Optical Measurement of In-plane Elastic Waves in Mechanical Metamaterials Through Digital Image Correlation

TL;DR

This paper introduces a Digital Image Correlation-based method for visualizing in-plane elastic waves in lattice structures, aiding the design of advanced mechanical metamaterials with unique wave propagation properties.

Contribution

The study presents a novel experimental technique combining high-speed imaging and image stitching to accurately capture in-plane wavefields in complex lattice structures.

Findings

Successfully visualized wave propagation in a hexagonal lattice.

Validated experimental results against numerical predictions.

Demonstrated high spatial resolution of wavefield measurements.

Abstract

We report on a Digital Image Correlation-based technique for the detection of in-plane elastic waves propagating in structural lattices. The experimental characterization of wave motion in lattice structures is currently of great interest due its relevance to the design of novel mechanical metamaterials with unique/unusual properties such as strongly directional behavior, negative refractive indexes and topologically protected wave motion. Assessment of these functionalities often requires the detection of highly spatially resolved in-plane wavefields, which for reticulated or porous structural assemblies is an open challenge. A Digital Image Correlation approach is implemented that tracks small displacements of the lattice nodes by centering image subsets about the lattice intersections. A high speed camera records the motion of the points by properly interleaving subsequent frames thus artificially enhancing the available sampling rate. This, along with an imaging stitching procedure, enables the capturing of a field of view that is sufficiently large for subsequent processing. The transient response is recorded in the form of the full wavefields, which are processed to unveil features of wave motion in a hexagonal lattice. Time snapshots and frequency contours in the spatial Fourier domain are compared with numerical predictions to illustrate the accuracy of the recorded wavefields and demonstrate the suitability of this technique for the experimental characterization of wave properties.