Optimization of Graded Metamaterials for Control of Energy Transmission Using a Genetic Algorithm

TL;DR

This paper presents a method combining genetic algorithms and reduced order models to efficiently optimize graded metamaterial arrays for enhanced energy attenuation and reduced interlayer mismatch, validated with 3D printed prototypes.

Contribution

It introduces a novel optimization framework that integrates genetic algorithms with reduced order models for designing graded metamaterials with improved acoustic properties.

Findings

Optimized 6-unit cell arrays achieve wider stop bands with sharper boundaries.

Symmetric graded structures are identified as optimal configurations.

Printing uncertainties can be quantified and mitigated using the proposed models.

Abstract

Optimization of functionally graded metamaterial arrays with a high dimensional and continuous geometric design space is cumbersome and could be accelerated via machine learning tools. Mechanical metamaterials can manipulate acoustic or ultrasonic waves by introducing large dispersive and attenuative effects near their natural frequency. In this work functionally graded structures are designed and optimized to combine the energy attenuation performance of a number of unit cells with varying frequency responses and to reduce the interlayer mismatch effects. Optimization through genetic algorithm avoids the many local minima related to high dimensionality of the design space but requires many iterations. A reduced order model (ROM) is applied that can reproduce the transmission response that is traditionally calculated with FEM, in a fraction of the time. Pairing GA and the ROM together, an array of 6 unit cells (with a total of 18 independent geometric design variables) is optimized to have stop bands with extended width and sharper boundaries. Symmetric functionally graded structures are determined to be optimal geometric configurations. Measured 3D printed features are projected onto the ROM solutions to quantify the effect of printing uncertainty on array performance. Repeatability error of $\pm~20$ $\mu$m is determined to reduce the mean depth of the transmission stop band by a factor of $10^2$ and introduce small shifts in center frequency and band width. Proposed methods to improve the resolution of accessible points in the ROM space, reduce sensitivity to geometric uncertainty, and add design freedom include introducing out-of-plane perforations and varying constituent materials using tunable filled resin systems.