Design of acoustic metamaterials through nonlinear programming

TL;DR

This paper presents a method to design acoustic metamaterials with tunable band gaps by optimizing their geometry and resonator parameters using nonlinear programming techniques.

Contribution

It introduces a constrained nonlinear optimization framework to maximize low-frequency band gaps in tetrachiral acoustic metamaterials with local resonators.

Findings

Optimized parameters significantly increase low-frequency band gaps.

The method effectively identifies geometrical configurations for desired spectral properties.

The approach can be applied to passive control of wave propagation in metamaterials.

Abstract

The dispersive wave propagation in a periodic metamaterial with tetrachiral topology and inertial local resonators is investigated. The Floquet-Bloch spectrum of the metamaterial is compared with that of the tetrachiral beam lattice material without resonators. The resonators can be designed to open and shift frequency band gaps, that is, spectrum intervals in which harmonic waves do not propagate. Therefore, an optimal passive control of the frequency band structure can be pursued in the metamaterial. To this aim, a suitable constrained nonlinear optimization problem on a compact set of admissible geometrical and mechanical parameters is stated. According to functional requirements, the particular set of parameters which determines the largest low-frequency band gap between a pair of consecutive branches of the Floquet-Bloch spectrum is obtained. The optimization problem is successfully solved by means of a version of the method of moving asymptotes, combined with a quasi-Monte Carlo multi-start technique.