Optimization-based trajectory generation methods are widely used in whole-body planning for robots. However, existing work either oversimplifies the robot's geometry and environment representation, resulting in a conservative trajectory, or suffers from a huge overhead in maintaining additional information such as the Signed Distance Field (SDF). To bridge the gap, we consider the robot as an implicit function, with its surface boundary represented by the zero-level set of its SDF. Based on this, we further employ another implicit function to lazily compute the signed distance to the swept volume generated by the robot and its trajectory. The computation is efficient by exploiting continuity in space-time, and the implicit function guarantees precise and continuous collision evaluation even for nonconvex robots with complex surfaces. Furthermore, we propose a trajectory optimization pipeline applicable to the implicit SDF. Simulation and real-world experiments validate the high performance of our approach for arbitrarily shaped robot trajectory optimization.
翻译:优化轨道生成方法被广泛用于机器人的整体规划中,然而,现有的工作要么过于简化机器人的几何和环境代表,导致保守的轨迹,要么在维护更多信息方面承受巨大的间接费用,如 " 远距离场 " 。为了缩小差距,我们认为机器人是一种隐含的功能,其表面边界由SDF的零水平构成。在此基础上,我们进一步使用另一种隐含功能,以拉伸计算机器人所完成的体积及其轨迹的连接距离。计算效率是利用空间时的连续性,而隐含功能保证精确和持续碰撞评价,即使是对有复杂表面的非康威克斯机器人也是如此。此外,我们提议了适用于隐含SDF的轨迹优化管道。模拟和现实世界实验证实了我们任意形状的机器人轨迹优化方法的高度性能。</s>