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Massive Autonomous UAV Path Planning: A Neural Network Based Mean-Field Game Theoretic Approach

conference contribution
posted on 2019-01-01, 00:00 authored by H Shiri, Jihong ParkJihong Park, M Bennis
© 2019 IEEE. This paper investigates the autonomous control of massive unmanned aerial vehicles (UAVs) for mission-critical applications (e.g., dispatching many UAVs from a source to a destination for firefighting). Achieving their fast travel and low motion energy without inter-UAV collision under wind perturbation is a daunting control task, which incurs huge communication energy for exchanging UAV states in real time. We tackle this problem by exploiting a mean-field game (MFG) theoretic control method that requires the UAV state exchanges only once at the initial source. Afterwards, each UAV can control its acceleration by locally solving two partial differential equations (PDEs), known as the Hamilton-Jacobi- Bellman (HJB) and Fokker-Planck-Kolmogorov (FPK) equations. This approach, however, brings about huge computation energy for solving the PDEs, particularly under multi-dimensional UAV states. We address this issue by utilizing a machine learning (ML) method where two separate ML models approximate the solutions of the HJB and FPK equations. These ML models are trained and exploited using an online gradient descent method with low computational complexity. Numerical evaluations validate that the proposed ML aided MFG theoretic algorithm, referred to as emph{MFG learning control}, is effective in collision avoidance with low communication energy and acceptable computation energy.

History

Location

Waikoloa, HI, USA

Start date

2019-12-09

End date

2019-12-13

ISBN-13

9781728109626

Language

eng

Publication classification

E1.1 Full written paper - refereed

Title of proceedings

GLOBECOM 2019: Proceedings of the IEEE Global Communications Conference

Event

IEEE Global Communications. Conference (2019 : Waikoloa, Hl, USA)

Publisher

Institute of Electrical and Electronics Engineers

Place of publication

Piscataway, N.J.

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