Impact of HF radar current gap-filling methodologies on the Lagrangian assessment of coastal dynamics

High-frequency radar, HFR, is a cost-effective monitoring technique that allows us to obtain high-resolution continuous surface currents, providing new insights for understanding small-scale transport processes in the coastal ocean. In the last years, the use of Lagrangian metrics to study mixing an...

Full description

Saved in:
Bibliographic Details
Published in:Ocean science 2018-08, Vol.14 (4), p.827-847
Main Authors: Herandez-Carrasco, Ismael, Solabarrieta, Lohitzune, Rubio, Anna, Esnaola, Ganix, Reyes, Emma, Orfila, Alejandro
Format: Article
Language:English
Subjects:
Cluster analysis
Clustering
Coastal currents
Coastal dynamics
Coastal processes
Computation
Data
Data processing
Dynamics
Empirical analysis
Empirical orthogonal functions
Environmental monitoring
Failures
Fields
HF radar
Liapunov exponents
Methods
Modal analysis
Observations
Ocean currents
Ocean dynamics
Oceanic mixing
Oceanic transport
Oceans
Orthogonal functions
Properties
Radar
Reliability analysis
Self organizing maps
Spatial data
Spatial distribution
Surface currents
Transport
Transport processes
Transport properties
Vector quantization
Velocity
Velocity distribution
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:High-frequency radar, HFR, is a cost-effective monitoring technique that allows us to obtain high-resolution continuous surface currents, providing new insights for understanding small-scale transport processes in the coastal ocean. In the last years, the use of Lagrangian metrics to study mixing and transport properties has been growing in importance. A common condition among all the Lagrangian techniques is that complete spatial and temporal velocity data are required to compute trajectories of virtual particles in the flow. However, hardware or software failures in the HFR system can compromise the availability of data, resulting in incomplete spatial coverage fields or periods without data. In this regard, several methods have been widely used to fill spatiotemporal gaps in HFR measurements. Despite the growing relevance of these systems there are still many open questions concerning the reliability of gap-filling methods for the Lagrangian assessment of coastal ocean dynamics. In this paper, we first develop a new methodology to reconstruct HFR velocity fields based on self-organizing maps (SOMs). Then, a comparative analysis of this method with other available gap-filling techniques is performed, i.e., open-boundary modal analysis (OMA) and data interpolating empirical orthogonal functions (DINEOFs). The performance of each approach is quantified in the Lagrangian frame through the computation of finite-size Lyapunov exponents, Lagrangian coherent structures and residence times. We determine the limit of applicability of each method regarding four experiments based on the typical temporal and spatial gap distributions observed in HFR systems unveiled by a K-means clustering analysis. Our results show that even when a large number of data are missing, the Lagrangian diagnoses still give an accurate description of oceanic transport properties.
ISSN:1812-0792
1812-0784
1812-0792
DOI:10.5194/os-14-827-2018