Extreme Statistics: Theory and Methods for Modeling Rare High-Impact Events in Complex Settings

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Auditorium between B4 and 5, L0

Abstract

Rare, low-probability events often lead to the biggest impacts. The goal of the Extreme Statistics (extSTAT) research group at KAUST is to develop cutting-edge statistical approaches for modeling, predicting and quantifying risks associated with these extreme events in complex systems arising in various scientific fields, such as climate science and finance. In particular, the work that we develop and continue to refine has a direct potential impact to climate scientists and related stakeholders, such as engineers and insurers, who have realized that under climate change, the greatest environmental and infrastructural risks and damages, are often caused by changes in the intensity, frequency, persistence, and spatial extent of extreme events, rather than changes in their average behavior. However, while datasets are often massive in modern day applications, extreme events are always scarce by nature. This makes it very challenging to provide reliable risk assessment, especially when extrapolation to yet-unseen levels is required. To overcome these limitations, the extSTAT research group develops novel methods that transcend classical extreme-value theory to build new resilient statistical models, as well as computationally efficient inference methods, that improve the prediction of rare events in complex, high-dimensional, spatio-temporal, non-stationary settings. In this talk, I will provide an overview of my group's recent research activities and future directions with a focus on core statistical methodology contributions. The technical part of the talk will describe selected research highlights, which include (but are not limited to) the development of new sub-asymptotic models applied to assessing contagion risk among leading cryptocurrencies, the development of a novel low-rank spatial modeling framework applied to estimating extreme Red Sea surface temperature hotspots, and the development of specialized spatio-temporal point process models applied to predicting devastating rainfall-induced landslides. I will conclude my talk with an outlook on my future research plans. Motivated by methodological obstacles that arise with “big models” for complex extremes data, we will embark on the development of fundamentally superior models that have an intrinsically sparse probabilistic structure, as well as new "hybrid" methods that combine the strength of (parametric) models from extreme-value theory with the pragmatism and predictive power of (nonparametric) machine learning algorithms, thus opening the door to interpretable and “extreme-ly” accurate predictive models for rare events in unprecedented dimensions.

Brief Biography

Raphaël Huser is an Assistant Professor of Statistics in the KAUST Computer, Electrical and Mathematical Sciences and Engineering (CEMSE) Division, where he leads the Extreme Statistics (extSTAT) research group. Before joining KAUST—initially, as a Postdoctoral Fellow in January 2014 before transitioning to his current Assistant Professor role in March 2015—Huser received his Ph.D. degree in statistics from the Swiss Institute of Technology (EPFL), Switzerland, in 2013. He also holds a B.S. in Mathematics and an M.S. in Applied Mathematics from EPFL. Professor Huser has received several awards for his research work, including the 2019 ENVR Early Investigator Award from the Section on Statistics and the Environment (ENVR) of the American Statistical Association (ASA), the 2015 Lambert Award from the Swiss Statistical Association, and the 2014 EPFL Doctorate Award. He is also an Elected Member of the International Statistical Institute (ISI), and is currently serving as an Associate Editor for five statistics journals, namely Extremes, the Journal of Agricultural, Biological and Environmental Statistics, Environmetrics, the Journal of the Royal Statistical Society: Series C (Applied Statistics), and Statistics and Computing. Professor Huser's research at KAUST focuses on the development of new flexible and theoretically-motivated statistical models, as well as computationally efficient inference methods, for extreme events in complex systems arising in various applications from environmental sciences and finance. His work aims at making an impact in statistics of extremes and beyond, by improving models, prediction, and quantification of risk associated with extreme events in high-dimensional, spatio-temporal, non-stationary settings.

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