Flexible and Topological Consistent Local Replanning for Multirotors

In many situations such as city delivery and wild inspection, quadrotors are often required to follow a pre- defined reference trajectory. However, these reference trajec- tories cannot be perfectly safe, resulting in conflicts between tracking the reference precisely, flying safely, and finishing the mission timely. This paper proposes to solve the above problem, by introducing a replanning framework that first generates a topological consistent collision-free initial path and then flexibly optimizes the rejoin point and trajectory duration to generate a smooth and safe local rejoining trajectory. To avoid local trajectory switching in different directions during high-frequency replanning, we propose a topology-preserving path search algorithm based on kinodynamic RRT*. To satisfy dynamic constraints, avoid delays, and achieve a smooth rejoin of the reference trajectory, we propose an optimization-based approach to refine the initial trajectory. The simulation results confirm that our proposed topological consistency and flexible optimization methods can reduce the risk of local trajectory and decrease obstacle avoidance delay for tracking reference trajectory. We also conduct real-world experiments in challeng- ing environments and verify the effectiveness of our method.