TY - JOUR
T1 - Ocean mover’s distance: using optimal transport for analysing oceanographic data
AU - Hyun, Sangwon
AU - Mishra, Aditya
AU - Follett, Christopher
AU - Jonsson, Bror
AU - Kulk, Gemma
AU - Forget, Gael
AU - Racault, Marie-Fanny
AU - Jackson, Thomas
AU - Dutkiewicz, Stephanie
AU - Muller, Christian
AU - Bien, Jacob
N1 - Funding Information: This work was supported by grants by the Simons Collaboration on Computational Biogeochemical Modeling of Marine Ecosystems/CBIOMES (grant no. 549939 to B.J.; 827829 and 553242 to C.L.F.; 549931 to M.-F.R.). Dr J.B. was also supported in part by NIH grant no. R01GM123993 and NSF CAREER award DMS-1653017. T.J. was also supported by the National Centre for Earth Observations of the UK. M.-F.R. was also partially funded by the ‘Frontiers of instability in marine ecosystems and carbon export (Marine Frontiers) [NE/V011103/1]’.
PY - 2022/6/22
Y1 - 2022/6/22
N2 - Remote sensing observations from satellites and global biogeochemical models have combined to revolutionize the study of ocean biogeochemical cycling, but comparing the two data streams to each other and across time remains challenging due to the strong spatial-temporal structuring of the ocean. Here, we show that the Wasserstein distance provides a powerful metric for harnessing these structured datasets for better marine ecosystem and climate predictions. The Wasserstein distance complements commonly used point-wise difference methods such as the root-mean-squared error, by quantifying differences in terms of spatial displacement in addition to magnitude. As a test case, we consider chlorophyll (a key indicator of phytoplankton biomass) in the northeast Pacific Ocean, obtained from model simulations, in situ measurements, and satellite observations. We focus on two main applications: (i) comparing model predictions with satellite observations, and (ii) temporal evolution of chlorophyll both seasonally and over longer time frames. The Wasserstein distance successfully isolates temporal and depth variability and quantifies shifts in biogeochemical province boundaries. It also exposes relevant temporal trends in satellite chlorophyll consistent with climate change predictions. Our study shows that optimal transport vectors underlying the Wasserstein distance provide a novel visualization tool for testing models and better understanding temporal dynamics in the ocean.
AB - Remote sensing observations from satellites and global biogeochemical models have combined to revolutionize the study of ocean biogeochemical cycling, but comparing the two data streams to each other and across time remains challenging due to the strong spatial-temporal structuring of the ocean. Here, we show that the Wasserstein distance provides a powerful metric for harnessing these structured datasets for better marine ecosystem and climate predictions. The Wasserstein distance complements commonly used point-wise difference methods such as the root-mean-squared error, by quantifying differences in terms of spatial displacement in addition to magnitude. As a test case, we consider chlorophyll (a key indicator of phytoplankton biomass) in the northeast Pacific Ocean, obtained from model simulations, in situ measurements, and satellite observations. We focus on two main applications: (i) comparing model predictions with satellite observations, and (ii) temporal evolution of chlorophyll both seasonally and over longer time frames. The Wasserstein distance successfully isolates temporal and depth variability and quantifies shifts in biogeochemical province boundaries. It also exposes relevant temporal trends in satellite chlorophyll consistent with climate change predictions. Our study shows that optimal transport vectors underlying the Wasserstein distance provide a novel visualization tool for testing models and better understanding temporal dynamics in the ocean.
KW - Wasserstein distance
KW - chlorophyll
KW - data-model comparison
KW - earth mover's distance
KW - optimal transport
KW - remote sensing
UR - http://www.scopus.com/inward/record.url?scp=85142711237&partnerID=8YFLogxK
U2 - 10.1098/rspa.2021.0875
DO - 10.1098/rspa.2021.0875
M3 - Article
VL - 478
JO - Proceedings of the Royal Society A-Mathematical Physical and Engineering Sciences
JF - Proceedings of the Royal Society A-Mathematical Physical and Engineering Sciences
SN - 1364-5021
IS - 2262
M1 - 20210875
ER -