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Lidia Cucurull UCARNOAAJCSDANCEP

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Atmospheric Remote Sensing Using the Global Positioning System, ... Obs Iter Pos ratio Neg ratio. 1 1 0.909090909 -0.909090909. 1 2 0.952380952 -0.952380952 ... – PowerPoint PPT presentation

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Title: Lidia Cucurull UCARNOAAJCSDANCEP


1
Use of COSMIC observations in the NCEP/JCSDA data
assimilation system
Lidia Cucurull (UCAR-NOAA/JCSDA/NCEP) Jo
hn Derber, Russ Treadon
(NOAA/NCEP) James G. Yoe
(NOAA/NESDIS) Bill Kuo (UCAR)
2
Motivation
  • To develop the total infrastructure (codes,
    scripts, etc.) necessary to monitor and
    assimilate radio-occultation (RO) observations at
    NOAA.
  • Work schedule enables complete preparation of
    NCEP data assimilation system in time for COSMIC
    launch (estimated Dec 2005 or Jan 2006).

3
Getting COSMIC data to Weather Centers
This system is currently under development by
UCAR, NESDIS, UKMO
4
What has been done?
  • Analysis of the differences between the different
    GPS processing centers to assure high quality RO
    retrievals at CDAAC.
  • Comparison of retrievals of refractivity between
    the different processing centers and the NASA
    GMAO (formerly, DAO) analysis system (PSAS). Work
    done in collaboration with Paul Poli and Joanna
    Joiner. (Results presented at the GPS RO Data
    Users Workshop, MD, October 2003).
  • Implementation of the local refractivity operator
    in the Gridpoint Statistical Interpolation (GSI)
    analysis system.
  • Ability to ingest refractivity profiles in the
    system.
  • Compute the innovation vector with CHAMP data
    (Forward Model).
  • Tangent Linear and Adjoint codes (implemented and
    tested).
  • Impact studies using a single observation, a
    single profile of refractivity and all the
    available profiles at a given analysis time.

5
GSI Analysis System
  • Developed by NOAA/EMC and others JCSDA partners
    including NASA/GMAO.
  • System is still under development.
  • Planned to replace the NCEPs current operational
    Spectral Statistical Interpolation (SSI) analysis
    system and regional data assimilation system
    prior to availability of the COSMIC data.
  • Characteristics
  • The background error covariance matrix is defined
    in a grid space. This allows the definition of
    spatially varying covariance structures.
  • T254 (nx512,ny256 for the linear gaussian grid)
    with 64 levels in the vertical (from surface to
    about 0.27 hPa). Experiments are conducted in a
    lower resolution grid T62 (nx192,ny94 for the
    quadratic gaussian grid) with 28 levels in the
    vertical.
  • MPP code running on IBM-SP.

6
GSI Analysis System (II)
  • The background or first guess is a 3,6,9 hour
    forecast.
  • Analysis variables u-wind, v-wind, temperature,
    ln(surface pressure), specific humidity, ozone,
    surface skin temperature, and coefficients for
    bias correction for satellite radiance and
    precipitation data and for the background state.
  • The analysis assimilates most conventional and
    satellite data.
  • Analysis procedure
  • 2 external iterations in the first one, the
    solution is linearized around the forecast. In
    the second one, the solution is linearized around
    the previous iteration.
  • For each external iteration, there is a series of
    internal iterations to create the analysis. The
    forward model is applied to the solution (or
    forecast) interpolated in time and space to the
    observation locations.
  • The current solution is iteratively updated by
    use of a nonlinear conjugate gradient algorithm
    to find the solution which minimizes the cost
    function.
  • Linearization of the forward model.
  • Adjoint of the forward model.

7
Forward Operator
  • Model variables of pressure, temperature and
    specific humidity are interpolated to
    refractivity observation locations.
  • Model refractivity is computed from the
    interpolated values.
  • Tangent Linear Model consistency with Forward
    Model
  • FM(x) Forward model acting on x
  • FM(xDx)perturbed Forward model acting on
    xDx
  • TL(x,Dx) Tangent Linear model acting on Dx
    (at x)

8
Tangent Linear Test
  • Obs Iter Pos ratio Neg ratio
  • 1 1 0.909090909 -0.909090909
  • 1 2 0.952380952 -0.952380952
  • 1 3 0.975609756 -0.975609756
  • 1 4 0.987654321 -0.987654321
  • 1 5 0.993788820 -0.993788820
  • 1 6 0.996884735 -0.996884735
  • 1 7 0.998439938 -0.998439938
  • 1 8 0.999219360 -0.999219360
  • 1 9 0.999609528 -0.999609528
  • 1 10 0.999804726 -0.999804726
  • 1 11 0.999902353 -0.999902353
  • 1 12 0.999951174 -0.999951174
  • 1 13 0.999975587 -0.999975587
  • 1 14 0.999987793 -0.999987793
  • 1 15 0.999993897 -0.999993897

9
Adjoint Test
  • Abs(TL-AD)/TL lt MP
  • Specific humidity
  • 0.2633763648317E04 0.2633763648317E04
    -0.1726606528179E-15
  • Temperature
  • -0.5465696094271E00 -0.5465696094271E00
    -0.0000000000000E00

10
Single observation Test
  • One random observation from a CHAMP profile.
  • Coordinates lat70.216,lon125.38,height6.40km
    (p438mb)
  • The observation error has been modified to
    account for representativeness error. The ratio
    (O-B)/? 1
  • The horizontal and vertical structure of the
    increments are determined by the scales and
    structure of the background error covariance
    matrix.
  • The impact is not only found in temperature and
    humidity. The balance constraint specified in the
    background error statistics drives increments on
    the wind field.

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13
Single profile
  • CHAMP profile located at lon259.288, lat-53.933

N Fractional difference
14
N fractional differences
15
Analysis Background
16
Profiles in 6hr assimilation window
  • Analysis Time 2002080812
  • 51 profiles from CHAMP
  • Observations of refractivity rejected if (O-B)gt 5
    error(O)
  • Experiments
  • Assimilation of profiles of refractivity only.
  • Assimilation of profiles of refractivity and all
    the conventional observations.
  • Assimilation of conventional observations only.

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20
Outlook
  • (1) QC and monitoring
  • Develop (real time) Monitoring System (O-B) for
    calibration/testing of the radio occultation
    observations.
  • QC checks (like account for SR).
  • (2) Error
  • Examine representativeness error.
  • Adjustment of the background error covariance
    matrix according to the results of the
    assimilation of profiles of refractivity.
  • (3) Experiments
  • Compute statistics of the assimilation
    experiments with CHAMP.
  • Assess the impact of the RO observations of
    refractivity when combined with all other
    available observations.
  • Superob (average in the simplest case) vertical
    levels appropriate to model vertical resolution.
  • Test other Forward Models
  • Local bending angle
  • Non-local linear observational operator
    (bending?, phase?)
  • OSSE Studies.
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