Topological Design of Two-Dimensional Phononic Crystals Based on Genetic Algorithm

Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient design of phononic crystals with specific bandgap characteristics has attracted increasing attention in past decades. In this paper, an improve...

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Veröffentlicht in:	Materials Jg. 16; H. 16; S. 5606
Hauptverfasser:	Wen, Xiaodong, Kang, Lei, Sun, Xiaowei, Song, Ting, Qi, Liangwen, Cao, Yue
Format:	Journal Article
Sprache:	Englisch
Veröffentlicht:	Basel MDPI AG 13.08.2023 MDPI
Schlagworte:	Acoustic insulation Acoustics Adaptive algorithms Algorithms Crystal structure Crystals Design Energy bands Energy gap Finite element method Genetic algorithms Metamaterials Methods Modulus of elasticity Noise control Optimization techniques Transmission loss Vibration Wave attenuation
ISSN:	1996-1944, 1996-1944
Online-Zugang:	Volltext
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Abstract	Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient design of phononic crystals with specific bandgap characteristics has attracted increasing attention in past decades. In this paper, an improved adaptive genetic algorithm is proposed for the reverse customization of two-dimensional phononic crystals designed to maximize the relative bandwidth at low frequencies. The energy band dispersion relation and transmission loss of the optimal structure are calculated by the finite-element method, and the effective wave-attenuation effect in the bandgap range is verified. This provides a solution for the custom-made design of acoustic metamaterials with excellent low-frequency bandgap sound insulation or other engineering applications.
AbstractList	Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient design of phononic crystals with specific bandgap characteristics has attracted increasing attention in past decades. In this paper, an improved adaptive genetic algorithm is proposed for the reverse customization of two-dimensional phononic crystals designed to maximize the relative bandwidth at low frequencies. The energy band dispersion relation and transmission loss of the optimal structure are calculated by the finite-element method, and the effective wave-attenuation effect in the bandgap range is verified. This provides a solution for the custom-made design of acoustic metamaterials with excellent low-frequency bandgap sound insulation or other engineering applications. Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient design of phononic crystals with specific bandgap characteristics has attracted increasing attention in past decades. In this paper, an improved adaptive genetic algorithm is proposed for the reverse customization of two-dimensional phononic crystals designed to maximize the relative bandwidth at low frequencies. The energy band dispersion relation and transmission loss of the optimal structure are calculated by the finite-element method, and the effective wave-attenuation effect in the bandgap range is verified. This provides a solution for the custom-made design of acoustic metamaterials with excellent low-frequency bandgap sound insulation or other engineering applications.Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient design of phononic crystals with specific bandgap characteristics has attracted increasing attention in past decades. In this paper, an improved adaptive genetic algorithm is proposed for the reverse customization of two-dimensional phononic crystals designed to maximize the relative bandwidth at low frequencies. The energy band dispersion relation and transmission loss of the optimal structure are calculated by the finite-element method, and the effective wave-attenuation effect in the bandgap range is verified. This provides a solution for the custom-made design of acoustic metamaterials with excellent low-frequency bandgap sound insulation or other engineering applications.
Audience	Academic
Author	Wen, Xiaodong Song, Ting Qi, Liangwen Cao, Yue Sun, Xiaowei Kang, Lei
AuthorAffiliation	School of Mathematics and Physics, Lanzhou Jiaotong University, Lanzhou 730070, China
AuthorAffiliation_xml	– name: School of Mathematics and Physics, Lanzhou Jiaotong University, Lanzhou 730070, China
Author_xml	– sequence: 1 givenname: Xiaodong surname: Wen fullname: Wen, Xiaodong – sequence: 2 givenname: Lei surname: Kang fullname: Kang, Lei – sequence: 3 givenname: Xiaowei surname: Sun fullname: Sun, Xiaowei – sequence: 4 givenname: Ting surname: Song fullname: Song, Ting – sequence: 5 givenname: Liangwen surname: Qi fullname: Qi, Liangwen – sequence: 6 givenname: Yue surname: Cao fullname: Cao, Yue
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Snippet	Phononic crystals are a kind of artificial acoustic metamaterial whose mass density and elastic modulus are periodically arranged. The precise and efficient...
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SubjectTerms	Acoustic insulation Acoustics Adaptive algorithms Algorithms Crystal structure Crystals Design Energy bands Energy gap Finite element method Genetic algorithms Metamaterials Methods Modulus of elasticity Noise control Optimization techniques Transmission loss Vibration Wave attenuation
Title	Topological Design of Two-Dimensional Phononic Crystals Based on Genetic Algorithm
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