[3] CHEN Xiaolong, GUAN Jian, CHEN Weishi. Sparse long-time coherent integration-based detection method for radar lowobservable maneuvering target[J]. IET Radar,Sonar and Navigation, 2019,14(4):538-546.

[4] ABU-SHABAN Z, ZHOU X, ABHAYAPALA T D. A novel TOA-based mobile localization technique under mixed LOS/NLOS conditions for cellular networks[J]. IEEE Transactions on Vehicular Technology, 2016,65(11):8841-8853.

[5] WANG G,LI Y,ANSARI N. A semidefinite relaxation method for source localization using TDOA and FDOA measurements[J].IEEE Transactions on Vehicular Technology, 2013,62(2):853-862.

[6] WEISS L G. Wavelets and wideband correlation processing[J]. IEEE Processing Magazine, 1994,11(1):13-32.

[7] CHAN Y T, HO K C. Joint time-scale and TDOA estimation: analysis and fast approximation[J]. IEEE Transactions on Signal Processing, 2005,53(8):2634-2652.

[8] MA F, LIU Z, GUO F. Direct position determination for wideband sources using fast approximation[J]. IEEE Transactions on Vehicular Technology, 2019,68(8):8216-8221.

[9] JEAN O, WEISS A J. Passive localization and synchronization using arbitrary signals[J]. IEEE Transactions on Signal Processing, 2014,62(8):2143-2150.

[10] SUN C,, ZENG J, PAN J. An improved vector particle swarm optimization for constrained optimization problems[J]. Information Sciences, 2010,181(6):1153-1163.

[11] KOHLER M, VELLASCO M M B R, TANSCHEIT R. PSO+ : a new particle swarm optimization algorithm for constrained problems[J]. Applied Soft Computing, 2019(85):105865.

[13] ULLAH A S S M B,ELFEKY E Z,CORNFORTH D,et al. Improved evolutionary algorithms for solving constrained optimization problems with tiny feasible space[C]// IEEE International Conference on Systems,Man and Cybernetics. [S.l]:IEEE, 2008:1426-1433.