A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations

Coincident ocean drifter position and surface wind time series observed on hourly timescales are used to estimate upper ocean dissipation and atmosphere-ocean cou-pling coefficients in the Labrador Sea. A discrete-process model based on finite dif-ferences is used to regress ocean accelerations on o...

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Main Authors: Thomas Bengtsson, Ralph Milliff, Richard Jones, Doug Nychka, Peter P. Niiler
Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
Subjects:
2
Labrador Sea
Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.76.4062
http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf
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spelling ftciteseerx:oai:CiteSeerX.psu:10.1.1.76.4062 2023-05-15T17:06:02+02:00 A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations Thomas Bengtsson Ralph Milliff Richard Jones Doug Nychka Peter P. Niiler The Pennsylvania State University CiteSeerX Archives application/pdf http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.76.4062 http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf en eng http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.76.4062 http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf Metadata may be used without restrictions as long as the oai identifier remains attached to it. http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf 2 text ftciteseerx 2016-01-08T19:07:02Z Coincident ocean drifter position and surface wind time series observed on hourly timescales are used to estimate upper ocean dissipation and atmosphere-ocean cou-pling coefficients in the Labrador Sea. A discrete-process model based on finite dif-ferences is used to regress ocean accelerations on ocean velocity estimates but fails because errors in the discrete approximations for the ocean velocities are biased and accumulate over time. Model identification is achieved by fitting a stochastic differen-tial equation model based on classical upper ocean physics to the drifter data via the Kalman filter. Ocean parameters are shown to be non-identifiable in a direct appli-cation to the Labrador Sea data when the known Coriolis parameter is not identified by the model. To address this the ocean parameters are estimated in an empirical sequence. Data from the Ocean Storms experiment are used to estimate ocean dissi-pation in isolation from complexities introduced by strong and variable winds. Given a realistic estimate of the ocean dissipation, a second application in the Labrador Sea successfully estimates atmosphere-ocean coupling coefficients and reproduces the Coriolis parameter. Model assessments demonstrate the robustness of the parameter estimates. The model parameter estimates are discussed in comparison with Ekman theory and results from analyses of the global ocean surface drifter dataset. Text Labrador Sea Unknown
institution Open Polar
collection Unknown
op_collection_id ftciteseerx
language English
topic 2
spellingShingle 2
Thomas Bengtsson
Ralph Milliff
Richard Jones
Doug Nychka
Peter P. Niiler
A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
topic_facet 2
description Coincident ocean drifter position and surface wind time series observed on hourly timescales are used to estimate upper ocean dissipation and atmosphere-ocean cou-pling coefficients in the Labrador Sea. A discrete-process model based on finite dif-ferences is used to regress ocean accelerations on ocean velocity estimates but fails because errors in the discrete approximations for the ocean velocities are biased and accumulate over time. Model identification is achieved by fitting a stochastic differen-tial equation model based on classical upper ocean physics to the drifter data via the Kalman filter. Ocean parameters are shown to be non-identifiable in a direct appli-cation to the Labrador Sea data when the known Coriolis parameter is not identified by the model. To address this the ocean parameters are estimated in an empirical sequence. Data from the Ocean Storms experiment are used to estimate ocean dissi-pation in isolation from complexities introduced by strong and variable winds. Given a realistic estimate of the ocean dissipation, a second application in the Labrador Sea successfully estimates atmosphere-ocean coupling coefficients and reproduces the Coriolis parameter. Model assessments demonstrate the robustness of the parameter estimates. The model parameter estimates are discussed in comparison with Ekman theory and results from analyses of the global ocean surface drifter dataset.
author2 The Pennsylvania State University CiteSeerX Archives
format Text
author Thomas Bengtsson
Ralph Milliff
Richard Jones
Doug Nychka
Peter P. Niiler
author_facet Thomas Bengtsson
Ralph Milliff
Richard Jones
Doug Nychka
Peter P. Niiler
author_sort Thomas Bengtsson
title A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
title_short A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
title_full A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
title_fullStr A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
title_full_unstemmed A State-Space Model for Ocean Drifter Motions Dominated by Inertial Oscillations
title_sort state-space model for ocean drifter motions dominated by inertial oscillations
url http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.76.4062
http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf
genre Labrador Sea
genre_facet Labrador Sea
op_source http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf
op_relation http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.76.4062
http://www.cgd.ucar.edu/~tocke/BuoyTB.pdf
op_rights Metadata may be used without restrictions as long as the oai identifier remains attached to it.
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