Trajectory generation for autonomous soaring UAS

Author

Clarke, J.H.A. ; Chen, W.-H.

Author_Institution

Dept. of Aeronaut. & Automotive Eng., Loughborough Univ., Loughborough, UK

fYear

2011

fDate

10-10 Sept. 2011

Firstpage

121

Lastpage

126

Abstract

As unmanned aerial vehicles are expected to do more and more advanced tasks, improved range and persistence is required. This paper presents a method of using shallow layer cumulus convection to extend the range and duration of small UAVs. A simulation model of an X-Models XCalubur electric motor-glider is used in combination with a refined parametric thermal model to simulate soaring flight. The parametric thermal model builds on previous successful models with refinements to more accurately describe the weather in northern Europe. The implementation of the variation of the MacCready setting is discussed. Methods for generating efficient trajectories are evaluated and recommendations are made regarding implementation.

Keywords

aircraft control; position control; remotely operated vehicles; sport; UAS; X-models XCalubur electric motor glider; autonomous soaring; parametric thermal model; shallow layer cumulus convection; soaring flight simulation; trajectory generation; unmanned aerial vehicles; Aerospace control; Aircraft; Atmospheric modeling; Mathematical model; Meteorology; Trajectory; Heuristic; Optimal; Soaring; Trajectory; UAS; UAV; thermal;

fLanguage

English

Publisher

ieee

Conference_Titel

Automation and Computing (ICAC), 2011 17th International Conference on

Conference_Location

Huddersfield

Print_ISBN

978-1-4673-0000-1

Type

conf

Filename

6084913