Achieving stable hopping has been a hallmark challenge in the field of dynamic legged locomotion. Controlled hopping is notably difficult due to extended periods of underactuation, combined with very short ground phases wherein ground interactions must be modulated to regulate global state. In this work, we explore the use of hybrid nonlinear model predictive control, paired with a low-level feedback controller in a multi-rate hierarchy, to achieve dynamically stable motions on a novel 3D hopping robot. In order to demonstrate richer behaviors on the manifold of rotations, both the planning and feedback layers must be done in a geometrically consistent fashion; therefore, we develop the necessary tools to employ Lie group integrators and an appropriate feedback controller. We experimentally demonstrate stable 3D hopping on a novel robot, as well as trajectory tracking and flipping in simulation.
翻译:实现稳定的购物一直是动态腿动脉移动领域的一个标志性挑战。 控制型购物特别困难,原因是长时间的低活动,加上极短的地面阶段,地面互动必须调整以调节全球状态。 在这项工作中,我们探索使用混合的非线性模型预测控制,同时配以一个多层次的低级别反馈控制器,以在新型的3D型购物机器人上实现动态稳定的动作。 为了显示在轮椅组合上较富裕的行为,规划和反馈层必须以几何一致的方式进行;因此,我们开发了必要的工具,以使用Lie组集成器和适当的反馈控制器。我们实验性地展示了在新型机器人上稳定的3D型购物,以及模拟中的轨迹跟踪和翻转。</s>