-
摘要:
本文简要介绍了飞艇的发展沿革和研究现状. 通过同传统的航空器、航天器、潜艇和低空飞艇进行比较, 阐述了平流层飞艇的飞行原理. 从基本运动模型和复杂受力情况的角度, 系统地讨论了飞艇动力学研究进展, 包括空气动力学研究、静力分析、热力学分析、柔性体动力学及流固耦合研究. 然后综述了飞艇控制方法研究进展, 包括小扰动线性化控制、输入输出反馈线性化控制、基于Lyapunov 非线性稳定性的控制及其他控制方法. 最后展望了在平流层飞艇动力学与控制领域需要从6 个方面加强研究.
Abstract:The developmental history and research status of airship are briefly presented. Compared with the traditional aircraft, spacecraft, submarines and low altitude airship, the flight principle of stratospheric airships is elaborated. From the point of view of basic motion model and the complex force condition, progresses in dynamics research are discussed systematically, including aerodynamics research, static analysis, thermodynamic analysis, flexible body dynamics and the study of fluid-solid coupling. Then the progress in airship control methods is reviewed, including the small disturbance linearization control, input output feedback linearization control, the Lyapunov nonlinear stability based control and other control method. Finally, it is proposed to reinforce research efforts in six directions in the field of stratospheric airship dynamics and control.
-
Key words:
- stratospheric airships /
- flight mechanics /
- aerodynamics /
- thermodynamics /
- control
-
1 Khoury G A, Gillett J D. Airship Technology. London: Cambridge University Press, 1999 2 Toshitaka T, Takashi A. Effects of meteorological condition the operation of a stratospheric platform. The 3rd Stratospheric Platform System Workshop. Tokyo, Japan,2001 3 樊昌信. 一种发展中的新移动通信方式—- 平流层通信研 发概况. 现代电子技术, 2005, 19(210): 1-3, 9 4 Nayler A. Airship activity and development world-wide-2003. AIAA 2003-6727, 2003 5 Sano M, Komatsu K, Kimura J, et al. Airship shaped balloon test flights to the stratosphere. AIAA 2003-6798,2003 6 Harada K, Eguchi K, Sano M, et al. Experimental study of thermal modeling for stratospheric platform airships. AIAA 2003-6833, 2003 7 Funk P, Lutz T, Wagner S. Experimental investigations on hull-fin interferences of the LOTTE airship. Aerospace Science and Technology, 2003, 7: 603-610 8 Gomes S B V, Ramos J J G. Airship dynamic modeling for autonomous operation. Proceeding of the 1998 IEEE International Conference on Robotics & Automation, Leuven, Belgium, 1998. 3462-3467 9 Mueller J B, Paluszek M A, Zhao Y. Development of an aerodynamic model and control law design for a high altitude airship, AIAA 2004-6479, 2004 10 欧阳晋, 屈卫东, 席裕庚. 平流层验证飞艇的建模与分析. 上 海交通大学学报, 2003, 37(5): 956-960 11 陈澜, 安锦文, 杨常伟. 平流层飞艇建模关键问题研究. 西北 工业大学学报, 2007, 25(3): 383-387 12 李智斌, 吴雷, 刘其睿, 等. 小型全电飞艇巡航机动控制器设 计及仿真. 见: 2009 年先进航天控制技术发展学术会议论文 集, 福建武夷山, 2009. 121-129 13 Gomes S B V. An investigation of the flight dynamics of airships with application to the YEZ-2A : [PhD Thesis]. Cranfield Institute of Technology, 1990 14 蔡自立, 屈卫东, 席裕庚. 带有升降气囊与压块的飞艇动力学 建模. 应用数学和力学, 2005, 26(8): 979-987 15 施生达. 潜艇操纵性. 北京: 国防工业出版社, 1995 16 吴子牛. 空气动力学(下). 北京: 清华大学出版社, 2008 17 刘丹, 王晓亮, 单雪雄. 平流层飞艇的附加质量及其对飞艇 运动的影响. 计算机仿真, 2006, 23(6): 52-56 18 (俄) 尼卡拉伊维奇, 著. 现代飞艇设计导论. 吴飞, 王培美, 译. 北京: 国防工业出版社, 2009 19 徐忠新. 飞艇附加惯性的工程计算. 见: 浮空器发展与应用 学术交流会论文集, 北京, 2005 20 马烨, 单雪雄. 数值计算复杂外形物体附加质量的新方法. 计算机仿真, 2007, 24(5): 75-78 21 傅慧萍, 李杰. 附加质量CFD 计算方法研究. 哈尔滨工程大 学学报, 2011, 32(2): 148-152 22 黄旋, 鲁传敬, 李杰. 带空泡运动航行的附加质量研究. 水动 力研究与进展(A 辑), 2009, 24(6): 800-806 23 单雪雄, 薛雷平, 孙刚. 平流层定点平台若干空气动力学和 飞行力学问题. 见: 2003 空气动力学前沿研究论文集, 北京,2003. 404-409 24 Jones S P, DeLaurier J D. Aerodynamics estimation techniques for aerostat and airships. Journal of Aircraft, 1982,20(2): 120-126 25 苗景刚, 杨新, 周江华. 飞艇气动力半经验模型及其参数辨 识. 见: 2007 年中国浮空器大会论文集, 北京, 2007. 282-287 26 王晓亮, 单雪雄. 平流层飞艇空气动力估算. 力学季刊, 2006,27(2): 295-304 27 张向强, 姜鲁华, 王生, 等. 飞艇动力学方程. 计算机仿真,2008, 25(6): 79-82 28 张博, 王大华. 对流层飞艇净浮力变化规律的仿真研究. 海 军工程大学学报, 2009, 21(1): 107-112 29 Chen X, Qi H, Wang X, et al. Modeling and simulation of pressure control for stratospheric platform airship. In: Proceedings of the 6thWorld Congress on Intelligent Control and Automation, Dalian, China, 2006. 6208-6212 30 Kreider J F. Mathematical modeling of high altitude balloon performance. AIAA 1975-1385, 1975 31 Leland A C, Walter J H. New thermal and trajectory model for high-altitude balloons. Journal of Aircraft,1983, 20(6): 500-507 32 施红, 宋保银, 姚秋萍. 平流层飞艇上升过程的数值模拟. 导 弹与航天运载技术, 2008(3): 37-40 33 郑威, 王文隽, 李勇, 等. 平流层飞艇高度方向稳态运动建模 与特性分析. 系统仿真学报, 2008, 20(24): 6830-6833, 6838 34 方贤德, 王伟志, 李小建. 平流层飞艇热仿真初步探讨. 航天 返回与遥感, 2007, 28(2): 5-9 35 Cho C S, Raque S M.Influence of the infrared radiation on a high altitude scientific balloon. AIAA 2002-1044, 2002 36 姚伟, 李勇, 王文隽, 等. 平流层飞艇热力学模型和上升过程 仿真分析. 宇航学报, 2007, 28(3): 603-607 37 李德富, 夏新林, 杨小川. 球形浮空器升空过程中的瞬态热响 应. 工程热物理学报, 2009, 30(1): 108-110 38 Lei C, Patterson J C. A direct three-dimensional simulation of radiation-induced natural convection in a shallow wedge patterson. International Journal of Heat and Mass Transfer, 2003, 46(7): 1183-1197 39 Sparrow E M, Abraham J P. A new buoyancy model replacing the standard pseudo-density difference for internal natural convection in gases. International Journal of Heat and Mass Transfer, 2003, 46: 3583-3591 40 Henze M, Weigand B, Jens V W. Natural convection inside airship. AIAA 2006-3798, 2006 41 Yuwen Li, Meyer N, Inna S. Dynamics modeling of flexible airships, AIAA 2007-2212, 2007 42 Liu J, Lu C, Xue L. Investigation of airship aeroelasticity using fluid-structure interaction. Journal of Hydrody- namic, 2008, 20(2): 164-171 43 de Paiva E C, Benjovengo F, Bueno S S, et al. Nonlinear control approaches for an autonomous unmanned robotic airship. AIAA Aviation Technology, Integration and Operations Conference, Belfast, Northern Ireland, 2007 44 Schmidt D K. Dynamic modeling, control, and stationkeeping guidance of a large high-altitude near-space airship. AIAA 2006-6781, 2006 45 Miller C J, Sullivan J, McDonald S. High altitude airship simulation control and low altitude flight demonstration. AIAA 2007-2766, 2007 46 Elfes A, Bueno S S, Ramos J J G, et al. Modeling, control and perception for an autonomous robotic airships. Lecture Notes in Computer Science, 2002, 2238: 216-244 47 D’Ambrosio D, de Matteis G, deSocio L M. Controlled ascent of an airship for high altitudes. AIAA1995-3447,1995 48 Kaempf B G, Well K H. Attitude control system for a remotely-controlled airship. AIAA 1995-1622, 1995 49 de Paiva E C, Bueno S S, Bergerman M. A robust pitch attitude controller for AURORA’s semi-autonomous robotic airship. AIAA 1999-3907, 1999 50 王明建. 平流层飞艇平台的建模与控制方法研究: [硕士论 文]. 长沙: 国防科学技术大学, 2007 51 屈卫东, 罗昌行, 欧阳晋. 无人飞艇的鲁棒航向控制系统设 计. 系统仿真学报, 2004, 16(11): 2575-2579 52 Trevino R, Frye M, Franz J A, et al. Robust receding horizon control of a tri-turbofan airship. 2007 IEEE International Conference on Control and Automation, Guangzhou, China, 2007 53 Isidori A. Nonlinear Control System. New York: Springer- Verleg, 1995 54 Lee S J, Kim D M. Feedback linearization controller for semistation keeping of the unmanned airship. In: The 5th AIAA Aviation, Technology, Integration, and Operations Conference, Virginia, USA, 2005 55 Kusagaya T, Fujii H A, Kojima H, et al. Nonlinear optimal control applied to longitudinal motion of an airship. AIAA 2003-6801, 2003 56 Kulczycki E A, Joshi S S, Hess R A. Towards controller design for autonomous airships using SLC and LQR methods. AIAA 2006-6778, 2006 57 Wu Y, Zhu M, Zuo Z, et al. Trajectory Tracking of a high alitude unmanned airship based on adaptive feedback linearization. In: 2011 International Conference on Mechatronic Science, Electric Engineering and Computer, Jilin, China, 2011. 2257-2261 58 王晓亮, 单雪雄. 平流层飞艇姿态鲁棒控制研究. 系统仿真 学报, 2006, 18(5): 1271-1274, 1282 59 Wang X, Shan X. Airship attitude tracking system. Ap- plied Mathematics and Mechanics, 2006, 27(7): 919-926 60 Acosta D M, Joshi S S. Adptive nonlinear dynamic inversion control of an autonomous airship for the Exploration of Titan, AIAA 2007-6502, 2007 61 蔡自立. 平流层自治飞艇动力学建模与非线性控制研究: [博 士论文]. 上海: 上海交通大学, 2006 62 Beji L, Abichou A. Stabilization of a nonlinear underactuated autonomous airship-a combined averaging and backstepping approach. In: 3th International Workshop on Robot Motion and Control, Bukowy Dworek, Poland,2002 63 Benjovengo F P, Paiva E C. Nonlinear control approaches for an autonomous unmanned robotic airship. In: 17th AIAA Aviation Technology Conference, Belfast, Northern Ireland, 2007 64 Beji L, Abichou A. Tracking control of trim trajectories of a blimp for ascent and descent flight manieuvres. Inter- national Journal of Control, 2005, 78(10): 706-719 65 Hygounenc E, Soueres P. Automatic airship control involving backstepping techniques. In: 2002 IEEE Inter national Conference on Systems, Man, and Cybernetics, Hammamet, Tunisia, 2002 66 Lee S, Lee H. Back-stepping approach of trajectory tracking control for the mid-altitude unmanned airship. AIAA2007-6319, 2007 67 Repoulias F, Papadopoulos E. Robotic airship trajectory tracking control using a back-stepping methodology. In:2008 IEEE International Conference on Robotics and Automation, Pasadena, CA, USA, 2008 68 Azinheira J R, Moutinho A, Paiva E C. A backstepping controller for path-tracking of an underactuated autonomous airship. International Journal of Robust and Nonlinear Control, 2009, 19(4): 418-441 69 Azinheira J R, Moutinho A, Paiva E C. Airship hover stabilization using a backstepping control approach. Journal of Guidance, Control and Dynamics, 2006, 29(4): 903-914 70 Azinheira J R, Moutinho A. Hover control of an UAV with backstepping design including input saturations. IEEE Transactions on Control Systems Technology, 2008, 16(3):517-526 71 梁栋. 平流层飞艇定点保持模式控制方法研究: [硕士论文]. 北京: 中国空间技术研究院, 2007 72 de Paiva E C, Benjovengo F, Bueno S S. Sliding mode control for the path following of an unmanned airship. In:6th IFAC Symposium on Intelligent Autonomous Vehicles, Toulouse, France, 2007. 221-227 73 Benjovengo F P, Paiva E C. Sliding mode control approaches for an autonomous unmanned airship. AIAA2009-2869, 2009 74 刘健. 基于滑模变结构理论的平流层平台姿态控制: [硕士论 文]. 上海: 上海交通大学, 2006 75 付平, 周军, 郭建国. 基于变结构控制方法的自主飞艇定点控 制. 飞行力学, 2008, 26(5): 28-31 76 方存光. 平流层信息平台— 自主飞艇动力学建模与控制的 研究: [博士论文]. 沈阳: 东北大学, 2003 77 欧阳晋. 空中无人飞艇的建模与控制方法研究: [博士论文]. 上海: 上海交通大学, 2003 78 Maryam F, Hassan M, Hazem H R, et al. Performance comparison of classic and fuzzy logic controller for communication airship. IEEE/AIAA 28th Digital Avionics Systems Conference, Orlando, FL, USA, 2009 79 王润平, 安娜文, 吴梅, 等. 基于EA、LMI 与ANN 的平流 层飞艇纵向智能增稳控制系统设计. 弹箭与制导学报, 2007,27(2): 21-25, 28 80 Park C, Lee H, Tahk M, et al. Airship control using neural network augmented model inversion. In: Proceedings of 2003 IEEE Conference on Control Applications, Istanbul, Turkey, 2003. 558-563 81 Luo J, Xie S, Rao J, et al. Robotic airship mission path tracking control based on human operator’s skill. In: Proceedings 2005 IEEE International Symposium on Computational Intelligence in Robotics and Automation, Espoo, Finland, 2005. 537-540 82 刘其睿, 李勇. 平流层飞艇巡航姿态自适应神经网络补偿控 制. 空间控制技术与应用, 2009, 35(4): 34-38 83 Jia R, Frye M T, Qian C. Control of an airship using particle swarm optimization and neural network. In: Proceeding of the 2009 IEEE International Conference on Systems, Man, and Cybernetics, San Antonio, TX, USA,2009. 1809-1814 84 任一鹏, 田中伟, 吴子牛. 飞艇空气动力学及其相关问题. 航 空学报, 2010, 31(3): 431-443 85 李智斌, 岳宝增. 平流层飞艇大范围变参数与多场耦合的控 制. 见:《10000 个科学难题-信息科学卷》. 北京: 科学出版 社, 2011. 740-743 86 吴雷, 李勇, 李智斌. 一类平流层飞艇质量和惯量的计算方法 与分析. 空间控制技术与应用, 2010, 36(6): 39-42 87 Shi H, Song B, Yao Q. Thermal performance of stratospheric airships during ascent and descent. J. of Thermo- physics and Heat Transfer, 2009, 23(4): 816-821 88 Munk J, Hillsdon R. Design challenge of a long endurance airship. AIAA 1992-1266, 1992 89 Rooz N, Johnson E N. Design and modeling of an airship station holding. AIAA 2005-6200, 2005
计量
- 文章访问数: 3058
- HTML全文浏览量: 392
- PDF下载量: 2981
- 被引次数: 0