Surrogate tree ensemble model representing 2D population doses over complex terrain in the event of a radiological release into the air

Atmospheric dispersion models predict the dispersion of harmful substances in case of accidents at industrial facilities and nuclear power plants (NPPs). However, high computation time limits their usage in an emergency or long-term analyses. This paper reduces the computation time by designing a su...

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Bibliographic Details
Published in:Progress in nuclear energy (New series) 2023-04, Vol.158, p.104594, Article 104594
Main Authors: Hvala, Nadja, Mlakar, Primož, Grašič, Boštjan, Božnar, Marija Zlata, Perne, Matija, Kocijan, Juš
Format: Article
Language:English
Subjects:
Atmospheric dispersion
Complex terrain
Radiological release
Surrogate model
Tree ensembles
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Summary:Atmospheric dispersion models predict the dispersion of harmful substances in case of accidents at industrial facilities and nuclear power plants (NPPs). However, high computation time limits their usage in an emergency or long-term analyses. This paper reduces the computation time by designing a surrogate data-driven model using a grid of tree ensemble models as a surrogate for the physical model and meteorological station measurements as model regressors. Regression tree modelling provided information for selecting the most important variables for prediction, while model ensembles improved the prediction accuracy. The approach is tested for an NPP in complex terrain to predict spatial (2D) maps of population doses for 24 h after a radiological release. The average performance of 2D maps against the physical model is SMSE (Standardized Mean Square Error)  0.5. The designed model performs very well in predicting the long-term mean and 95th percentile of population doses. The main shortcoming is the underestimation of very high doses. Performance is expected to be further improved by selecting training data using pattern selection techniques and potentially by alternative machine learning algorithms or interconnected models, which we intend to apply in future work. [Display omitted] •Data-driven fast emulation of atmospheric dispersion around the nuclear power plant.•A grid of regression tree ensembles predicts spatial 2D maps of population doses.•Meteorological measurements provide input information for dispersion emulation.•Prediction of 24 h relative doses for a large set of realistic meteorological data.•Homogenous 2D maps for an emergency, reliable long-term mean and 95th percentile.
ISSN:0149-1970
DOI:10.1016/j.pnucene.2023.104594