Litcius/Paper detail

Uncertainty quantification of tunable elastic metamaterials using polynomial chaos

H. Al Ba’ba’a, S. Nandi, T. Singh, M. Nouh

2020Journal of Applied Physics15 citationsDOIOpen Access PDF

Abstract

Owing to their periodic and intricate configurations, metamaterials engineered for acoustic and elastic wave control inevitably suffer from manufacturing anomalies and deviate from theoretical dispersion predictions. This work exploits the Polynomial Chaos Theory to quantify the magnitude and extent of these deviations and assess their impact on the desired behavior. It is shown that uncertainties stemming from surface roughness, tolerances, and other inconsistencies in a metamaterial’s unit-cell parameters alter the targeted bandgap width, frequency range, and the confidence level with which it is guaranteed. The effect of uncertainties is projected from a Bloch-wave dispersion analysis of three distinct phononic and resonant cellular configurations and is further confirmed in the frequency response of the finite structures. The analysis concludes with a unique algorithm intended to guide the design of metamaterials in the presence of system uncertainties.

Topics & Concepts

Polynomial chaosMetamaterialDispersion (optics)Uncertainty quantificationPhysicsFrequency bandWork (physics)PolynomialStatistical physicsAcousticsAcoustic metamaterialsAcoustic dispersionFinite element methodComputational physicsDispersion relationWave propagationOpticsPropagation of uncertaintyLow frequencyCHAOS (operating system)Band gapSurface waveFrequency responseInterference (communication)Mathematical analysisComputer scienceAcoustic Wave Phenomena ResearchMusic Technology and Sound StudiesCellular and Composite Structures