Optimal multi-target navigation in complex environments via Generalized Voronoi Diagram graph structures

Black, Brandon

10 May 2024

With many robots now being developed for indoor settings, an autonomous mobile robot should be capable of reaching multiple targets within a dense, complex environment while maintaining the optimal path taken and avoiding all obstacles. In this thesis, we propose a global path planning algorithm that uses data created from a Generalized Voronoi Diagram (GVD) to traverse complex environments. The global route is made from the skeleton of the diagram that ensures the avoidance of static obstacles. Once this route is determined, dynamic programming is used to determine the optimal route to reach each target location while safely navigating obstacles in the map. A Dynamic Window Approach (DWA) local path planner is integrated into the algorithm to provide collision-free navigation in case of unexpected or dynamic obstacles that may be encountered during traversal. Our comprehensive simulations and comparative analyses highlight the proposed model’s robustness, demonstrating its ability to efficiently navigate to multiple targets through the shortest routes while adeptly circumventing obstacles. These findings validate the model’s effectiveness, confirming its superior performance in complex multi-target navigation scenarios and its capability to dynamically adapt to unforeseen obstacles, thereby illustrating a significant advancement in the field of autonomous indoor navigation.

Obstacle Avoidance Path Planning for Worm-like Robot

Liu, Zehao

01 September 2021

No description available.

Mechanical Engineering

Robotics

Robots

Path planning

Worm-like robot

Obstacle avoidance path planning

Bezier Curve

Matlab simulation