Dynamic inverse control of feedback linearization in ballistic correction based on nose cone swinging

Dynamic inverse control of feedback linearization in ballistic correction based on nose cone swinging

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摘要 It is a complicated nonlinear controlling problem to conduct a two-dimensional trajectory correction of rockets.By establishing the aerodynamic correction force mathematical model of rockets on nose cone swinging,the linear control is realized by the dynamic inverse nonlinear controlling theory and the three-time-scale separation method.The control ability and the simulation results are also tested and verified.The results show that the output responses of system track the expected curve well and the error is controlled in a given margin.The maximum correction is about±314 m in the lengthwise direction and±1 212 m in the crosswise direction from the moment of 5 s to the drop-point time when the angle of fire is 55°.Thus,based on the dynamic inverse control of feedback linearization,the trajectory correction capability of nose cone swinging can satisfy the requirements of two-dimensional ballistic correction,and the validity and effectiveness of the method are proved. It is a complicated nonlinear controlling problem to conduct a two-dimensional trajectory correction of rockets.By establishing the aerodynamic correction force mathematical model of rockets on nose cone swinging,the linear control is realized by the dynamic inverse nonlinear controlling theory and the three-time-scale separation method.The control ability and the simulation results are also tested and verified.The results show that the output responses of system track the expected curve well and the error is controlled in a given margin.The maximum correction is about ±314 m in the lengthwise direction and ±1 212 m in the crosswise direction from the moment of 5 s to the drop-point time when the angle of fire is 55°.Thus,based on the dynamic inverse control of feedback linearization,the trajectory correction capability of nose cone swinging can satisfy the requirements of two-dimensional ballistic correction,and the validity and effectiveness of the method are proved.

作者秦华伟王华

机构地区 College of Mechanical and Electrical Engineering School of Astronautics

出处《Journal of Central South University》 SCIE EI CAS 2013年第9期2447-2453,共7页 中南大学学报（英文版）

基金 Project(9140A05030109HK01)supported by Equipment Pre-research Foundation,China

关键词动态逆控制反馈线性化弹道修正摆动鼻锥非线性控制理论基础修正能力 nose cone swinging two-dimensional ballistic correction feedback linearization dynamic inverse control three-time-scale separation method

分类号 TJ013 [兵器科学与技术—兵器发射理论与技术]

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参考文献9

1王梦龙,王华,韩晶.基于引信头锥摆动的火箭弹弹道修正方法[J].探测与控制学报,2011,33(4):23-27. 被引量：5
2李怡勇,沈怀荣.无人机非线性动态逆控制器的设计研究[J].航天控制,2007,25(5):54-57. 被引量：7
3杨志峰,雷虎民,李庆良,李炯.基于RBF网络的导弹滑模动态逆控制律设计[J].北京航空航天大学学报,2011,37(2):167-170. 被引量：4
4林鹏,周军,周凤岐.变质心再入飞行器的动态逆控制器设计[J].飞行力学,2009,27(1):59-62. 被引量：5
5魏方海,王志军,尹建平.有头部偏角的尾翼火箭弹气动性能数值计算[J].弹箭与制导学报,2006,26(S3):553-554. 被引量：9
6韩飞,莫健华,龚攀,李敏.Method of closed loop springback compensation for incremental sheet forming process[J].Journal of Central South University,2011,18(5):1509-1517. 被引量：1
7Dan Necsulescu,Yi-Wu Jiang,Bumsoo Kim.Neural Network Based Feedback Linearization Control of an Unmanned Aerial Vehicle[J].International Journal of Automation and computing,2007,4(1):71-79. 被引量：3
8YOON Tae-Sung,王法广,PARK Seung-Kyu,KWAK Gun-Pyong,AHN Ho-Kyun.Linearization of T-S fuzzy systems and robust H_∞ control[J].Journal of Central South University,2011,18(1):140-145. 被引量：4
9乔清青,陈万春.基于动态逆的空空导弹奇异摄动中制导律[J].北京航空航天大学学报,2011,37(11):1365-1371. 被引量：7

二级参考文献62

1张艳,段朝阳,张平,陈宗基.基于动态逆的BTT导弹自动驾驶仪设计[J].北京航空航天大学学报,2007,33(4):422-426. 被引量：20
2潘明存,刘纯国,李明哲.基于快速测量的曲面多点成形精度控制[J].塑性工程学报,2007,14(3):16-19. 被引量：2
3曾颖超.战术导弹弹道与姿态动力学[M].西安：西北工业大学出版社,1991..
4Raymond H B. A Moving Mass Trini Control System for Re-Entry Vehicle Guidance [ J ]. Journal of Guidance, Control, and Dynamics, 1996,19 ( 2 ) :205-216.
5Sturgis. Moving Mass Trim Control for Aerospace Vehicles [J]. Journal of Guidance, Control, and Dynamics, 1996, 19(5) :1 064-1 070.
6HOW H,TSAI J T,CHOU J H.Robust-stable and quadratic-optimal control for TS-fuzzy-model-based control systems with elemental parametric uncertainties[J].IET Control Theory & Applications,2007,1(3):731-742.
7HOW H,TSAI J T,CHOU J H.Robust quadratic-optimal control of TS-fuzzy-model-based dynamic systems with both elemental parametric uncertainties and norm-bounded approximation error[J].IEEE Trans Fuzzy Systems,2009,17(3):518-531.
8HSU M R,HO W H,CHOU J H.Stable and quadratic optimal control for TS fuzzy-model-based time-delay control systems[J].IEEE Trans Man and Cybernetics Systems,Part A:Sysemns and Humans,2008,38(4):933-944.
9KRUSZEWSKI A,WANG R,GUERRA T M.Nonquadratic stabilization conditions for a class of uncertain nonlinear discrete time TS fuzzy models:A new approach[J].IEEE Trans Automatic Control,2008,53(2):606-611.
10TAKAGI T,SUGENO M.Fuzzy identification of systems and its applications to modeling and control[J].IEEE Trans Man and Cybernetics Systems,Part A:Systems and Humans,1985,15:116-132.

共引文献34

1崔世海,吴振雨,张晓东,娄术根.导弹自动驾驶仪设计方法综述[J].飞航导弹,2009(9):56-60. 被引量：5
2曾耀华,王华,韩晶,王义宁.基于非线性动态逆的弹道修正控制设计研究[J].弹箭与制导学报,2010,30(3):131-134. 被引量：2
3李明,陈智刚,董素荣,侯秀成.亚音速条件下可偏转头部弹气动特性研究[J].弹箭与制导学报,2010,30(5):147-148. 被引量：4
4Junaid Arshad,Paul Townend.An Automatic Intrusion Diagnosis Approach for Clouds[J].International Journal of Automation and computing,2011,8(3):286-296. 被引量：2
5Ahmad T.Abdulsadda,Kamran Iqbal.An Improved SPSA Algorithm for System Identification Using Fuzzy Rules for Training Neural Networks[J].International Journal of Automation and computing,2011,8(3):333-339. 被引量：1
6王梦龙,王华,韩晶.基于引信头锥摆动的火箭弹弹道修正方法[J].探测与控制学报,2011,33(4):23-27. 被引量：5
7王朋飞,曹红松,刘务平,刘莎,解宁波,沈冠军.引信头锥摆动角对火箭弹气动特性及控制能力影响[J].弹箭与制导学报,2013,33(1):152-155. 被引量：4
8崔乃刚,白瑜亮,常亚武,王小刚,许江涛.基于非线性动态逆的水下运载器控制方法研究[J].兵工学报,2013,34(4):443-450. 被引量：2
9史鲲,梁晓庚.实现中远程空空导弹铅垂面攻击的中制导律[J].计算机仿真,2013,30(5):86-89.
10秦华伟,王华.基于引信头锥摆动的弹道修正执行器设计[J].弹箭与制导学报,2013,33(3):87-90.

1杨志峰,雷虎民,李庆良,李炯.基于RBF网络的导弹滑模动态逆控制律设计[J].北京航空航天大学学报,2011,37(2):167-170. 被引量：4
2梅生伟,黎雄,卢强,孙元章,王文聪.Feedback Linearization H_∞ Control and Its Applicationto Excitation Systems[J].Tsinghua Science and Technology,1999,4(4):1701-1706. 被引量：2
3冯伟.基于REST风格的Android系统Web服务的研究[J].淮北职业技术学院学报,2012,11(3):87-88. 被引量：7
4郑丹.动能拦截器轨道修正能力的数值计算方法[J].现代防御技术,2017,45(1):62-69.
5Jing Hua Yang Cai Yimin Li.Adaptive Interval Type-2 Fuzzy Sliding Mode Control Based on Feedback Linearization[J].控制工程期刊（中英文版）,2014,4(5):138-149.
6杨志峰,雷虎民,董飞垚,徐剑芸.基于LS-SVM的导弹在线误差补偿逆控制[J].系统工程与电子技术,2010,32(6):1314-1317. 被引量：8
7S.X. Wang H. Li Z.X. Li.Control of Neural Network Feedback Linearization Based on Chaotic Particle Swarm Optimization[J].Journal of Energy and Power Engineering,2010,4(4):37-44. 被引量：1
8陈谋,邹庆元,姜长生,吴庆宪.基于神经网络干扰观测器的动态逆飞行控制[J].控制与决策,2008,23(3):283-287. 被引量：19
9刘玉玺,周军,周凤岐.A Study on Missile Reentry Control Based on the Method of Feedback Linearization[J].Defence Technology（防务技术）,2007,3(2):117-120.
10吴健.具有误差修正和智能接口的DSP测试系统研究[J].科技创新与生产力,2011(9):102-105.

Journal of Central South University

2013年第9期

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Dynamic inverse control of feedback linearization in ballistic correction based on nose cone swinging

参考文献9

二级参考文献62

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