Abstract
Risk assessment for extreme events requires accurate estimation of high quantiles that go beyond the range of historical observations. When the risk depends on the values of observed predictors, regression techniques are used to interpolate in the predictor space. We propose the EQRN model that combines tools from neural networks and extreme value theory into a method capable of extrapolation in the presence of complex predictor dependence. Neural networks can naturally incorporate additional structure in the data. We develop a recurrent version of EQRN that is able to capture complex sequential dependence in time series. We apply this method to forecast flood risk in the Swiss Aare catchment. It exploits information from multiple covariates in space and time to provide one-day-ahead predictions of return levels and exceedance probabilities. This output complements the static return level from a traditional extreme value analysis, and the predictions are able to adapt to distributional shifts as experienced in a changing climate. Our model can help authorities to manage flooding more effectively and to minimize their disastrous impacts through early warning systems.
Funding Statement
Both authors were supported by the Swiss National Science Foundation Eccellenza Grant 186858.
Acknowledgments
The authors would like to thank Daniel Viviroli for his valuable insights as well as the editorial team and the anonymous reviewers for their helpful comments.
Citation
Olivier C. Pasche. Sebastian Engelke. "Neural networks for extreme quantile regression with an application to forecasting of flood risk." Ann. Appl. Stat. 18 (4) 2818 - 2839, December 2024. https://doi.org/10.1214/24-AOAS1907
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