Towards robust prediction of material properties for nuclear reactor design under scarce data -- a study in creep rupture property
Abstract: Advances in Deep Learning bring further investigation into credibility and robustness, especially for safety-critical engineering applications such as the nuclear industry. The key challenges include the availability of data set (often scarce and sparse) and insufficient consideration of the uncertainty in the data, model, and prediction. This paper therefore presents a meta-learning based approach that is both uncertainty- and prior knowledge-informed, aiming at trustful predictions of material properties for the nuclear reactor design. It is suited for robust learning under limited data. Uncertainty has been accounted for where a distribution of predictor functions are produced for extrapolation. Results suggest it achieves superior performance than existing empirical methods in rupture life prediction, a case which is typically under a small data regime. While demonstrated herein with rupture properties, this learning approach is transferable to solve similar problems of data scarcity across the nuclear industry. It is of great importance to boosting the AI analytics in the nuclear industry by proving the applicability and robustness while providing tools that can be trusted.
- Imprecise probabilities in engineering analyses. Mechanical systems and signal processing 37, 4–29.
- Prediction of creep failure time using machine learning. Scientific Reports 10, 16910.
- Machine learning-based framework for predicting creep rupture life of modified 9cr-1mo steel. Applied Sciences 13, 4972.
- Uncertainty quantification over spectral estimation of stochastic processes subject to gapped missing data using variational bayesian inference .
- A bayesian augmented-learning framework for spectral uncertainty quantification of incomplete records of stochastic processes. Mechanical Systems and Signal Processing 200. doi:10.1016/j.ymssp.2023.110573.
- A physics-informed bayesian framework for characterization of ground motion with missing data. Earthquake Engineering & Structural Dynamics doi:10.1002/eqe.3877.
- Probabilistic machine learning and artificial intelligence. Nature 521, 452–459.
- Deep learning. nature 521, 436–444.
- Probabilistic artificial intelligence prediction of material properties for nuclear reactor designs .
- On the physical basis of a larson-miller constant of 20. International Journal of Pressure Vessels and Piping 159, 93–100.
- Artificial intelligence in nuclear. American Society for Quality Winter , 18–22.
- Limitations on the computational analysis of creep failure models: A review. Engineering Failure Analysis 134, 105968.
- Robust on-line diagnosis tool for the early accident detection in nuclear power plants. Reliability Engineering & System Safety 186, 110–119.
- High-throughput map design of creep life in low-alloy steels by integrating machine learning with a genetic algorithm. Materials & Design 213, 110326.
- A method for predicting the creep rupture life of small-sample materials based on parametric models and machine learning models. Materials 16, 6804.
- A deep learning based life prediction method for components under creep, fatigue and creep-fatigue conditions. International Journal of Fatigue 148, 106236.
- Creep rupture life prediction of high-temperature titanium alloy using cross-material transfer learning. Journal of Materials Science & Technology 178, 39–47.
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