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StressNet - Deep learning to predict stress with fracture propagation in brittle materials

Yinan Wang, Diane Oyen, Weihong Guo, Anishi Mehta, Cory Braker Scott, Nishant Panda, M. Giselle Fernández-Godino, G. Srinivasan, Xiaowei Yue

2021npj Materials Degradation91 citationsDOIOpen Access PDF

Abstract

Abstract Catastrophic failure in brittle materials is often due to the rapid growth and coalescence of cracks aided by high internal stresses. Hence, accurate prediction of maximum internal stress is critical to predicting time to failure and improving the fracture resistance and reliability of materials. Existing high-fidelity methods, such as the Finite-Discrete Element Model (FDEM), are limited by their high computational cost. Therefore, to reduce computational cost while preserving accuracy, a deep learning model, StressNet, is proposed to predict the entire sequence of maximum internal stress based on fracture propagation and the initial stress data. More specifically, the Temporal Independent Convolutional Neural Network (TI-CNN) is designed to capture the spatial features of fractures like fracture path and spall regions, and the Bidirectional Long Short-term Memory (Bi-LSTM) Network is adapted to capture the temporal features. By fusing these features, the evolution in time of the maximum internal stress can be accurately predicted. Moreover, an adaptive loss function is designed by dynamically integrating the Mean Squared Error (MSE) and the Mean Absolute Percentage Error (MAPE), to reflect the fluctuations in maximum internal stress. After training, the proposed model is able to compute accurate multi-step predictions of maximum internal stress in approximately 20 seconds, as compared to the FDEM run time of 4 h, with an average MAPE of 2% relative to test data.

Topics & Concepts

Fracture (geology)Computer scienceBrittlenessStress (linguistics)Mean absolute percentage errorApproximation errorMean squared errorConvolutional neural networkArtificial neural networkAlgorithmStructural engineeringMaterials scienceArtificial intelligenceGeologyStatisticsMathematicsGeotechnical engineeringEngineeringComposite materialLinguisticsPhilosophyRock Mechanics and ModelingInfrastructure Maintenance and MonitoringNon-Destructive Testing Techniques
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