processing, 1995, 43(6):1511-1515.
[23] 邓新文, 许琦, 高守勇. 混响背景下应用岭回归对角加载的空时处理方法[J]. 声学技术, 2011, 30(2):188-192. Deng Xinwen, Xu Qi, Gao Shouyong. Ridge-Regression-DiagonalLoading-based space-time adaptive processing for active sonar in re-verberation[J]. Technical Acoustics, 2011, 30(2):188-192.
[24] Brennan L E, Reed I S. Theory of adaptive radar[J]. IEEE Transac-tions on Aerospace & Electronic Systems, 1973, 9(2):237-252.
[25] Wang Y L, Peng Y N. Configuration and performance analysis of space-time adaptive signal processor for airborne radar[C]//Proceed-ings of the 1997 IEEE National Radar Conference. Piscataway, NJ:IEEE, 1997:343-348.
[26] Barboy B, Lomes A, Perkalski E. Cell-averaging CFAR for multiple target situation[J]. IEE Proceedings F (Communications, Radar and Signal Processing), 1986, 133(2):176-186.
[27] Rohling H. Radar CFAR thresholding in clutter and multiple target sit-uations[J]. IEEE Transactions on Aerospace & Electronic Systems, 1983, 19(4):608-621.
[28] Finn H M, Johnson R S. Adaptive detection mode with threshold con-trol as a function of spatially sampled clutter-level estimation[J]. RCA Review, 1968, 29:414-464.
[28] Liu W J, Xie W C, Wang Y L. Diagonally loaded space-time adaptive detection[C]//IEEE CIE International Conference on Radar. Piscat-away, NJ:IEEE, 2011:1115-1119.
[29] 王永良, 刘维建, 谢文冲, 等. 机载雷达空时自适应检测方法研究进展[J]. 雷达学报, 2014, 3(2):201-207. Wang Yongliang, Liu Weijian, Xie Wenchong, et al. Research prog-ress of space-time adaptive detection for airborne radar[J]. Journal of Radars, 2014, 3(2):201-207.
[30] 吕维, 王志杰, 李健辰, 等. 修正空时自适应处理在水下自导系统中的应用[J]. 兵工学报, 2012, 33(8):944-950 Lu Wei, Wang Zhijie, Li Jianchen, et al. Application of modified space-time adaptive processing in sonar[J]. Acta Armamentarii, 2012, 33(8):944-950.
[31] Klemm R. Principles of space-time adaptive processing[M]. 3rd Edi-tion. London:IET, 2006:545-561.
[32] Kelly E J. An adaptive detection algorithm[J]. IEEE Transactions on Aerospace & Electronic Systems, 2007, AES-22(2):115-127.
[33] Robey F C, Fuhrmann D R, Kelly E J, et al. A CFAR adaptive matched filter detector[J]. IEEE Transactions on Aerospace & Elec-tronic Systems, 1992, 28(1):208-216.
[34] Maio A D. Rao test for adaptive detection in gaussian interference with unknown covariance matrix[J]. IEEE Transactions on Signal Pro-cessing, 2007, 55(7):3577-3584.
[35] Shi B, Hao C H, Hou C P, et al. Parametric Rao test for multichannel adaptive detection of range-spread target in partially homogeneous en-vironments[J]. Signal Processing, 2015, 108(108):421-429.
[36] Hao C P, Shang X Q, Bandiera F, et al. Bayesian radar detection with orthogonal rejection[J]. IEICE Transactions on Fundamentals of Elec-tronics Communications & Computer Sciences, 2012, 95-A(2):596-599.
[37] Cai L J, Wang H. A persymmetric multiband GLR algorithm[J]. IEEE Transactions on Aerospace & Electronic Systems, 1992, 28(3):806-816.
[38] Mio K, Chocheyras Y, Doisy Y. Space time adaptive processing for low frequency sonar[C]//Oceans, 2000 MTS/IEEE Conference and Ex-hibition. Piscataway, NJ:IEEE, 2000, doi:10.1109/OCEANS.2000.881786.
[39] 赵申东, 唐劲松, 蔡志明. 声自导鱼雷空时自适应处理[J]. 鱼雷技术, 2008, 16(2):24-30. Zhao Shendong, Tang Jinsong, Cai Zhiming. Space time adaptive pro-cessing of acoustic homing torpedo[J]. Torpedo Technology, 2008, 16(2):24-30.
[40] 詹昊可, 蔡志明, 苑秉成. 鱼雷声呐空时自适应混响抑制方法[J]. 武汉理工大学学报(交通科学与工程版), 2007, 31(6):946-950.Zhan Haoke, Cai Zhiming, Yuan Bingcheng. Space-time adaptive re-verberation suppression in active sonar of torpedo[J]. Journal of Wu-han University of Technology(Transportation Science & Engineering), 2007, 31(6):946-950.
[41] 王磊, 朱埜, 孙长瑜. 空时处理及在混响抑制中的应用[J]. 声学技术, 2003, 22(增刊2):185-187. Wang Lei, Zhu Ye, Sun Changyu. Space-time processing and it's ap-plication in reverberation rejection[J]. Technical Acoustics, 2003, 22(Suppl 2):185-187