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A Voronoi–A* Fusion Algorithm with Adaptive Layering for Efficient UAV Path Planning in Complex Terrain

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Publicado en:Drones vol. 9, no. 8 (2025), p. 542-568
Autor Principal: Dong Boyu
Outros autores: Zhang, Gong, Yang, Yan, Yuan Peiyuan, Lu Shuntong
Publicado:
MDPI AG
Materias:
Apexes
Adaptability
Optimization
Greedy algorithms
Safety margins
Horizontal flight
Layering
Unmanned aerial vehicles
Systems stability
Heuristic
Density
Energy consumption
Efficiency
Adaptive algorithms
Performance enhancement
Digital Elevation Models
Genetic algorithms
Planes
Impact analysis
Flexibility
Methods
Weighting functions
Complexity
Real time
Segments
Path planning
Obstacle avoidance
Terrain
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Resumo:<sec sec-type="highlights"> This paper proposes a Voronoi–A* fusion algorithm for UAV path planning in complex terrain. A DEM layering method based on obstacle density is introduced to decompose complex 3D terrain into multiple horizontal flight planes, significantly reducing computational complexity while maintaining 3D flexibility. Within each plane, a greedy Voronoi algorithm constructs a sparse vertex network as path nodes. A weighting function incorporates start/goal proximity, heading consistency, and altitude safety. The algorithm employs greedy heuristics to prioritize high-weight vertices, enabling the rapid generation of safe paths. What are the main findings? <list list-type="bullet"> <list-item> </list-item>A DEM layering method based on obstacle density. <list-item> A greedy Voronoi algorithm applied within each flight plane. </list-item> What is the implication of the main finding? <list list-type="bullet"> <list-item> </list-item>Computational complexity is minimized, and efficiency is enhanced. <list-item> Generated paths closely approximate the optimal path. </list-item> Unmanned Aerial Vehicles (UAVs) face significant challenges in global path planning within complex terrains, as traditional algorithms (e.g., A*, PSO, APF) struggle to balance computational efficiency, path optimality, and safety. This study proposes a Voronoi–A* fusion algorithm, combining Voronoi-vertex-based rapid trajectory generation with A* supplementary expansion for enhanced performance. First, an adaptive DEM layering strategy divides the terrain into horizontal planes based on obstacle density, reducing computational complexity while preserving 3D flexibility. The Voronoi vertices within each layer serve as a sparse waypoint network, with greedy heuristic prioritizing vertices that ensure safety margins, directional coherence, and goal proximity. For unresolved segments, A* performs localized searches to ensure complete connectivity. Finally, a line-segment interpolation search further optimizes the path to minimize both length and turning maneuvers. Simulations in mountainous environments demonstrate superior performance over traditional methods in terms of path planning success rates, path optimality, and computation. Our framework excels in real-time scenarios, such as disaster rescue and logistics, although it assumes static environments and trades slight path elongation for robustness. Future research should integrate dynamic obstacle avoidance and weather impact analysis to enhance adaptability in real-world conditions.
ISSN:2504-446X
DOI:10.3390/drones9080542
Fonte:Advanced Technologies & Aerospace Database