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Use of Suomi-NPP in NAVDAS-AR*
Benjamin Ruston1, Steve Swadley1, Nancy Baker1, Rolf Langland1
1NRL, Monterey, CA
*Navy Atmospheric Variational Data Assimilation System – Accelerated Representer
Suomi-NPP in NAVDAS-AR
ATMS• Operationally assimilated using JCSDA CRTM• Improved coverage compared to AMSU-A/MHS• Improved performance of water vapor channels compared to MHS, both
spectrally and in noise performance
OMPS• OMPS Nadir Profiler (NP) assimilation only• First use of passive tracer assimilation capability in NAVDAS-AR• Transferred along with SBUV/2• Inactive due to missing stratospheric photochemistry
CrIS• Awaiting promotion with NAVGEM v1.3.1 (Aug2015)• Using JCSDA CRTM• Following McNally and Watts cloud detection (also used for IASI and AIRS)• 84 LW (CO2 temperature) and 49 MW (H2O humidity) channels
VIIRS• AMV direct broadcast from Fairbanks via CIMSS implemented Jul 2014 • AMV feed from NESDIS finally sorted late Nov2014 operational Jan2015
NCODANRL Coupled Ocean Data Assimilation System
Multivariate Analysis of ocean u,v,T,s,ice,SSH,SWH. Global, Regional, Local Ocean Data Assimilation.
NAVDASNRL Atmospheric Variational Data Assimilation System 3D Variational Analysis, Observation Space.
Global, Regional, or Local Application.
NAVDAS-ARNAVDAS Accelerated Representer 4D Variational Analysis, Weak Constraint, Model Space.
Global or Regional Application. High Altitude DA.
ADJOINTS
NAVDAS(–AR) Adjoints of 3D & 4D Data Assimilation Systems NOGAPS TLM; Moist Adjoint COAMPS®TLM; Moist Adjoint, including explicit moist physics
NAVOBSNAVDAS-Adjoint OBservation Monitoring System Real-time monitoring of all data assimilated.
Identification of observation quality problems. Real-time data selection and data targeting.
Ensemble
DA
Ensemble Kalman Filter Algorithm Testing for COAMPS® using real observations. EnKF/4DVAR Hybrid for the NAVDAS-AR framework.
Navy’s Data Assimilation Tools
Outline
VIIRS Atmospheric Motion Vector Assimilation• Polar winds impact on global system
Ozone in the Navy global model and OMPS assimilation• Navy Global Environmental Model (NAVGEM) Ozone analysis• Passive tracers in NAVGEM and NAVDAS-AR• Impacts of OMPS-NP and SBUV/2 on NAVDAS-AR increment
Current ATMS operational performance• How does the impact of ATMS compare with other Microwave (MW)
and Infrared (IR) sensors• How has ATMS looked from a stability standpoint• What components could be added for additional ATMS impacts
Current development work with CrIS• Channel selection and questions• Data thinning, current strategy and concepts• Observation errors as diagnosed from innovation statistics
Summary and Future Directions
VIIRS Atmospheric Motion Vectors
http://www.nrlmry.navy.mil/obsens/navgem/obsens_main_od.html
• VIIRS AMVs have been added in addition to winds from AVHRR, MODIS, Geostationary, and combined LeoGeo winds
• Impacts are similar to if not slightly improved from those of MODIS
• Vertical distribution of impact shows greatest benefit in the mid to upper troposphere
OMPS Ozone Assimilation
8.7 hPa 0.91 hPa 0.096 hPa 0.042 hPa 0.010 hPa 0.0033 hPa
NAVGEM currently uses a linearized ozone photochemistry parameterization based on diurnally averaged odd-oxygen (O3+O) production and loss rates in the stratosphere. It does not account for diurnal cycle in ozone present above 1 hPa.
A new generalized ozone photochemistry parameterization has been tested in NOGAPS-ALPHA (above), and is slated for testing in L74 NAVGEM.
OMPS Ozone Assimilation
• Capability added to operational system; however, it is not active
• This is largely due to missing photochemistry in stratosphere
• Also a bias correction between OMPS and SBUV/2 should be examined
Increments to Ozone
Operational Use of ATMS
• ATMS is treated as a primary sensor and has a first priority weighting along with MetOp-B, DMSP-F19, and NOAA-19.
• A 36km Gaussian 100pt filter is used to scene average the data• The ATMS data are thinned to ~135km before assimilation• In addition to quality flags in the data itself; a sea ice, cloud
liquid water and scattering index is generated and applied to water vapor and tropospheric temperature channels
• Operational bias correction is variational; however, a Harris-Kelley offline type is available
Operational Use of ATMS
1
2
2
ˆ ( , ) ( ) ( , )
( ) exp2
( , ), ( , )
N
B i B i ii
ii
i i i
T s b w p T s b
rw p
r s b s s b b
N = 200* pre-computed closest points*note: a 100-point filter is used operationally
Gaussian AverageBoxcar Average
s: Scan Position, b: Beam position
Channel Full Res 3x3 Boxcar Gaussian σ=25km
Gaussian σ=36km
Gaussian σ=50km
7 0.43 0.37 0.36 0.36 0.37
8 0.36 0.29 0.30 0.30 0.31
9 0.45 0.38 0.38 0.38 0.39
10 0.46 0.32 0.33 0.32 0.34
11 0.56 0.33 0.33 0.32 0.33
12 0.64 0.43 0.43 0.42 0.43
13 0.90 0.56 0.54 0.52 0.52
14 1.24 0.72 0.69 0.66 0.65
15 2.04 1.18 1.12 1.06 1.04
ATMS Spatial Smoothing Effects on OB-BK StDvDTG: 2012070412
Operational Use of ATMS
• Monitoring of operational data streams at FNMOC– http://www.nrlmry.navy.mil/metoc/ar_monitor/
RadgramsGlobal mean and stdv of
innovation
Zonal InnovationLatitudinal dependence
of mean and stdv
Observation ImpactReduction of NWP error due
to observation
Monitoring of ATMS
• ATMS contributes close to 5% of total FSOI
• Water vapor channels impact are higher than MHS or SSMIS• Also exhibit best noise
characteristics (lowest [O-B] RMS)
• NAVGEM v1.2 06Nov2013• NAVGEM v1.2.2
25Jul2014From initial implementation in NAVGEM v1.2 ATMS biases have generally seen a reduction
• CrIS is treated as a primary sensor and has a first priority weighting along with MetOp-B, DMSP-F19, and NOAA-19.
• Data is selected for only a single FOV of the 9 per “golf ball”• The CrIS data is thinned to ~135km before assimilation• A Hamming apodization is performed on the radiances before
conversion to brightness temperature to match coefficients in JCSDA CRTM
• In addition to quality flags in the data itself; a cloud screen is applied using the innovation similar to IASI and AIRS, if a cloud is detected water vapor channels will not be assimilated for that pixel
• Experimental bias correction is variational; however, a Harris-Kelley offline type will be developed before delivery to operations
CrIS Assimilation
CrIS Assimilation
• CrIS performance continues to meet expectations for the sensor• Advanced planning beginning for full resolution CrIS which
impacts mid- and short-wave bands• Ingest, quality control and assimilation tests have been
completed. Promotion planned with NAVGEM v1.3.1 release.• No correlated error is included in the initial release for either the
longwave temperature or mid-wave (humidity channels).
Monitoring of CrIS
Evaluate CrIS against currently assimilated AIRS and IASI
Jacobians from CrIS were evaluated on channel-by-channel basis
CrIS Assimilation
8-day summary for STDV of Innovation for 5x5-degree box CrIS has very good noise performance in this band
CrIS Assimilation
Current channel selection: 84 longwave CO2 channels and 49 H20 channels
Cloud screening uses the McNally and Watts (2003)
CrIS consistently shows a lower innovation standard deviation than that seen for AIRS or IASI.
This is due in part to the coarser spectral resolution of CrIS
FY15 transfer: NPP CrIS
Per ObImpact
3.233.262.340.840.850.420.311.761.985.094.915.715.961.040.770.971.270.671.51
x 10-6
FY15 transfer: NPP CrIS30-day Forecast Error Reduction (IR/MW Sounders)
`
CrIS Assimilation
Summary
Ozone from OMPS-NP is awaiting activationAssimilation capability was delivered with NAVGEM v1.2.1, it does not have a dramatic impact on the global atmospheric forecasts, particularly in the troposphere. Decision made to wait for photochemistry update.
VIIRS Atmospheric Motion Vectors (AMV) are operationalA small subset was initially assimilated real time (via direct broadcast Fairbanks, AK) beginning July of 2014, but global real-time feed established Nov2014 and operationally promoted in February 2015.
ATMS has positive impact on Navy Global NWPATMS is consistently showing a positive impact on Navy global NWP via the NAVGEM/NAVDAS-AR system. The impact is very similar to that of SSMIS and is an improvement over a combined AMSU-A/MHS sensor suite from the NOAA or MetOp satellite series.
CrIS will be operationally assimilatedAll pre-operational testing is showing the CrIS sensor has beneficial impact on the NAVGEM/NAVDAS-AR system. It is being prepared as one of the updates with the NAVGEM v1.3.1 system, and will include both temperature and moisture channel assimilation.
Future Directions
• Aid in promotion of CrIS assimilation to operations• Explore more dynamic thinning for ATMS, rather than evenly
spaced• Test any striping mitigation strategies which are proposed and
provided• Correlated error (see Campbell et al) for both ATMS and CrIS
• Channel down-selection based on condition number of correlation matrix
• Investigate impacts of improved normalization of moisture variable (such as Hölm transform)
• Re-evaluate assimilation after stratospheric Ozone photochemistry update
• Investigate potential “bias” correction between SBUV/2 and OMPS-NP