Linear Temporal Logic-based Mixed-Integer Linear Problem Planning with the Koopman Operator

IECON 2022 – 48th Annual Conference of the IEEE Industrial Electronics Society Pub Date : 2022-10-17 DOI:10.1109/IECON49645.2022.9969097

Shumpei Tokuda, M. Yamakita, Hiroyuki Oyama, Rin Takano

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Abstract

We present a formulation for a linear temporal logic (LTL)-based task planning using the Koopman operator. The dynamics of nonlinear systems can be represented as linear systems by lifting them to a space of augmented states using the Koopman operator. On the other hand, the lifted linear system cannot capture the nonlinear effects of inputs, which appear in many robotic systems. Therefore, instead of a lifted linear system, we can consider representing control-affine bilinear systems. However, since the lifted bilinear systems are nonlinear, we need to solve nonlinear programming problems for trajectory optimization. This paper presents a methodology for the trajectory optimization problem of the lifted bilinear system. Using the mixed-integer convex approximation, we can solve the trajectory optimization problem of the lifted bilinear systems as a mixed-integer linear programming problem. This formulation allows us to solve LTL-based task planning problems for nonlinear systems. The effectiveness of the proposed method was confirmed by numerical simulations.

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基于时间线性逻辑的Koopman算子混合整数线性问题规划

我们提出了一个基于线性时间逻辑(LTL)的任务规划公式，该公式使用Koopman算子。非线性系统的动力学可以用库普曼算子表示为线性系统，将其提升到增广状态空间。另一方面，提升的线性系统无法捕捉输入的非线性效应，这在许多机器人系统中都存在。因此，我们可以考虑表示控制仿射双线性系统，而不是一个提升的线性系统。然而，由于提升双线性系统是非线性的，我们需要解决非线性规划问题来进行轨迹优化。本文提出了一种求解升力双线性系统轨迹优化问题的方法。利用混合整数凸逼近，将提升双线性系统的轨迹优化问题求解为一个混合整数线性规划问题。这个公式允许我们解决非线性系统的基于ltl的任务规划问题。数值仿真验证了该方法的有效性。

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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IECON 2022 – 48th Annual Conference of the IEEE Industrial Electronics Society

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