Radar Sensors in Collaborative Robotics: Fast Simulation and Experimental Validation

Christian Stetco, Barnaba Ubezio, Stephan Mühlbacher-Karrer, H. Zangl
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引用次数: 10

Abstract

With the availability of small system in package realizations, radar systems become more and more attractive for a variety of applications in robotics, in particular also for collaborative robotics. As the simulation of robot systems in realistic scenarios has become an important tool, not only for design and optimization, but also e.g. for machine learning approaches, realistic simulation models are needed. In the case of radar sensor simulations, this means providing more realistic results than simple proximity sensors, e.g. in the presence of multiple objects and/or humans, objects with different relative velocities and differentiation between background and foreground movement. Due to the short wavelength in the millimeter range, we propose to utilize methods known from computer graphics (e.g. z-buffer, Lambertian reflectance model) to quickly acquire depth images and reflection estimates. This information is used to calculate an estimate of the received signal for a Frequency Modulated Continuous Wave (FMCW) radar by superposition of the corresponding signal contributions. Due to the moderate computational complexity, the approach can be used with various simulation environments such as V-Rep or Gazebo. Validity and benefits of the approach are demonstrated by means of a comparison with experimental data obtained with a radar sensor on a UR10 arm in different scenarios.
协同机器人中的雷达传感器:快速仿真与实验验证
随着小型系统在封装实现中的可用性,雷达系统在机器人,特别是协作机器人中的各种应用中变得越来越有吸引力。由于机器人系统在真实场景下的仿真已经成为一个重要的工具,不仅是设计和优化,而且对于机器学习方法来说,都需要真实的仿真模型。在雷达传感器模拟的情况下,这意味着提供比简单的接近传感器更真实的结果,例如,在多个物体和/或人类存在的情况下,具有不同相对速度的物体以及背景和前景运动之间的差异。由于波长在毫米范围内较短,我们建议利用计算机图形学中已知的方法(例如z-buffer, Lambertian反射模型)来快速获取深度图像和反射估计。该信息用于通过叠加相应的信号贡献来计算调频连续波(FMCW)雷达接收信号的估计。由于计算复杂度适中,该方法可用于各种仿真环境,如V-Rep或Gazebo。通过与UR10臂上雷达传感器在不同场景下获得的实验数据进行比较,证明了该方法的有效性和优越性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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