Presentation is loading. Please wait.

Presentation is loading. Please wait.

4DVar Assimilation (physics) in ROMS ESPreSSO * John Wilkin, Julia Levin, Javier Zavala-Garay 2006 reanalysis (SW06) Operational system for OOI CI OSSE.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "4DVar Assimilation (physics) in ROMS ESPreSSO * John Wilkin, Julia Levin, Javier Zavala-Garay 2006 reanalysis (SW06) Operational system for OOI CI OSSE."— Presentation transcript:

1 4DVar Assimilation (physics) in ROMS ESPreSSO * John Wilkin, Julia Levin, Javier Zavala-Garay 2006 reanalysis (SW06) Operational system for OOI CI OSSE (ongoing) Assimilating: altimeter SLA; satellite IR SST; CODAR surface currents; climatology; glider T,S; T,S from XBT/CTD, Argo, NDBC (via GTS) Use methodology developed for spring 2006 LaTTE reanalysis Zhang et al., Ocean Modelling, submitted 2009 Skill assessed in forecast window – several days for T,S – 1-2 days for velocity *Experimental System for Predicting Shelf and Slope Optics

2

3 ROMS ESPreSSO configuration 5 km horizontal resolution Cape Cod to Cape Hatteras 36 levels in traditional ROMS s-coordinate ( stretching=1 ) 4 th order Akima T,S advection; 3 rd order upwind u,v advection Bathymetry, land-sea mask from NGDC Coastal Relief Model Open boundary data HyCOM+NCODA (no bias correction) – stiff boundary nudging in forward simulations Meteorology forcing 3-hourly 12-km NCEP NAM-WRF – 72-hour forecast window – sea level atmospheric conditions + bulk formulae = fluxes – [use NCEP NARR in 2006 reanalysis] River daily average discharge USGS gauges – adjusted for ungauged fraction of watershed Tides TPXO0.7 tides (5 harmonics) We are working in a data rich location for 4DVar assimilation…

4 4 Mid-Atlantic Regional Coastal Ocean Observing System (MARCOOS) CODAR, gliders, moorings, tide gauges, drifters, satellites …

5 5 IS4DVAR* Given a first guess (the forward trajectory)… and given the available data… and given the available data… *Incremental Strong Constraint 4-Dimensional Variational data assimilation

6 6 IS4DVAR Given a first guess (the forward trajectory)… and given the available data… what change (or increment) to the initial conditions (IC) produces a new forward trajectory that better fits the observations? what change (or increment) to the initial conditions (IC) produces a new forward trajectory that better fits the observations?

7 7 The “best fit” becomes the analysis assimilation window t i = analysis initial time t f = analysis final time The strong constraint requires the trajectory satisfies the physics in ROMS. The Adjoint enforces the consistency among state variables.

8 8 The final analysis state becomes the IC for the forecast window assimilation windowforecast t f = analysis final time t f +  = forecast horizon

9 9 Forecast verification is with respect to data not yet assimilated assimilation windowforecast verification t f +  = forecast horizon

10 10

11 11

12 12

13 LaTTE domain and observation locations. Bathymetry of the New York Bight is in grayscale and dashed contours. yellow star is location of Ambrose Tower green squares are CODAR HF Radar sites LaTTE 2006 reanalysis (60 days)

14 Comparison of observed and modeled sea surface temperature and current at 0700 UTC 20 April 2006.

15 2-D histograms comparing observed and modeled temperature, salinity, and u- component of velocity model before (control simulation) and after (analysis) data assimilation. Color indicates the log 10 of the number of observations. LaTTE 2006 reanalysis (60 days)

16 Ensemble average of the DA skill for analysis and forecast periods for different data withheld from system Vertical bars are 95% confidence. Vertical dashed line is boundary between analysis and forecast. LaTTE 2006 reanalysis (60 days) Removing any data from the analysis system has more or less predictable negative impact on the forecast. More data is always better.

17 Ensemble average of the DA skill for analysis and forecast periods for different data withheld from system, evaluated with respect to: (a)glider-measured temperature and (b)satellite-measured SST Vertical bars are 95% confidence. Vertical dashed line is boundary between analysis and forecast. LaTTE 2006 reanalysis (60 days) Satellite SST is crucial to forecast skill for this skill metric; namely, comparison to new observations in the forecast window.

18 4DVar Assimilation (physics) in ROMS ESPreSSO 2006 reanalysis (SW06) – Basis for experiments with ecosystem and bio-optical modeling 2009- operational System for OOI CI OSSE (ongoing) – 72-hour forecast (NAM-WRF meteorology) – tides, rivers, OBC HyCOM NCODA etc. – assimilates: altimeter along-track SLA satellite IR SST CODAR surface currents climatology glider T,S GTS: XBT/CTD, Argo, NDBC

19 Work flow for operational ESPreSSO/MARCOOS 4DVar Analysis interval is 00:00 – 24:00 UTC Input data preparation commences 01:00 EST (05:00 UT) RU CODAR is hourly - but with 4-hour delay RU glider T,S where available (approx 1 hour delay) USGS daily average flow available 11:00 EST – persist in forecast AVHRR IR passes (approx 2 hour delay) HyCOM NCODA forecast updated daily Jason-2 along-track SLA via RADS (4 to 16 hour delay) GTS XBT/CTD, Argo, NDBC from AOML (intermittent) T,S climatology (MOCHA)

20 Work flow for operational ESPreSSO/MARCOOS 4DVar Input preprocessing RU CODAR de-tided (harmonic analysis) and binned to 5km – variance within bins and OI combiner expected u_err used for QC – ROMS tide solution added to de-tided CODAR – this approach reduces tide phase error contribution to cost function RU glider T,S averaged to ~5 km horiz. and 5 m vertical bins – developed thermal lag salinity correction using constrained parametric fit to minimize statically unstable profiles AVHRR IR individual passes 6-8 per day – use Matt Oliver’s cloud mask; bin to 5 km resolution – [2006 reanalysis uses REMSS daily SST OI combination of AVHRR, GOES, AMSR] Jason-2 alongtrack 5 km bins (no coastal corrections) – MDT from 4DVAR on “mean model” (climatology 3D T,S, u surface,  wind )

21 Comparison of HF Radar observed and modeled M 2 tide in LaTTE.

22

23 Work flow for operational ESPreSSO/MARCOOS Input preprocessing completes approximately 05:00 EST 4DVAR analysis completes approx 08:00 EST 24-hour analysis is followed by 72-hour forecast using NCEP NAM 00Z cycle available from NOMADS OPeNDAP at 02:30 UT (10:30 pm EST) Forecast complete and transferred to OPeNDAP by 09:00 EST Effective forecast is ~ 60 hours OPeNDAP http://tashtego.marine.rutgers.edu:8080/thredds/catalog.html ncWMS http://tashtego.marine.rutgers.edu:8081/ncWMS/godiva2.html

24 Output OPeNDAP http://tashtego.marine.rutgers.edu:8080/thredds/catalog.html ncWMS http://tashtego.marine.rutgers.edu:8081/ncWMS/godiva2.html

25 ESPreSSO operational system

26

27

28

29

30 Lessons from operational IS4DVAR for ESPreSSO More and diverse data is better –use all available observations and platforms Quality control –outliers in CODAR –cloud clearing from IR –coastal altimetry High resolution regional climatology –removes bias from Open Boundary Condition –improves representation of dynamic modes and adjoint-based increments IR SST individual passes work best with 4DVAR –time variability is explicitly resolved –implications for optics Useful skill for operational applications –glider reachability forecast Physics analysis affects ecosystem/optics model skill

31 RU Endurance Line glider transect May 18-24, 2006 Small scales may be important to large scale dynamics (and ecosystem)

32 t f = analysis final time assimilation window

33 The analysis final hours becomes the data for the high-res 4DVAR, then forecast high-res assimilation window high-res forecast t f = analysis final time t f +  = forecast horizon assimilation window

34 Issues/Tasks ahead for 4DVAR ESPreSSO High frequencies –Filter inertial oscillations/tides in increment when updating outer loop –High frequencies in coastal altimetry (keep or remove IB correction?) Background error covariance –Can we use multi-variate “balance” constraint in coastal ocean? –Wide shelf, steep slope, anisotropic variability –Ecosystem / bio-optics? Ecosystem/bio-optics assimilation in 4DVar –have Adjoint for NZPD model (ecosystem emphasis) –have Adjoint for simple bio-optical model (IOP emphasis) –Climatology? Initialization? –need dense data set for assimilation development –twin experiments? –optics in Community Sediment Transport Model? Couple ecosystem/optics with thermodynamics –interaction is significant on NJ inner shelf (“just do it”) Downscaling –1 km resolution grid (better bathymetry and land/sea mask) –5 km IS4DVAR analysis at end of interval treated as “data” –assimilate analysis into 1 km model with 1 4DVAR cycle

Download ppt "4DVar Assimilation (physics) in ROMS ESPreSSO * John Wilkin, Julia Levin, Javier Zavala-Garay 2006 reanalysis (SW06) Operational system for OOI CI OSSE."

Similar presentations

ROMS User Workshop, October 2, 2007, Los Angeles

ROMS User Workshop, October 2, 2007, Los Angeles
Mercator Ocean activity

Mercator Ocean activity
The Inverse Regional Ocean Modeling System:

The Inverse Regional Ocean Modeling System:
Polly Smith, Alison Fowler, Amos Lawless School of Mathematical and Physical Sciences, University of Reading Exploring coupled data assimilation using.

Polly Smith, Alison Fowler, Amos Lawless School of Mathematical and Physical Sciences, University of Reading Exploring coupled data assimilation using.
Assimilation of Sea Surface Temperature into a Northwest Pacific Ocean Model using an Ensemble Kalman Filter B.-J. Choi Kunsan National University, Korea.

Assimilation of Sea Surface Temperature into a Northwest Pacific Ocean Model using an Ensemble Kalman Filter B.-J. Choi Kunsan National University, Korea.
Kevin O’Brien University of Washington/JISAO NOAA/PMEL Interoperable Access to Near Real Time Ocean Observations with the Observing System Monitoring Center.

Kevin O’Brien University of Washington/JISAO NOAA/PMEL Interoperable Access to Near Real Time Ocean Observations with the Observing System Monitoring Center.
1 Evaluation of two global HYCOM 1/12º hindcasts in the Mediterranean Sea Cedric Sommen 1 In collaboration with Alexandra Bozec 2 and Eric Chassignet 2.

1 Evaluation of two global HYCOM 1/12º hindcasts in the Mediterranean Sea Cedric Sommen 1 In collaboration with Alexandra Bozec 2 and Eric Chassignet 2.
ROMS User Workshop: Modern Observational and Modeling Systems Rio de Janeiro, Brazil, October 3-4.

ROMS User Workshop: Modern Observational and Modeling Systems Rio de Janeiro, Brazil, October 3-4.
Rutgers Ocean Modeling Group ROMS 4DVar data assimilation Mid-Atlantic Bight and Gulf of Maine John Wilkin with Julia Levin, Javier Zavala-Garay, Hernan.

Rutgers Ocean Modeling Group ROMS 4DVar data assimilation Mid-Atlantic Bight and Gulf of Maine John Wilkin with Julia Levin, Javier Zavala-Garay, Hernan.
1 Accomplishments: * Nested ROMS in larger domain forward simulation (MABGOM-ROMS) with configuration suitable for IS4DVAR experimentation. Considerations:

1 Accomplishments: * Nested ROMS in larger domain forward simulation (MABGOM-ROMS) with configuration suitable for IS4DVAR experimentation. Considerations:
1 4-Dimensional Variational Assimilation of Satellite Temperature and Sea Level Data in the Coastal Ocean and Adjacent Deep Sea John Wilkin Javier Zavala-Garay.

1 4-Dimensional Variational Assimilation of Satellite Temperature and Sea Level Data in the Coastal Ocean and Adjacent Deep Sea John Wilkin Javier Zavala-Garay.
Www.cmar.csiro.au/bluelink/ Building Bluelink David Griffin, Peter Oke, Andreas Schiller et al. March 2007 CSIRO Marine and Atmospheric Research.

Building Bluelink David Griffin, Peter Oke, Andreas Schiller et al. March 2007 CSIRO Marine and Atmospheric Research.
Indirect Determination of Surface Heat Fluxes in the Northern Adriatic Sea via the Heat Budget R. P. Signell, A. Russo, J. W. Book, S. Carniel, J. Chiggiato,

Indirect Determination of Surface Heat Fluxes in the Northern Adriatic Sea via the Heat Budget R. P. Signell, A. Russo, J. W. Book, S. Carniel, J. Chiggiato,
Application of Satellite Data in the Data Assimilation Experiments off Oregon Peng Yu in collaboration with Alexander Kurapov, Gary Egbert, John S. Allen,

Application of Satellite Data in the Data Assimilation Experiments off Oregon Peng Yu in collaboration with Alexander Kurapov, Gary Egbert, John S. Allen,
NRL modeling during ONR Monterey Bay 2006 experiment. Igor Shulman, Clark Rowley, Stephanie Anderson, John Kindle Naval Research Laboratory, SSC Sergio.

NRL modeling during ONR Monterey Bay 2006 experiment. Igor Shulman, Clark Rowley, Stephanie Anderson, John Kindle Naval Research Laboratory, SSC Sergio.
MARCOOS/ESPreSSO ROMS RU Coastal Ocean Modeling and Prediction group John Wilkin, Gordon Zhang, Julia Levin, Naomi Fleming, Javier Zavala-Garay, Hernan.

MARCOOS/ESPreSSO ROMS RU Coastal Ocean Modeling and Prediction group John Wilkin, Gordon Zhang, Julia Levin, Naomi Fleming, Javier Zavala-Garay, Hernan.
Coastal Ocean Observation Lab John Wilkin, Hernan Arango, John Evans Naomi Fleming, Gregg Foti, Julia Levin, Javier Zavala-Garay,

Coastal Ocean Observation Lab John Wilkin, Hernan Arango, John Evans Naomi Fleming, Gregg Foti, Julia Levin, Javier Zavala-Garay,
Coastal Ocean Observation Lab John Wilkin, Hernan Arango, Julia Levin, Javier Zavala-Garay, Gordon Zhang Regional Ocean.

Coastal Ocean Observation Lab John Wilkin, Hernan Arango, Julia Levin, Javier Zavala-Garay, Gordon Zhang Regional Ocean.
Forecasting the dispersal of the Hudson River Plume John Wilkin Gregg Foti Byoung-Ju Choi Institute of Marine and Coastal Sciences Rutgers, The State University.

Forecasting the dispersal of the Hudson River Plume John Wilkin Gregg Foti Byoung-Ju Choi Institute of Marine and Coastal Sciences Rutgers, The State University.
Dale haidvogel US East Coast ROMS/TOMS Projects North Atlantic Basin (NATL) Northeast North American shelf (NENA) NSF CoOP Buoyancy.

Dale haidvogel US East Coast ROMS/TOMS Projects North Atlantic Basin (NATL) Northeast North American shelf (NENA) NSF CoOP Buoyancy.

Similar presentations

Ads by Google