Adjoint-Free Variational Data Assimilation into a Regional Wave Model

A variational data assimilation algorithm is developed for the ocean wave prediction model [Wave Model WAM]. The algorithm employs the adjoint-free technique and was tested in a series of data assimilation experiments with synthetic observations in the Chukchi Sea region from various platforms. The...

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Bibliographic Details
Main Authors: Panteleev, Gleb, Yaremchuk, Max, Rogers, W E
Other Authors: NAVAL RESEARCH LAB STENNIS DETACHMENT STENNIS SPACE CENTER MS
Format: Text
Language:English
Published: 2015
Subjects:
Atmospheric Physics
Meteorology
Physical and Dynamic Oceanography
Active & Passive Radar Detection & Equipment
*OCEAN CURRENTS
*OCEAN MODELS
ALGORITHMS
ALTIMETERS
ASSIMILATION
BUOYS
CHUKCHI SEA
COVARIANCE
FEASIBILITY STUDIES
HIGH FREQUENCY
KALMAN FILTERING
METEOROLOGICAL SATELLITES
MOORING
RADAR TRACKING
SPATIAL DISTRIBUTION
SPECTRA
TELEMETERING DATA
WAVE PROPAGATION
WAVES
WEATHER FORECASTING
HFRS(HIGH-FREQUENCY RADARS)
SWH(SIGNIFICANT WAVE HEIGHT)
WAM(WAVE MODEL)
DATA ASSIMILATION
PE0602435N
Chukchi Sea
Chukchi
Online Access:http://www.dtic.mil/docs/citations/ADA623048
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA623048
Description
Summary:A variational data assimilation algorithm is developed for the ocean wave prediction model [Wave Model WAM]. The algorithm employs the adjoint-free technique and was tested in a series of data assimilation experiments with synthetic observations in the Chukchi Sea region from various platforms. The types of considered observations are directional spectra estimated from point measurements by stationary buoys significant wave height (SWH) observations by coastal high-frequency radars (HFRs) within a geographic sector, and SWH from satellite altimeter along a geographic track. Numerical experiments demonstrate computational feasibility and robustness of the adjoint-free variational algorithm with the regional configuration of WAM. The largest improvement of the model forecast skill is provided by assimilating HFR data (the most numerous among the considered types). Assimilating observations of the wave spectrum from a moored platform provides only moderate improvement of the skill, which disappears after 3 h of running WAMin the forecast mode, whereas skill improvement provided by HFRs is shown to persist up to 9 h. Spaceborne observations, being the least numerous, do not have a significant impact on the forecast skill but appear to have a noticeable effect when assimilated in combination with other types of data. In particular, when spectral data from a single mooring are used, the satellite data are found to be the most beneficial as a supplemental data type, suggesting the importance of spatial coverage of the domain by observations. Published in the Journal of Atmospheric and Oceanic Technology, v32 p1386-1399, July 2015.

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