3D reconstruction of ocean velocity from high-frequency radar and acoustic Doppler current profiler: a model-based assessment study

3D reconstruction of ocean velocity from high-frequency radar and acoustic Doppler current profiler: a model-based assessment study

The effective monitoring and understanding of the dynamics of coastal currents is crucial for the development of environmentally sustainable coastal activities in order to preserve marine ecosystems as well as to support marine and navigation safety. This need is driving the set-up of a growing numb...

Full description

Saved in:
Bibliographic Details
Published in:Ocean science Vol. 16; no. 3; pp. 575 - 591
Main Authors: Manso-Narvarte, Ivan, Fredj, Erick, Jordà, Gabriel, Berta, Maristella, Griffa, Annalisa, Caballero, Ainhoa, Rubio, Anna
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 12-05-2020
Copernicus Publications
Subjects:
Acoustic Doppler Current Profiler
Approximation
Aquatic ecosystems
Coastal currents
Coastal dynamics
Coasts
Computation
Computer simulation
Criminal investigation
Current profiles
Current velocity
Data
Deep sea moorings
Discrete cosine transform
Doppler sonar
Ecology
Ecosystems
Environmental monitoring
Errors
Fields
Fisheries
History
Interpolation
Least squares method
Marine ecology
Marine ecosystems
Marine fish
Marine fisheries
Marine technology
Mathematical models
Monitoring
Mooring
Navigation
Navigation safety
Numerical analysis
Numerical simulations
Observatories
Oceans
Performance evaluation
Profiles
Protection and preservation
Radar
Reconstruction
Simulation
Skills
Smoothness
Sustainable development
Technology
Time
Velocity
Velocity distribution
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The effective monitoring and understanding of the dynamics of coastal currents is crucial for the development of environmentally sustainable coastal activities in order to preserve marine ecosystems as well as to support marine and navigation safety. This need is driving the set-up of a growing number of multiplatform operational observing systems, aiming for the continuous monitoring of the coastal ocean. A significant percentage of the existing observatories is equipped with land-based high-frequency radars (HFRs), which provide real-time currents with high spatio-temporal coverage and resolutions. Several approaches have been used in the past to expand the surface current velocity measurements provided by HFR to subsurface levels, since this can expand the application of the technology to other fields, like marine ecology or fisheries. The possibility of obtaining 3D velocity current fields from the combination of data from HFRs with complementary data, such as the velocity current profiles provided by in situ acoustic Doppler current profiler (ADCP) moorings is explored here. To that end, two different methods to reconstruct the 3D current velocity fields are assessed by a standard approach conceptually similar to OSSEs (observing system simulation experiments), where 3D numerical simulations are used as true ocean in order to evaluate the performance of the data-reconstruction methods. The observations of currents from a HFR and ADCP moorings are emulated by extracting the corresponding data from the 3D true ocean, and used as input for the methods. Then, the 3D reconstructed fields (outputs of the methods) are compared to the true ocean to assess the skills of the data-reconstruction methods. These methods are based on different approaches: on the one hand, the reduced order optimal interpolation uses an approximation to the velocity covariances (which can be obtained from historical data or a realistic numerical simulation) and on the other hand, the discrete cosine transform penalized least square is based on penalized least squares regression that balances fidelity to the data and smoothness of the solution. This study, which is based on the configuration of a real observatory located in the south-eastern Bay of Biscay (SE-BoB), is a first step towards the application of the data-reconstruction methods to real data, since it explores their skills and limitations. In the SE-BoB, where the coastal observatory includes a long-range HFR and two ADCP moorings inside the HFR footprint area, the results show satisfactory 3D reconstructions with mean spatial (for each depth level) errors between 0.55 and 7 cm s−1 for the first 150 m depth and mean relative errors of 0.07–1.2 times the rms value for most of the cases. The data-reconstruction methods perform better in well-sampled areas, and both show promising skills for the 3D reconstruction of currents as well as for the computation of new operational products integrating complementary observations, broadening the applications of the in situ observational data in the study area.
ISSN:1812-0792
1812-0784
1812-0792
DOI:10.5194/os-16-575-2020