Saved in:
Bibliographic Details
Main Authors: Yoo, Myungsoo, Gopalan, Giri, Hoffman, Matthew J., Coulson, Sophie, Han, Holly Kyeore, Wikle, Christopher K., Hillebrand, Trevor
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.17729
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914159288909824
author Yoo, Myungsoo
Gopalan, Giri
Hoffman, Matthew J.
Coulson, Sophie
Han, Holly Kyeore
Wikle, Christopher K.
Hillebrand, Trevor
author_facet Yoo, Myungsoo
Gopalan, Giri
Hoffman, Matthew J.
Coulson, Sophie
Han, Holly Kyeore
Wikle, Christopher K.
Hillebrand, Trevor
contents Projecting sea-level change in various climate-change scenarios typically involves running forward simulations of the Earth's gravitational, rotational and deformational (GRD) response to ice mass change, which requires high computational cost and time. Here we build neural-network emulators of sea-level change at 27 coastal locations, due to the GRD effects associated with future Antarctic Ice Sheet mass change over the 21st century. The emulators are based on datasets produced using a numerical solver for the static sea-level equation and published ISMIP6-2100 ice-sheet model simulations referenced in the IPCC AR6 report. We show that the neural-network emulators have an accuracy that is competitive with baseline machine learning emulators. In order to quantify uncertainty, we derive well-calibrated prediction intervals for simulated sea-level change via a linear regression postprocessing technique that uses (nonlinear) machine learning model outputs, a technique that has previously been applied to numerical climate models. We also demonstrate substantial gains in computational efficiency: a feedforward neural-network emulator exhibits on the order of 100 times speedup in comparison to the numerical sea-level equation solver that is used for training.
format Preprint
id arxiv_https___arxiv_org_abs_2406_17729
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Emulation with uncertainty quantification of regional sea-level change caused by the Antarctic Ice Sheet
Yoo, Myungsoo
Gopalan, Giri
Hoffman, Matthew J.
Coulson, Sophie
Han, Holly Kyeore
Wikle, Christopher K.
Hillebrand, Trevor
Atmospheric and Oceanic Physics
Machine Learning
Projecting sea-level change in various climate-change scenarios typically involves running forward simulations of the Earth's gravitational, rotational and deformational (GRD) response to ice mass change, which requires high computational cost and time. Here we build neural-network emulators of sea-level change at 27 coastal locations, due to the GRD effects associated with future Antarctic Ice Sheet mass change over the 21st century. The emulators are based on datasets produced using a numerical solver for the static sea-level equation and published ISMIP6-2100 ice-sheet model simulations referenced in the IPCC AR6 report. We show that the neural-network emulators have an accuracy that is competitive with baseline machine learning emulators. In order to quantify uncertainty, we derive well-calibrated prediction intervals for simulated sea-level change via a linear regression postprocessing technique that uses (nonlinear) machine learning model outputs, a technique that has previously been applied to numerical climate models. We also demonstrate substantial gains in computational efficiency: a feedforward neural-network emulator exhibits on the order of 100 times speedup in comparison to the numerical sea-level equation solver that is used for training.
title Emulation with uncertainty quantification of regional sea-level change caused by the Antarctic Ice Sheet
topic Atmospheric and Oceanic Physics
Machine Learning
url https://arxiv.org/abs/2406.17729