基于EKF的雷达惯性里程测量方法

C. Doer, G. Trommer
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引用次数: 23

摘要

精确定位是自主机器人的关键。在gnss拒绝和退化的视觉环境中导航仍然是非常具有挑战性的。基于视觉传感器的方法通常在黑暗、阳光直射、雾或烟雾等条件下失败。我们的方法是基于毫米波FMCW雷达传感器和惯性测量单元(IMU),因为这两个传感器都可以在这些条件下工作。具体来说,我们提出了一种基于扩展卡尔曼滤波(EKF)的三维雷达惯性里程计(里约热内卢)解决方案。使用标准的汽车FMCW雷达测量每个被探测目标的三维位置和多普勒速度。在雷达测量的基础上,进行了RANSAC三维自我速度估计。与惯性数据的融合进一步提高了精度、鲁棒性,并提供了高速率的运动估计。提出了一种基于气压高度融合的扩展。在一个运动捕捉系统中,对基于雷达的自我速度估计进行了仿真测试,并用真实世界的数据集评估了其精度。在超过200米的室内和室外环境中进行的测试,最终定位误差低于行驶距离的0.6%。所提出的里程计方法即使在嵌入式计算机上也比实时运行更快。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An EKF Based Approach to Radar Inertial Odometry
Accurate localization is key for autonomous robotics. Navigation in GNSS-denied and degraded visual environment is still very challenging. Approaches based on visual sensors usually fail in conditions like darkness, direct sunlight, fog or smoke.Our approach is based on a millimeter wave FMCW radar sensor and an Inertial Measurement Unit (IMU) as both sensors can operate in these conditions. Specifically, we propose an Extended Kalman Filter (EKF) based solution to 3D Radar Inertial Odometry (RIO). A standard automotive FMCW radar which measures the 3D position and Doppler velocity of each detected target is used. Based on the radar measurements, a RANSAC 3D ego velocity estimation is carried out. Fusion with inertial data further improves the accuracy, robustness and provides a high rate motion estimate. An extension with barometric height fusion is presented.The radar based ego velocity estimation is tested in simulation and the accuracy evaluated with real world datasets in a motion capture system. Tests in indoor and outdoor environments with trajectories longer than 200m achieved a final position error below 0.6% of the distance traveled. The proposed odometry approach runs faster than realtime even on an embedded computer.
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