Quantification of Aquarius, SMAP, SMOS and Argo-Based Gridded Sea Surface Salinity Product Sampling Errors

Evaluating and validating satellite sea surface salinity (SSS) measurements is fundamental. There are two types of errors in satellite SSS: measurement error due to the instrument’s inaccuracy and problems in retrieval, and sampling error due to unrepresentativeness in the way that the sea surface is sampled in time and space by the instrument. In this study, we focus on sampling errors, which impact both satellite and in situ products. We estimate the sampling errors of Level 3 satellite SSS products from Aquarius, SMOS and SMAP, and in situ gridded products. To do that, we use simulated L2 and L3 Aquarius, SMAP and SMOS SSS data, individual Argo observations and gridded Argo products derived from a 12-month high-resolution 1/48° ocean model. The use of the simulated data allows us to quantify the sampling error and eliminate the measurement error. We found that the sampling errors are high in regions of high SSS variability and are globally about 0.02/0.03 psu at weekly time scales and 0.01/0.02 psu at monthly time scales for satellite products. The in situ-based product sampling error is significantly higher than that of the three satellite products at monthly scales (0.085 psu) indicating the need to be cautious when using in situ-based gridded products to validate satellite products. Similar results are found using a Correlated Triple Collocation method that quantifies the standard deviation of products’ errors acquired with different instruments. By improving our understanding and quantifying the effect of sampling errors on satellite-in situ SSS consistency over various spatial and temporal scales, this study will help to improve the validation of SSS, the robustness of scientific applications and the design of future salinity missions.

[1]  J. Boutin,et al.  Satellite‐based Sea Surface Salinity designed for Ocean and Climate Studies , 2021, Journal of Geophysical Research: Oceans.

[2]  S. Fournier,et al.  Matchup Characteristics of Sea Surface Salinity Using a High-Resolution Ocean Model , 2021, Remote. Sens..

[3]  Manuel Martin-Neira,et al.  Triple Collocation Analysis for Two Error-Correlated Datasets: Application to L-Band Brightness Temperatures over Land , 2020, Remote. Sens..

[4]  A. Turiel,et al.  Nine years of SMOS sea surface salinity global maps at the Barcelona Expert Center , 2020, Earth System Science Data.

[5]  Frederick M. Bingham,et al.  Subfootprint Variability of Sea Surface Salinity Observed during the SPURS-1 and SPURS-2 Field Campaigns , 2019, Remote. Sens..

[6]  Sidharth Misra,et al.  Satellite Salinity Observing System: Recent Discoveries and the Way Forward , 2019, Front. Mar. Sci..

[7]  Javier L. Lara,et al.  Operational Oceanography at the Service of the Ports , 2018, New Frontiers in Operational Oceanography.

[8]  David M. Le Vine,et al.  The Salinity Retrieval Algorithms for the NASA Aquarius Version 5 and SMAP Version 3 Releases , 2018, Remote. Sens..

[9]  Wenming Lin,et al.  Error Characterization of Sea Surface Salinity Products Using Triple Collocation Analysis , 2018, IEEE Transactions on Geoscience and Remote Sensing.

[10]  Dimitris Menemenlis,et al.  Seasonality in Transition Scale from Balanced to Unbalanced Motions in the World Ocean , 2018 .

[11]  Dimitris Menemenlis,et al.  Ocean submesoscales as a key component of the global heat budget , 2018, Nature Communications.

[12]  Dimitris Menemenlis,et al.  An Observing System Simulation Experiment for the Calibration and Validation of the Surface Water Ocean Topography Sea Surface Height Measurement Using In Situ Platforms , 2017 .

[13]  Mikael Kuusela,et al.  Locally stationary spatio-temporal interpolation of Argo profiling float data , 2017, Proceedings of the Royal Society A.

[14]  Dimitris Menemenlis,et al.  Spectral decomposition of internal gravity wave sea surface height in global models , 2017 .

[15]  D. Menemenlis,et al.  Seasonality of submesoscale dynamics in the Kuroshio Extension , 2016 .

[16]  Tong Lee,et al.  Satellite and In Situ Salinity: Understanding Near-Surface Stratification and Subfootprint Variability , 2016 .

[17]  Tong Lee Consistency of Aquarius sea surface salinity with Argo products on various spatial and temporal scales , 2016 .

[18]  C. Wunsch,et al.  ECCO version 4: an integrated framework for non-linear inverse modeling and global ocean state estimation , 2015 .

[19]  I. Fukumori,et al.  Estimating satellite salinity errors for assimilation of Aquarius and SMOS data into climate models , 2014 .

[20]  Bertrand Chapron,et al.  Sea surface salinity structure of the meandering Gulf Stream revealed by SMOS sensor , 2014 .

[21]  Nick Rayner,et al.  EN4: Quality controlled ocean temperature and salinity profiles and monthly objective analyses with uncertainty estimates , 2013 .

[22]  R. Ponte,et al.  Small-Scale Variability in Sea Surface Salinity and Implications for Satellite-Derived Measurements , 2013 .

[23]  Gary S. E. Lagerloef,et al.  Ocean Salinity and the Aquarius/SAC-D Mission: A New Frontier in Ocean Remote Sensing , 2013 .

[24]  Raj Kumar,et al.  Assessment of Satellite-Derived Sea Surface Salinity in the Indian Ocean , 2013, IEEE Geoscience and Remote Sensing Letters.

[25]  Nadya T. Vinogradova,et al.  Assessing Temporal Aliasing in Satellite-Based Surface Salinity Measurements , 2012 .

[26]  Yann Kerr,et al.  SMOS: The Challenging Sea Surface Salinity Measurement From Space , 2010, Proceedings of the IEEE.

[27]  Jiancheng Shi,et al.  The Soil Moisture Active Passive (SMAP) Mission , 2010, Proceedings of the IEEE.

[28]  Dean Roemmich,et al.  The 2004-2008 mean and annual cycle of temperature, salinity, and steric height in the global ocean from the Argo Program , 2009 .

[29]  T. Lee,et al.  ECCO2: High Resolution Global Ocean and Sea Ice Data Synthesis , 2008 .

[30]  Simon Yueh,et al.  The Aquarius/SAC-D mission: Designed to meet the salinity remote-sensing challenge , 2008 .

[31]  Michael J. McPhaden,et al.  Time and space scales for sea surface salinity in the tropical oceans , 2005 .

[32]  Adriano Camps,et al.  Radiometric sensitivity computation in aperture synthesis interferometric radiometry , 1998, IEEE Trans. Geosci. Remote. Sens..

[33]  L. Perelman,et al.  A finite-volume, incompressible Navier Stokes model for studies of the ocean on parallel computers , 1997 .

[34]  Nikolai Maximenko,et al.  Optimum interpolation analysis of Aquarius sea surface salinity , 2016 .

[35]  Frederik Michel Dekking,et al.  A Modern Introduction to Probability and Statistics , 2005 .