Machine learning based topology optimization of fiber orientation for variable stiffness composite structures

Xu, Yanan; Gao, Yunkai; Wu, Chi; Fang, Jianguang; Steven, Grant P.; Li, Qing

doi:10.1002/nme.6809

Cited by 18 publications

(1 citation statement)

References 55 publications

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“…Also, Sanchez‐Majano et al 21 analyzed the mechanical behavior of VSCL shells structures subjected to different external loadings and boundary conditions. Recently, Yanan et al 22 proposed a machine learning (ML) based approach for optimizing fiber orientations of variable stiffness carbon fiber reinforced plastic (CFRP) structures.…”

Section: Introductionmentioning

confidence: 99%

Finite strip method based on Carrera unified formulation for the free vibration analysis of variable stiffness composite laminates

Shojaee

Hamzehei‐Javaran

2022

Numerical Meth Engineering

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This work presents a refinement of the finite strip method (FSM) based on the Carrera unified formulation (CUF) and is applied to free vibration analysis of variable stiffness composite laminated (VSCL) plates. VSCL plates considered here are composed of layers with curvilinear fibers in which their orientation angle changes linearly with respect to one of the in‐plane coordinates. The FSM permits the plate to be divided into some finite strips connected along the so‐called nodal lines. The conventional finite strip method involves an approximation of the solution of a plate problem by using continuously harmonic series in the longitudinal direction along the nodal lines and simple polynomial shape functions (the usual beam shape functions) in the transverse direction of the plate. However, refined finite strip model that presented in this paper allows one to express the unknown variables as a set of thickness functions that only depend on the thickness coordinate and the corresponding variable that depends on the in‐plane coordinates which involve continuously harmonic series and polynomial shape functions. Thanks to this new finite strip model, the shape functions used in the transverse direction can be chosen as 1D bar shape functions, and also, all three components of the displacement field are considered in each nodal line. Moreover, based on this approach, three‐dimensional displacement field is approximated in a compact form as a generic N‐order expansion. Therefore, explicit expressions of fundamental nuclei of finite strip matrices are obtained in a compact form and presented here. The results obtained by the present formulation for VSCL plates are compared with those obtained from published data. The results show that this kind of strip is efficient and useful. Further, several numerical examples are presented, and the effect of the order of expansion, the number of strips, curvilinear fiber angle, and various boundary conditions are examined.

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Section: Introductionmentioning

confidence: 99%

Finite strip method based on Carrera unified formulation for the free vibration analysis of variable stiffness composite laminates

Shojaee

Hamzehei‐Javaran

2022

Numerical Meth Engineering

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A survey of machine learning techniques in structural and multidisciplinary optimization

Ramu

Thananjayan

Acar

et al. 2022

Struct Multidisc Optim

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Machine Learning in Biomaterials, Biomechanics/Mechanobiology, and Biofabrication: State of the Art and Perspective

Wu,

Xu,

Fang

et al. 2024

Arch Computat Methods Eng

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In the past three decades, biomedical engineering has emerged as a significant and rapidly growing field across various disciplines. From an engineering perspective, biomaterials, biomechanics, and biofabrication play pivotal roles in interacting with targeted living biological systems for diverse therapeutic purposes. In this context, in silico modelling stands out as an effective and efficient alternative for investigating complex interactive responses in vivo. This paper offers a comprehensive review of the swiftly expanding field of machine learning (ML) techniques, empowering biomedical engineering to develop cutting-edge treatments for addressing healthcare challenges. The review categorically outlines different types of ML algorithms. It proceeds by first assessing their applications in biomaterials, covering such aspects as data mining/processing, digital twins, and data-driven design. Subsequently, ML approaches are scrutinised for the studies on mono-/multi-scale biomechanics and mechanobiology. Finally, the review extends to ML techniques in bioprinting and biomanufacturing, encompassing design optimisation and in situ monitoring. Furthermore, the paper presents typical ML-based applications in implantable devices, including tissue scaffolds, orthopaedic implants, and arterial stents. Finally, the challenges and perspectives are illuminated, providing insights for academia, industry, and biomedical professionals to further develop and apply ML strategies in future studies.

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Machine learning based topology optimization of fiber orientation for variable stiffness composite structures

Cited by 18 publications

References 55 publications

Finite strip method based on Carrera unified formulation for the free vibration analysis of variable stiffness composite laminates

Finite strip method based on Carrera unified formulation for the free vibration analysis of variable stiffness composite laminates

A survey of machine learning techniques in structural and multidisciplinary optimization

Machine Learning in Biomaterials, Biomechanics/Mechanobiology, and Biofabrication: State of the Art and Perspective

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