Physics-Informed Neural Network Based Digital Image Correlation Method
- URL: http://arxiv.org/abs/2409.00956v1
- Date: Mon, 2 Sep 2024 05:53:00 GMT
- Title: Physics-Informed Neural Network Based Digital Image Correlation Method
- Authors: Boda Li, Shichao Zhou, Qinwei Ma, Shaopeng Ma,
- Abstract summary: Digital Image Correlation (DIC) is a key technique in experimental mechanics for full-field deformation measurement.
Recent deep learning-based DIC approaches, both supervised and unsupervised, use neural networks to map speckle images to deformation fields.
This paper introduces PINN-DIC, a novel DIC method based on Physics-Informed Neural Networks (PINNs)
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Digital Image Correlation (DIC) is a key technique in experimental mechanics for full-field deformation measurement, traditionally relying on subset matching to determine displacement fields. However, selecting optimal parameters like shape functions and subset size can be challenging in non-uniform deformation scenarios. Recent deep learning-based DIC approaches, both supervised and unsupervised, use neural networks to map speckle images to deformation fields, offering precise measurements without manual tuning. However, these methods require complex network architectures to extract speckle image features, which does not guarantee solution accuracy This paper introduces PINN-DIC, a novel DIC method based on Physics-Informed Neural Networks (PINNs). Unlike traditional approaches, PINN-DIC uses a simple fully connected neural network that takes the coordinate domain as input and outputs the displacement field. By integrating the DIC governing equation into the loss function, PINN-DIC directly extracts the displacement field from reference and deformed speckle images through iterative optimization. Evaluations on simulated and real experiments demonstrate that PINN-DIC maintains the accuracy of deep learning-based DIC in non-uniform fields while offering three distinct advantages: 1) enhanced precision with a simpler network by directly fitting the displacement field from coordinates, 2) effective handling of irregular boundary displacement fields with minimal parameter adjustments, and 3) easy integration with other neural network-based mechanical analysis methods for comprehensive DIC result analysis.
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