期刊文献+

Dynamic simulation of aerial towed decoy system based on tension recurrence algorithm 被引量:5

Dynamic simulation of aerial towed decoy system based on tension recurrence algorithm
原文传递
导出
摘要 Dynamic model of aerial towed decoy system is established and simulations are performed to research the dynamic characteristics of the system. Firstly, Kinetic equations based on spinor are built, where the cable is discretized into a number of rigid segments while the decoy is modeled as a rigid body hinged on the cable. Then tension recurrence algorithm is developed to improve computational efficiency, which makes it possible to predict the dynamic response of aerial towed decoy system rapidly and accurately. Subsequently, the efficiency and validity of this algorithm are verified by comparison with Kane’s function and further validated by wind tunnel tests.Simulation results indicate that the distance between the towing point and the decoy’s center of gravity is suggested to be 5%–20% of the length of decoy body to ensure the stability of system.In up-risen maneuver process, the value of angular velocity is recommended to be less than0.10 rad/s to protect the cable from the aircraft exhaust jet. During the turning movement of aircraft, the cable’s extent of stretching outwards is proportional to the aircraft’s angular velocity.Meanwhile, the decoy, aircraft and missile form a triangle, which promotes the decoy’s performance. Dynamic model of aerial towed decoy system is established and simulations are performed to research the dynamic characteristics of the system. Firstly, Kinetic equations based on spinor are built, where the cable is discretized into a number of rigid segments while the decoy is modeled as a rigid body hinged on the cable. Then tension recurrence algorithm is developed to improve computational efficiency, which makes it possible to predict the dynamic response of aerial towed decoy system rapidly and accurately. Subsequently, the efficiency and validity of this algorithm are verified by comparison with Kane's function and further validated by wind tunnel tests.Simulation results indicate that the distance between the towing point and the decoy's center of gravity is suggested to be 5%–20% of the length of decoy body to ensure the stability of system.In up-risen maneuver process, the value of angular velocity is recommended to be less than0.10 rad/s to protect the cable from the aircraft exhaust jet. During the turning movement of aircraft, the cable's extent of stretching outwards is proportional to the aircraft's angular velocity.Meanwhile, the decoy, aircraft and missile form a triangle, which promotes the decoy's performance.
出处 《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2016年第6期1484-1495,共12页 中国航空学报(英文版)
关键词 Numerical simulation SPINOR Tension recurrence algorithm Towed cable Towed decoy Numerical simulation Spinor Tension recurrence algorithm Towed cable Towed decoy
  • 相关文献

参考文献3

二级参考文献23

  • 1Nam-Il KIM,Sang-Soo JEON,Moon-Young KIM.Nonlinear Finite Element Analysis of Ocean Cables[J].海洋工程:英文版,2004,18(4):537-550. 被引量:9
  • 2Ames B.Digital receivers power a new generation of electronic warfare[EB/OL].(2005-10-01)[2013-08-23].http://www.militaryaerospace.com/articles/print/volume16/issue-10/features/special-report/digital-receivers-power-a-new-generation of-electronic-warfare.html.
  • 3Nashua N H.Navy AN/ALE-55 aircraft electronic warfare system moves to full-rate production at BAE systems[EB/OL].(2011-10-02)[2013-08-23].http://www.militaryaerospace.com/articles/2011 / 10 /navy-an-ale-55-aircraft.html.
  • 4Zhu F,Rahn C D.Stability analysis of a circularly towed cable body system[J].Journal of Sound and Vibration,1998,217(3):435-452.
  • 5Jeffrey F,Joseph N,Timothy M.Design and control of a maneuverable towed aerial vehicle[C]//AIAA Guidance,Navigation,and Control Conference and Exhibit,2012.
  • 6Quisenberry J E,Arena A S.Discrete cable modeling and dynamic analysis[C]//44th AIAA Aerospace Sciences Meeting and Exhibit,2006.
  • 7Williams P,Trivailo P.A study on the transitional dynamics of a towed circular aerial cable system[C]//AIAA Atmospheric Flight Mechanics Conference and Exhibit,2005.
  • 8Williams P,Segarioto D,Trivailo P.Motion planning for an aerial-towed cable system[C]//AIAA Guidance,Navigation,and Control Conference and Exhibit,2005.
  • 9Williams P,Trivailo P.Periodic solutions for flexible cable-body systems towed in circular and elliptical paths[C]//AIAA Atmospheric Flight Mechanics Conference and Exhibit,2006.
  • 10Williams P,Trivailo P.Periodic optimal control of a towed aerial-cable system in presence of cross wind[C]//AIAA Atmospheric Flight Mechanics Conference and Exhibit,2006.

共引文献24

同被引文献27

引证文献5

二级引证文献15

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部