面向射频隐身的机载网络化雷达资源协同优化技术
上QQ阅读APP看本书,新人免费读10天
设备和账号都新为新人
上一章目录下一章

1.6 参考文献

[1] 董晓明. 海上无人装备体系概览[M]. 哈尔滨: 哈尔滨工程大学出版社,2020.

[2] 姜秋喜. 网络雷达对抗系统导论[M]. 北京: 国防工业出版社,2010.

[3] 时晨光,周建江,汪飞,等. 机载雷达组网射频隐身技术[M]. 北京: 国防工业出版社,2019.

[4] 梁晓龙,胡利平,张佳强,等. 航空集群自主空战研究进展[J]. 科技导报,2020,38(15): 74-88.

[5] 王祥科,沈林成,李杰,等. 无人机集群控制理论与方法[M]. 上海: 上海交通大学出版社,2021.

[6] Lynch D. Introduction to RF stealth[M]. Hampshire: Sci Tech Publishing Inc,2004.

[7] 时晨光,董璟,周建江,等. 飞行器射频隐身技术研究综述[J]. 系统工程与电子技术,2021,43(6): 1452-1467.

[8] 王谦喆,何召阳,宋博文,等. 射频隐身技术研究综述[J]. 电子与信息学报,2018,40(6): 1505-1514.

[9] Pace P E. 低截获概率雷达的检测与分类[M]. 陈祝明,江朝抒,段锐,译. 北京: 国防工业出版社,2012.

[10] 刘敏,任翔宇. 电子战动态[J]. 国际电子战,2016,9: 34-35.

[11] 美国战略与预算评估中心. 决胜灰色地带—运用电磁战重获局势掌控优势[M].《国际电子战》编辑部,译. 北京: 中国电子科技集团有限公司发展战略研究中心,2017.

[12] 李硕,李祯静,朱松,等. 美军电磁频谱战发展分析及启示[J]. 中国电子科学研究院学报,2020,15(8): 721-724.

[13] 张澎,张成,管洋阳,等. 关于电磁频谱作战的思考[J]. 航空学报,2021,42(8): 94-105.

[14] 唐永年. 雷达对抗工程[M]. 北京: 国防工业出版社,2012.

[15] Hume A L,Baker C J. Netted radar sensing[C]. Proceedings of the IEEE Radar Conference,2001: 23-26.

[16] Teng Y,Griffiths H D,Baker C J,et al. Netted radar sensitivity and ambiguity[J]. IET Radar,Sonar & Navigation,2007,1(6): 479-486.

[17] Haimovich A M,Blum R S,Cimini L J. MIMO radar with widely separated antennas[J]. IEEE Signal Processing Magazine,2008,25(1): 116-129.

[18] Li J,Stoica P. MIMO radar signal processing[M]. Hoboken,Wiley-IEEE Press,2009.

[19] 王正,韩英永,姜秋喜,等. 网络雷达对抗系统的相控阵雷达波束扫描分析[J]. 火力与指挥控制,2012,37(11): 109-112.

[20] 陈小龙,薛永华,张林,等. 机载雷达系统与信息处理[M]. 北京: 电子工业出版社,2021.

[21] 陈浩文,黎湘,庄钊文,等. 多发多收雷达系统分析及应用[M]. 北京: 科学出版社,2016.

[22] 陈浩文. MIMO阵列雷达目标参数估计与系统设计研究[D]. 长沙: 国防科学技术大学,2012.

[23] 孙斌. 分布式MIMO雷达目标定位与功率分配研究[D]. 长沙: 国防科学技术大学,2014.

[24] Derham T,Doughty S,Baker C,et al. Ambiguity functions for spatially coherent and incoherent multistatic radar[J]. IEEE Transactions on Aerospace and Electronic Systems,2010,46(1): 230-245.

[25] Battistelli G,Chisci L,Morrocchi S,et al. Robust multisensor multitarget tracker with application to passive multistatic radar tracking[J]. IEEE Transactions on Aerospace and Electronic Systems,2012,48(4): 3450-3472.

[26] Baumgarten D. Optimum detection and receiver performance for multistatic radar configurations[C]. IEEE International Conference on Acoustics,Speech and Signal Processing (ICASSP),1982: 359-362.

[27] Seliga T A,Coyne F J. Multistatic radar as a means of dealing with the detection of multipath false targets by airport surface detection equipment radars[C]. 2003 IEEE Radar Conference,2003: 329-336.

[28] Adjrad M,Woodbridge K. A framework for the analysis of spatially coherent and incoherent multistatic radar systems[C]. The 7th International Workshop on Systems,Signal Processing and their Applications (WOSSPA),2011: 155-158.

[29] 陈卫东. 基于宽带多传感器系统的目标精确定位与跟踪[D]. 合肥: 中国科学技术大学,2005.

[30] 赵锋,艾小锋,刘进,等. 组网雷达系统建模与仿真[M]. 北京: 电子工业出版社,2018.

[31] 周生华. 分集MIMO雷达目标散射特性与检测算法[D]. 西安: 西安电子科技大学,2011.

[32] 陈伯孝,吴剑旗. 综合脉冲孔径雷达[M]. 北京: 国防工业出版社,2011.

[33] 电科战略情报团队. 世界预警探测领域2019年发展回顾与2020年展望[EB/OL].

[34] 电科战略情报团队. 世界预警探测领域2021年度十大进展[EB/OL].

[35] 戴喜增,彭应宁,汤俊. MIMO雷达检测性能[J]. 清华大学学报(自然科学版),2007,47(1): 88-91.

[36] 汤小为,唐波,汤俊. 集中式多输入多输出雷达信号盲分离算法研究[J]. 宇航学报,2013,34(5): 679-685.

[37] 李艳艳,苏涛. 机动目标跟踪的分布式MIMO雷达资源分配算法[J]. 西安电子科技大学学报(自然科学版),2016,43(4): 10-16.

[38] 冯涵哲,严俊坤,刘宏伟. 一种用于多目标定位的MIMO雷达快速功率分配算法[J]. 电子与信息学报,2016,38(12): 3219-3223.

[39] 何茜. MIMO雷达检测与估计理论研究[D]. 成都: 电子科技大学,2009.

[40] 廖宇羽. 统计MIMO雷达检测理论研究[D]. 成都: 电子科技大学,2012.

[41] Yang J C,Su W M,Gu H. 3D imaging using narrowband bistatic MIMO radar[J]. Electronics Letters,2014,50(15): 1090-1092.

[42] 周伟.多发多收合成孔径雷达成像及动目标检测技术研究[D].长沙:国防科学技术大学,2013.

[43] Wang P,Li H B,Himed B. Centralized and distributed tests for moving target detection with MIMO radars in clutter of non-homogeneous power[C]. 2011 Conference Record of the 44th Asilomar Conference on Signals,Systems and Computers (ASILOMAR),2011: 878-882.

[44] Wang P,Li H B,Himed B. Distributed detection of moving target using MIMO radar in clutter with non-homogeneous power[C]. The 7th International Workshop on Systems,Signal Processing and their Applications (WOSSPA),2011: 383-387.

[45] Hack D E,Patton L K,Himed B,et al. Detection in passive MIMO radar networks[J]. IEEE Transactions on Signal Processing,2014,62(11): 2999-3012.

[46] Ali T,Sadeque A Z,Saquib M,et al. MIMO radar for target detection and localization in sensor networks[J]. IEEE Systems Journal,2014,8(1): 75-82.

[47] Li H B,Wang Z,Liu J,et al. Moving target detection in distributed MIMO radar on moving platforms[J]. IEEE Journal of Selected Topics in Signal Processing,2015,9(8): 1524-1535.

[48] Fishler E,Haimovich A,Blum R S,et al. Spatial diversity in radars-models and detection performance [J]. IEEE Transactions on Signal Processing,2006,54(3): 823-838.

[49] Song X F,Willett P,Zhou S L. Detection performance for statistical MIMO radar with identical and orthogonal waveforms[C]. IEEE Radar Conference,2011: 22-26.

[50] 宋靖,张剑云. 分布式全相参雷达相参性能分析[J]. 电子与信息学报,2015,37(1): 9-14.

[51] 程子扬,何子述,王智磊,等. 分布式MIMO雷达目标检测性能分析[J]. 雷达学报,2017,6(1): 81-89.

[52] 曹鼎,周生华,刘宏伟,等. 基于删失数据的低通信量融合检测方法[J]. 电子与信息学报,2018,40(12): 2826-2833.

[53] Hassanien A,Himed B,Metcalf J,et al. Moving target detection in spatially heterogeneous clutter using distributed MIMO radar[C]. 2018 International Conference on Radar (RADAR),2018: 1-6.

[54] 孙文杰,张彦飞,孙玉梅,等.非均匀环境中MIMO雷达距离扩展目标检测器[J]. 电光与控制,2019,26(10): 67-72.

[55] 龚树凤,龙伟军,贲德,等. 组网雷达自适应模糊CFAR检测融合算法[J]. 系统工程与电子技术,2022,44(1): 100-107.

[56] 徐洪奎,王东进. 基于卡尔曼滤波的组网雷达系统目标跟踪分析[J]. 系统工程与电子技术,2011,23(11): 67-69.

[57] Godrich H,Haimovich A M,Blum R S. A MIMO radar system approach to target tracking[C]. 2009 Conference Record of the 43rd Asilomar Conference on Signals,Systems and Computers (ASILOMAR),2009: 1186-1190.

[58] Hachour S,Delmotte F,Mercier D,et al. Multi-sensor multi-target tracking with robust kinematic data based credal classification[C]. 2013 Workshop on Sensor Data Fusion: Trends,Solutions,Applications (SDF),2013: 1-6.

[59] 罗浩,尚朝轩,韩壮志,等. 组网火控雷达传感器分配研究[J]. 传感器与微系统,2014,33(6): 45-48.

[60] Liu H W,Liu H L,Dan X D,et al. Cooperative track initiation for distributed radar network based on target track information[J]. IET Radar,Sonar & Navigation,2016,10(4): 735-741.

[61] Yan J K,Liu H W,Pu W Q,et al. Benefit analysis of data fusion for target tracking in multiple radar system[J]. IEEE Sensors Journal,2016,16(16): 6359-6366.

[62] 张正言,张剑云,周青松. 目标个数未知时双基地MIMO雷达多目标角度跟踪算法研究[J]. 电子与信息学报,2018,40(10): 2491-2497.

[63] 王树亮,毕大平,阮怀林,等. 基于信息熵准则的认知雷达机动目标跟踪算法[J]. 电子学报,2019,47(6): 1277-1284.

[64] 王经鹤,易伟,孔令讲. 组网雷达多帧检测前跟踪算法研究[J]. 雷达学报,2019,8(4): 490-500.

[65] 赵艳丽,王雪松,王国玉,等. 多假目标欺骗干扰下组网雷达跟踪技术[J]. 电子学报,2007,35(3): 454-458.

[66] Yang C Q,Zhang H,Qu F Z,et al. Performance of target tracking in radar network system under deception attack[C]. International Conference on Wireless Algorithms,Systems,and Applications,2015: 664-673.

[67] 李世忠,王国宏,吴巍,等. 分布式干扰下组网雷达目标检测与跟踪技术[J]. 系统工程与电子技术,2012,34(4): 782-788.

[68] 胡子军,张林让,赵珊珊,等. 组网无源雷达高速多目标初始化及跟踪算法[J]. 西安电子科技大学学报(自然科学版),2014,41(6): 25-30,110.

[69] 贺达超,孙殿星,杨忠,等. 压制干扰下雷达网基于UCMKF的目标跟踪技术[C]. 第七届中国信息融合大会,2015: 977-982.

[70] He Q,Blum R S,Haimovich A M. Noncoherent MIMO radar for location and velocity estimation: More antennas means better performance[J]. IEEE Transactions on Signal Processing,2010,58(7): 3661-3680.

[71] He Q,Blum R S. Noncoherent versus coherent MIMO radar: Performance and simplicity analysis[J]. Signal Processing,2012,92(10): 2454-2463.

[72] 马鹏,郑志东,张剑云,等. 分布式MIMO雷达的参数估计与检测联合算法[J]. 电路与系统学报,2013,18(2): 228-235.

[73] 郑志东,周青松,张剑云,等. 运动双基地MIMO雷达的参数估计性能[J]. 电子与信息学报,2013,35(8): 1847-1853.

[74] 宋靖,张剑云,郑志东,等. 分布式全相参雷达相干参数估计性能[J]. 电子与信息学报,2014,36(8): 1926-1931.

[75] 张洪纲,雷子健,刘泉华. 基于MUSIC法的宽带分布式全相参雷达相参参数估计方法[J]. 信号处理,2015,31(2): 208-214.

[76] 程院兵,吴临江,郑昱,等. 基于多维范德蒙德结构的双基地MIMO雷达收发角及多普勒频率联合估计[J]. 电子与信息学报,2018,40(9): 2258-2264.

[77] 徐保庆,赵永波,庞晓娇. 基于实值处理的联合波束域双基地MIMO雷达测角算法[J]. 电子与信息学报,2019,41(7): 1721-1727.

[78] 师俊朋,文方青,艾林,等. 空域色噪声背景下双基地MIMO雷达角度估计[J]. 系统工程与电子技术,2021,43(6): 1477-1485.

[79] Gogineni S,Rangaswamy M,Rigling B D,et al. Cramer-Rao bounds for UMTS-based passive multistatic radar[J]. IEEE Transactions on Signal Processing,2014,62(1): 95-106.

[80] Filip A,Shutin D. Cramér-Rao bounds for L-band digital aeronautical communication system type 1 based passive multiple-input multiple-output radar[J]. IET Radar,Sonar & Navigation,2016,10(2): 348-358.

[81] Javed M N,Ali S,Hassan S A. 3D MCRLB evaluation of a UMTS-based passive multistatic radar operating in a line-of-sight environment[J]. IEEE Transactions on Signal Processing,2016,64(19): 5131-5144.

[82] Antonio G S,Fuhrmann D R,Robey F C. MIMO radar ambiguity functions[J]. IEEE Journal of Selected Topics in Signal Processing,2007,1(1): 167-177.

[83] Chen C Y,Vaidyanathan P P. MIMO radar ambiguity properties and optimization using frequency-hopping waveforms[J]. IEEE Transactions on Signal Processing,2008,56(12): 5926-5936.

[84] Yang Y,Blum R S. MIMO radar waveform design based on mutual information and minimum mean-square error estimation[J]. IEEE Transactions on Aerospace and Electronic Systems,2007,43(1): 330-343.

[85] Tang B,Tang J,Peng Y N. MIMO radar waveform design in colored noise based on information theory[J]. IEEE Transactions on Signal Processing,2010,58(9): 4684-4697.

[86] Naghsh M M,Mahmoud M H,Shahram S P,et al. Unified optimization framework for multi-static radar code design using information-theoretic criteria[J]. IEEE Transactions on Signal Processing,2013,61(21): 5401-5416.

[87] Nguyen N H,Dogancay K,Davis L M. Adaptive waveform selection for multistatic target tracking[J]. IEEE Transactions on Aerospace and Electronic Systems,2015,51(1): 688-700.

[88] Tang B,Li J. Spectrally constrained MIMO radar waveform design based on mutual information[J]. IEEE Transactions on Signal Processing,2019,67(3): 821-834.

[89] Daniel A,Popescu D C. MIMO radar waveform design for multiple extended target estimation based on greedy SINR maximization[C]. IEEE International Conference on Acoustics,Speech and Signal Processing (ICASSP),2016: 3006-3010.

[90] Panoui A,Lambotharan S,Chambers J A. Game theoretic distributed waveform design for multistatic radar networks[J]. IEEE Transactions on Aerospace and Electronic Systems,2016,52(4): 1855-1865.

[91] 徐磊磊,周生华,刘宏伟,等. 一种分布式MIMO雷达正交波形和失配滤波器组联合设计方法[J]. 电子与信息学报,2018,40(6): 1476-1483.

[92] 刘永军,廖桂生,李海川,等. 电磁空间分布式一体化波形设计与信息获取[J]. 中国科学基金,2021,35(5): 701-707.

[93] Yang Y,Blum R S. Minimax robust MIMO radar waveform design[J]. IEEE Journal of Selected Topics in Signal Processing,2007,4(1): 1-9.

[94] Jiu B,Liu H W,Feng D Z,et al. Minimax robust transmission waveform and receiving filter design for extended target detection with imprecise prior knowledge[J]. Signal Processing,2012,92(1): 210-218.

[95] Shi C G,Wang F,Sellathurai M,et al. Power minimization-based robust OFDM radar waveform design for radar and communication systems in Coexistence[J]. IEEE Transactions on Signal Processing,2018,66(5): 1316-1330.

[96] 孟令同. 机载平台相控阵雷达波束和路径资源管理算法研究[D]. 成都: 电子科技大学,2019.

[97] Godrich H,Petropulu A P,Poor H V. Power allocation strategies for target localization in distributed multiple-radar architectures[J]. IEEE Transactions on Signal Processing,2011,59(7): 3226-3240.

[98] Sun B,Chen H W,Wei X Z,et al. Power allocation for range-only localization in distributed multiple-input multiple-output radar networks-a cooperative game approach[J]. IET Radar,Sonar & Navigation,2014,8(7): 708-718.

[99] Ma B T,Chen H W,Sun B,et al. A joint scheme of antenna selection and power allocation for localization in MIMO radar sensor networks[J]. IEEE Communications Letters,2014,18(12): 2225-2228.

[100] Garcia N,Haimovich A M,Coulon M,et al. Resource allocation in MIMO radar with multiple targets for non-coherent localization[J]. IEEE Transactions on Signal Processing,2014,62(10): 2656-2666.

[101] 胡捍英,孙扬,郑娜娥. 多目标速度估计的分布式MIMO雷达资源分配算法[J]. 电子与信息学报,2016,38(10): 2453-2460.

[102] 孙扬,郑娜娥,李玉翔,等. 目标定位的分布式MIMO雷达资源分配算法[J]. 系统工程与电子技术,2017,39(2): 304-309.

[103] Chavali P,Nehorai A. Scheduling and power allocation in a cognitive radar network for multiple-target tracking[J]. IEEE Transactions on Signal Processing,2012,60(2): 715-729.

[104] 严俊坤,戴奉周,秦童,等. 一种针对目标三维跟踪的多基地雷达系统功率分配算法[J]. 电子与信息学报,2013,35(4): 901-907.

[105] 严俊坤,纠博,刘宏伟,等. 一种针对多目标跟踪的多基地雷达系统聚类与功率联合分配算法[J]. 电子与信息学报,2013,35(8): 1875-1881.

[106] Chen H W,Ta S Y,Sun B. Cooperative game approach to power allocation for target tracking in distributed MIMO radar sensor networks[J]. IEEE Sensors Journal,2015,15(10): 5423-5432.

[107] Yan J K,Liu H W,Pu W Q,et al. Joint beam selection and power allocation for multiple targets tracking in netted colocated MIMO radar system[J]. IEEE Transactions on Signal Processing,2016,64(24): 6417-6427.

[108] 鲁彦希,何子述,程子扬,等. 多目标跟踪分布式MIMO雷达收发站联合选择优化算法[J]. 雷达学报,2017,6(1): 73-80.

[109] 宋喜玉,任修坤,郑娜娥,等. 多目标跟踪下的分布式MIMO雷达资源联合优化算法[J]. 西安交通大学学报,2018,52(10): 110-115,123.

[110] Zhang H W,Liu W J,Xie J W,et al. Joint subarray selection and power allocation for cognitive target tracking in large-scale MIMO radar networks[J]. IEEE Systems Journal,2020,14(2): 2569-2580.

[111] Yi W,Yuan Y,Hoseinnezhad R,et al. Resource scheduling for distributed multi-target tracking in netted colocated MIMO radar systems[J]. IEEE Transactions on Signal Processing,2020,68: 1602-1617.

[112] Sun H,Li M,Zuo L,et al. Resource allocation for multitarget tracking and data reduction in radar network with sensor location uncertainty[J]. IEEE Transactions on Signal Processing,2021,69: 4843-4858.

[113] Bell K,Kreucher C,Rangaswamy M. An evaluation of task and information driven approaches for radar resource allocation[C]. 2021 IEEE Radar Conference (RadarConf21),Atlanta,2021: 1-6.

[114] Du Y,Liao K F,Duyang Shan,et al. Time and aperture resource allocation strategy for multitarget ISAR imaging in a radar network[J]. IEEE Sensors Journal,2020,20(6): 3196-3206.

[115] Su Y,Cheng T,He Z S,et al. Joint waveform control and resource optimization for maneuvering targets tracking in netted colocated MIMO radar systems[J]. IEEE Systems Journal,2021.

[116] Durst S,Bruggenwirth S. Quality of service based radar resource management using deep reinforcement learning[C]. 2021 IEEE Radar Conference (RadarConf21),Atlanta,2021: 1-6.

[117] Rock J,Roth W,Toth M,et al. Resource-efficient deep neural networks for automotive radar interference mitigation[J]. IEEE Journal of Selected Topics in Signal Processing,2021,15(4): 927-940.

[118] Shi Y C,Jiu B,Yan J K,et al. Data-driven radar selection and power allocation method for target tracking in multiple radar system[J]. IEEE Sensors Journal,2021,21(17): 19296-19306.

[119] 陈国海. 先进战机多功能相控阵系统综合射频隐身技术[J]. 现代雷达,2007,29(12): 1-4.

[120] Schleher D C. Low probability of intercept radar[C]. International Radar Conference,1985:346-349.

[121] Schrick G,Wiley R G. Interception of LPI radar signals[C]. Record of the IEEE 1990 International Radar Conference,1990: 108-111.

[122] Denk A. Detection and jamming low probability of intercept (LPI)radars[D]. California: Naval Post Graduate School,2006.

[123] Liu G S,Gu H,Su W M,et al. The analysis and design of modern low probability of intercept radar[C]. Proceedings of the 2001 CIE International Conference on Radar,2001: 120-124.

[124] Schleher D C. LPI radar: fact or fiction[J]. IEEE Aerospace and Electronic Systems Magazine,2006,21(5): 3-6.

[125] Wu P H . On sensitivity analysis of low probability of intercept (LPI)capability[C]. IEEE Military Communications Conference (MILCOM),2005: 2889-2895.

[126] Dishman J F,Beadle E R. SEVR: A LPD metric for a 3-D battle space[C]. IEEE Military Communications Conference (MILCOM),2007: 1-5.

[127] 杨红兵,周建江,汪飞,等. 飞机射频隐身表征参量及其影响因素分析[J]. 航空学报,2010,31(10): 2040-2045.

[128] 朱银川. 飞行器射频隐身技术内涵及性能度量研究[J]. 电讯技术,2013,53(1): 6-11.

[129] 赵宜楠,亓玉佩,赵占峰,等. 分布式MIMO雷达的低截获特性分析[J]. 哈尔滨工业大学学报,2014,46(1): 59-63.

[130] 何召阳,王谦喆,宋博文,等. 雷达信号波形域射频隐身性能评估方法[J]. 系统工程与电子技术,2017,39(10): 2234-2238.

[131] 曾小东. 基于层析分析法的射频隐身性能评估[J]. 现代雷达,2018,40(8): 16-19.

[132] 杨诚修,王谦喆,李淑婧,等. 突防场景下基于NWHFS的集群射频隐身性能评估[J]. 系统工程与电子技术,2020,42(5): 1109-1115.

[133] 高超,邓晓波,郑世友. 基于瞬时时宽带宽积的LPI波形射频隐身性能评估方法[J]. 现代雷达,2021,43(8): 62-65.

[134] 魏保华,王成,范书义,等. 地空导弹武器平台射频隐身性能内涵及度量研究[J]. 战术导弹技术,2021,(6): 78-84.

[135] Duncan P H. Overlapping search with scanned beam applications[J]. IEEE Transactions on Aerospace and Electronic Systems,1996,32(3): 984-994.

[136] Billam E R. The problem of time in phased array radar[C]. Proceedings of IET Conference on Radar,1997: 563-575.

[137] Abdel-Samad A A,Tewfik A H. Search strategies for radar target localization[C]. Proceedings of International Conference on Image Processing,1999: 862-866.

[138] 徐斌,杨晨阳,李少洪,等. 相控阵雷达的最优分区搜索算法[J]. 电子学报,2000,28(12): 69-73.

[139] Zatman M. Radar resource management for UESA[C]. Proceedings of the IEEE Radar Conference,2002: 73-76.

[140] Matthiesen D J. Optimal search radar[C]. Proceedings of the IEEE International Symposium on Phased Array Systems and Technology,2003: 259-264.

[141] 王雪松,汪连栋,肖顺平,等. 相控阵雷达天线最佳波位研究[J]. 电子学报,2003,31(6): 805-808.

[142] 周颖,王雪松,王国玉,等. 相控阵雷达最优波位编排的边界约束算法研究[J]. 电子学报,2004,32(6): 997-1000.

[143] 周颖,王雪松,王国玉. 相控阵雷达最优搜索随机规划研究[J]. 现代雷达,2005,27(4): 60-63.

[144] Gillespie B,Hughes E,Lewis M. Scan scheduling of multi-function phased array radars using heuristic techniques[C]. Proceedings of the IEEE International Radar Conference,2005: 513- 518.

[145] 张贞凯,周建江,汪飞,等. 机载相控阵雷达射频隐身时最优搜索性能研究[J]. 宇航学报,2011,32(9): 2023-2028.

[146] 张杰,汪飞,阮淑芬.基于射频隐身的相控阵雷达搜索控制参量优化设计[J]. 数据采集与处理,2014,29(4): 636-641.

[147] 李寰宇,查宇飞,李浩,等. 联合截获威胁下的雷达射频隐身目标搜索算法[J]. 航空学报,2015,36(6): 1953-1963.

[148] 刘一鸣,盛文. 相控阵雷达资源受限时搜索参数调整策略[J]. 现代雷达,2020,42(1): 8-12.

[149] 王亚涛,曾小东,周龙建. 雷达间歇辐射对测向交叉定位性能的影响分析[J]. 电子与信息学报,2020,42(2): 452-457.

[150] 王奥亚,周生华,彭晓军,等. 机载静默射频噪声掩护技术研究[J]. 电子与信息学报,2021,43(10): 2790-2797.

[151] 裴云,杨青山. 机载火控雷达的射频隐身与电磁机动[J]. 电光与控制,2021,28(10): 104-109.

[152] Gilson W H. Minimum Power Requirements for Tracking[C]. IEEE International Radar Conference,1990: 417-421.

[153] Keuk G V,Blackman S S. On phased-array radar tracking and parameter control[J]. IEEE Transactions on Aerospace and Electronic Systems,1993,29(1): 186-194.

[154] Daeipour E,Bar-Shalom Y,Li X. Adaptive beam pointing control of a phased array radar using an IMM estimator[C]. Proceedings of the American Control Conference,1994: 2093-2097.

[155] Blair W D,Watson G A,Kirubarajan T,et al. Benchmark for radar allocation and tracking in ECM[J]. IEEE Transactions on Aerospace and Electronic Systems,1998,34(4): 1097-1114.

[156] Kirubarajan T,Bar-Shalom Y,Blair W D,et al. IMMPDAF for radar management and tracking benchmark with ECM[J]. IEEE Transactions on Aerospace and Electronic Systems,1998,34(4): 1115-1134.

[157] Zwaga J H,Boers Y,Driessen H. On tracking performance constrained MFR parameter control[C]. Proceedings of the Sixth International Conference of Information Fusion,2003: 712-718.

[158] Kuo T W,Chao Y S,Kuo C F,et al. Real-time dwell scheduling of component-oriented phased array radars[J]. IEEE Transactions on Computers,2005,54(1): 47-60.

[159] 鉴福升,徐跃民,阴泽杰.基于IMM的电扫描雷达参数控制算法研究[J]. 中国科学技术大学学报,2010,40(3): 294-298.

[160] 张贞凯,周建江,田雨波,等. 基于射频隐身的采样间隔和功率设计[J]. 现代雷达,2012,34(4): 19-23.

[161] 李寰宇,柏鹏,王徐华,等. 电波频率对射频隐身性能的影响分析[J]. 系统工程与电子技术,2012,34(6): 1108-1112.

[162] 刘宏强,魏贤智,黄俊,等. 雷达单目标跟踪射频隐身控制策略[J]. 空军工程大学学报(自然科学版),2013,14 (4): 32-35.

[163] 刘宏强,魏贤智,李飞,等. 基于射频隐身的雷达跟踪状态下单次辐射能量实时控制方法[J]. 电子学报,2015,43(10): 2047-2052.

[164] 张贞凯,许娇,田雨波. 多目标跟踪时的自适应功率分配算法[J]. 信号处理,2017,33(S1): 22-26.

[165] 张昀普,单甘霖,段修生,等. 主/被动传感器辐射控制的调度方法[J]. 西安电子科技大学学报,2019,46(6): 67-74.

[166] Shi C G,Ding L T,Wang F,et al. Low probability of intercept-based collaborative power and bandwidth allocation strategy for multi-target tracking in distributed radar network system[J]. IEEE Sensors Journal,2020,20(12): 6367-6377.

[167] 漆杨. MIMO雷达射频隐身性能研究[D]. 成都: 电子科技大学,2012.

[168] 蔡茂鑫,舒其建,李勇华,等. MIMO雷达射频隐身性能的评估[J]. 雷达科学与技术,2013,11(3): 267-270.

[169] 廖雯雯,程婷,何子述. MIMO雷达射频隐身性能优化的目标跟踪算法[J]. 航空学报,2014,35(4): 1134-1141.

[170] 杨少委,程婷,何子述. MIMO雷达搜索模式下的射频隐身算法[J]. 电子与信息学报,2014,36(5): 1017-1022.

[171] 赵晓彤,周建江. 低截获MIMO雷达改进MUSIC算法[J]. 系统工程与电子技术,2022,44(2): 490-497.

[172] 杨宇晓,周建江,陈卫东,等. 基于空间信息的射频隐身数据链最优能量控制算法[J]. 宇航学报,2013,34(7): 1008-1013.

[173] 杨宇晓,周建江,徐川. 射频隐身数据链功率控制方法研究[J]. 现代雷达,2013,35(12): 80-84.

[174] 王正海. 战术数据链射频辐射特征控制技术[J]. 电讯技术,2014,54(5): 668-673.

[175] 刘淑慧. 机载数据链射频隐身综合控制技术[J]. 指挥控制与仿真,2015,37(5): 108-112.

[176] 谢桂辉,田茂,王正海,等. 射频隐身数据链的通信波形参数优化建模[J]. 西安交通大学学报,2015,49(4): 116-122.

[177] 杨宇晓,周建江,陈军,等. 基于最大条件熵的射频隐身数据链猝发通信模型[J]. 航空学报,2014,35(5): 1385-1393.

[178] 贺刚,柏鹏,彭卫东,等. 数据链中基于组合代价函数的博弈功率控制[J]. 江西师范大学学报(自然科学版),2012,36(6): 615-618.

[179] 贺刚,柏鹏,彭卫东,等. 数据链中基于动态博弈的联合功率与速率控制[J]. 西南交通大学学报,2013,48(3): 473-480.

[180] 杨宇晓,汪德鑫,黄琪. 四维超混沌射频隐身跳频通信设计方法[J]. 宇航学报,2020,41(10): 1341-1349.

[181] 胡梦中,宋铮,刘月平. 一种新的低副瓣多波束形成方法[J]. 现代雷达,2007,29(10): 71-74.

[182] 刘姜玲,王小谟. 具有低截获概率的新型阵列天线[J]. 电波科学学报,2010,25(3): 441-444.

[183] Lawrence D E. Low probability of intercept antenna array beamforming[J]. IEEE Transactions on Antennas and Propagation,2010,58(9): 2858-2865.

[184] 李寰宇,柏鹏,王谦喆. 天线波束对飞机射频隐身性能的影响分析[J]. 现代防御技术,2012,40(4): 128-133,137.

[185] 肖永生,周建江,黄丽贞,等. 机载雷达射频隐身的空域不确定性研究与设计[J]. 现代雷达,2012,34(8): 11-15.

[186] Wang W Q,Shao H Z,Cai J Y. Range-angle-dependent beamforming by frequency diverse array antenna[J]. International Journal of Antennas and Propagation,2012,2012: 1-10.

[187] 张贞凯,周建江,汪飞. 基于射频隐身的雷达发射波束形成方法[J]. 雷达科学与技术,2013,11(2): 203-208,213.

[188] Basit A,Qureshi I M,Khan W,et al. Hybridization of cognitive radar and phased array radar having low probability of intercept transmit beamforming[J]. International Journal of Antennas and Propagation,2014,2014: 1-11.

[189] 李文兴,毛晓军,孙亚秀. 一种新的波束形成零陷展宽算法[J]. 电子与信息学报,2014,36(12): 2882-2888.

[190] Huang L,Gao K D,He Z M,et al. Cognitive MIMO frequency diverse array radar with high LPI performance[J]. International Journal of Antennas and Propagation,2016,2016: 1-11.

[191] 王文钦,邵怀宗,陈慧. 频控阵雷达: 概念、原理与应用[J]. 电子与信息学报,2016,38(4): 1000-1011.

[192] 王文钦,陈慧,郑植,等. 频控阵雷达技术及其应用研究进展[J]. 电子与信息学报,2018,7(2): 153-166.

[193] Wang W Q. Potential transmit beamforming schemes for active LPI radars[J]. IEEE Aerospace and Electronic Systems Magazine,2017,32(5): 46-52.

[194] Chen K J,Yang S W,Chen Y K,et al. LPI beamforming based on 4-D antenna arrays with pseudorandom time modulation[J]. IEEE Transactions on Antennas and Propagation,2020,68(3): 2068-2077.

[195] Chen K J,Yang S W,Chen Y K,et al. Transmit beamforming based on 4-D antennas arrays for low probability of intercept systems[J]. IEEE Transactions on Antennas and Propagation,2020,68(5): 3625-3634.

[196] 窦山岳,汪飞,于伟强,等. 基于频控阵的多普勒波束锐化高度表设计[J]. 系统工程与电子技术,2021,43(9): 2383-2391.

[197] Sun H B,Lu Y L. Ultra-wideband technology and random signal radar: An ideal combination[J]. IEEE Aerospace and Electronic Systems Magazine,2003,18(11): 3-7.

[198] Witte E D,Griffiths H D. Improved ultra-low range sidelobe pulse compression waveform design[J]. Electronics Letters,2004,40(22): 1448-1450.

[199] Dietl G,Wang J,Ding P,et al. Hybrid transmit waveform design based on beamforming and orthogonal space-time block coding[C]. IEEE International Conference on Acoustics,Speech,and Signal Processing,2005: 893-896.

[200] Kassab R,Lesturgie M,Fiorina J. Quasi-continuous waveform design for dynamic range reduction[J]. Electronics Letters,2008,44(10): 646-647.

[201] Geroleo F G,Brandt-Pearce M. Detection and estimation of multi-pulse LFMCW radar signals[C]. IEEE Radar Conference,2010: 1009-1013.

[202] 孙东延,陶建锋,付全喜. 用于低截获概率雷达的混合波形研究[J]. 航天电子对抗,2001,(3): 33-36.

[203] 姬长华,刘晓娟,张军杰,等. 低截获概率雷达复合信号设计技术[J]. 郑州大学学报(理学版),2002,34(3): 53-56.

[204] 程翥. 低截获概率雷达信号分析与一种新型信号的设计[J]. 系统工程与电子技术,2002,24(11): 31-33.

[205] Hou J G,Ran T,Tao S,et al. A novel LPI radar signal based on hyperbolic frequency hopping combined with Barker phase code[C]. 7th International Conference on Signal Processing (ICSP),2004: 2070-2073.

[206] 张艳芹,许录平,李剑. 一种具有低截获特性的组合调制雷达信号[J]. 弹道学报,2006,18(3): 90-93.

[207] 武文,李江,张兵,等. 一种低截获概率雷达信号设计与仿真[J]. 计算机技术与应用进展,2007,25(6): 1393-1396.

[208] 林云,司锡才,张振. 高距离分辨率的低截获概率雷达信号性能研究[J]. 航空电子技术,2008,39(3): 29-33.

[209] 郭贵虎,文贻军,戴天. 一种新型低截获FSK/PSK雷达信号分析[J]. 电讯技术,2009,49(8): 49-53.

[210] 杨红兵,周建江,汪飞,等. STLFMCW雷达信号波形设计与射频隐身特性分析[J]. 现代雷达,2011,33(4): 17-21.

[211] 杨红兵,周建江,汪飞,等. 噪声调制连续波雷达信号波形射频隐身特性[J]. 航空学报,2011,32(6): 1102-1111.

[212] Yang H B,Zhou J J,Wang F,et al. Design and analysis of Costas/PSK RF stealth signal waveform[C]. Proceedings of 2011 IEEE CIE International Conference on Radar,2011: 1247-1250.

[213] 黄美秀,陈祝明,段锐,等. 编码调频信号的低截获性能分析[J]. 现代雷达,2011,33(10): 33-37.

[214] 肖永生,周建江,黄丽贞,等. 基于OTR和SHT的射频隐身雷达信号设计[J]. 航空学报,2016,37(6): 1931-1939.

[215] 马晨曦. 低截获雷达通信一体化波形设计[D]. 西安: 西安电子科技大学,2018.

[216] 付银娟,李勇,徐丽琴,等. NLFM-Costas射频隐身雷达信号设计及分析[J]. 吉林大学学报(工学版),2019,49(3): 994-999.

[217] 付银娟,李勇,卢光跃,等. 脉间复合调频脉内相位编码雷达信号设计及分析[J]. 哈尔滨工程大学学报,2019,40(7): 1347-1353.

[218] 张然,程珺炜,苏文宇,等. 基于混沌理论的低截获波形设计[J]. 大连大学学报,2019,40(6): 1-7.

[219] 孙岩博,王亚涛,黄小艳. 基于随机化调制的射频隐身波形识别性能分析[J]. 计算机仿真,2020,37(10): 1-5,13.

[220] 张巍巍,时晨光,周建江,等. 面向射频隐身的组网雷达多目标跟踪波形优化设计方法[J]. 无人系统技术,2021,4(5): 53-60.

[221] 贾金伟,刘利民,韩壮志,等. 射频隐身雷达波形设计技术研究综述[J]. 电光与控制,2022.

[222] Deb S,Pattipati K R,Bar-Shalom Y. A multisensor-multitarget data association algorithm for heterogeneous sensors[J]. IEEE Transactions on Aerospace and Electronic Systems,1993,29(2): 560-568.

[223] Hathaway R J,Bezdek J C,Pedrycz W. A parametric model for fusing heterogeneous fuzzy data[J]. IEEE Transactions on Fuzzy Systems,1996,4(3): 270- 281.

[224] Challa S,Pulford G W. Joint target tracking and classification using radar and ESM sensors[J]. IEEE Transactions on Aerospace and Electronic Systems,2001,37(3): 1039-1055.

[225] Mhatre V P,Rosenberg C,Kofman D,et al. A minimum cost heterogeneous sensor network with a lifetime constraint[J]. IEEE Transactions on Mobile Computing,2005,4(1): 4-15.

[226] Lázaro M,Sanchez-Fernandez M,Artés-Rodriguez A. Optimal sensor selection in binary heterogeneous sensor networks[J]. IEEE Transactions on Signal Processing,2009,57(4): 1577-1587.

[227] 吴剑锋,赵玉芹. 多传感器数据融合技术研究[J]. 弹箭与制导学报,2004,24(4): 356-358.

[228] 王建明,刘国朝. 舰载雷达与ESM协同探测方法研究[J]. 舰船电子对抗,2007,30(6): 11-15.

[229] 吴巍,柳毅,杨玉山,等. 机载多传感器协同跟踪与辐射控制研究[J]. 弹箭与制导学报,2011,31(1): 153-156.

[230] 吴巍,柳毅,王国宏,等. 辐射限制下有源无源协同跟踪技术[J]. 信息与控制,2011,40(3): 418-423.

[231] 吴巍,王国宏,柳毅,等. 机载雷达、红外、电子支援措施协同跟踪与管理[J]. 系统工程与电子技术,2011,33(7): 1517-1522.

[232] 吴巍,王国宏,李世忠,等. ESM量测间歇下雷达/ESM协同跟踪与辐射控制[J]. 现代防御技术,2011,39(3): 132-138.

[233] 熊久良,封吉平,韩壮志,等. 组网红外/雷达协同间歇式目标跟踪[J]. 电讯技术,2011,51(11): 5-10.

[234] 刘浩,任清安,方青. 机载有源无源雷达联合探测数据融合研究[J]. 中国电子科学研究院学报,2011,6(1): 49-53.

[235] 薛朝晖,周文辉,李元平. 机载雷达与红外协同资源管理技术[J]. 现代雷达,2012,34(3): 1-5,21.

[236] 吴巍,王国宏,李世忠. 雷达间歇辅助下雷达红外协同跟踪技术[J]. 火力与指挥控制,2012,37(1): 155-158,163.

[237] 刘学全,李波,万开方,等. 基于多传感器协同的雷达猝发技术研究[J]. 中国民航大学学报,2012,30(6): 17-20.

[238] Zhang Z K,Zhu J H,Tian Y B,et al. Novel sensor selection strategy for LPI based on an improved IMMPF tracking method[J]. Journal of Systems Engineering and Electronics,2014,25(6): 1004-1010.

[239] Chen J,Wang F,Zhou J J,et al. A novel radar radiation control strategy based on passive tracking in multiple aircraft platforms[C]. 2014 IEEE China Summit & International Conference on Signal and Information Processing (ChinaSIP),2014: 777-780.

[240] 周峰,张亮亮,王建军,等. 一种主/被动雷达协同探测跟踪模式及算法研究[J]. 电光与控制,2014,21(2): 12-16.

[241] 吴卫华,江晶,高岚. 机载雷达辅助无源传感器对杂波环境下机动目标跟踪[J]. 控制与决策,2015,30(2): 277-282.

[242] 庞策,单甘霖,段修生,等. 基于风险理论的主动传感器管理方法及应用研究[J]. 电子学报,2019,47(7): 1425-1433.

[243] 赖作镁,乔文昇,古博,等. 任务性能约束下传感器协同辐射控制策略[J]. 系统工程与电子技术,2019,41(8): 1749-1754.

[244] 张宏斌,鞠艳秋,齐驰,等. 辐射控制条件下直升机多机传感器协同探测方法[J]. 探测与控制学报,2020,42(5): 63-67.

[245] 乔成林,单甘霖,王一川,等. 面向协同检测与跟踪的多传感器长时调度方法[J]. 控制与决策,2020,35(4): 799-806.

上一章目录下一章