二阶和高阶系统的搭配方法

IF 3.7 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Autonomous Robots Pub Date : 2024-01-28 DOI:10.1007/s10514-023-10155-z

Siro Moreno-Martín, Lluís Ros, Enric Celaya

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引用次数: 0

摘要

人们往往没有注意到，在应用于机器人优化控制时，主要的搭配方法存在根本性缺陷。这种方法假定系统动力学由一阶 ODE 给出，而机器人通常受二阶或更高阶的 ODE 控制，其中涉及配置变量及其时间导数。因此，要应用配位法，通常的做法是采用众所周知的将 M 阶 ODE 转化为 M 阶一阶 ODE 的程序。这种操作方法在连续域中完全有效，但在问题离散化时却会导致不一致。由于配置变量及其时间导数是用同阶多项式逼近的，因此无法满足它们的微分依赖关系，也就无法满足实际的动力学要求，甚至在配置点上也是如此。本文提请注意这一问题，并开发了梯形和赫米特-辛普森配准方法的改进版本，这些方法不会出现这些不一致问题。在许多情况下，新方法将动力学转录误差减少了一个数量级，甚至更多，而计算求解的成本却没有明显增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Collocation methods for second and higher order systems

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Collocation methods for second and higher order systems

It is often unnoticed that the predominant way to use collocation methods is fundamentally flawed when applied to optimal control in robotics. Such methods assume that the system dynamics is given by a first order ODE, whereas robots are often governed by a second or higher order ODE involving configuration variables and their time derivatives. To apply a collocation method, therefore, the usual practice is to resort to the well known procedure of casting an Mth order ODE into M first order ones. This manipulation, which in the continuous domain is perfectly valid, leads to inconsistencies when the problem is discretized. Since the configuration variables and their time derivatives are approximated with polynomials of the same degree, their differential dependencies cannot be fulfilled, and the actual dynamics is not satisfied, not even at the collocation points. This paper draws attention to this problem, and develops improved versions of the trapezoidal and Hermite–Simpson collocation methods that do not present these inconsistencies. In many cases, the new methods reduce the dynamics transcription error in one order of magnitude, or even more, without noticeably increasing the cost of computing the solutions.

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来源期刊

Autonomous Robots 工程技术-机器人学

CiteScore

7.90

自引率

5.70%

发文量

审稿时长

3 months

期刊介绍： Autonomous Robots reports on the theory and applications of robotic systems capable of some degree of self-sufficiency. It features papers that include performance data on actual robots in the real world. Coverage includes: control of autonomous robots · real-time vision · autonomous wheeled and tracked vehicles · legged vehicles · computational architectures for autonomous systems · distributed architectures for learning, control and adaptation · studies of autonomous robot systems · sensor fusion · theory of autonomous systems · terrain mapping and recognition · self-calibration and self-repair for robots · self-reproducing intelligent structures · genetic algorithms as models for robot development. The focus is on the ability to move and be self-sufficient, not on whether the system is an imitation of biology. Of course, biological models for robotic systems are of major interest to the journal since living systems are prototypes for autonomous behavior.