泡泡一分钟：Efficient Trajectory Planning for High Speed Flight in Unknown Environments

张宁  Efficient Trajectory Planning for High Speed Flight in Unknown Environments

高效飞行在未知环境中的有效轨迹规划
连接：https://pan.baidu.com/s/1l0HtSOU-6QSojq7ELrmLIA  提取码：ayc1

Markus Ryll, John Ware, John Carter and Nick Roy

There has been considerable recent work in motion planning for UAVs to enable aggressive, highly dynamic flight in known environments with motion capture systems. However, these existing planners have not been shown to enable the same kind of flight in unknown, outdoor environments. In this paper we present a receding horizon planning architecture that enables the fast replanning necessary for reactive obstacle avoidance by combining three techniques. First, we show how previous work in computationally efficient, closed-form trajectory generation method can be coupled with spatial partitioning data structures to reason about the geometry of the environment in real-time. Second, we show how to maintain safety margins during fast flight in unknown environments by planning velocities according to obstacle density. Third, our recedinghorizon, sampling-based motion planner uses minimum-jerk trajectories and closed-loop tracking to enable smooth, robust, high-speed flight with the low angular rates necessary for accurate visual-inertial navigation. We compare against two state-of-the-art, reactive motion planners in simulation and benchmark solution quality against an offline global planner. Finally, we demonstrate our planner over 80 flights with a combined distance of 22km of autonomous quadrotor flights in an urban environment at speeds up to 9.4ms-1.

最近在无人机的运动规划方面进行了大量工做，以便在具备运动捕捉系统的已知环境中实现积极，高度动态的飞行。然而，这些现有的规划者还没有被证实可以在未知的室外环境中实现一样的飞行。在本文中，咱们提出了一种后退的地平线规划架构，经过结合三种技术，能够实现反应性避障所需的快速从新规划。首先，咱们展现了先前在计算上有效的闭合轨迹生成方法中的工做如何与空间划分数据结构相结合，以实时推理环境的几何形状。其次，咱们展现了如何经过根据障碍物密度规划速度来在未知环境中快速飞行期间保持安全裕度。第三，咱们的后退运动，基于采样的运动规划器使用最小冲击轨迹和闭环跟踪，以实现平稳，稳健，高速飞行，具备精确视觉惯性导航所需的低角速率。咱们将模拟和基准解决方案质量方面的两个最早进的反应式运动规划器与一个全局规划师进行比较。 最后，咱们展现了超过80个飞行计划器，在城市环境中，自动四旋翼飞行器的总距离为22km，速度高达9.4ms-1。