Litcius/Paper detail

Machine learning in solid mechanics: Application to acoustic metamaterial design

D. Yago, G. Sal‐Anglada, D. Roca, J. Cante, J. Oliver

2024International Journal for Numerical Methods in Engineering34 citationsDOIOpen Access PDF

Abstract

Abstract Machine learning (ML) and Deep learning (DL) are increasingly pivotal in the design of advanced metamaterials, seamlessly integrated with material or topology optimization. Their intrinsic capability to predict and interconnect material properties across vast design spaces, often computationally prohibitive for conventional methods, has led to groundbreaking possibilities. This paper introduces an innovative machine learning approach for the optimization of acoustic metamaterials, focusing on Multiresonant Layered Acoustic Metamaterial (MLAM), designed for targeted noise attenuation at low frequencies (below 1000 Hz). This method leverages ML to create a continuous model of the Representative Volume Element (RVE) effective properties essential for evaluating sound transmission loss (STL), and subsequently used to optimize the overall topology configuration for maximum sound attenuation using a Genetic Algorithm (GA). The significance of this methodology lies in its ability to deliver rapid results without compromising accuracy, significantly reducing the computational overhead of complete topology optimization by several orders of magnitude. To demonstrate the versatility and scalability of this approach, it is extended to a more intricate RVE model, characterized by a higher number of parameters, and is optimized using the same strategy. In addition, to underscore the potential of ML techniques in synergy with traditional topology optimization, a comparative analysis is conducted, comparing the outcomes of the proposed method with those obtained through direct numerical simulation (DNS) of the corresponding full 3D MLAM model. This comparative analysis highlights the transformative potential of this combination, particularly when addressing complex topological challenges with significant computational demands, ushering in a new era of metamaterial and component design.

Topics & Concepts

MetamaterialTopology optimizationComputer scienceScalabilityOverhead (engineering)Topology (electrical circuits)Computer engineeringAttenuationElectronic engineeringFinite element methodArtificial intelligenceMaterials scienceEngineeringPhysicsDatabaseOpticsOperating systemStructural engineeringElectrical engineeringOptoelectronicsAcoustic Wave Phenomena ResearchNoise Effects and ManagementHearing Loss and Rehabilitation