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[3] 余旭東.未來戰(zhàn)場上無人機(jī)作戰(zhàn)使用十大方式[J].國防科技,2005(03):76-78.
Yu X D.Ten ways of UAV operation in the future battlefield[J].National Defense Science & Technology,2005(03):76-78.
[4] 馬碩,馬亞平.基于分層目標(biāo)任務(wù)網(wǎng)絡(luò)的作戰(zhàn)任務(wù)規(guī)劃方法[J].火力與指揮控制,2020,45(02):110-114.
Ma S,Ma Y P.A Mission planning method based on hierarchical goal-task network[J].Fire Control & Command Control,2020,45(02):110-114.
[5] 李鵬舉,毛鵬軍,耿乾,等.無人機(jī)集群技術(shù)研究現(xiàn)狀與趨勢[J].航空兵器,2020,27(04):25-32.
Li P J,Mao P J,Geng Q,et al.Research status and trend of UAV swarm technology[J].Aero Weaponry,2020,27(04):25-32.
[6] 薛瞾涵.艦載直升機(jī)安全著艦策略分析[D].南京:南京航空航天大學(xué),2018.
Xue Z H.Analysis of safe landing strategy of shipborne helicopter[D].Nanjing University of Aeronautics and Astronautics,2018.
[7] 陳杰敏,吳發(fā)林,耿澄浩,等.四旋翼無人機(jī)一致性編隊飛行控制方法[J].航空兵器,2017(06):25-31.
Chen J M,Wu F L,Geng C H,et al.Consensus-based formation control approach for quadrotor UAVs[J].Aero Weaponry,2017(06):25-31.
[8] 孫盛智,孟春寧,侯妍.無人機(jī)與巡航導(dǎo)彈自主協(xié)同作戰(zhàn)模式及關(guān)鍵技術(shù)[J].航空兵器,2019,26(04):10-15.
Sun S Z,Meng C N,Hou Y.Autonomous coordinated operation modes and key technologies between UAVS and cruise missiles[J].Aero Weaponry,2019,26(04):10-15.
[9] 韓維,吳立堯,張勇.艦載戰(zhàn)斗機(jī)/無人機(jī)編隊飛行控制研究現(xiàn)狀與展望[J].科學(xué)技術(shù)與工程,2019,19(36):73-80.
Han W,Wu L Y,Zhang Y.Review and prospect of flight control of carrier-based aircraft/unmanned aerial vehicles formation[J].Science Technology and Engineering,2019,19(36):73-80.
[10] 杜梓冰,張立豐,陳敬志,等.有人/無人機(jī)協(xié)同作戰(zhàn)演示驗證試飛關(guān)鍵技術(shù)[J].航空兵器,2019,26(04):75-81.
Du Z B,Zhang L F,Chen J Z,et al .Critical technologies of demonstration flight test of cooperative operation for manned/unmanned aerial vehicles[J].Aero Weaponry,2019,26(04):75-81.
Operational application mode and key technology of shipborne unmanned helicopter
SUN Shengzhi1, SUN Xiaoting2, ZHENG Weijuan1, ZHAO Xueyang1, MIAO Zhuang3
(1.China Coast Guard Academy, Ningbo 315801, China;2. Zhejiang DataCenter Data & Technology Co., Ltd., Ningbo 315048, China; 3. Information Research Center for Military Science, Beijing 100142, China)
Abstract: With the development of the ship borne unmanned helicopters, it has been widely used on marine combat, and it has become one of the important topics. From the view of marine combat, this paper described the key combat tasks about anti-submarine, anti-ship and air warning. With the progress of artificial intelligence technology, it researched three operational combat modes of shipborne unmanned helicopter passive mechanization, semi-autonomous informatization and full-autonomous intelligence. It proposed the key technologies of autonomous landing, autonomous formation flight and autonomous mission planning, and it provided important evidence and key support for the development of the unmanned helicopter combat equipment.
北京高博特廣告有限公司 版權(quán)所有,并保留所有權(quán)利 ? 2018 -2021
