NOAA Objective Sea Surface Salinity Analysis P. Xie, Y. Xue, and A

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Presentation transcript:

NOAA Objective Sea Surface Salinity Analysis P. Xie, Y. Xue, and A NOAA Objective Sea Surface Salinity Analysis P. Xie, Y. Xue, and A. Kumar NOAA Climate Prediction Center 2015.02.25.

Objective: To develop an objective analysis of sea surface salinity (SSS) for climate / oceanic analysis as well as real-time operational applications through blending information from in situ measurements as well as retrievals from Aquarius and SMOS satellite passive microwave observations. NOAA Blended Analysis of Surface Salinity (BASS) Covering the entire global oceans on a 1olat/lon grid Starting from (at least) January 2010 on a time resolution of monthly or finer Quantitative consistency with in situ based analysis for longer period Updated on a quasi real-time basis

A Collaborative Effort: NESDIS/NODC provides quality controlled in situ data NESDIS/STAR acquires / decodes satellite retrievals NWS/CPC develops blending algorithm and products

The Blending Algorithm [1] In Situ and Satellite Inputs In situ (from NODC) Grid box mean SSS from all measurements collected from Argo and other buoy arrays (e.g. TAO/TRITON, PIRATA, RAMA) Monthly mean SSS Number of profiles Monthly climatology on a 1o lat/lon global grid SMOS (from ESA) Level 2 retrievals (Version 5.50) at ~50km pixels averaged into 1olat/lon grid Number of pixels in each monthly / 1olat/lon grid box counted and used in defining random error Aquarius (from NASA) Level 2 retrievals (Version 1.3) at ~100km pixels averaged into 1olat/lon grid Number of pixels in each monthly / 1olat/lon grid box computed and used in defining random error

The Blending Algorithm [2] Mean SSS from Sep.’11 to Dec.’12 Similar large scale distribution patterns Differences in the SSS magnitude and distribution of finer scales High SSS in SMOS over SE Pacific not observed in NODC in situ and Aquarius retrievals Location of SSS maxima in SMOS shifted compared to NODC and Aquarius

The Blending Algorithm [3] Blending Strategy Similar to the strategy employed in the development of SST and precipitation merging algorithms (Wang and Xie 2005; Xie and Xiong 2011) A Two-Step Approach Bias correction for satellite retrievals PDF tables are constructed using co-located satellite and in situ data covering a 5-month period centering at the target month and over a spatial domain centering at the target grid box The spatial domain is expended until sufficient number of data pairs are collected Blending in situ measurements and bias corrected satellite retrievals Optimal Interpolation First Guess : Analysis for the previous time step Observations: In situ, satellite retrievals

The Blending Algorithm [4] Bias Correction Results for Oct.2011

The Blending Algorithm [5] Comparison with In Situ Data After the bias correction, both the spatial pattern and the magnitude of SSS match closely with those in the in situ measurements Artificial band of large SSS over SE Pacific in the raw SMOS retrieval is removed Positions of the maxima SSS in SMOS close to those in the in situ analysis and the Aquarius retrievals

The Blending Algorithm [6] Crs-Val Results for Bias Correction Statistics SMOS -1 Raw SMOS-1 Adjusted Aquarius BIAS -0.232 0.012 -0.082 0.020 RMS Error 0.502 0.303 0.406 0.268 Correlation 0.903 0.960 0.926 0.970 Cross-validation tests were done for withdrawing in situ data at 10% randomly selected grid boxes and perform the bias correction using the in situ data at the 90% remaining grid boxes After the PDF bias correction, the bias in the raw satellite retrievals is removed almost completely while pattern correlation is improved

The Blending Algorithm [7] PDF Before and After the Bias Correction Results based on cross-validation tests After the bias correction, PDF for the SMOS and Aquarius matches closely with that for the in situ measurements

The Blending Algorithm [8] Sample Inputs to the OI for Oct.’11 The bias corrected SMOS and Aquarius SSS retrievals are further combined with in the NODC in situ measurement (not the analysis) through OI Similar patterns of SSS anomaly from the in situ measurements and the two satellite retrievals Differences observed over high latitudes and along the coasts

The Blending Algorithm [9] Sample Blended Analysis for Oct.’11 Analysis looks reasonable over most of the global ocean In addition to the analyzed fields of SSS, the OI algorithm also generates estimation of error for the SSS analysis Estimated analysis error is on the order of ~0.2PSU over most of the open oceans and reaches more than 1PSU over high latitudes

The Blending Algorithm [10] Crs-Val Results for the OI Combining Tropics (20oS-20oN) SMOS Aquarius Blended BIAS 0.005 0.014 0.008 RMS Error 0.323 0.289 0.216 Correlation 0.507 0.586 0.686 Globe (90oS-90oN) SMOS Aquarius Blended BIAS -0.001 0.010 0.006 RMS Error 0.315 0.290 0.205 Correlation 0.407 0.495 0.628

Comparison with NODC Analysis [1] Example for July 2012 NODC analysis defined by interpolating in situ measurements within 770km through a distance-weighting technique Overall similar anomaly patterns BASS presents more details Differences over costal regions and high-latitude oceans

Comparison with NODC Analysis [2] Comparison Statistics for 2010-2012 Good agreements between BASS and the NODC in situ analysis over majority of the tropical oceans, with high correlation and low RMS differences Poor agreements over high latitude oceans with RMS differences on the order of the signal indicated by the standard deviation of the BASS Differences are also large over coastal regions

Applications of the SSS Analysis [1] Anomaly Correlation with P and E P from CMORPH, E from OAFlux Precip presents high correlation with SSS over tropics Evaporation exhibits correlation over parts of tropical ocean with strong evaporations

Applications of the SSS Analysis [2] Combined EOF with P and E Combined EOF Model 1 shows coherent variation patterns of SSS, P, and E in association with the evolution of ENSO Positive precipitation yields reduced SSS over tropical open oceans with strong convective activities (ITCZ, SPCZ et al) Enhanced evaporation is related to increased SSS when/where precipitation is absent or weak

Applications of the SSS Analysis [3] Real-time oceanic monitoring SSS analysis updated on a quasi real-time basis (within 7 days after the end of the target month) A simple package created describing the anomaly and tendency of SSS and associated fresh water flux over the global oceans for CPC Global Ocean Briefing

SUMMARY An objective analysis of global SSS is created through blending information from in situ measurements and satellite observations Called NOAA Blended Analysis of Surface Salinity (BASS), the SSS analysis is constructed on a 1o lat/lon grid over the global ocean for a 5+ years period from January 2010 The data set is updated on a quasi real-time basis and available through ftp at: ftp.cpc.ncep.noaa.gov/precip/BASS Further work is under way to refine the objective SSS analysis to pentad temporal resolution