Litcius/Paper detail

Incorporating Uncertainty Into a Regression Neural Network Enables Identification of Decadal State‐Dependent Predictability in CESM2

Emily M Gordon, Elizabeth A. Barnes

2022Geophysical Research Letters45 citationsDOIOpen Access PDF

Abstract

Abstract Predictable internal climate variability on decadal timescales (2–10 years) is associated with large‐scale oceanic processes, however these predictable signals may be masked by the noisy climate system. One approach to overcoming this problem is investigating state‐dependent predictability—how differences in prediction skill depend on the initial state of the system. We present a machine learning approach to identify state‐dependent predictability on decadal timescales in the Community Earth System Model version 2 pre‐industrial control simulation by incorporating uncertainty estimates into a regression neural network. We leverage the network's prediction of uncertainty to examine state dependent predictability in sea surface temperatures by focusing on predictions with the lowest uncertainty outputs. In particular, we study two regions of the global ocean—the North Atlantic and North Pacific—and find that skillful initial states identified by the neural network correspond to particular phases of Atlantic multi‐decadal variability and the interdecadal Pacific oscillation.

Topics & Concepts

PredictabilityClimatologyLeverage (statistics)Artificial neural networkPacific decadal oscillationRegressionComputer scienceClimate systemNorth Atlantic oscillationSea surface temperatureForecast skillClimate modelEnvironmental scienceEconometricsMachine learningGeologyClimate changeStatisticsMathematicsOceanographyClimate variability and modelsOceanographic and Atmospheric ProcessesMeteorological Phenomena and Simulations