A pnh-Adaptive Refinement Procedure for Numerical Optimal Control Problems

IF 1.9 4区 工程技术 Q3 ENGINEERING, MECHANICAL Journal of Computational and Nonlinear Dynamics Pub Date : 2023-05-04 DOI:10.1115/1.4062227
Lorenzo Bartali, Marco Gabiccini, Massimo Guiggiani
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Abstract

Abstract This paper presents an automatic procedure to enhance the accuracy of the numerical solution of an optimal control problem (OCP) discretized via direct collocation at Gauss–Legendre points. First, a numerical solution is obtained by solving a nonlinear program (NLP). Then, the method evaluates its accuracy and adaptively changes both the degree of the approximating polynomial within each mesh interval and the number of mesh intervals until a prescribed accuracy is met. The number of mesh intervals is increased for all state vector components alike, in a classical fashion. Instead, improving on state-of-the-art procedures, the degrees of the polynomials approximating the different components of the state vector are allowed to assume, in each finite element, distinct values. This explains the pnh definition, where n is the state dimension. With respect to the approaches found in the literature, where the degree is always raised to the highest order for all the state components, our methods allow a sensible reduction of the overall number of variables of the resulting NLP, with a corresponding reduction of the computational burden. Numerical tests on three OCP problems highlight that, under the same maximum allowable error, by independently selecting the degree of the polynomial for each state, our method effectively picks lower degrees for some of the states, thus reducing the overall number of variables in the NLP. Accordingly, various advantages are brought about, the most remarkable being: (i) an increased computational efficiency for the final enhanced mesh with solution accuracy still within the prescribed tolerance, (ii) a reduced risk of being trapped by local minima due to the reduced NLP size, and (iii) a gain of the robustness of the convergence process due to the better-behaved solution landscapes.
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数值最优控制问题的pnn -自适应细化方法
本文提出了一种提高高斯-勒让德点直接配置离散的最优控制问题(OCP)数值解精度的自动算法。首先,通过求解非线性程序(NLP)得到数值解。然后,该方法评估其精度,并自适应地改变每个网格间隔内逼近多项式的程度和网格间隔的数量,直到满足规定的精度。以经典的方式增加所有状态向量分量的网格间隔数量。相反,改进了最先进的程序,允许在每个有限元中假设近似状态向量的不同分量的多项式的度有不同的值。这解释了pnh的定义,其中n是状态维。对于文献中发现的方法,其程度总是提高到所有状态分量的最高阶,我们的方法允许合理地减少结果NLP的变量总数,相应减少计算负担。对三个OCP问题的数值测试表明,在相同的最大允许误差下,通过独立选择每个状态的多项式度,我们的方法有效地为某些状态选择了较低的度,从而减少了NLP中变量的总数。因此,带来了各种优势,最显著的是:(i)提高了最终增强网格的计算效率,且解精度仍在规定的公差范围内,(ii)由于减少了NLP大小而降低了被局部最小值困住的风险,以及(iii)由于表现更好的解景观而获得了收敛过程的鲁棒性。
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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来源期刊
CiteScore
4.00
自引率
10.00%
发文量
72
审稿时长
6-12 weeks
期刊介绍: The purpose of the Journal of Computational and Nonlinear Dynamics is to provide a medium for rapid dissemination of original research results in theoretical as well as applied computational and nonlinear dynamics. The journal serves as a forum for the exchange of new ideas and applications in computational, rigid and flexible multi-body system dynamics and all aspects (analytical, numerical, and experimental) of dynamics associated with nonlinear systems. The broad scope of the journal encompasses all computational and nonlinear problems occurring in aeronautical, biological, electrical, mechanical, physical, and structural systems.
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