Title :
A method for tracking individual planetary waves in remotely sensed data
Author :
Cipollini, Paolo ; Challenor, Peter G. ; Colombo, Stefano
Author_Institution :
Nat. Oceanogr. Centre, Southampton, UK
Abstract :
We describe a methodology for tracking individual planetary waves in longitude-time plots of satellite data, based on fitting an elementary wave shape model to subsets of the data by maximum likelihood, then reconstructing the trajectory and evolution of every single wave (where for "single wave" we mean an individual positive or negative westward propagating anomaly) by joining the elementary waves according to their similarity. We then illustrate the potential of the methodology with an example at 34°N in the Atlantic Ocean and its adaptability to different cases with a second example on eastward-propagating Kelvin waves in the equatorial Pacific. Although the examples given use sea surface height anomaly data, the technique lends itself to be applied to any space-time plot of any dataset displaying propagation and, in particular, to sea surface temperature data.
Keywords :
height measurement; maximum likelihood estimation; ocean temperature; ocean waves; oceanographic regions; oceanographic techniques; remote sensing; Atlantic Ocean; Rossby waves; altimetry; eastward-propagating Kelvin waves; elementary wave shape model; elementary waves; equatorial Pacific Ocean; feature tracking; maximum likelihood method; planetary wave tracking; remote sensing; satellite data; sea surface height anomaly; sea surface temperature; trajectory reconstruction; wave evolution; wave propagation; Atmospheric waves; Joining IEEE; Kelvin; Large-scale systems; Ocean temperature; Ocean waves; Satellites; Sea surface; Shape; Trajectory; Altimetry; Rossby waves; feature tracking; planetary waves;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
DOI :
10.1109/TGRS.2005.859355
