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Improving Fatigue Life Prediction of Natural Rubber Using a Physics‐Informed Neural Network Model

Yingshuai Sun, Xiangnan Liu, Xiangnan Liu, Qing Yang, Xiao Liu, Xiao Liu, Kuanfang He

2024Fatigue & Fracture of Engineering Materials & Structures12 citationsDOIOpen Access PDF

Abstract

ABSTRACT Traditional physical models and purely data‐driven approaches often struggle with small sample sizes and the complex effects of strain ratios. To overcome these challenges, this study integrates physical principles with machine learning techniques to improve fatigue life predictions for natural rubber (NR). A uniaxial fatigue test on NR was performed, generating data to construct a physical model. A physics‐informed neural network (PINN) model was subsequently developed, utilizing the fatigue life predicted by the physical model, along with engineering strain amplitude and strain ratio as input variables, whereas the experimentally observed fatigue life served as the output variable. The accuracy of the physical model, a data‐driven model, and the proposed PINN model was evaluated by comparing their predictions against measured fatigue life data. The findings demonstrate that the PINN model significantly enhances prediction accuracy, with its fatigue life estimates consistently falling within 1.5 times the measured values.

Topics & Concepts

Artificial neural networkNatural rubberNatural (archaeology)Materials scienceEngineeringComputer scienceArtificial intelligenceComposite materialGeologyPaleontologyMechanical Engineering and Vibrations ResearchNatural Fiber Reinforced CompositesTribology and Wear Analysis
Improving Fatigue Life Prediction of Natural Rubber Using a Physics‐Informed Neural Network Model | Litcius