Sage Journals: Discover world-class research

Abstract

This paper employs a unique extension-decomposition-aggregation (EDA) scheme to solve the formation flight control problem for multiple unmanned aerial vehicles (UAVs). The corresponding decentralised longitudinal and lateral formation autopilots are novelly designed to maintain the overall formation stability when encountering changes of the formation error and topologies. The concept of propagation layer number (PLN) is also proposed to provide an intuitive criterion to judge which type of formation topology is more suitable to minimise formation error propagation (FEP). The criterion states that the smaller the PLN of the formation is, the quicker the response to the formation error is. A smaller PLN also means that the resulting topology provides better prevention to the FEP. Simulation studies of formation flight of multiple Aerosonde UAVs demonstrate that the designed formation controller based on the EDA strategy performs satisfactorily in maintaining the overall formation stable, and the bidirectional partial-mesh topology is found to provide the best overall response to the formation error propagation based on the PLN criterion.

Keywords

Extension-decomposition-aggregation formation autopilot formation topology formation error propagation longitudinal and lateral formation control

Get full access to this article

View all access options for this article.

References

Murray

. Recent research in cooperative control of multi-vehicle systems. J Dyn Syst Meas Control 2007; 129: 571–583.

Vachon MJ, Ray RJ, Walsh KR, et al. F/A-18 performance benefit measured during the autonomous formation flight project. Technical Report NASA/TM-2003-210734, NASA Dryden, Edward, CA, 2003.

Seanor

Campa

. Design and flight testing evaluation of formation control laws. IEEE Trans Control Syst Technol 2006; 14: 1105–1112.

Balch

Arkin

. Behavior-based formation control for multi-robot teams. IEEE Trans Robot Autom 1998; 14: 926–939.

Monteiro

Bicho

. Attractor dynamics approach to formation control: Theory and application. Autonom Robot 2010; 29: 331–355.

Wang

Slotine

J-JE

. A theoretical study of different leader roles in networks. IEEE Trans Autom Control 2006; 51: 1156–1161.

Wang

. Leader-following formation control of multi-agent systems under fixed and switching topologies. Int J Control 2012; 85: 695–705.

Li N and Liu H. Formation UAV flight control using virtual structure and motion synchronization. In: Proceedings of American control conference, Seattle, Washington, USA, 11–13 June 2008, pp.1782–1787.

Askari A, Mortazavi M and Talebi H. UAV formation control via the virtual structure approach. J Aerosp Eng 2013. DOI: 10.1061/(ASCE)AS.1943-5525.0000351.

10.

Krick

Broucke

Francis

. Stabilisation of infinitesimally rigid formations of multi-robot networks. Int J Control 2009; 82: 423–439.

11.

Xue

Yao

Chen

. Formation control of networked multi-agent system. IET Control Theory Appl 2010; 4: 2168–2176.

12.

Wang

Xin

. Integrated optimal formation control of multiple unmanned aerial vehicles. IEEE Trans Control Syst Technol 2013; 21: 1731–1744.

13.

Yang A, Naeem W, Irwin GW, et al. Novel decentralised formation control for unmanned vehicles. In: Proceedings of IEEE intelligent vehicles symposium (IV 2012), Alcalá de Henares, Spain, June 2012, pp.13–18.

14.

Yang

Naeem

Irwin

. Stability analysis and implementation of a decentralised formation control strategy for unmanned vehicles. IEEE Trans Control Syst Technol 2014; 22: 706–720.

15.

Yang A, Naeem W, Irwin GW, et al. A decentralised control strategy for formation flight of unmanned aerial vehicles. In: Proceedings of 2012 UKACC international conference on control, Cardiff, UK, 3–5 September 2012, pp.345–350.

16.

Yang A. A novel decentralised formation control strategy for unmanned vehicles. PhD Dissertation, Queen’s University Belfast, UK, 2012.

17.

Beard

McLain

. Small unmanned aircraft: Theory and practice, Princeton, NJ: Princeton University Press, 2012.

18.

Duke EL, Antoniewicz RF and Krambeer KD. Derivation and definition of a linear aircraft model. Technical Report NASA Reference Publication 1207, NASA Dryden Flight Research Facility, Edward, CA, USA, 1988.

19.

Scherer

Gahinet

Chilali

. Multiobjective output-feedback control via LMI optimization. IEEE Trans Autom Control 1997; 42: 896–911.

20.

Šiljak

Stipanović

. Robust stabilization of nonlinear systems: The LMI approach. Math Prob Eng 2000; 6: 461–493.

21.

AeroSim aeronautical simulation block set V1.2, users guide, Unmanned Dynamics, 2003.

Multi-UAVs formation autopilot design and performance analysis under interconnection topologies

Abstract

Keywords

Get full access to this article

References