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A New Ocean Suite Algorithm for AMSR2 David I. Duncan September 16 th, 2015 AMSR Science Team Meeting Huntsville, AL
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Outline 1. Algorithm Description 2. Key Innovations 3. Validation & Comparison 4. Ongoing Work
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Algorithm Description 1DVAR (Optimal Estimation) simultaneous retrieval of atmospheric and ocean surface properties (TPW, 10m wind, CLWP, SST) via a physical forward model, f, y = f(x,b) + ε, where y is the Tb vector and x is state vector. Iterate to find simulated Tbs that minimize the cost function: Φ = (x-x a ) T S a -1 (x-x a ) + [y-f(x,b)] T S y -1 [y- f(x,b)]
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Algorithm Description RT model employed is NOAA’s Community Radiative Transfer Model (CRTM) v2.2.1 Coded to allow different channel combinations, various emissivity models, various amounts of ancillary data ECMWF Interim Reanalysis employed as constraints on the retrieval Non-raining retrieval, so assumed non-scattering Ability to run for AMSR2 and GMI, all channels AMSR2: L1R Tbs at 23.8GHz resolution,12-channel and 9-channel versions GMI: L1CR Tbs for 13 channel retrieval
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Key Innovations: WV profile Structure of water vapor profile is now retrieved explicitly Coefficients of 3 EOFs of water vapor mixing ratio are retrieved parameters, indexed by SST Mean profile and EOFs are derived from ECMWF analyses EOF1 EOF2 EOF3
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Key Innovations: WV profile Structure of water vapor profile is now retrieved explicitly Coefficients of 3 EOFs of water vapor mixing ratio are retrieved parameters, indexed by SST Mean profile and EOFs are derived from ECMWF analyses
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Key Innovations: S y Matrix Most satellite retrievals and DA systems assume uncorrelated channel errors Via an innovative method for determining the impact of forward model assumptions (non-scattering, single cloud layer, 3 EOFs of water vapor, etc.), channel variances/covariances and offsets are calculated Add published values of NEdT to diagonal terms to yield S y matrix Must be calculated for all forward model and sensor combinations! In practice, slight increase may be required in diagonal elements to achieve adequate convergence
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Key Innovations: Ancillary data Microwave imager retrievals are under-constrained due to finite channels and limited information content in the Tbs To assess the impact of ancillary data, while ensuring that the retrieval is not model-dependent, the algorithm can be run in two modes: Initial Conditions ‘Climatology’‘Analysis’ SSTReynolds OI Wind Direction*/Magnit ude ECMWF / ClimatologyECMWF / ECMWF WV ProfileClimatological from SSTECMWF Temperature Profile* Global mean lapse rateECMWF Cloud LWPThin static cloudECMWF LWP Sfc Pressure*1000mbECMWF * not retrieved
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Key Innovations: Posterior Errors Uncertainty values from a retrieval product are very useful to users, yet many products do not provide uncertainties/error estimates Posterior errors drop out of the mathematics of the 1DVAR approach for all retrieved parameters
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Key Innovations: Posterior Errors Uncertainty values from a retrieval product are very useful to users, yet many products do not provide uncertainties/error estimates Posterior errors drop out of the mathematics of the 1DVAR approach for all retrieved parameters
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Validation & Comparison For GMI version, can use Dual Frequency Precipitation Radar (GPM DPR) to verify if retrieval screens out rain adequately DPR data averaged into FOV of GMI footprint Tricky for RR<1mm/hr, robust above 2mm/hr
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Validation & Comparison Preliminary results from matchups with radiosonde network (RAOB) Matchup criteria not finalized Difficulty at high latitudes Green ‘+’ signifies higher quality convergence Near-zero bias for high quality retrievals
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Validation & Comparison Comparison with RSS AMSR2 product LWP maps very different due to rain screening Many of the same features Difficult/impossible to validate LWP retrievals
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Validation & Comparison Comparison with RSS AMSR2 product TPW shows many similarities Slightly higher values in Deep Tropics, lower in storm tracks, higher at high latitudes Over most of the globe agreement to within 1mm
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Validation & Comparison Comparison with RSS AMSR2 product Wind patterns are nearly identical Retrieval is picking up smaller regional features RSS values are lower (~20%) almost uniformly over the globe Test sensitivity of result to emissivity model
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Ongoing Work Continue matchup/validation work with RAOB, Suominet, and floating buoys Examine LWP/TPW biases and adjust assumed covariances in algorithm to help remove biases Work more on minimizing Tb residuals (Tb Observed – Tb Simulated ) for each channel Further experimentation with emissivity models and channel combinations Upcoming paper will focus on the impact of using model data to constrain the retrieval, i.e. ‘climatological’ vs. ‘analysis’ versions
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Thank you!
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