Model Predictive Control Using Dynamic Model Decomposition Applied to Two-Wheeled Inverted Pendulum Mobile Robot

2022 19th International Conference on Ubiquitous Robots (UR) Pub Date : 2022-07-04 DOI:10.1109/ur55393.2022.9826244

Junjie Shen, D. Hong

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Abstract

In this paper, we discuss the locomotion control for the two-wheeled inverted pendulum (TWIP) mobile robot. The robot in consideration involves two independent driving wheels sharing the same axle as well as one inverted pendulum in the middle acting as the main body. Instead of considering the entire TWIP mobile robot as a whole, following the idea of Dynamic Model Decomposition, we decompose the robot into the body and the two wheels, with interaction forces and moments connecting them. The effect is that we can thus enjoy lower-dimensional dynamics for each subsystem while their composition maintaining the equivalence to the full-order robot model. Based on that, we further propose a corresponding model predictive control framework via quadratic programming, which considers linearly approximated body dynamics with constrained wheel reaction forces as inputs. The overall methodology was successfully implemented on a TWIP mobile robot in the simulation environment. The simulation results show that the robot is capable of station keeping, disturbance rejection, velocity tracking, and path following.

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基于动态模型分解的两轮倒立摆移动机器人模型预测控制

研究了两轮倒立摆移动机器人的运动控制问题。所考虑的机器人包括两个共享同一轴的独立驱动轮以及中间的一个倒立摆作为主体。我们没有将整个TWIP移动机器人作为一个整体来考虑，而是遵循动力学模型分解的思想，将机器人分解为身体和两个轮子，并通过相互作用的力和力矩将它们连接起来。这样做的效果是，我们可以享受每个子系统的低维动力学，同时它们的组成保持与全阶机器人模型的等价。在此基础上，利用二次规划方法提出了一种模型预测控制框架，该框架以车轮反作用力约束下的线性近似车身动力学为输入。整个方法在TWIP移动机器人仿真环境中成功实现。仿真结果表明，该机器人具有良好的站位保持、抗干扰、速度跟踪和路径跟踪能力。

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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2022 19th International Conference on Ubiquitous Robots (UR)

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