Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour

Dilaksan Thillaithevan; Ryan Murphy; Robert Hewson; Matthew Santer

doi:10.1007/s00158-024-03761-7

Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour

Dilaksan Thillaithevan^*
, Ryan Murphy
, Robert Hewson
, Matthew Santer

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

This paper introduces an inverse design framework for the precise tailoring of desired nonlinear mechanical responses in periodic microstructures, with particular focus on prescribed nonlinear stress–strain relationships. The topology optimization hinges on minimizing the error between the target and realized properties of the microstructures. A deformation-driven homogenization framework is setup. The periodic constraints needed for the microscale equilibrium equation are imposed through strongly enforced periodic boundary conditions and the removal of the translational nullspace, avoiding the need for Lagrange multipliers, greatly simplifying the implementation. Automatic differentiation is leveraged to efficiently calculate the necessary sensitivities for the gradient-based optimization. To further aid the design of discrete designs a intermediate density penalty constraint is proposed. Numerical examples underscore the efficacy of our methodology, showcasing microstructures that demonstrate targeted softening and stiffening as well as distinctive directional behaviour.

Original language	English
Article number	55
Number of pages	16
Journal	Structural and Multidisciplinary Optimization
Volume	67
Issue number	4
Early online date	18 Mar 2024
DOIs	https://doi.org/10.1007/s00158-024-03761-7
Publication status	Published - Apr 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

Keywords

Finite strain
Hyperelasticity
Inverse design
Inverse homogenization
Metamaterials
Periodic microstructures
Topology optimization

ASJC Scopus subject areas

Software
Control and Systems Engineering
Computer Science Applications
Computer Graphics and Computer-Aided Design
Control and Optimization

Access to Document

10.1007/s00158-024-03761-7Licence: Creative Commons: Attribution (CC BY)

ThillaithevanD2024InverseFinal published version, 3.79 MBLicence: Creative Commons: Attribution (CC BY)

Correction to: Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour
Thillaithevan, D., Murphy, R., Hewson, R. & Santer, M., Dec 2025, In: Structural and Multidisciplinary Optimization. 68, 12, 1 p., 256.
Research output: Contribution to journal › Comment/debate

Open Access
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Oncological Engineering - A new concept in the treatment of bone metastases
Bryant, M. (Co-Investigator) & Hall, R. (Principal Investigator)
Engineering & Physical Science Research Council
8/01/24 → 30/09/28
Project: Research Councils

Cite this

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title = "Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour",

abstract = "This paper introduces an inverse design framework for the precise tailoring of desired nonlinear mechanical responses in periodic microstructures, with particular focus on prescribed nonlinear stress–strain relationships. The topology optimization hinges on minimizing the error between the target and realized properties of the microstructures. A deformation-driven homogenization framework is setup. The periodic constraints needed for the microscale equilibrium equation are imposed through strongly enforced periodic boundary conditions and the removal of the translational nullspace, avoiding the need for Lagrange multipliers, greatly simplifying the implementation. Automatic differentiation is leveraged to efficiently calculate the necessary sensitivities for the gradient-based optimization. To further aid the design of discrete designs a intermediate density penalty constraint is proposed. Numerical examples underscore the efficacy of our methodology, showcasing microstructures that demonstrate targeted softening and stiffening as well as distinctive directional behaviour.",

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AU - Thillaithevan, Dilaksan

AU - Murphy, Ryan

AU - Hewson, Robert

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N1 - Publisher Copyright: © The Author(s) 2024.

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Y1 - 2024/4

N2 - This paper introduces an inverse design framework for the precise tailoring of desired nonlinear mechanical responses in periodic microstructures, with particular focus on prescribed nonlinear stress–strain relationships. The topology optimization hinges on minimizing the error between the target and realized properties of the microstructures. A deformation-driven homogenization framework is setup. The periodic constraints needed for the microscale equilibrium equation are imposed through strongly enforced periodic boundary conditions and the removal of the translational nullspace, avoiding the need for Lagrange multipliers, greatly simplifying the implementation. Automatic differentiation is leveraged to efficiently calculate the necessary sensitivities for the gradient-based optimization. To further aid the design of discrete designs a intermediate density penalty constraint is proposed. Numerical examples underscore the efficacy of our methodology, showcasing microstructures that demonstrate targeted softening and stiffening as well as distinctive directional behaviour.

AB - This paper introduces an inverse design framework for the precise tailoring of desired nonlinear mechanical responses in periodic microstructures, with particular focus on prescribed nonlinear stress–strain relationships. The topology optimization hinges on minimizing the error between the target and realized properties of the microstructures. A deformation-driven homogenization framework is setup. The periodic constraints needed for the microscale equilibrium equation are imposed through strongly enforced periodic boundary conditions and the removal of the translational nullspace, avoiding the need for Lagrange multipliers, greatly simplifying the implementation. Automatic differentiation is leveraged to efficiently calculate the necessary sensitivities for the gradient-based optimization. To further aid the design of discrete designs a intermediate density penalty constraint is proposed. Numerical examples underscore the efficacy of our methodology, showcasing microstructures that demonstrate targeted softening and stiffening as well as distinctive directional behaviour.

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KW - Hyperelasticity

KW - Inverse design

KW - Inverse homogenization

KW - Metamaterials

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KW - Topology optimization

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Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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Research output

Correction to: Inverse design of periodic microstructures with targeted nonlinear mechanical behaviour

Projects

Oncological Engineering - A new concept in the treatment of bone metastases

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