[6] HMS Queen Elizabeth: Royals attend aircraft carrier ceremony[EBOL]. BBC News. (20171207)[20220128]. https:latterdaysaintmag.comnewshmsqueenelizabethroyalsattendaircraftcarrierceremony.

[8] T DING, M QU, X WU et al. Defense strategy for resilient shipboard power systems considering sequential attacks. IEEE Transactions on Information Forensics and Security, 15, 3443-3453(2020).

[9] ZOHRABI N, ABDELWAHED S, SHI J. Reconfiguration of MVDC shipboard power systems: a model predictive control approach[C]2017 IEEE Electric Ship Technologies Symposium (ESTS). Arlington: IEEE, 2017: 253–258.

[12] M BABAEI, J SHI, S ABDELWAHED. A survey on fault detection, isolation, and reconfiguration methods in electric ship power systems. IEEE Access, 6, 9430-9441(2018).

[13] L N XU, J M GUERRERO, A LASHAB et al. A review of DC shipboard microgrids—Part II: control architectures, stability analysis, and protection schemes. IEEE Transactions on Power Electronics, 37, 4105-4120(2022).

[15] SABATUCCI L, SIMONE G D, COSSENTINO M. Shipboard power system reconfiguration: a selfadaptation exemplar[C]2018 IEEEACM 4th International Wkshop on Software Engineering f Smart CyberPhysical Systems. Gothenburg: IEEE, 2018: 4952.

[17] E SKJONG, R VOLDEN, E RODSKAR et al. Past, present, and future challenges of the marine vessel's electrical power system. IEEE Transactions on Transportation Electrification, 2, 522-537(2016).

[18] JAVAID U, DUJI D, VAN DER MERWE W. MVDC marine electrical distribution: are we ready[C]IECON 2015 41st Annual Conference of the IEEE Industrial Electronics Society. Yokohama: IEEE, 2016: 823–828.

[19] GLOVER J D, SARMA M S, OVERBYE T J. Power system analysis design[M]. 4th ed. Tampa: Thomson, 2008.

[20] ZHU W L, LIANG Z Z, ZHU Z Y, et al. A distributed hybrid control framewk f shipboard power system reconfiguration[C]2021 4th IEEE International Conference on Industrial CyberPhysical Systems (ICPS). Victia: IEEE, 2021: 769–774.

[25] SCHUDDEBEURS J D, BOOTH C D, BURT G M, et al. Impact of marine power system architectures on IFEP vessel availability survivability[C]2007 IEEE Electric Ship Technologies Symposium. Arlington: IEEE, 2007: 14–21.

[34] HU J, WANG T, WANG Z, et al. Switching system''s MLE based transient stability assessment of ACDC hybrid system considering continuous commutation failure[J] IEEE Transactions on Power Systems, 2021, 36(1): 757−768.

[35] CHEN K, LI Y G, ZHANG J L, et al. Dynamic economic dispatch f CHPMG system based on mixed logical dynamic model MPC method[C]2020 39th Chinese Control Conference (CCC). Shenyang: IEEE, 2020: 1630–1636.

[36] YASAR M, BEYTIN A, BAJPAI G, et al. Integrated electric power system supervision f reconfiguration damage mitigation[C]2009 IEEE Electric Ship Technologies Symposium. Baltime: IEEE, 2009: 345−352.

[37] BABAEI M, SHI J, ZOHRABI N, et al. Development of a hybrid model f shipboard power systems[C]2015 IEEE Electric Ship Technologies Symposium (ESTS). Old Town Alexria: IEEE, 2015: 145−149.

[38] LIANG Z Z, ZHU W L, SHI J, et al. Ship integrated power system reconfiguration research under partial observation[J]. Energy Repts, 2022, 8(Supp 5): 444−452.

[47] T F ZHANG, D F WU, L Y LI et al. A fault reconfiguration strategy based on adjustable space operator discrete state transition algorithm for ship microgrid system. Electric Power Systems Research, 205, 107707(2022).

[48] S BOSE, S PAL, B NATARAJAN et al. Analysis of optimal reconfiguration of shipboard power systems. IEEE Transactions on Power Systems, 27, 189-197(2012).

[50] W L ZHU, J SHI, P F ZHI et al. Distributed reconfiguration of a hybrid shipboard power system. IEEE Transactions on Power Systems, 36, 4-16(2021).

[51] S K SRIVASTAVA, K L BUTLER-PURRY. Probability-based predictive self-healing reconfiguration for shipboard power systems. IET Generation, Transmission & Distribution, 1, 405-413(2007).

[52] N D R SARMA, K S P RAO. A new 0-1 integer programming method of feeder reconfiguration for loss minimization in distribution systems. Electric Power Systems Research, 33, 125-131(1995).

[53] OUYANG L, LI Y, TAN Y, et al. Reconfiguration optimization of DC zonal distribution wk of shipboard power system[C]2016 IEEE Transptation Electrification Conference Expo, AsiaPacific (ITEC AsiaPacific). Busan: IEEE, 2016: 444448.

[54] BUTLER K L, SARMA N D R. General reconfiguration methodology f AC radial shipboard power systems[C]2000 IEEE Power Engineering Society Winter Meeting. Singape: IEEE, 2000: 1226−1230.

[56] F SHARIATZADEH, N KUMAR, A K SRIVASTAVA. Optimal control algorithms for reconfiguration of shipboard microgrid distribution system using intelligent techniques. IEEE Transactions on Industry Applications, 53, 474-482(2017).

[57] Y J JIANG, J G JIANG, Y K ZHANG. A novel fuzzy multiobjective model using adaptive genetic algorithm based on cloud theory for service restoration of shipboard power systems. IEEE Transactions on Power Systems, 27, 612-620(2012).

[60] M BABAEI, R JAFARI-MARANDI, S ABDELWAHED et al. A novel approach for real-time implementation of MVDC shipboard power system reconfiguration. International Journal of Electrical Power & Energy Systems, 100, 240-252(2018).

[61] C J WANG, X H WANG, J M XIAO et al. Fault reconfiguration of shipboard power system based on triple quantum differential evolution algorithm. Journal of Shanghai Jiao Tong University (Science), 21, 433-442(2016).

[62] S K SRIVASTAVA, K L BUTLER-PURRY, N D R SARMA. Shipboard power restored for active duty. IEEE Computer Applications in Power, 15, 16-23(2002).

[63] DING Z P, SRIVASTAVA S, CARTES D. Expert system based dynamic load shedding scheme f shipboard power systems[C]Conference Recd of the 2006 IEEE Industry Applications Conference FtyFirst IAS Annual Meeting. Tampa: IEEE, 2006: 13381344.

[67] C L SU, C K LAN, T C CHOU et al. Performance evaluation of multiagent systems for navy shipboard power system restoration. IEEE Transactions on Industry Applications, 51, 2769-2779(2015).

[71] BELKACEMI R, FELIACHI A. Design deployment of a multiagent system on a hardware prototype[C]IEEE PES General Meeting. Minneapolis: IEEE, 2010: 17.

[72] Z WANG, Z Y HU, X F YANG. Multi-agent and ant colony optimization for ship integrated power system network reconfiguration. Journal of Systems Engineering and Electronics, 33, 489-496(2022).

[73] Z WANG, L XIA, Y J WANG et al. Multiagent and particle swarm optimization for ship integrated power system network reconfiguration. Mathematical Problems in Engineering, 2014, 280345(2014).

[74] D PANASETSKY, D SIDOROV, Y LI et al. Centralized emergency control for multi-terminal VSC-based shipboard power systems. International Journal of Electrical Power & Energy Systems, 104, 205-214(2019).

[75] ZHU W L, SHI J, ZHI P F, et al. Mission based reconfiguration f hybrid shipboard power systems considering threats[C]2020 IEEE 18th International Conference on Industrial Infmatics (INDIN). Warwick: IEEE, 2020: 833838.