Prediction Systems With Data Assimilation For Coupled Ocean Science And Ocean Acoustics
Data Assimilation in Coastal Models – Moving toward IOOS and Prediction
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Transcript of Data Assimilation in Coastal Models – Moving toward IOOS and Prediction
Data Assimilation in Coastal Models – Moving toward IOOS and Prediction
J. S. Allen, G. D. Egbert, A. L. Kurapov, R. N. Miller, R. M. SamelsonCollege of Oceanic and Atmospheric Sciences, Oregon State University
Projects with support through CIOSS:
Real-time Oregon coastal simulation system (Pilot project)(PIs: R. M. Samelson, G. D. Egbert, A. L. Kurapov; associate: S. Erofeeva)
US-GLOBEC-NEP Phase IIIa (CCS): Effects of meso- and basin scale variability on zooplankton populations in the California Current System using data-assimilative, physical/ecosystem models, 2005-2008. (PIs: J. S. Allen, G. D. Egbert, A. L. Kurapov, R. N. Miller, D. B. Haidvogel (Rutgers U.),
T. M. Powell (UC Berkley), E. N. Curchitser (Columbia U.)) CIOSS provides partial support for a post-doctoral research associate
+ Interaction with ongoing ONR, NOPP, NSF funded projects on coastal ocean/atmosphere modeling and data assimilation
With CIOSS support: Real-time Oregon coastal simulation system (OCS)
Coastal Ocean Data Assimilation: Long Term Goals/Vision
Develop and utilize advanced modeling and data assimilation techniques to improve scientific understanding of oceanic dynamic processes on the continental shelf and interactions of the shelf flows with the interior ocean
Transfer new computational technologies into operational nowcast/forecast systems
OCS, present implementation:
Oceanic model: ROMS (x = 2 km), periodic channel domain (A. Kurapov, S. Erofeeva)
Atmospheric model: ETA (run at OSU by R. M. Samelson and P. Bourbur)
OCS, future developments:
- improve ocean model formulation (open boundaries, nesting)
- data assimilation capability (improve forcing and boundary conditions, assimilate SSH, SST, HF radar surface currents)
GLOBEC study: analysis of NEP model simulationFocus on coastal transition zone (CTZ), altimetry + long range HF radar assimilation
Model solution for 2000 provided by E. Curchitser, currently being analyzed by CIOSS-supported post-doc B. J. Choi)
ROMS model
x=3 km
Initial and boundary conditions: from 10 km NEP model
Atmospheric forcing: NCEP reanalysis (2.5 degree)
Extent of regional model (apprx. 650 250 km) for initial tests on nesting, data assimilation
Model bathymetry
Time-averaged SSH anomaly (August 2000)
Tracks shown: T/P, ERS
Gridded altimetry (AVISO)Model: includes spatial structures not resolved by gridded product
By assimilation of along-track altimetry from multiple satellites we can:
Improve mapping of SSH by incorporating dynamics
Increase understanding of interactions between coastal flows and oceanic meso-scale eddies
Comparison between model and gridded altimetry products
A critical need for coastal modeling: Learn to assimilate SSH, SST, and long-range HF radar data to improve boundary conditions
Model SST and surf. currents (August 2000):
Coastal ocean interacts with interior ocean
Separation near Heceta Bank, Cape Blanco
Upwelling is weaker than observed (should be improved using higher resolution winds)
Linearized models + rigorous (variational) DA
1) Theoretical models: help formulate model error statistics for practical applications [Scott et al., JPO, 2000, Kurapov et al., Mon. Wea Rev., 2002]
2) Internal tide, HF radar surface velocity data [Kurapov et al., JPO, 2003]
Fully nonlinear model + suboptimal, sequential DA (Optimal Interpolation)
1) HF radar surface velocity data [Oke et al., JGR, 2002]
2) moored ADP velocities [Kurapov et al., JGR, 2005a, 2005b, JPO, 2005]
“Dual Approach”
Application of tangent linear and adjoint ROMS for variational DA
Barotropically unstable jet in a channel [Kurapov and Di Lorenzo, 2005]
Forced-dissipative flows in the nearshore: ongoing research
Three-dimensional, stratified flows on shelf: ongoing research
Present focus: merger of these approaches:
Development of DA methods for the Coastal Ocean (research supported by ONR)
Advantages of variational DA: the study of M2 internal tide off Oregon
• HF radar data for summer 1998 (provided by P. M. Kosro) are assimilated in a linear frequency-domain model [Kurapov et al. JPO, 2003]
• DA corrects open boundary (OB) baroclinic tidal currents
• Inverse solution minimizes penalty function: J(u)= || OB error ||2 + || data error ||2
HF
HF
ADPADP
Representer-based minimization optimally projects surface observational information to 3D
(Improvement is verified to be obtained at ADP site)
Day, 1998
Dep
th
Tidal ellipses of the horizontal current (for a series of overlapped 2-week time windows)
depth-ave
Deviations from
depth-aveValidation ADP
DA
no DA
Time-ave baroclinic KE:
Surface Bottom
lat 45.65N lat 45.55N
Inverse solutions provide a uniquely detailed picture of the spatial and temporal variability of the M2 internal tide
Surface tidal ellipses Day 139
Deviations from depth-ave
(gray ellipses rotate CW)
Depth-ave (white ellipses rotate CCW)
Experience assimilating data into the fully nonlinear, primitive eqn. model of wind-driven shelf circulation (studies of summer upwelling)
Dynamics: Princeton Ocean Model (free surface, nonlinear, primitive eqn., w/ turbulence parameterization [Mellor & Yamada 1982])
-Realistic bathymetry-Boundary conditions: periodic (south to north)-Forcing: alongshore wind stress and heat flux
HF radars (HF radars (Kosro))
Moorings (ADP, T, S: Moorings (ADP, T, S: Levine, Kosro, Boyd))
Optimal Interpolation (OI) Data assimilation:
- sequential, optimal interpolation (OI)
- correction is added in small increments every time step
,a ft t t POMν ν
( )a f ft t t t ν ν G obs Hν
matrix matching observations to state vector
- correction only to u:
-correction term is present in momentum equations
-however, equations for T, S, q2, q2l are dynamically balanced (which facilitates their term balance analysis)
- Approximate gain matrix obtained from an ensemble of model runs
Time-invariant gain matrix
Effects of ADP velocity DA: improvement in near-shore SSH time series
Assimilation of velocity observations in shelf circulation models can improve accuracy of SSH maps in the coastal zone, where altimetry is not available
comparison with coastal tide gauge data near Newport
obs, no DA, DA
SSH, surf v, no DA SSH, surf v, DA surf v, HF radar [Kosro]Flow control over Stonewall Bank(Day 166, 2001)
Effects of ADP velocity DA: improvement in near-surface salinity transport
to introduce Columbia River, salinity is assimilated at 45N
No ADP assim.ADP assimilationObserved, days 162-164 (SeaSoar - Barth et al.)
S<32 psu: effect of Columbia R.
Time series of salinity at 2.4 m, 44.2N: obs, DA, no DA
Effects of ADP velocity DA: improvement in the level and temporal variability of near-bottom turbulent dissipation rate and bottom stress
12 transects, days 139-148 (2001)
Turbulence Observations: Moum et al.
transect 1
Area-ave.
Area-ave. bottom stress
yearday, 2001
Optimal Interpolation: limitations
OI corrects the ocean state, not forcing limited control over source of model error
OI assumes time-invariant forecast error covariance (Pf), used to compute the gain matrix satisfactory performance on average over a season, but possibly difficulties predicting events (instabilities, relaxation from upwelling to downwelling, etc.). State-dependent covariance is needed.
Observations (such as satellite SSH, SST, HF radar) will generally have to be processed into maps (without spatial or temporal gaps) before using OI-DA
Variational, representer based, generalized inverse method (GIM) has potential of resolving these and some other deficiencies of OI.
Methodology has been developed for using GIM efficiently with nonlinear oceanic models [Chua and Bennett, 2001]. This technology is yet to be tried in
the context of coastal ocean circulation modeling.
To use GIM, tangent linear and adjoint models have to be developed.
Ongoing research: variational representer-based assimilation into nonlinear coastal models
Tangent Linear (TL) and Adjoint (ADJ) of ROMS have been developed by ROMS AD Group (A. Moore et al.)
We are testing these tools as they become available:
Use available version of TL-AD ROMS (initial value problem – see poster)
Construct our own shallow water TL and AD codes to learn details of GIM (forced-dissipative cases)
Transition to use of full ROMS TL/ADJ as these become available over the next year or so
Some research issues:
Assimilation in presence of frontal instabilities (nonlinearity constrains growth of instabilities in the fully nonlinear model, but not so in the TL model)
Proper linearization of open boundary conditions (e.g., radiation conditions with non-smooth switching from inflow to outflow conditions)
R. Samelson, E. Skyllingstad, N. Perlin, P. Barbour
College of Oceanic and Atmospheric Sciences
Oregon State University
Coastal Ocean-Atmosphere Boundary Layer Interactions
Coastal Ocean-Atmosphere Boundary Layer Interactions
Long Range Objectives
• Improve our ability to understand and predict environmental conditions in the coastal zone, especially with regard to the use and augmentation of satellite observations of wind stress
• Improve understanding of the processes that link wind stress variations to sea-surface temperature variability and ocean circulation patterns.
Coastal Ocean Data Assimilation: Long Term Goals/Vision
Develop and utilize advanced modeling and data assimilation techniques to improve scientific understanding of oceanic dynamic processes on the continental shelf and interactions of the shelf flows with the interior ocean
Transfer new computational technologies into operational nowcast/forecast systems