CJA ENGLISH

导航

联系我们
学术质量   |
广告服务   |
期刊征订   |
English Version CJA

航空学报 >

0 0 - 0

DOI: https://doi.org/10.7527/S1000-6893.2023.29720

新一代飞行器导航制导与控制技术发展趋势

  • 杨卫平
展开
  • 中国航空工业集团公司西安飞行自动控制研究所

收稿日期: 2023-10-13

  修回日期: 2023-11-06

  网络出版日期: 2023-11-07

收起

Development trend of navigation guidance and control technology for aircraft

  • YANG Wei-Ping
Expand

Received date: 2023-10-13

  Revised date: 2023-11-06

  Online published: 2023-11-07

Fold

摘要

本文系统梳理了航空导航制导与控制技术的国内外发展现状,通过在需求牵引、原理机理、产品实现、应用服务等几个方面的对比,分析了存在的差距并剖析了原因。在航空飞行器支撑体系化协同作战的大背景下,将网络化、体系化、智能化要求作为技术发展目标,在支撑新质作战概念、高精度自主导航、多体协同飞行器控制、新一代核心器件研发、下一代飞行器控制管理统一架构五个方面提出了导航制导与控制技术未来的发展重点和方案路线,最终在技术和管理两个层面提出行动建议,为引导我国优势创新资源有效联合,面向未来装备发展需要推进国防科技迈向高质量发展道路提供了重要参考。

关键词: 导航制导与控制(GNC); 航空飞行器; 高精度自主导航; 飞行控制; 飞行器管理

本文引用格式

杨卫平 . 新一代飞行器导航制导与控制技术发展趋势[J]. 航空学报, 0 : 0 -0 . DOI: 10.7527/S1000-6893.2023.29720

Abstract

This paper systematically sorts out the development status of aviation navigation guidance and control technology at home and abroad, analyzes the existing gaps and analyzes the reasons through the comparison of demand traction, principle mechanism, product realization and application services. Under the background of systematic coordinated operation supported by aviation aircraft, the requirements of networking, systematization and intelligence are taken as the technical development goals, and the future development priorities and program routes of navigation guidance and control technology are proposed in five aspects: supporting new quality combat concepts, high-precision autonomous navigation, multi-body cooperative aircraft control, research and development of new generation core devices, and unified architecture of next-generation air-craft control management, and finally put forward action suggestions at the two levels of technology and management, in order to guide the effective combination of China's advantageous innovation resources. Facing the needs of future equipment development, it provides an important reference for promoting national defense science and technology towards a high-quality development path.

Key words: Navigation, guidance and control(GNC); Aerial vehicles; High-precision autonomous navigation; Flight control; Aircraft management

参考文献

[1]范晋翔,陈晶华.未来空战新概念及其实现挑战[J][J].航空兵器, 2020, 27(2):15-24
[2]石玲玲,张恒,吕博等.美国空军装备技术体系规划及发展分析[J][J].国防科技, 2017, 306(5):31-35
[3]孙盛智,苗壮,高赞.美国马赛克战构想[J][J].火力与指挥控制, 2022, 47(10):180-184
[4]鲜勇,李扬.人工智能技术对未来空战武器的变革与展望[J][J].航空兵器, 2019, 26(5):26-31
[5]AF/ST.Report on technology horizons: a vision for Air Force Science & Technology during 2010-2030 [R]., 2010, :-
[6]Butz H.THE AIRBUS APPROACH TO OPEN INTEGRATED MODULAR AVIONICS (IMA): TECHNOLOGY, METHODS, PROCESSES AND FUTURE ROAD MAP[C].International Workshop on Aircraft System Technologies, 2010, :-
[7]Fengming Z, Wenkui C, Xiaoguang F, et al.Research on Architecture of Integrated Modular Avionics[J][J].Electronics Optics and Control, 2009, 09(013):1671-637X
[8]René L.C. Eveleens.Integrated Modular Avionics Development Guidance and Certification Considerations[J][J].national aerospace laboratory, 2006, 2(4):1-18
[9]MOORE, J.F .Civil integrated modular avi-onics – a longer‐term view[J].Aircraft Engineering & Aerospace Technology An In-ternational Journal, 1999, 71(6):550-557
[10]Savage, Paul G.Blazing Gyros: The Evolution of Strapdown Inertial Navigation Technology for Aircraft[J].Journal of Guid-ance Control & Dynamics, 2013, 36(3):637-655
[11]谭祖锋.惯性导航技术的新进展及其发展趋势[J][J].电子技术与软件工程, 2019, 05(05):76-76
[12] 高钟毓.惯性导航系统技术 : Inertial navigation system technology[M].清华大学出版社, 2012.
[13]Titterton D H, Weston J L.Strapdown Inertial Navigation Technology[J][J].Aerospace and Electronic Systems Magazine, 2004, 10(10):1049-1049
[14]杨新民, 陶征宇.世界上最小的嵌入式惯导/GPS组合导航系统H—764G的鉴定[J][J].惯导与仪表, 1997, 4(4):12-12
[15] 刘基余.GPS卫星导航定位原理与方法[M].科学出版社, 2003.
[16]陈忠贵, 帅平, 曲广吉.现代卫星导航系统技术特点与发展趋势分析[J][J].中国科学E辑, 2009, 4(10):1016-1016
[17] 方群.卫星定位导航基础[M].西北工业大学出版社, 1999.
[18]武珺,刘春保,李俊博.2021年国外导航卫星系统发展综述[J][J].国际太空, 2022, 2(2):38-41
[19]过静珺, 卢建刚, 吴卫峰, 等.欧洲伽利略导航系统的发展[J][J].测绘通报, 2002, 2(2):51-52
[20]李航, 蔡群, 王林强.俄罗斯GLONASS导航系统的现状与未来[J][J].外军信息战, 2010, 3(3):42-46
[21] 李建文.GLONASS卫星导航系统及GPS/GLONASS组合应用研究[D].解放军信息工程大学, 2001.
[22] 伯恩哈德?霍夫曼-韦伦霍夫, 赫伯特?利希特内格尔, 埃尔马?瓦斯勒, 等.全球卫星导航系统:GPS, GLONASS, Galileo及其他系统[M].测绘出版社, 2009.
[23]刘建业, 冷雪飞, 熊智, 等.惯性组合导航系统的实时多级景象匹配算法[J].航空学报, 2007, 28(6):7-7
[24]XIONG Z, LIU J Y, LENG X F.The Study of Image Matching Algorithm for Scene Matching Aided Navigation System[J][J].Journal of Image and Graphics, 2004, 10(10):1023-1023
[25] 赵锋伟.景象匹配算法, 性能评估及其应用[D].中国人民解放军国防科学技术大学, 2002.DOI:10.7666/d.w024720.
[26]陈苗海.机载光电导航瞄准系统的应用和发展概况[J].电光与控制, 2003, 10(4):6-6
[27] 马涛, 胡小平, 练军想, 等.仿生导航技术研究综述[C]//洛阳惯性技术学会.洛阳惯性技术学会, 2014.
[28]王耀南, 李树涛.多传感器信息融合及其应用综述[J].控制与决策, 2001, 16(5):5-5
[29] 孙建峰.信息融合理论在惯性/天文/GPS 组合导航系统中的应用[M].国防工业出版社, 1998.
[30]王慧哲, 曾庆化, 刘建业, 等.基于因子图的无人机全源导航关键技术研究[J].导航与控制, 2017, 16(2):5-5
[31]刘春保.美国打造新的军用全源导航 [J][J].国际太空, 2013, 4(4):13-13
[32] 陈颖, 马忠孝, 贺峻峰.全源定位与导航技术发展概况和应用展望[C]//中国惯性技术学会第七届学术年会论文集.2015.
[33] 郑峰婴.舰载机着舰引导技术研究[D].南京航空航天大学, 2007.DOI:10.7666/d.d038458.
[34]周煜, 伍逸夫, 赵峰.航母着舰引导系统概述[J][J].舰船电子工程, 2011, 31(11):4-4
[35] 戴文正.无人直升机自主着舰引导与控制技术研究[D].南京航空航天大学, 2014.
[36]董新民, 徐跃鉴, 陈博.自动空中加油技术研究进展与关键问题[J].空军工程大学学报自然科学版, 2008, 9(6):5-5
[37] 钦庆生.飞行管理计算机系统[M].国防工业出版社, 1991.
[38]罗巧云.第五代战斗机在未来空战中的应用[J][J].国防科技, 2017, 4(4):57-62
[39] JUNHYUNG B.A review of electric actuation and flight control system for More/All Electric aircraft [C]// 2021 24th In-ternational Conference on Electrical Ma-chines and Systems (ICEMS), 2021: 1943-1947.
[40] KIM N H, CHOI J H, DAWN A.Prog-nostics and health management of engineer-ing systems[M]. Cham, Switzerland: Spring-er International Publishing, 2017: 2-4.
[41] HARRIS J J .F-35 Flight Control Law Design, Development and Verifica-tion[C]//2018 Aviation Technology, Integra-tion, and Operations Conference, 2018: 1-18.
[42] MALISANI S, CAPELLO E.Modeling Framework for Dynamic Wing Loads and Control Design of a Flexible Aircraft[C]. AIAA Scitech 2021 Forum. 2021.
[43] SINGH L, MIOTTO P, BREGER L S.L1 Adaptive Control Design for Improved Handling of the F/A-18 class of Aircraft[C]// AIAA Guidance, Navigation, and Control Conference. 2013.
[44] AVANZINI G, CAPELLO E, PIACENZA I, et al.L1 Adaptive Control of Flexible Aircraft: Preliminary Results[C]. AIAA Atmospheric Flight Mechanics Con-ference. 2010.
[45]蔡琰.国外射流飞行控制技术发展及前景分析[J].航空科学技术, 2020, 31(1):85-86
[46]MEYER D, LARSEN M.Nuclear magnetic resonance gyro for inertial navigation[J][J].Gyroscopy and Navigation, 2014, 5(2):75-82
[47]SAVOIE D,ALTORIO M,FANG B,et al.Interleaved atom in-terferometry for high-sensitivity inertial measurements[J][J].Science Advances, 2018, 12(4):7948-7948
[48]WU X J, PAGEL Z, MALEK B S, et al.Gravity surveys using a mobile atom inter-ferometer[J][J].Science Advances, 2019, 5(9):800-800
[49] GAEL Dée, TILLO Vanthuyne, ALESSANDRO Potini, et al.Electromechan-ical Thrust Vector Control Systems for the Vega-C Launcher[C]. 8TH European Confer-ence for Aeronautics and Space Sciences (EUCASS), Madrid, 2019-186.
[50]MECROW B C, JACK A G, ATKINSON G J, et al.Design and Testing of a Four-phase Fault-tolerant Permanent-magnet Machine for An Engine Fuel Pump[J].IEEE Transactions on Energy Conversion, 2004, 19(4):671-678
[51] ATKINSON G J, MECROW B C, JACK A G, et al.The Design of Fault Toler-ant Machines for Aerospace Applications[C]. IEEE International Conference on Electric Machines and Drives, San Antonio, 2005:1863-1869.
[52]Wang Bo, WANG Jiabin, GRIFFO An-tonio, SHI Yanwen.Investigation into Fault-Tolerant Capability of a Triple Redundant PMA SynRM Drive[J].IEEE Transactions on Power Electronics, 2019, 34(2):1611-1621
[53]Zhao K,Chu J,Wang T,et al.A novel angle algorithm of polarization sensor for navigation[J].IEEE Transactions on In-strumentation and Measurement, 2009, 58(8):2791-2796
[54]Fan C, Hu X, Lian J, et al.Design and calibration of a novel camera-based bio-inspired polarization navigation sensor[J].IEEE Sensors Journal, 2016, 16(10):3640-3648
[55]曹昭睿, 郝永平, 刘万成等.紧凑折反式仿生复眼及图像快速拼接识别算法[J][J].兵工学报, 2022, 43(8):1845-1857
[56]Liu X, Yang J, Guo L, et al.Design and calibration model of a bioinspired atti-tude and heading reference system based on compound eye polarization com-pass[J].Bioinspiration & Biomimetics, 2021, 16(1):016001-016001
[57]Shanpeng Wang, Zhenbing Qiu, Panpan Huang, Xiang Yu, Jian Yang, and Lei Guo.A Bio-Inspired Navigation System for Multi-Rotor UAV by Integrating Polarization Compass/Magnetometer/INS/GNSS[J].IEEE ransactions on Industrial Electronics, 2022, 10(10):3212412-3212412
[58]Yueting Yang, Yan Wang, Xiang Yu, Panpan Huang, Xin Liu, Qingfeng Dou, Jian Yang, and Lei Guo.Moonlit Polarized Sky-light-aided INS/CNS: An Enhanced Atti-tude Determination Method[J][J].Control Engineering Practice, 2023, 132(132):105408-105408
[59]吴文海, 高阳, 汪节.飞行控制系统的发展历程, 现状与趋势[J].飞行力学, 2018, 36(4):1-6
[60] 李哲.大型运输机飞控系统可靠性设计技术分析[C]//大型飞机关键技术高层论坛暨中国航空学会2007年学术年会, 2007, 1-6.
[61]占正勇, 刘林.控制分配在复杂飞行控制系统中的应用设计[J].飞行力学, 2006, 24(2):73-77
[62]李冀鑫, 侯志强, 徐彦军.基于总能量理论的着舰飞行推力控制系统[J].飞行力学, 2010, 28(02):35-38
[63]范超, 赵琳, 段海军.航空数据总线技术研究[J][J].信息技术与信息化, 2022(04):160-163., 4(4):160-163
[64]夏立群, 张新国.直接驱动阀式伺服作动器研究[J][J].西北工业大学学报, 2006, 3(3):308-312
[65]魏毅寅, 郝明瑞, 范宇.人工智能技术在宽域飞行器控制中的应用[J][J].宇航学报, 2023, 44(4):530-537
[66]马卫华.导弹火箭制导、导航与控制技术发展与展望[J].宇航学报, 2020, 41(7):860-867
[67]杨涛, 杨博, 殷允强, 等.多智能体系统协同控制与优化专刊序言[J].控制与决策, 2023, 38(5):1153-1158
[68]李文革, 黄晓利, 谢世富.导航战在信息化战争中的作用[J].信息与电子工程, 2004, 002(002):153-156
[69]马海宁,潘颜楠,孙志.基于欺骗干扰技术的导航对抗新途径[J][J].指挥控制与仿真, 2021, 43(4):128-133
[70]杨元喜.综合PNT体系及其关键技术[J][J].测绘学报, 2016(5):6, 5(6):001-001
[71]王巍, 孟凡琛, 阚宝玺.国家综合体系下的多源自主导航系统技术[J][J].导航与控制, 2022, 21(3):10-10
[72]卞鸿巍, 许江宁, 何泓洋, 等.国家综合体系弹性概念[J][J].武汉大学学报:信息科学版, 2021, 46(9):8-8
[73]杨昆,康戈文,李洪.重力场和地磁场综合匹配在导航中的运用[J][J].船海工程, 2010, 39(01):129-131
[74]黄高明, 景桐, 田威.机会信号导航综述[J][J].控制与决策, 2019, 6(11):0623-0623
[75]冯云皓.低地球轨道卫星导航的当前能力与未来展望[J][J].防务视点, 2017, Z1(Z1):118-119
[76] Zhou Y B, Lai J, Guo X Y, et al.A Research on All Source Navigation and Posi-tioning and Its Critical Technology[C]//China Satellite Navigation Conference.2015.
[77]宋丽君,薛连莉,董燕琴等.全源定位与导航的发展与建议[J][J].导航与控制, 2017, 16(6):99-105
[78]雷宏杰,姚呈康.面向军事应用的航空人工智能技术架构研究[J].导航定位与授时, 2020, 7(1):1-11
[79]樊会涛,闫俊.空战体系的演变及发展趋势[J][J].航空学报, 2022, 43(10):296-305
[80]孙聪.从空战制胜机理演变看未来战斗机发展趋势[J][J].航空学报, 2021, 42(8):8-20
[81]柳文林, 潘子双, 韩维, 等.有人无人机协同作战运用研究现状与展望[J].海军航空大学学报, 2022, 37(3):231-241
[82]钟赟, 姚佩阳, 张杰勇, 等.基于的有人-无人机作战系统交互式协同决策[J].系统工程理论与实践, 2021, 41(10):2748-2760
[83]雷耀麟, 丁文锐, 李雅, 等.群体智能支撑的无人机群航路规划应用综述[J].无线电工程, 2023, 53(07):1509-1519
[84]苗昊春, 刘重, 王根.协同制导控制技术发展现状及展望[J].前瞻科技, 2022, 1(04):40-54
[85]张栋, 王孟阳, 唐硕.面向任务的无人机集群自主决策技术[J].指挥与控制学报, 2022, 8(04):365-377
[86]高杨, 李东生, 柳向.无人机集群协同态势觉察一致性评估[J].电子学报, 2019, 47(01):190-196
[87]Takase, K.Precision Rotation Rate Measurements with a Mobile Atom Interfer-ometer[D].Stanford University, Stanford, CA, USA,2008, 2008, 1(1):1-138
[88]Larsen M, Bulatowicz M.Nuclear Magnetic Resonance Gyroscope: For DARPA's micro-technology for position-ing, navigation and timing pro-gram[C].Frequency Control Symposium.IEEE, 2012, 10(10):6243606-6243606
[89]Grace M R , Gagatsos C N , Zhuang Q ,et al..Quantum-Enhanced Fiber-Optic Gyroscopes using Quadrature Squeezing and Continuous-Variable Entanglement[C].Conference on Lasers and Electro-Optics. IEEE, 2020, 9(9):2160-8989-2160-8989
[90]郑纬民.处理人工智能应用的高性能计算机的架构和评测[J][J].重庆邮电大学学报(自然科学版), 2021, 2(2):171-175
[91]段宇博, 边庆, 齐宇心.机载计算机多核系统架构选择分析[J][J].长江信息通信, 2022, 12(12):67-69
[92]鄂金龙, 何林.基于异构算力节点协同的高效视频分发[J][J].计算机研究与发展, 2023, 4(4):772-785
[93]马跃,朱纪洪,杨佳利.基于时间触发通信的机载网络可靠性[J][J].计算机工程与设计, 2020, 5(5):1201-1206
[94]王昭, 成书锋, 马小博.综合多任务的高可靠容错计算机设计与实现[J][J].航空计算技术, 2020, 4(4):110-112
[95]吴美平,唐康华,任彦超,等.基于SIP的低成本微小型GNC系统技术[J][J].导航定位与授时, 2021, 6(6):19-27
[96]华虹, 刘鸿瑾, 李宾, 等.一种宇航微系统SiP计算机模块的分析及设计[J].微电子学与计算机, 2023, 1(1):156-164
[97]王宁, 王保传, 郭国平.硅基半导体量子计算研究进展[J][J].物理学报, 2022, 23(23):1-13
[98]陈雨, 王修业, 孙芹芹, 等.基于伺服约束的无人作战平台跟随避让控制[J][J].南京理工大学学报(自然科学版), 2023, 1(1):24-32
[99]郭涛, 陈朝, 程瀚等.美军的年制空优势项目——“下一代空中主宰”项目发展启示[J].航天电子对抗, 2022, 38(05):50-53
[100]Takahashi M D , Fujizawa B T , Lusardi J A ,et al.Autonomous Guidance and Flight Control on a Partial-Authority Black Hawk Helicop-ter[C].AIAA AVIATION 2020 FORUM.2020, 2020, 10(10):2020-3286-2020-3286
[101]WIGGINTON S A.Joint Common Architecture Demonstration (JCA Demo) Final Report[J][J].Joint Common Architecture Demonstration, 2023, 9(9):1-1
[102]RICHARD Levinson, JEREMY D, Frank, MICHAEL Iatauro, et al..Development and Testing of a Vehicle Management System for Autonomous Spacecraft Habitat Operations[J][J].2018 AIAA SPACE and Astronautics Forum and Exposition, 2018, 9(9):2018-5148-2018-5148
[103]SIMON Grke, ROLF-REKKE Riebeling, FLORIAN Kraus, et al.Flexible platform approach for fly-by-wire system[J][J].2013 IEEE/AIAA 32nd Digital Avion-ics Systems Conference (DASC), 2013, 10(10):6719619-6719619
[104]ANDREW Loveless,.On TTE thernet for Integrated Fault-Tolerant Spacecraft Net-works[J][J].AIAA SPACE 2015 Conference and Exposition, 2015, 8(8):4526-4526
[105]MITCHELL Fletcher.DESIGN TO COST METHODS TO LOWER THE AVIONICS COST FOR NASA COMMERCIAL CREW EFFORTS[J][J].AIAA SPACE 2010 Conference and Exposition, 2010, 8(8):8916-8916
[106]A Raschellà, F. Bouhafs, M. Mackay, et al.Smart access point selection for dense WLANs: A use-case[J][J].2018 IEEE Wireless Communications and Networking Conference (WCNC), 2018, 6(6):17841395-17841395
[107]程林, 蒋方华, 李俊峰.深度学习在飞行器动力学与控制中的应用研究综述[J].力学与实践, 2020, 42(3):267-276
[108]XU J, DU T, FOSHEY M, et al.Learn-ing to fly: Computational controller design for hyrid UAVs with reinforcement learning[J].ACM Transactions on Graphics, 2019, 38(4):1-12
[109]褚思真,万劲波.创新链产业链的融合机制与路径研究[J][J].创新科技, 2022, 22(10):41-50
[110]刘传明,王睿,姜长梅.国家创新体系整体效能的理论阐释、现实挑战与实现路径[J][J].国际金融, 2023, 05(05):3-13
Options
文章导航

/

地址:北京市海淀区北四环中路辅路238号柏彦大厦

邮政编码:100083

E-mail:hkxb@buaa.edu.cn

关于我们

期刊社服务

专业学科

封面文章

友情链接

版权所有 © 航空学报编辑部

版权所有 © 2011航空学报杂志社

主管单位:中国科学技术协会 主办单位:中国航空学会 北京航空航天大学