A geometrical path planning method for unmanned aerial vehicle in 2D/3D complex environment

Xiao, Limin; Meng, Guang; Xu, Yimin; Luo, Haitao

doi:10.1007/s11370-018-0254-0

Cited by 38 publications

(17 citation statements)

References 28 publications

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“…Among the path generators in the specialized literature, the A-Star algorithm is a well-known efficient alternative that deterministically finds sub-optimal feasible paths in complex scenarios [60]. A-Star operates over a grid discretization of the workspace that considers the cells containing obstacles or threats as prohibited regions.…”

Section: ) Enhanced Path-search Mechanismmentioning

confidence: 99%

Optimized Path-Planning in Continuous Spaces for Unmanned Aerial Vehicles Using Meta-Heuristics

et al. 2020

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This work presents a novel path-planning approach for Unmanned Aerial Vehicles (UAVs) in continuous 3D environments. This proposal aims to minimize the path length while avoiding collisions through the suitable adjusting of control points (the points that take the UAV from a start position to a target location). The above is stated as a constrained global optimization problem. This problem considers the overall length of the path as the single objective function. Regarding the problem constraints, they are related to the collision of the obstacles with the 3D shape of a path. The assignment of the path shape is also proposed in this work to streamline the planning process. Due to the optimization problem features (high nonlinearity, multimodality, non-differentiability, and the lack of an initial guess solution), a constraintshandling mechanism is used in meta-heuristics to find suitable optimized paths. Also, an enhanced pathsearch mechanism is included in these algorithms to deal with complex planning scenarios. The enhanced mechanism incorporates a path computed by a variant of the A-Star method (the Pruned A-Star) in the first set of candidate solutions of the meta-heuristics. The proposed approach is tested through six complex scenarios. Moreover, the performance of three well-known meta-heuristics, Differential Evolution (DE), Particle Swarm Optimization (PSO), and the Genetic Algorithm (GA), is studied to find a potential candidate to solve the path-planning problem. In this way, the paths found by DE show outstanding performance. The paths obtained by the Pruned A-Star technique are adopted as a point of comparison to determine the advantages and drawbacks of the proposal. INDEX TERMS Path-planning, optimization problem, aerial vehicles, meta-heuristics, continuous spaces.

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Section: ) Enhanced Path-search Mechanismmentioning

confidence: 99%

Optimized Path-Planning in Continuous Spaces for Unmanned Aerial Vehicles Using Meta-Heuristics

et al. 2020

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“…In Figure 4(a), Property I indicates that the subgoal S must be in the shortest path between P 2 and E. e role of the subgoal of P 2 is to drive and force E so that the situation is more beneficial to pursuers. When P 1 performs 3D interception, the subgoal of P 1 can be obtained according to our previous works [31,32]. Figure 4(b) shows the calculation of a 3D subgoal by taking a cuboid obstacle as an example.…”

Section: Complexitymentioning

confidence: 99%

Collaborative Pursuit-Evasion Strategy of UAV/UGV Heterogeneous System in Complex Three-Dimensional Polygonal Environment

2020

Self Cite

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The UAV/UGV heterogeneous system combines the air superiority of UAV (unmanned aerial vehicle) and the ground superiority of UGV (unmanned ground vehicle). The system can complete a series of complex tasks and one of them is pursuit-evasion decision, so a collaborative strategy of UAV/UGV heterogeneous system is proposed to derive a pursuit-evasion game in complex three-dimensional (3D) polygonal environment, which is large enough but with boundary. Firstly, the system and task hypothesis are introduced. Then, an improved boundary value problem (BVP) is used to unify the terrain data of decision and path planning. Under the condition that the evader knows the position of collaborative pursuers at any time but pursuers just have a line-of-sight view, a worst case is analyzed and the strategy between the evader and pursuers is studied. According to the state of evader, the strategy of collaborative pursuers is discussed in three situations: evader is in the visual field of pursuers, evader just disappears from the visual field of pursuers, and the position of evader is completely unknown to pursuers. The simulation results show that the strategy does not guarantee that the pursuers will win the game in complex 3D polygonal environment, but it is optimal in the worst case.

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“…According to formulas (9), (10), (13) and (14), Wmax, V, t, ρ and r were set to 0.013/s, 4 m/s, 10 s, 307.69 m and 3 m, respectively. Then, the boundaries of the reachable set RSxy, i.e.…”

Section: Reachable Set On 2d Planementioning

confidence: 99%

“…Many reviews have been completed on relevant issues in the past two years [5][6][7][8]. Popular collision avoidance algorithms include geometric method [9][10][11], sampling-based method [12][13][14], numerical optimization [15][16][17][18][19], and artificial potential field (APF) [20][21][22][23][24][25][26][27][28]. The geometric method considers the geometric representation of the collision scene in the search for collision avoidance maneuvers.…”

Section: Introductionmentioning

confidence: 99%

Automatic Separation Management Between Multiple Unmanned Aircraft Vehicles in Uncertain Dynamic Airspace Based on Trajectory Prediction

Du¹,

Wang²,

Zhang³

et al. 2019

RIA

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In an uncertain dynamic airspace, the future trajectories of noncooperative aircrafts (obstacles) are very uncertain. Multiple unmanned aircraft vehicles (UAVs) must avoid colliding into noncooperative obstacles and keep a safe distance between each other. This poses a huge challenge to the unmanned aircraft system traffic management (UTM). To cope with the challenge, this paper puts forward an automatic separation management method for a formation of multiple UAVs based on trajectory prediction in 3D dynamic airspace. Firstly, the uncertain trajectories of each obstacle in a time horizon were predicted based on the reachable set, producing an ellipsoidal reachable region. Next, a safe and efficient double-layer separation management strategy was proposed based on the improved artificial potential field (APF) method, considering the safe distance between cooperative UAVs and that between cooperative and noncooperative UAVs. The distance-based traditional APF method was adopted to manage the conflicts according to the reachable region of each obstacle, maximizing the safety between the UAV and the obstacle. The APF method based on relative motion state was employed to manage the conflicts, and adaptively adjust the dynamic safe separation between the UAVs. Experimental results prove that our method can effectively prevent the conflicts between a UAV and other UAVs in the formation or noncooperative obstacle. Besides, the collision-free trajectory generated by our method is smooth and stable, and close to the planned trajectory. The proposed method provides a solid guarantee to UAV flight safety, while minimizing the impacts on nearby aircrafts. The research findings shed new light on the UTM of highly uncertain low-altitude airspaces.

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A geometrical path planning method for unmanned aerial vehicle in 2D/3D complex environment

Cited by 38 publications

References 28 publications

Optimized Path-Planning in Continuous Spaces for Unmanned Aerial Vehicles Using Meta-Heuristics

Optimized Path-Planning in Continuous Spaces for Unmanned Aerial Vehicles Using Meta-Heuristics

Collaborative Pursuit-Evasion Strategy of UAV/UGV Heterogeneous System in Complex Three-Dimensional Polygonal Environment

Automatic Separation Management Between Multiple Unmanned Aircraft Vehicles in Uncertain Dynamic Airspace Based on Trajectory Prediction

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