Uncertainty quantification of bistable variable stiffness laminate using machine learning assisted perturbation approach

Research output: Contribution to journalArticleResearchpeer review

Authors

External Research Organisations

  • Indian Institute of Technology Madras (IITM)
  • University of Texas at Austin
View graph of relations

Details

Original languageEnglish
Article number117072
JournalComposite structures
Volume319
Early online date2 May 2023
Publication statusPublished - 1 Sept 2023
Externally publishedYes

Abstract

Morphing structures have received growing interest in aerospace structures and wind turbines due to their rapid shape-changing ability in response to the change in operating conditions. Bistable laminates using variable stiffness composites are considered potential candidates in morphing structures for their ability to tailor the design space with a plethora of multiple stable configurations and satisfy the conflicting requirements of load-carrying capacity and deformability. Even though extensive works have been reported on the analysis and design of the cured shape of unsymmetrical variable stiffness laminates for morphing application, the effect of uncertainty in design variables on the behavior of bistable laminates is not profoundly assessed in the literature. In particular, uncertainty propagation through a highly non-linear map can lead to a significant discrepancy between the numerically predicted and experimental observations. Therefore, for adaptability in practical application, it is imperative to quantify the uncertainty as well as to characterize the non-linearity present near the design point of interest. In this work, a general purpose machine learning assisted uncertainty quantification (MLAUQ) framework is developed and demonstrated on unsymmetrical bistable laminate. The study considers three different variants of the approach based on the order of approximation (O(hk)) used for the training purpose. It is found that the MLAUQ−3 approach performs better than other approaches, and a theoretical justification for the same is provided. The method relies on the fact that expensive computation of the Hessian required for standard perturbation approaches can be bypassed by training a neural network while retaining accurate gradient information near the design point of interest. In the case of bistable laminate, a network trained with a few training samples can capture the local model non-linearity. Further, numerical investigations reveal that the proposed approach is computationally efficient and accurate compared to traditional uncertainty quantification (UQ) approaches.

Keywords

    Bistability, Composites, Finite element, Sensitivity, Snap-through, Uncertainty, Variable stiffness

ASJC Scopus subject areas

Cite this

Uncertainty quantification of bistable variable stiffness laminate using machine learning assisted perturbation approach. / Suraj, K. S.; Anilkumar, P. M.; Krishnanunni, C. G. et al.
In: Composite structures, Vol. 319, 117072, 01.09.2023.

Research output: Contribution to journalArticleResearchpeer review

Suraj KS, Anilkumar PM, Krishnanunni CG, Rao BN. Uncertainty quantification of bistable variable stiffness laminate using machine learning assisted perturbation approach. Composite structures. 2023 Sept 1;319:117072. Epub 2023 May 2. doi: 10.1016/j.compstruct.2023.117072
Download
@article{1116f8b911c94bc6a6d84e309b97a5ce,
title = "Uncertainty quantification of bistable variable stiffness laminate using machine learning assisted perturbation approach",
abstract = "Morphing structures have received growing interest in aerospace structures and wind turbines due to their rapid shape-changing ability in response to the change in operating conditions. Bistable laminates using variable stiffness composites are considered potential candidates in morphing structures for their ability to tailor the design space with a plethora of multiple stable configurations and satisfy the conflicting requirements of load-carrying capacity and deformability. Even though extensive works have been reported on the analysis and design of the cured shape of unsymmetrical variable stiffness laminates for morphing application, the effect of uncertainty in design variables on the behavior of bistable laminates is not profoundly assessed in the literature. In particular, uncertainty propagation through a highly non-linear map can lead to a significant discrepancy between the numerically predicted and experimental observations. Therefore, for adaptability in practical application, it is imperative to quantify the uncertainty as well as to characterize the non-linearity present near the design point of interest. In this work, a general purpose machine learning assisted uncertainty quantification (MLAUQ) framework is developed and demonstrated on unsymmetrical bistable laminate. The study considers three different variants of the approach based on the order of approximation (O(hk)) used for the training purpose. It is found that the MLAUQ−3 approach performs better than other approaches, and a theoretical justification for the same is provided. The method relies on the fact that expensive computation of the Hessian required for standard perturbation approaches can be bypassed by training a neural network while retaining accurate gradient information near the design point of interest. In the case of bistable laminate, a network trained with a few training samples can capture the local model non-linearity. Further, numerical investigations reveal that the proposed approach is computationally efficient and accurate compared to traditional uncertainty quantification (UQ) approaches.",
keywords = "Bistability, Composites, Finite element, Sensitivity, Snap-through, Uncertainty, Variable stiffness",
author = "Suraj, {K. S.} and Anilkumar, {P. M.} and Krishnanunni, {C. G.} and Rao, {B. N.}",
note = "Funding Information: The second author would like to acknowledge the Prime Minister Research Fellowship (PMRF) scheme by the Ministry of Education (India) for the research grant during the course of his doctoral research. Authors extend their acknowledgment to Dr.-Ing. Sven Scheffler and Institute of Structural Analysis, Leibniz Universit{\"a}t Hannover, for the support during the manufacturing of bistable laminates. ",
year = "2023",
month = sep,
day = "1",
doi = "10.1016/j.compstruct.2023.117072",
language = "English",
volume = "319",
journal = "Composite structures",
issn = "0263-8223",
publisher = "Elsevier BV",

}

Download

TY - JOUR

T1 - Uncertainty quantification of bistable variable stiffness laminate using machine learning assisted perturbation approach

AU - Suraj, K. S.

AU - Anilkumar, P. M.

AU - Krishnanunni, C. G.

AU - Rao, B. N.

N1 - Funding Information: The second author would like to acknowledge the Prime Minister Research Fellowship (PMRF) scheme by the Ministry of Education (India) for the research grant during the course of his doctoral research. Authors extend their acknowledgment to Dr.-Ing. Sven Scheffler and Institute of Structural Analysis, Leibniz Universität Hannover, for the support during the manufacturing of bistable laminates.

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Morphing structures have received growing interest in aerospace structures and wind turbines due to their rapid shape-changing ability in response to the change in operating conditions. Bistable laminates using variable stiffness composites are considered potential candidates in morphing structures for their ability to tailor the design space with a plethora of multiple stable configurations and satisfy the conflicting requirements of load-carrying capacity and deformability. Even though extensive works have been reported on the analysis and design of the cured shape of unsymmetrical variable stiffness laminates for morphing application, the effect of uncertainty in design variables on the behavior of bistable laminates is not profoundly assessed in the literature. In particular, uncertainty propagation through a highly non-linear map can lead to a significant discrepancy between the numerically predicted and experimental observations. Therefore, for adaptability in practical application, it is imperative to quantify the uncertainty as well as to characterize the non-linearity present near the design point of interest. In this work, a general purpose machine learning assisted uncertainty quantification (MLAUQ) framework is developed and demonstrated on unsymmetrical bistable laminate. The study considers three different variants of the approach based on the order of approximation (O(hk)) used for the training purpose. It is found that the MLAUQ−3 approach performs better than other approaches, and a theoretical justification for the same is provided. The method relies on the fact that expensive computation of the Hessian required for standard perturbation approaches can be bypassed by training a neural network while retaining accurate gradient information near the design point of interest. In the case of bistable laminate, a network trained with a few training samples can capture the local model non-linearity. Further, numerical investigations reveal that the proposed approach is computationally efficient and accurate compared to traditional uncertainty quantification (UQ) approaches.

AB - Morphing structures have received growing interest in aerospace structures and wind turbines due to their rapid shape-changing ability in response to the change in operating conditions. Bistable laminates using variable stiffness composites are considered potential candidates in morphing structures for their ability to tailor the design space with a plethora of multiple stable configurations and satisfy the conflicting requirements of load-carrying capacity and deformability. Even though extensive works have been reported on the analysis and design of the cured shape of unsymmetrical variable stiffness laminates for morphing application, the effect of uncertainty in design variables on the behavior of bistable laminates is not profoundly assessed in the literature. In particular, uncertainty propagation through a highly non-linear map can lead to a significant discrepancy between the numerically predicted and experimental observations. Therefore, for adaptability in practical application, it is imperative to quantify the uncertainty as well as to characterize the non-linearity present near the design point of interest. In this work, a general purpose machine learning assisted uncertainty quantification (MLAUQ) framework is developed and demonstrated on unsymmetrical bistable laminate. The study considers three different variants of the approach based on the order of approximation (O(hk)) used for the training purpose. It is found that the MLAUQ−3 approach performs better than other approaches, and a theoretical justification for the same is provided. The method relies on the fact that expensive computation of the Hessian required for standard perturbation approaches can be bypassed by training a neural network while retaining accurate gradient information near the design point of interest. In the case of bistable laminate, a network trained with a few training samples can capture the local model non-linearity. Further, numerical investigations reveal that the proposed approach is computationally efficient and accurate compared to traditional uncertainty quantification (UQ) approaches.

KW - Bistability

KW - Composites

KW - Finite element

KW - Sensitivity

KW - Snap-through

KW - Uncertainty

KW - Variable stiffness

UR - http://www.scopus.com/inward/record.url?scp=85159853799&partnerID=8YFLogxK

U2 - 10.1016/j.compstruct.2023.117072

DO - 10.1016/j.compstruct.2023.117072

M3 - Article

AN - SCOPUS:85159853799

VL - 319

JO - Composite structures

JF - Composite structures

SN - 0263-8223

M1 - 117072

ER -

By the same author(s)