«Previous Article|Table of Contents|Next Article»

《交通运输工程学报》[ISSN:1671-1637/CN:61-1369/U]

Issue:

2013年06期

Page:

90-98

Research Field:

交通运输规划与管理

Publishing date:

Info

Title:

Modeling and simulation of collaborative flight based on multi-agent technique

Author(s):

YE Bo-jia¹; 2;  HU Ming-hua¹; 2;  TIAN Yong¹; 3

1. School of Civil Aviation, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, Jiangsu, China; 2. National Key Laboratory of Air Traffic Flow Management, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, Jiangsu, China; 3. Center for Air Transportation Systems Research, George Mason University, Fairfax 22030, Virginia, USA

Keywords:

air transportation;  collaborative flight;  modeling and simulation;  mulit-agent technique;  air corridor

PACS:

V355.2

DOI:

-

Abstract:

The flight risk of aircraft agent flying in air corridor was studied by using multi-agent modeling and simulation technique. According to the flight aim, main function and interior structure of aircraft agent in air corridor, the inference rule and collaborative state were analyzed, the interactive structure of collaborative flight was put out, and simulation experiment was carried out by using hybrid simulation method. Simulation result shows that when the maximum and minimum cruising speeds of large-sized aircraft are 880, 620 km·h^-1 respectively, the maximum and minimum cruising speeds of medium-sized aircraft are 790, 525 km·h^-1 respectively, and the maximum and minimum accelerations of the two aircrafts are 0.608 and -0.780 m·s^-2, the aircraft flight state in air corridor can be divided into four typical conditions. Under condition 1, aircraft speed is always 745.17 km·h^-1, and the total flight time is 708 s. Under condition 2, aircraft adjusts its speed according to the leading aircraft, the initial and maximum speeds are 658, 778 km·h^-1, and the total flight time is 648 s. Under condition 3, aircraft changes its flight line in air corridor in order to avoid flight conflict, and the total flight time is 744 s. Under condition 4, aircraft breaks away from air corridor for safety problem, and the total flight time is 66 s. The proposed model can meet the actual requirement. 1 tab, 19 figs, 24 refs.

References:

[1] Joint Planning and Development Office. Concept of operations for the next generation air transportation system[R]. Washington DC: Federal Aviation Administration, 2007.
[2] ALIPIO J, CASTRO P, KAING H, et al. Dynamic airspace super sectors(DASS)as high-density highways in the sky for a new US air traffic management system[C]∥IEEE. Proceedings of the 2003 Systems and Information Engineering Design Symposium. New York: IEEE, 2003: 57-66.
[3] YOUSEFI A, DONOHUE G. High-volume tube-shape sectors(HTS): a network of high capacity ribbons connecting congested city pairs [C]∥IEEE. The 23rd Digital Avionics Systems Conference. New York: IEEE, 2004: 12-21.
[4] SRIDHAR B, GRABBE S, SHETH K, et al. Initial study of tube networks for flexible airspace utilization [C]∥AIAA. 2006 AIAA Guidance, Navigation, and Control Conference. Washington DC: AIAA, 2006: 237-252.
[5] HOFFMAN R, PRETE J. Principles of airspace tube design for dynamic airspace configuration [C]//AIAA. 26th Congress of International Council of the Aeronautical Sciences. Anchorage: AIAA, 2008: 108-139.
[6] XUE Min, KOPARDEKAR P. High-capacity tube network design using the hough transform [J]. Journal of Guidance, Control and Dynamics, 2009, 32(3): 788-795.
[7] XUE Min, ZELINSKI S J. Complexity analysis of traffic in corridors-in-the-sky [C]//AIAA. 10th AIAA Aviation Technology, Integration and Operations Conference. Fort Worth: AIAA, 2000: 110-122.
[8] HEXMOOR H, HENG T. Air traffic control agents: landing and collision avoidance[C]∥AIAA. International Conference in Artificial Intelligence. Las Vegas:AIAA, 2000: 21-35.
[9] NITSCHKE G. Cooperating air traffic control agents[J]. Applied Artificial Intelligence, 2001, 15(2): 209-235.
[10] CALLANTINE T J. CATS-based air traffic controller agents[R].Sacramento: NASA Ames Research Center, 2002.
[11] NGUYEN M, BRIOT J, DROGOUL A. An application of multi-agent coordination techniques in air traffic management[C]∥IEEE. 2003 IEEE/WIC International Conference in Intelligent Agent Technology. Halifax: IEEE, 2003: 622-625.
[12] HILL J, ARCHIBALD J, STIRLING W, et al. A multi-agent system architecture for distributed air traffic control[C]∥AIAA. 2005 AIAA Guidance, Navigation and Control Conference. San Francisco: AIAA, 2005: 1005-1049.
[13] AGOGINO A, TUMER K. Learning indirect actions in complex domains: action suggestions for air traffic control[J]. Advances in Complex Systems, 2009, 12(4): 493-512.
[14] 张洪海.机场终端区协同流量管理关键技术研究[D].南京:南京航空航天大学,2009. ZHANG Hong-hai. The key technologies of collaborative flow management in airport terminal area[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2009.(in Chinese)
[15] 黎新华,张兆宁.基于Agent的空中交通流量管理系统结构研究[J].交通运输工程与信息学报,2007,5(1):56-61. LI Xin-hua, ZHANG Zhao-ning. Research of the structure of air traffic flow management system based on the agent[J]. Journal of Transportation Engineering and Information, 2007, 5(1): 56-61.(in Chinese)
[16] 王万乐.Multi-Agent系统在飞行冲突探测与解脱中的应用[J].交通信息与安全,2009,27(3):9-15. WANG Wan-le. Application of multi-agent system in flight conflict detection and resolution[J]. Journal of Transport Information and Safety, 2009, 27(3): 9-15.(in Chinese)
[17] 戴 玲,夏学知.多Agent技术在飞行冲解脱中的应用[J].舰船电子工程,2009,28(3):62-64,89. DAI Ling, XIA Xue-zhi. Application of multi-agent in flight conflict resolution[J]. Ship Electronic Engineering, 2009, 28(3): 62-64, 89.(in Chinese)
[18] 王 超,徐肖豪.基于Agent的空中交通系统建模与仿真研究[J].计算机工程与应用,2008,44(31):12-14. WANG Chao, XU Xiao-hao. Researching on air traffic system using agent-based modeling and simulation [J]. Computer Engineering and Applications, 2008, 44(31): 12-14.(in Chinese)
[19] 王 飞,徐肖豪,张 静.基于Multi-Agent的空中交通协同流量管理[J].广西师范大学学报:自然科学版,2008,26(1):125-128. WANG Fei, XU Xiao-hao, ZHANG Jing. Air traffic flow collaborate management based on multi-agent[J]. Jounal of Guangxi Normal University: Natural Science Edition, 2008, 26(1): 125-128.(in Chinese)
[20] 张钧翔,胡明华.基于多Agent的多机场终端区空中交通智能仿真系统设计[J].交通运输工程与信息学报,2009,7(2):90-98. ZHANG Jun-xiang, HU Ming-hua. Design of the air traffic intelligent simulation system for the airport with multi-terminal areas based on multi-agents[J]. Journal of Transportation Engineering and Information, 2009, 7(2): 90-98.(in Chinese)
[21] YOUSEFI A, LARD J, TIMMERMAN J. Nextgen flow corridors initial design, procedures, and display functionalities[C]∥IEEE. 29th Digital Avionics Systems Conference. Salt Lake City: IEEE, 2010: 201-219.
[22] YOUSEFI A, ZADEH A N. Dynamic allocation and benefit assessment of nextgen flow corridors[J]. Transportation Research Part C: Emerging Technologies, 2013, 33(2): 297-310.
[23] 黄卫芳.美国区域导航航路划设和实施研究[J].空中交通管理,2011(2):8-10,46. HUANG Wei-fang. Studies on US RNAV route alignment and implementation [J]. Air Traffic Management, 2011(2): 8-10, 46.(in Chinese)
[24] STROEVE S, BLOM H, BAKKER G. Systemic accident risk assessment in air traffic by Monte Carlo simulation[J]. Safety Science, 2009, 47(2): 238-249.

Memo

Memo:

-

Common functions

Last Update: 2013-12-20