Abstract
The ability of an autonomous Unmanned Aerial Vehicle (UAV) in an unknown environment is a prerequisite for its execution of complex tasks and is the main research direction in related fields. The autonomous navigation of UAVs in unknown environments requires solving the problem of autonomous exploration of the surrounding environment and path planning, which determines whether the drones can complete mission-based flights safely and efficiently. Existing UAV autonomous flight systems hardly perform well in terms of efficient exploration and flight trajectory quality. This paper establishes an integrated solution for autonomous exploration and path planning. In terms of autonomous exploration, frontier-based and sampling-based exploration strategies are integrated to achieve fast and effective exploration performance. In the study of path planning in complex environments, an advanced Rapidly Exploring Random Tree (RRT) algorithm combining the adaptive weights and dynamic step size is proposed, which effectively solves the problem of balancing flight time and trajectory quality. Then, this paper uses the Hermite difference polynomial to optimization the trajectory generated by the RRT algorithm. We named proposed UAV autonomous flight system as Frontier and Sampling-based Exploration and Advanced RRT Planner system (FSEPlanner). Simulation performs in both apartment and maze environment, and results show that the proposed FSEPlanner algorithm achieves greatly improved time consumption and path distances, and the smoothed path is more in line with the actual flight needs of a UAV.
Highlights
Unmanned aerial vehicles (UAVs) have good maneuverability and a strong hovering ability [1]
This paper introduced the dynamic step size and adaptive weight in UAV path planning system based on the rapid exploration tree
In the autonomous exploration experiment, we compared it with the bug algorithm for wall following algorithm proposed in [14], frontier-based exploration proposed in [13] and the receiving horizon next-best view (NBV) planner proposed in [18]
Summary
Unmanned aerial vehicles (UAVs) have good maneuverability and a strong hovering ability [1]. They are an ideal platform for surveillance, search and rescue in narrow indoor and outdoor environments [2]. Micro-UAVs equipped with airborne sensors are an ideal platform for autonomous navigation in complex and narrow environments and can solve problems such as exploration, mapping, search and rescue [3,4]. Navigating a micro-UAV in a chaotic and unknown environment is a challenging problem To perform these tasks effectively, UAVs must explore the unknown environment around them and detect obstacles and plan and execute a collision-free, dynamic and feasible trajectory [5].
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