Automated Extraction of Surface Water Extent from Sentinel-1 Data

Accurately quantifying surface water extent in wetlands is critical to understanding their role in ecosystem processes. However, current regional- to global-scale surface water products lack the spatial or temporal resolution necessary to characterize heterogeneous or variable wetlands. Here, we proposed a fully automatic classification tree approach to classify surface water extent using Sentinel-1 synthetic aperture radar (SAR) data and training datasets derived from prior class masks. Prior classes of water and non-water were generated from the Shuttle Radar Topography Mission (SRTM) water body dataset (SWBD) or composited dynamic surface water extent (cDSWE) class probabilities. Classification maps of water and non-water were derived over two distinct wetlandscapes: the Delmarva Peninsula and the Prairie Pothole Region. Overall classification accuracy ranged from 79% to 93% when compared to high-resolution images in the Prairie Pothole Region site. Using cDSWE class probabilities reduced omission errors among water bodies by 10% and commission errors among non-water class by 4% when compared with results generated by using the SWBD water mask. These findings indicate that including prior water masks that reflect the dynamics in surface water extent (i.e., cDSWE) is important for the accurate mapping of water bodies using SAR data.

[1]  Hankui K. Zhang,et al.  Finer resolution observation and monitoring of global land cover: first mapping results with Landsat TM and ETM+ data , 2013 .

[2]  Margaret A. Palmer,et al.  Surface Hydrologic Connectivity Between Delmarva Bay Wetlands and Nearby Streams Along a Gradient of Agricultural Alteration , 2015, Wetlands.

[3]  C. Kilsby,et al.  Multi‐temporal synthetic aperture radar flood mapping using change detection , 2018 .

[4]  Jeffrey S. Evans,et al.  Using a multiscale, probabilistic approach to identify spatial-temporal wetland gradients , 2016 .

[5]  Samuel Corgne,et al.  Mapping and Characterization of Hydrological Dynamics in a Coastal Marsh Using High Temporal Resolution Sentinel-1A Images , 2016, Remote. Sens..

[6]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[7]  P. Levelt,et al.  ESA's sentinel missions in support of Earth system science , 2012 .

[8]  Michael A. Wulder,et al.  Opening the archive: How free data has enabled the science and monitoring promise of Landsat , 2012 .

[9]  Matthias Drusch,et al.  Sentinel-2: ESA's Optical High-Resolution Mission for GMES Operational Services , 2012 .

[10]  Laurence C. Smith,et al.  Control on sediment and organic carbon delivery to the Arctic Ocean revealed with space-borne synthetic aperture radar: Ob' River, Siberia , 1998 .

[11]  Min Feng,et al.  A global, high-resolution (30-m) inland water body dataset for 2000: first results of a topographic–spectral classification algorithm , 2016, Int. J. Digit. Earth.

[12]  B. Brisco,et al.  The application of C-band polarimetric SAR for agriculture: a review , 2004 .

[13]  Andreas Schmitt,et al.  SAR polarimetric change detection for flooded vegetation , 2013, Int. J. Digit. Earth.

[14]  J. Wickham,et al.  Thematic accuracy of the NLCD 2001 land cover for the conterminous United States , 2010 .

[15]  Michael Dixon,et al.  Google Earth Engine: Planetary-scale geospatial analysis for everyone , 2017 .

[16]  Jin Chen,et al.  Comparison and improvement of methods for identifying waterbodies in remotely sensed imagery , 2012 .

[17]  Thomas C. Winter,et al.  Relation of streams, lakes, and wetlands to groundwater flow systems , 1999 .

[18]  Thuy Le Toan,et al.  Multitemporal ERS SAR analysis applied to forest mapping , 2000, IEEE Trans. Geosci. Remote. Sens..

[19]  Chengquan Huang,et al.  Automated Quantification of Surface Water Inundation in Wetlands Using Optical Satellite Imagery , 2017, Remote. Sens..

[20]  Heather McNairn,et al.  Compact polarimetry overview and applications assessment , 2010 .

[21]  P. Rosen,et al.  Global persistent SAR sampling with the NASA-ISRO SAR (NISAR) mission , 2017, 2017 IEEE Radar Conference (RadarConf).

[22]  Stefan Dech,et al.  Comparing four operational SAR-based water and flood detection approaches , 2015 .

[23]  Alan A. Thompson,et al.  Overview of the RADARSAT Constellation Mission , 2015 .

[24]  James W Jawitz,et al.  Enhancing protection for vulnerable waters. , 2017, Nature geoscience.

[25]  Megan W. Lang,et al.  advances in remotely sensed data and techniques for wetland mapping and monitoring , 2015 .

[26]  Matthew W Becker,et al.  Potential for Satellite Remote Sensing of Ground Water , 2006, Ground water.

[27]  Sangchul Lee,et al.  Improving the catchment scale wetland modeling using remotely sensed data , 2017, Environ. Model. Softw..

[28]  Brian Brisco,et al.  Operational Surface Water Detection and Monitoring Using Radarsat 2 , 2016, Remote. Sens..

[29]  Stefan Dech,et al.  Results of the Global WaterPack: a novel product to assess inland water body dynamics on a daily basis , 2015 .

[30]  Jiancheng Shi,et al.  The Future of Earth Observation in Hydrology. , 2017, Hydrology and earth system sciences.

[31]  M. Lefsky,et al.  Mapping tropical forest biomass with radar and spaceborne LiDAR in Lopé National Park, Gabon: Overcoming problems of high biomass and persistent cloud , 2012 .

[32]  Thomas L. Ainsworth,et al.  Improved Sigma Filter for Speckle Filtering of SAR Imagery , 2009, IEEE Transactions on Geoscience and Remote Sensing.

[33]  John W. Jones,et al.  Efficient Wetland Surface Water Detection and Monitoring via Landsat: Comparison within situ Data from the Everglades Depth Estimation Network , 2015, Remote. Sens..

[34]  Gavin A. Schmidt,et al.  An emissions‐based view of climate forcing by methane and tropospheric ozone , 2005 .

[35]  Florence Tupin,et al.  NL-SAR: A Unified Nonlocal Framework for Resolution-Preserving (Pol)(In)SAR Denoising , 2015, IEEE Transactions on Geoscience and Remote Sensing.

[36]  John R. Townshend,et al.  A new global raster water mask at 250 m resolution , 2009, Int. J. Digit. Earth.

[37]  Maurizio Santoro,et al.  Assessing Envisat ASAR and Sentinel-1 multi-temporal observations to map open water bodies , 2015, 2015 IEEE 5th Asia-Pacific Conference on Synthetic Aperture Radar (APSAR).

[38]  H. Winsemius,et al.  Automated global water mapping based on wide-swath orbital synthetic-aperture radar , 2012 .

[39]  Brian Brisco,et al.  Mapping and Monitoring Surface Water and Wetlands with Synthetic Aperture Radar , 2015 .

[40]  G. McCarty,et al.  Enhanced Detection of Wetland-Stream Connectivity Using LiDAR , 2012, Wetlands.

[41]  Patrick Matgen,et al.  Towards an automated SAR-based flood monitoring system: Lessons learned from two case studies , 2011 .

[42]  Hankui K. Zhang,et al.  Using the 500 m MODIS Land Cover Product to Derive a Consistent Continental Scale 30 m Landsat Land Cover Classification , 2017 .

[43]  Sandro Martinis,et al.  Towards operational near real-time flood detection using a split-based automatic thresholding procedure on high resolution TerraSAR-X data , 2009 .

[44]  Thomas J. Jackson,et al.  Radar Vegetation Index for Estimating the Vegetation Water Content of Rice and Soybean , 2012, IEEE Geoscience and Remote Sensing Letters.

[45]  B. Brisco,et al.  Evaluation of C-band polarization diversity and polarimetry for wetland mapping , 2011 .

[46]  Francisco Grings,et al.  Mapping Plant Functional Types in Floodplain Wetlands: An Analysis of C-Band Polarimetric SAR Data from RADARSAT-2 , 2016, Remote. Sens..

[47]  Yi Peng,et al.  Wetland inundation mapping and change monitoring using Landsat and airborne LiDAR data , 2014 .

[48]  Urs Wegmüller,et al.  Strengths and weaknesses of multi-year Envisat ASAR backscatter measurements to map permanent open water bodies at global scale , 2015 .

[49]  Eric S. Kasischke,et al.  Influence of incidence angle on detecting flooded forests using C-HH synthetic aperture radar data , 2008 .

[50]  Gerhard Krinner,et al.  Impact of lakes and wetlands on boreal climate , 2003 .

[51]  Alexandre Bouvet,et al.  Understanding the temporal behavior of crops using Sentinel-1 and Sentinel-2-like data for agricultural applications , 2017 .

[52]  Mark L. Carroll,et al.  Multi-Decadal Surface Water Dynamics in North American Tundra , 2017, Remote. Sens..

[53]  Malcolm Davidson,et al.  GMES Sentinel-1 mission , 2012 .

[54]  David Small,et al.  Flattening Gamma: Radiometric Terrain Correction for SAR Imagery , 2011, IEEE Transactions on Geoscience and Remote Sensing.

[55]  M. Claverie,et al.  Preliminary analysis of the performance of the Landsat 8/OLI land surface reflectance product. , 2016, Remote sensing of environment.

[56]  J. Pekel,et al.  High-resolution mapping of global surface water and its long-term changes , 2016, Nature.

[57]  Guoqing Sun,et al.  Sensitivity of multi-source SAR backscatter to changes of forest aboveground biomass , 2013, IGARSS.

[58]  Zhong Lu,et al.  Monitoring Everglades freshwater marsh water level using L-band synthetic aperture radar backscatter , 2014 .

[59]  Heiko Balzter,et al.  Modelling forest canopy height by integrating airborne LiDAR samples with satellite Radar and multispectral imagery , 2018, Int. J. Appl. Earth Obs. Geoinformation.

[60]  Urs Wegmüller,et al.  Multi-temporal Synthetic Aperture Radar Metrics Applied to Map Open Water Bodies , 2014, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.