Inverse design of high-Q wave filters in two-dimensional phononic crystals by topology optimization

Hao Wen Dong; Yue Sheng Wang; Chuanzeng Zhang

doi:10.1016/j.ultras.2016.12.018

Inverse design of high-Q wave filters in two-dimensional phononic crystals by topology optimization

Hao Wen Dong, Yue Sheng Wang^*, Chuanzeng Zhang

^*Corresponding author for this work

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

36 Citations (Scopus)

Abstract

Topology optimization of a waveguide-cavity structure in phononic crystals for designing narrow band filters under the given operating frequencies is presented in this paper. We show that it is possible to obtain an ultra-high-Q filter by only optimizing the cavity topology without introducing any other coupling medium. The optimized cavity with highly symmetric resonance can be utilized as the multi-channel filter, raising filter and T-splitter. In addition, most optimized high-Q filters have the Fano resonances near the resonant frequencies. Furthermore, our filter optimization based on the waveguide and cavity, and our simple illustration of a computational approach to wave control in phononic crystals can be extended and applied to design other acoustic devices or even opto-mechanical devices.

Original language	English
Pages (from-to)	109-124
Number of pages	16
Journal	Ultrasonics
Volume	76
DOIs	https://doi.org/10.1016/j.ultras.2016.12.018
Publication status	Published - 1 Apr 2017
Externally published	Yes

Keywords

Fano resonances
Filters
Phononic crystals
Q factor
Symmetric resonance
Topology optimization

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10.1016/j.ultras.2016.12.018

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title = "Inverse design of high-Q wave filters in two-dimensional phononic crystals by topology optimization",

abstract = "Topology optimization of a waveguide-cavity structure in phononic crystals for designing narrow band filters under the given operating frequencies is presented in this paper. We show that it is possible to obtain an ultra-high-Q filter by only optimizing the cavity topology without introducing any other coupling medium. The optimized cavity with highly symmetric resonance can be utilized as the multi-channel filter, raising filter and T-splitter. In addition, most optimized high-Q filters have the Fano resonances near the resonant frequencies. Furthermore, our filter optimization based on the waveguide and cavity, and our simple illustration of a computational approach to wave control in phononic crystals can be extended and applied to design other acoustic devices or even opto-mechanical devices.",

keywords = "Fano resonances, Filters, Phononic crystals, Q factor, Symmetric resonance, Topology optimization",

author = "Dong, {Hao Wen} and Wang, {Yue Sheng} and Chuanzeng Zhang",

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doi = "10.1016/j.ultras.2016.12.018",

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AU - Dong, Hao Wen

AU - Wang, Yue Sheng

AU - Zhang, Chuanzeng

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N2 - Topology optimization of a waveguide-cavity structure in phononic crystals for designing narrow band filters under the given operating frequencies is presented in this paper. We show that it is possible to obtain an ultra-high-Q filter by only optimizing the cavity topology without introducing any other coupling medium. The optimized cavity with highly symmetric resonance can be utilized as the multi-channel filter, raising filter and T-splitter. In addition, most optimized high-Q filters have the Fano resonances near the resonant frequencies. Furthermore, our filter optimization based on the waveguide and cavity, and our simple illustration of a computational approach to wave control in phononic crystals can be extended and applied to design other acoustic devices or even opto-mechanical devices.

AB - Topology optimization of a waveguide-cavity structure in phononic crystals for designing narrow band filters under the given operating frequencies is presented in this paper. We show that it is possible to obtain an ultra-high-Q filter by only optimizing the cavity topology without introducing any other coupling medium. The optimized cavity with highly symmetric resonance can be utilized as the multi-channel filter, raising filter and T-splitter. In addition, most optimized high-Q filters have the Fano resonances near the resonant frequencies. Furthermore, our filter optimization based on the waveguide and cavity, and our simple illustration of a computational approach to wave control in phononic crystals can be extended and applied to design other acoustic devices or even opto-mechanical devices.

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KW - Filters

KW - Phononic crystals

KW - Q factor

KW - Symmetric resonance

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ER -

Inverse design of high-Q wave filters in two-dimensional phononic crystals by topology optimization

Abstract

Keywords

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