Shape-Programming in Hyperelasticity Through Differential Growth

IF 1.6 2区 数学 Q2 MATHEMATICS, APPLIED
Rogelio Ortigosa-Martínez, Jesús Martínez-Frutos, Carlos Mora-Corral, Pablo Pedregal, Francisco Periago
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Abstract

This paper is concerned with the growth-driven shape-programming problem, which involves determining a growth tensor that can produce a deformation on a hyperelastic body reaching a given target shape. We consider the two cases of globally compatible growth, where the growth tensor is a deformation gradient over the undeformed domain, and the incompatible one, which discards such hypothesis. We formulate the problem within the framework of optimal control theory in hyperelasticity. The Hausdorff distance is used to quantify dissimilarities between shapes; the complexity of the actuation is incorporated in the cost functional as well. Boundary conditions and external loads are allowed in the state law, thus extending previous works where the stress-free hypothesis turns out to be essential. A rigorous mathematical analysis is then carried out to prove the well-posedness of the problem. The numerical approximation is performed using gradient-based optimisation algorithms. Our main goal in this part is to show the possibility to apply inverse techniques for the numerical approximation of this problem, which allows us to address more generic situations than those covered by analytical approaches. Several numerical experiments for beam-like and shell-type geometries illustrate the performance of the proposed numerical scheme.

Abstract Image

通过差异增长实现超弹性中的形状编程
摘要 本文主要研究生长驱动的形状规划问题,即确定一个生长张量,使超弹性体产生达到给定目标形状的变形。我们考虑了两种情况:一种是全局相容生长,即生长张量是未变形域上的变形梯度;另一种是不相容生长,即放弃这种假设。我们在超弹性最优控制理论的框架内提出了这一问题。Hausdorff 距离用于量化形状之间的差异;执行的复杂性也被纳入成本函数。在状态规律中允许边界条件和外部载荷,从而扩展了之前的研究,在这些研究中,无应力假设被证明是至关重要的。随后进行了严格的数学分析,以证明问题的合理性。使用基于梯度的优化算法进行数值逼近。本部分的主要目标是展示应用反演技术对该问题进行数值逼近的可能性,这使我们能够解决比分析方法更普遍的情况。针对梁状和壳状几何结构的几个数值实验说明了所提出的数值方案的性能。
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来源期刊
CiteScore
3.30
自引率
5.60%
发文量
103
审稿时长
>12 weeks
期刊介绍: The Applied Mathematics and Optimization Journal covers a broad range of mathematical methods in particular those that bridge with optimization and have some connection with applications. Core topics include calculus of variations, partial differential equations, stochastic control, optimization of deterministic or stochastic systems in discrete or continuous time, homogenization, control theory, mean field games, dynamic games and optimal transport. Algorithmic, data analytic, machine learning and numerical methods which support the modeling and analysis of optimization problems are encouraged. Of great interest are papers which show some novel idea in either the theory or model which include some connection with potential applications in science and engineering.
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