Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean

The detection of finite-time coherent particle sets in Lagrangian trajectory data, using data-clustering techniques, is an active research field at the moment. Yet, the clustering methods mostly employed so far have been based on graph partitioning, which assigns each trajectory to a cluster, i.e. t...

Full description

Bibliographic Details
Published in:Nonlinear Processes in Geophysics
Main Authors: Wichmann, David, Kehl, Christian, Dijkstra, Henk A., Sebille, Erik
Format: Text
Language:English
Published: 2021
Subjects:
Online Access:https://doi.org/10.5194/npg-28-43-2021
https://npg.copernicus.org/articles/28/43/2021/
id ftcopernicus:oai:publications.copernicus.org:npg86480
record_format openpolar
spelling ftcopernicus:oai:publications.copernicus.org:npg86480 2023-05-15T18:21:03+02:00 Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean Wichmann, David Kehl, Christian Dijkstra, Henk A. Sebille, Erik 2021-01-19 application/pdf https://doi.org/10.5194/npg-28-43-2021 https://npg.copernicus.org/articles/28/43/2021/ eng eng doi:10.5194/npg-28-43-2021 https://npg.copernicus.org/articles/28/43/2021/ eISSN: 1607-7946 Text 2021 ftcopernicus https://doi.org/10.5194/npg-28-43-2021 2021-01-25T17:22:13Z The detection of finite-time coherent particle sets in Lagrangian trajectory data, using data-clustering techniques, is an active research field at the moment. Yet, the clustering methods mostly employed so far have been based on graph partitioning, which assigns each trajectory to a cluster, i.e. there is no concept of noisy, incoherent trajectories. This is problematic for applications in the ocean, where many small, coherent eddies are present in a large, mostly noisy fluid flow. Here, for the first time in this context, we use the density-based clustering algorithm of OPTICS (ordering points to identify the clustering structure; Ankerst et al. , 1999 ) to detect finite-time coherent particle sets in Lagrangian trajectory data. Different from partition-based clustering methods, derived clustering results contain a concept of noise, such that not every trajectory needs to be part of a cluster. OPTICS also has a major advantage compared to the previously used density-based spatial clustering of applications with noise (DBSCAN) method, as it can detect clusters of varying density. The resulting clusters have an intrinsically hierarchical structure, which allows one to detect coherent trajectory sets at different spatial scales at once. We apply OPTICS directly to Lagrangian trajectory data in the Bickley jet model flow and successfully detect the expected vortices and the jet. The resulting clustering separates the vortices and the jet from background noise, with an imprint of the hierarchical clustering structure of coherent, small-scale vortices in a coherent, large-scale background flow. We then apply our method to a set of virtual trajectories released in the eastern South Atlantic Ocean in an eddying ocean model and successfully detect Agulhas rings. We illustrate the difference between our approach and partition-based k -means clustering using a 2D embedding of the trajectories derived from classical multidimensional scaling. We also show how OPTICS can be applied to the spectral embedding of a trajectory-based network to overcome the problems of k -means spectral clustering in detecting Agulhas rings. Text South Atlantic Ocean Copernicus Publications: E-Journals Nonlinear Processes in Geophysics 28 1 43 59
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description The detection of finite-time coherent particle sets in Lagrangian trajectory data, using data-clustering techniques, is an active research field at the moment. Yet, the clustering methods mostly employed so far have been based on graph partitioning, which assigns each trajectory to a cluster, i.e. there is no concept of noisy, incoherent trajectories. This is problematic for applications in the ocean, where many small, coherent eddies are present in a large, mostly noisy fluid flow. Here, for the first time in this context, we use the density-based clustering algorithm of OPTICS (ordering points to identify the clustering structure; Ankerst et al. , 1999 ) to detect finite-time coherent particle sets in Lagrangian trajectory data. Different from partition-based clustering methods, derived clustering results contain a concept of noise, such that not every trajectory needs to be part of a cluster. OPTICS also has a major advantage compared to the previously used density-based spatial clustering of applications with noise (DBSCAN) method, as it can detect clusters of varying density. The resulting clusters have an intrinsically hierarchical structure, which allows one to detect coherent trajectory sets at different spatial scales at once. We apply OPTICS directly to Lagrangian trajectory data in the Bickley jet model flow and successfully detect the expected vortices and the jet. The resulting clustering separates the vortices and the jet from background noise, with an imprint of the hierarchical clustering structure of coherent, small-scale vortices in a coherent, large-scale background flow. We then apply our method to a set of virtual trajectories released in the eastern South Atlantic Ocean in an eddying ocean model and successfully detect Agulhas rings. We illustrate the difference between our approach and partition-based k -means clustering using a 2D embedding of the trajectories derived from classical multidimensional scaling. We also show how OPTICS can be applied to the spectral embedding of a trajectory-based network to overcome the problems of k -means spectral clustering in detecting Agulhas rings.
format Text
author Wichmann, David
Kehl, Christian
Dijkstra, Henk A.
Sebille, Erik
spellingShingle Wichmann, David
Kehl, Christian
Dijkstra, Henk A.
Sebille, Erik
Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
author_facet Wichmann, David
Kehl, Christian
Dijkstra, Henk A.
Sebille, Erik
author_sort Wichmann, David
title Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
title_short Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
title_full Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
title_fullStr Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
title_full_unstemmed Ordering of trajectories reveals hierarchical finite-time coherent sets in Lagrangian particle data: detecting Agulhas rings in the South Atlantic Ocean
title_sort ordering of trajectories reveals hierarchical finite-time coherent sets in lagrangian particle data: detecting agulhas rings in the south atlantic ocean
publishDate 2021
url https://doi.org/10.5194/npg-28-43-2021
https://npg.copernicus.org/articles/28/43/2021/
genre South Atlantic Ocean
genre_facet South Atlantic Ocean
op_source eISSN: 1607-7946
op_relation doi:10.5194/npg-28-43-2021
https://npg.copernicus.org/articles/28/43/2021/
op_doi https://doi.org/10.5194/npg-28-43-2021
container_title Nonlinear Processes in Geophysics
container_volume 28
container_issue 1
container_start_page 43
op_container_end_page 59
_version_ 1766200105357017088