Modern defense systems are developing towards systematization, intellectualization and automation, which include the collaborative defense system on the sea between multiple unmanned surface vehicles (USVs) and unmanned aerial vehicles (UAVs). UAVs can fly in high altitude and collect marine environment information on patrolling. Furthermore, UAVs can plan defense paths for USVs to intercept intruders with full-assignment or reassignment strategies aiming at maximum overall beneˉts. Thus, we propose dynamic overlay reconnaissance algorithm based on genetic idea (GI-DORA) to solve the problem of multi-UAV multi-station reconnaissance. Moreover, we develop continuous particle swarm optimization based on obstacle dimension (OD-CPSO) to opti- mize defense path of USVs to intercept intruders. In addition, under the designed defense constraints, we propose dispersed particle swarm optimization based on mutation and crossover (MC-DPSO) and real-time batch assign- ment algorithm (RTBA) in emergency for formulating combat defense mission assignment strategy in di?erent scenarios. Finally, we illustrate the feasibility and effectiveness of the proposed methods.
WU Xing (武星), LIU Yuan (刘远), XIE Shaorong (谢少荣), GUO Yike (郭毅可)
. Collaborative Defense with Multiple USVs and UAVs Based on Swarm Intelligence[J]. Journal of Shanghai Jiaotong University(Science), 2020
, 25(1)
: 51
-56
.
DOI: 10.1007/s12204-019-2142-y
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