Related papers: Physics-based machine learning for fatigue lifetime prediction under non-uniform loading scenarios

Physics-based machine learning for fatigue lifetime prediction under non-uniform loading scenarios

URL: http://arxiv.org/abs/2503.05419v1
Date: Fri, 07 Mar 2025 13:45:06 GMT
Title: Physics-based machine learning for fatigue lifetime prediction under non-uniform loading scenarios
Authors: Abedulgader Baktheer, Fadi Aldakheel,
Abstract summary: This study highlights the potential of physics-based machine learning ($phi$ML) to predict the fatigue lifetime of materials.<n>It is trained using numerical simulations generated by a physically based anisotropic continuum damage fatigue model.<n>The proposed approach demonstrates superior accuracy compared to purely data-driven neural networks.
Score: 0.0
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Accurate lifetime prediction of structures subjected to cyclic loading is vital, especially in scenarios involving non-uniform loading histories where load sequencing critically influences structural durability. Addressing this complexity requires advanced modeling approaches capable of capturing the intricate relationship between loading sequences and fatigue lifetime. Traditional fatigue simulations are computationally prohibitive, necessitating more efficient methods. This study highlights the potential of physics-based machine learning ($\phi$ML) to predict the fatigue lifetime of materials. Specifically, a FFNN is designed to embed physical constraints from experimental evidence directly into its architecture to enhance prediction accuracy. It is trained using numerical simulations generated by a physically based anisotropic continuum damage fatigue model. The model is calibrated and validated against experimental fatigue data of concrete cylinder specimens tested in uniaxial compression. The proposed approach demonstrates superior accuracy compared to purely data-driven neural networks, particularly in situations with limited training data, achieving realistic predictions of damage accumulation. Thus, a general algorithm is developed and successfully applied to predict fatigue lifetimes under complex loading scenarios with multiple loading ranges. Hereby, the $\phi$ML model serves as a surrogate to capture damage evolution across load transitions. The $\phi$ML based algorithm is subsequently employed to investigate the influence of multiple loading transitions on accumulated fatigue life, and its predictions align with trends observed in recent experimental studies. This work demonstrates $\phi$ML as a promising technique for efficient and reliable fatigue life prediction in engineering structures, with possible integration into digital twin models for real-time assessment.

Related papers

Predictive Modeling and Uncertainty Quantification of Fatigue Life in Metal Alloys using Machine Learning [39.58317527488534]
This study introduces a novel approach for quantification uncertainty in fatigue life prediction of metal materials.<n>The proposed approach employs physics-based input features estimated using the Basquin fatigue model.<n>The synergy between physics-based models and data-driven models enhances the consistency in predicted values.
arXiv Detail & Related papers (2025-01-25T03:43:19Z)
Physics-guided Active Sample Reweighting for Urban Flow Prediction [75.24539704456791]
Urban flow prediction is a nuanced-temporal modeling that estimates the throughput of transportation services like buses, taxis and ride-driven models. Some recent prediction solutions bring remedies with the notion of physics-guided machine learning (PGML) We develop a atized physics-guided network (PN), and propose a data-aware framework Physics-guided Active Sample Reweighting (P-GASR)
arXiv Detail & Related papers (2024-07-18T15:44:23Z)
Improved Long Short-Term Memory-based Wastewater Treatment Simulators for Deep Reinforcement Learning [0.0]
We implement two methods to improve the trained models for wastewater treatment data. The experimental results showed that implementing these methods can improve the behavior of simulators in terms of Dynamic Time Warping throughout a year.
arXiv Detail & Related papers (2024-03-22T10:20:09Z)
Towards Theoretical Understandings of Self-Consuming Generative Models [56.84592466204185]
This paper tackles the emerging challenge of training generative models within a self-consuming loop. We construct a theoretical framework to rigorously evaluate how this training procedure impacts the data distributions learned by future models. We present results for kernel density estimation, delivering nuanced insights such as the impact of mixed data training on error propagation.
arXiv Detail & Related papers (2024-02-19T02:08:09Z)
Real-time simulation of viscoelastic tissue behavior with physics-guided deep learning [0.8250374560598492]
We propose a deep learning method for predicting displacement fields of soft tissues with viselastic properties. The proposed method achieves a better accuracy over the conventional CNN models. It is hoped that the present investigation will help in filling the gap in applying deep learning in virtual reality.
arXiv Detail & Related papers (2023-01-11T18:17:10Z)
Stabilizing Machine Learning Prediction of Dynamics: Noise and Noise-inspired Regularization [58.720142291102135]
Recent has shown that machine learning (ML) models can be trained to accurately forecast the dynamics of chaotic dynamical systems. In the absence of mitigating techniques, this technique can result in artificially rapid error growth, leading to inaccurate predictions and/or climate instability. We introduce Linearized Multi-Noise Training (LMNT), a regularization technique that deterministically approximates the effect of many small, independent noise realizations added to the model input during training.
arXiv Detail & Related papers (2022-11-09T23:40:52Z)
An Adversarial Active Sampling-based Data Augmentation Framework for Manufacturable Chip Design [55.62660894625669]
Lithography modeling is a crucial problem in chip design to ensure a chip design mask is manufacturable. Recent developments in machine learning have provided alternative solutions in replacing the time-consuming lithography simulations with deep neural networks. We propose a litho-aware data augmentation framework to resolve the dilemma of limited data and improve the machine learning model performance.
arXiv Detail & Related papers (2022-10-27T20:53:39Z)
Self-learning locally-optimal hypertuning using maximum entropy, and comparison of machine learning approaches for estimating fatigue life in composite materials [0.0]
We develop an ML nearest-neighbors-alike algorithm based on the principle of maximum entropy to predict fatigue damage. The predictions achieve a good level of accuracy, similar to other ML algorithms.
arXiv Detail & Related papers (2022-10-19T12:20:07Z)
Physics-informed machine learning with differentiable programming for heterogeneous underground reservoir pressure management [64.17887333976593]
Avoiding over-pressurization in subsurface reservoirs is critical for applications like CO2 sequestration and wastewater injection. Managing the pressures by controlling injection/extraction are challenging because of complex heterogeneity in the subsurface. We use differentiable programming with a full-physics model and machine learning to determine the fluid extraction rates that prevent over-pressurization.
arXiv Detail & Related papers (2022-06-21T20:38:13Z)
Deep Bayesian Active Learning for Accelerating Stochastic Simulation [74.58219903138301]
Interactive Neural Process (INP) is a deep active learning framework for simulations and with active learning approaches. For active learning, we propose a novel acquisition function, Latent Information Gain (LIG), calculated in the latent space of NP based models. The results demonstrate STNP outperforms the baselines in the learning setting and LIG achieves the state-of-the-art for active learning.
arXiv Detail & Related papers (2021-06-05T01:31:51Z)
Data-driven method for real-time prediction and uncertainty quantification of fatigue failure under stochastic loading using artificial neural networks and Gaussian process regression [0.0]
Methods for early failure prediction are essential for engineering, military, and civil applications. Uncertainty (UQ) is of major importance for real-time decision-making purposes.
arXiv Detail & Related papers (2021-03-11T13:57:08Z)

This list is automatically generated from the titles and abstracts of the papers in this site.