A Benchmarking of DCM Based Architectures for Position, Velocity and Torque Controlled Humanoid Robots

Int. J. Humanoid Robotics Pub Date : 2019-11-27 DOI:10.1142/S0219843619500348

Giulio Romualdi, Stefano Dafarra, Yue Hu, Prashanth Ramadoss, Francisco Javier Andrade Chavez, Silvio Traversaro, D. Pucci

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引用次数: 10

Abstract

This paper contributes toward the benchmarking of control architectures for bipedal robot locomotion. It considers architectures that are based on the Divergent Component of Motion (DCM) and composed of three main layers: trajectory optimization, simplified model control, and whole-body quadratic programming (QP) control layer. While the first two layers use simplified robot models, the whole-body QP control layer uses a complete robot model to produce either desired positions, velocities, or torques inputs at the joint-level. This paper then compares two implementations of the simplified model control layer, which are tested with position, velocity, and torque control modes for the whole-body QP control layer. In particular, both an instantaneous and a Receding Horizon controller are presented for the simplified model control layer. We show also that one of the proposed architectures allows the humanoid robot iCub to achieve a forward walking velocity of 0.3372[Formula: see text]m/s, which is the highest walking velocity achieved by the iCub robot.

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基于DCM的位置、速度和力矩控制仿人机器人体系结构的基准测试

本文为双足机器人运动控制体系的基准测试做出了贡献。它考虑了基于运动发散分量(DCM)的架构，并由三个主要层组成:轨迹优化、简化模型控制和全身二次规划(QP)控制层。前两层使用简化的机器人模型，而全身QP控制层使用完整的机器人模型在关节层面产生所需的位置、速度或扭矩输入。然后，对简化模型控制层的两种实现进行了比较，并对全身QP控制层的位置、速度和转矩控制模式进行了测试。特别地，对简化模型控制层提出了瞬时控制器和后退地平线控制器。我们还表明，其中一种提出的架构允许仿人机器人iCub实现0.3372[公式:见文本]m/s的向前行走速度，这是iCub机器人实现的最高行走速度。

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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Int. J. Humanoid Robotics

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