Abstract
Photoelastic techniques have a long tradition in both qualitative and quantitative analysis of the stresses in granular materials. Over the last two decades, computational methods for reconstructing forces between particles from their photoelastic response have been developed by many different experimental teams. Unfortunately, all of these methods are computationally expensive. This limits their use for processing extensive data sets that capture the time evolution of granular ensembles consisting of a large number of particles. In this paper, we present a novel approach to this problem that leverages the power of convolutional neural networks to recognize complex spatial patterns. The main drawback of using neural networks is that training them usually requires a large labeled data set which is hard to obtain experimentally. We show that this problem can be successfully circumvented by pretraining the networks on a large synthetic data set and then fine-tuning them on much smaller experimental data sets. Due to our current lack of experimental data, we demonstrate the potential of our method by changing the size of the considered particles which alters the exhibited photoelastic patterns more than typical experimental errors.
Highlights
Granular materials consist of macroscopic particles, they are ubiquitous in nature and indispensable for a large variety of human activities
We show that convolutional neural networks (CNN) produce accurate force reconstruction on synthetic data
0.25 (b) Mean relative magnitude the high accuracy that makes our approach to detecting the number of forces appealing
Summary
Granular materials consist of macroscopic particles, they are ubiquitous in nature and indispensable for a large variety of human activities. Similar patterns are produced by using monochromatic light and they can be used to reconstruct forces acting between the particles. If a circular particle is illuminated by monochromatic light, its photoelastic response can be computed from the forces acting on it, see Section 2 for more details. We use machine learning to accurately reconstruct the forces acting on a particle from its photoelastic response. The patterns depicted in the top row are computergenerated photoelastic responses of a single particle subject to a variety of different (known) forces acting on it. The stress tensor can be computed from the forces acting on the particle using elasticity theory [30, 31]. It is natural to require that there is no stress on the boundary of the particle except at the points where the external forces act on it. I=1 where the matrix T (θ) rotates the plane by the angle θ
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