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Optimal Path Planner Considering Real Terrain for Fixed-Wing UAVs

실제지형을 고려한 고정익 무인항공기의 최적 경로계획

  • Lee, Dasol (Department of Aerospace Engineering, Korea Advanced Institute of Science and Technology) ;
  • Shim, David Hyunchul (Department of Aerospace Engineering, Korea Advanced Institute of Science and Technology)
  • 이다솔 (한국과학기술원 항공우주공학과) ;
  • 심현철 (한국과학기술원 항공우주공학과)
  • Received : 2014.07.07
  • Accepted : 2014.09.15
  • Published : 2014.12.01

Abstract

This article describes a path planning algorithm for fixed-wing UAVs when a real terrain should be considered. Nowadays, many UAVs are required to perform mission flights near given terrain for surveillance, reconnaissance, and infiltration, as well as flight altitude of many UAVs are relatively lower than typical manned aerial vehicles. Therefore, real terrain should be considered in path planning algorithms of fixed-wing UAVs. In this research, we have extended a spline-$RRT^*$ algorithm to three-dimensional planner. The spline-$RRT^*$ algorithm is a $RRT^*$ based algorithm, and it takes spline method to extend the tree structure over the workspace to generate smooth paths without any post-processing. Direction continuity of the resulting path is guaranteed via this spline technique, and it is essential factor for the paths of fixed-wing UAVs. The proposed algorithm confirm collision check during the tree structure extension, so that generated path is both geometrically and dynamically feasible in addition to direction continuity. To decrease degrees of freedom of a random configuration, we designed a function assigning directions to nodes of the graph. As a result, it increases the execution speed of the algorithm efficiently. In order to investigate the performance of the proposed planning algorithm, several simulations are performed under real terrain environment. Simulation results show that this proposed algorithm can be utilized effectively to path planning applications considering real terrain.

Keywords

References

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