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contributor authorStevens, Abby;Willett, Rebecca;Mamalakis, Antonios;Foufoula-Georgiou, Efi;Tejedor, Alejandro;Randerson, James T.;Smyth, Padhraic;Wright, Stephen
date accessioned2022-01-30T17:59:25Z
date available2022-01-30T17:59:25Z
date copyright10/19/2020 12:00:00 AM
date issued2020
identifier issn0894-8755
identifier otherjclid200079.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4264310
description abstractUnderstanding the physical drivers of seasonal hydroclimatic variability and improving predictive skill remains a challenge with important socioeconomic and environmental implications for many regions around the world. Physics-based deterministic models show limited ability to predict precipitation as the lead time increases, due to imperfect representation of physical processes and incomplete knowledge of initial conditions. Similarly, statistical methods drawing upon established climate teleconnections have low prediction skill due to the complex nature of the climate system. Recently, promising data-driven approaches have been proposed, but they often suffer from over-parameterization and overfitting due to the short observational record, and they often do not account for spatiotemporal dependencies among covariates (i.e., predictors such as sea surface temperatures). This study addresses these challenges via a predictive model based on a graph-guided regularizer that simultaneously promotes similarity of predictive weights for highly correlated covariates and enforces sparsity in the covariate domain. This approach both decreases the effective dimensionality of the problem and identifies the most predictive features without specifying them a-priori. We use large ensemble simulations from a climate model to construct this regularizer, reducing the structural uncertainty in the estimation. We apply the learned model to predict winter precipitation in the southwestern US using sea surface temperatures over the entire Pacific basin, and demonstrate its superiority compared to other regularization approaches and statistical models informed by known teleconnections. Our results highlight the potential to combine optimally the space-time structure of predictor variables learned from climate models with new graph-based regularizers to improve seasonal prediction.
publisherAmerican Meteorological Society
titleGraph-guided regularized regression of Pacific Ocean climate variables to increase predictive skill of southwestern US winter precipitation
typeJournal Paper
journal titleJournal of Climate
identifier doi10.1175/JCLI-D-20-0079.1
journal fristpage1
journal lastpage50
treeJournal of Climate:;2020:;volume( ):;issue: -
contenttypeFulltext


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