Hybrid intelligent framework for designing band gap-rich 2D metamaterials

IF 3.4 3区 工程技术 Q1 MECHANICS
Mohamed Shendy , Mohammad A. Jaradat , Maen Alkhader , Bassam A. Abu-Nabah , T.A. Venkatesh
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引用次数: 0

Abstract

An artificial intelligence machine learning-based design framework is proposed to design lattice-based metamaterials with hexagonal symmetry that deliver wide band gaps at user-desired frequency ranges between 0 and 1000 kHz. The design approach starts by selecting a traditional, easy-to-manufacture parent lattice-based material that does not necessarily exhibit wide or functional band gaps. Subsequently, the parent lattice is transformed into a band-gap-rich lattice by superposing periodic triangular-shaped perturbations (i.e., zigzag-sine-based curvatures) with controllable frequencies and magnitudes on its ligaments. Finally, the frequency and magnitude parameters needed to deliver a specific band gap between 0 and 1000 kHz are determined using a hybrid intelligent framework, developed based on an Adaptive Neuro-Fuzzy Inference Systems (ANFIS). The ANFIS network integrates fuzzy logic expert models and artificial neural networks’ machine learning capabilities. Such a hybrid network is known for its ability to model strongly nonlinear and complex data. The data used in training the ANFIS models is generated using parametric finite element-based simulations where band gaps corresponding to a wide range of perturbation frequencies and magnitudes are computationally determined. The parametric study showed a nonlinear and complex topology-band gap characteristic relation; however, the Adaptive Neuro-Fuzzy Inference System (ANFIS) proved capable of modeling the observed complex topology-band gap behavior efficiently. The accuracy of the ANFIS models exceeded 99 % in several design ranges (i.e., perturbation parameters ranges). These were designated as high-accuracy design regions and were highlighted in the proposed design approach. Using multiple case studies with different band gap requirements, the ANFIS-based design framework proved effective in delivering customized lattice-based metamaterials with user-defined band gap frequencies.

设计带隙丰富的二维超材料的混合智能框架
本文提出了一种基于人工智能机器学习的设计框架,用于设计具有六边形对称性的基于晶格的超材料,在用户希望的 0 至 1000 kHz 频率范围内提供宽带隙。该设计方法首先选择一种传统的、易于制造的基于晶格的母体材料,这种材料不一定具有宽带隙或功能带隙。随后,通过在母晶格的韧带上叠加频率和幅度可控的周期性三角形扰动(即人字正弦曲线),将母晶格转化为带隙丰富的晶格。最后,利用基于自适应神经模糊推理系统(ANFIS)开发的混合智能框架,确定了提供 0 至 1000 kHz 特定带隙所需的频率和幅度参数。ANFIS 网络综合了模糊逻辑专家模型和人工神经网络的机器学习能力。这种混合网络以其对强烈非线性和复杂数据的建模能力而著称。用于训练 ANFIS 模型的数据是通过基于参数的有限元模拟生成的,其中对应于各种扰动频率和幅度的带隙是通过计算确定的。参数研究显示了非线性和复杂的拓扑-带隙特性关系;然而,自适应神经模糊推理系统 (ANFIS) 被证明能够有效地模拟观察到的复杂拓扑-带隙行为。在几个设计范围(即扰动参数范围)内,ANFIS 模型的精确度超过 99%。这些区域被指定为高精度设计区域,并在建议的设计方法中予以强调。通过对具有不同带隙要求的多个案例进行研究,证明基于 ANFIS 的设计框架能有效提供基于晶格的定制超材料,并具有用户定义的带隙频率。
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来源期刊
CiteScore
6.70
自引率
8.30%
发文量
405
审稿时长
70 days
期刊介绍: The International Journal of Solids and Structures has as its objective the publication and dissemination of original research in Mechanics of Solids and Structures as a field of Applied Science and Engineering. It fosters thus the exchange of ideas among workers in different parts of the world and also among workers who emphasize different aspects of the foundations and applications of the field. Standing as it does at the cross-roads of Materials Science, Life Sciences, Mathematics, Physics and Engineering Design, the Mechanics of Solids and Structures is experiencing considerable growth as a result of recent technological advances. The Journal, by providing an international medium of communication, is encouraging this growth and is encompassing all aspects of the field from the more classical problems of structural analysis to mechanics of solids continually interacting with other media and including fracture, flow, wave propagation, heat transfer, thermal effects in solids, optimum design methods, model analysis, structural topology and numerical techniques. Interest extends to both inorganic and organic solids and structures.
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