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Main Authors: Wang, Jingyi, Solberg, Jerome, Puso, Mike A., Chin, Eric B., Petra, Cosmin G.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.03081
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author Wang, Jingyi
Solberg, Jerome
Puso, Mike A.
Chin, Eric B.
Petra, Cosmin G.
author_facet Wang, Jingyi
Solberg, Jerome
Puso, Mike A.
Chin, Eric B.
Petra, Cosmin G.
contents Design optimization problems, e.g., shape optimization, that involve deformable bodies in unilateral contact are challenging as they require robust contact solvers, complex optimization methods that are typically gradient-based, and sensitivity derivations. Notably, the problems are nonsmooth, adding significant difficulty to the optimization process. We study design optimization problems in frictionless unilateral contact subject to pressure constraints, using both gradient-based and gradient-free optimization methods, namely Bayesian optimization. The contact simulation problem is solved via the mortar contact and finite element methods. For the gradient-based method, we use the direct differentiation method to compute the sensitivities of the cost and constraint function with respect to the design variables. Then, we use Ipopt to solve the optimization problems. For the gradient-free approach, we use a constrained Bayesian optimization algorithm based on the standard Gaussian Process surrogate model. We present numerical examples that control the contact pressure, inspired by real-life engineering applications, to demonstrate the effectiveness, strengths and shortcomings of both methods. Our results suggest that both optimization methods perform reasonably well for these nonsmooth problems.
format Preprint
id arxiv_https___arxiv_org_abs_2405_03081
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Design optimization in unilateral contact using pressure constraints and Bayesian optimization
Wang, Jingyi
Solberg, Jerome
Puso, Mike A.
Chin, Eric B.
Petra, Cosmin G.
Numerical Analysis
Design optimization problems, e.g., shape optimization, that involve deformable bodies in unilateral contact are challenging as they require robust contact solvers, complex optimization methods that are typically gradient-based, and sensitivity derivations. Notably, the problems are nonsmooth, adding significant difficulty to the optimization process. We study design optimization problems in frictionless unilateral contact subject to pressure constraints, using both gradient-based and gradient-free optimization methods, namely Bayesian optimization. The contact simulation problem is solved via the mortar contact and finite element methods. For the gradient-based method, we use the direct differentiation method to compute the sensitivities of the cost and constraint function with respect to the design variables. Then, we use Ipopt to solve the optimization problems. For the gradient-free approach, we use a constrained Bayesian optimization algorithm based on the standard Gaussian Process surrogate model. We present numerical examples that control the contact pressure, inspired by real-life engineering applications, to demonstrate the effectiveness, strengths and shortcomings of both methods. Our results suggest that both optimization methods perform reasonably well for these nonsmooth problems.
title Design optimization in unilateral contact using pressure constraints and Bayesian optimization
topic Numerical Analysis
url https://arxiv.org/abs/2405.03081