WaMaPro – a user friendly tool for water surface derivation from SAR data – and further products derived from optical data J. Huth a, M. Ahrens a, I. Klein a, U. Gessner a, J. Hoffmann b, C. Kuenzer a a German Aerospace Center (DLR), Earth Observation Center (EOC), German Remote Sensing Data Center (DFD), Land Surface Department, Oberpfaffenhofen, 82234 Wessling, Germany. b German Aerospace Center (DLR), Space Agency, 53227 Bonn, Germany. Overview WaMaPro introduction Implementation as a tool WaMaPro application in environmental research projects Further products related to water body mapping activities Introduction -Slide 3 WaMaPro – Aims and Goals WaMaPro = Water Mask Processor Original Ideas: Data analyses over time – with a focus on thematic analyses Create a simple image processing tool possible to hand over to project partners and people working in developing countries (access to software) Target user group: environmental scientists, remote sensing beginners, etc. Data we process with WaMaPro: TerraSAR-X Envisat-ASAR Sentinel-1A other SAR data possible WaMaPro – Principles and Techniques Input data (DN) Watermask Medianfilter (3x3) Remove ‚islands’ and ‚lakes’ (island size, lake size) Threshold Definition (water and land threshold) B5 Convert to binary images B1 (water) B2 (land) Image Dilation (sesize) Comparison (B3 && B2) || B1 B3 Morphological Closing (fix value) B4 DN values 3x3 Median Filter (speckle effect) Threshold definition (water and land) B1 confident water: image dilation (growing with sesize) = B3 B2 confident land Comparison of B2 and B3 (buffer area of unconfident land/water e.g. more soils) = B4 Morphological Closing (grow+shrink) for edge smoothing with fixed value (as if sesize is1) Removing of lakes and islands with user given size WaMaPro – Principles and Techniques B1 - confident water B2 - confident land B3 - dilate B1 B4 – water after buffer comparison WaMaPro test cases – Mekong Delta, Vietnam TSX WaMaPro - watermask Overlay WaMaPro test cases – Yellow River Delta, China TSX WaMaPro - watermask Overlay WaMaPro test cases – Mali, Africa TSX WaMaPro - watermask Overlay WaMaPro test cases – North sea coast - Watt, Netherlands Challenges: Wind artefacts on open ocean water; inland water shows good result TSX WaMaPro - watermask Overlay MARTINIS, S., KUENZER, C., WENDLEDER, A., HUTH, J., TWELE, A., ROTH, A., DECH, S.: Comparing four different approaches for operational SAR-based water and flood detection. Submitted to International Journal of Remote Sensing Accuracy Assessment (e.g. Vietnam – flood vs. dry season) Flood season Dry season Validation data of Jan. 2009 Blue – water 20 km Accuracy Assessment Watermask Validation for 2009-01-13 percentage of val.points [%] 40 35 30 25 20 15 10 5 0 0m 1-2m 2-5m 5-8m >8m distance between measured and calculated land-water boundary [m] source: WISDOM project GPS points at the land-water boundary with simultaneuosly acquired TerraSAR-X data 25% of points located at the land-water boundary 55% within 1-8m distance of watermask to land-water boundary GPS accuracy 2-10m (DGPS not possible) Geometric accuracy of TSX data approx. 1 pixels 20% „outliers“ (> 8m) Huth et al. (2009): Automated inundation monitoring using TerraSAR-X multi-temporal imagery. European Geosciences Union, EGU, General Assembly 2009, 19.-24. Apr. 2009, Vienna, Austria. Implementation as a tool -Slide 13 WaMaPro – open-source based tool implementation WaMaPro – open-source based tool implementation – GUI WaMaPro – open-source based tool implementation – result Application in environmental research projects -Slide 17 Slide 18 -Slide 19 KUENZER, C., GUO, H., LEINENKUGEL, L, HUTH, J., LI, X., and S. DECH, 2013: Flood mapping and flood dynamics of the Mekong Delta: An ENVISAT-ASAR-WSM based Time Series Analyses, Remote Sensing 5 (doi:10.3390/rs5020687), 687-715 Slide 20 KUENZER, C., GUO, H., LEINENKUGEL, L, HUTH, J., LI, X., and S. DECH, 2013: Flood mapping and flood dynamics of the Mekong Delta: An ENVISAT-ASAR-WSM based Time Series Analyses, Remote Sensing 5 (doi:10.3390/rs5020687), 687-715 2007-2011: 51 observations 10 per year in rainy season, ASAR, 150m Slide 21 Mekong Delta - Rainy Season 2007 b a c b Gulf of c Thailand South China Sea N 45 km 0 15 Largest common coverage Coastline Inundation mapping with TerraSAR-X vs. ASAR Kuenzer et al., (2013): Varying Scale and Capability of Envisat ASAR-WSM, TerraSAR-X Scansar and TerraSAR-X Stripmap Data to Assess Urban Flood Situations: A Case Study of the Mekong Delta in Can Tho Province. In: Remote Sensing Zeitreihenuntersuchung Überflutung 2005-2011 Coastal analyses – Inundation frequency 2005 – 2011 -2005 -2006 -2007 -2008 -2009 ASAR WSM data – 150 m resolution-Slide 24 2011 canal oil field Yellow River aquaculture wetland (reed) brine ponds TSX stripmap data – 3 m resolution KUENZER, C., HUTH, J., MARTINIS, S., LU, L., DECH, S., 2015: SAR Time Series for the Analysis of Inundation Patterns in the Yellow River Delta, China. In: Kuenzer, C., Dech, S., Wagner, W. (eds.), 2015: Remote Sensing Time Series Analyses revealing Land Surface Dynamics. In print, will be published in April, Springer, The Netherlands Inundation Frequency at East Dongting Lake 2012 2013 Datasets: TSX stripmap 3m resolution 2012 – 14 scenes (Jan–Dec) – 2013 – 8 scenes (Jan–Mar) - Yellow to orange – flood prone - Blue – permanent water bodies Flood Mapping of Northern Namibia with Sentinel-1A Publications related to WaMaPro - GSTAIGER, V., GEBHARDT, S., HUTH, J., WEHRMANN; T. and C. KUENZER, 2012: Multi-sensoral derivation of inundated areas using TerraSAR-X and ENVISAT ASAR data. International Journal of Remote Sensing, Vol. 33, 22, 7291-7304, DOI:10.1080/01431161.2012.700421 - KUENZER, C., GUO, H., LEINENKUGEL, L, HUTH, J., LI, X., and S. DECH, 2013: Flood mapping and flood dynamics of the Mekong Delta: An ENVISAT-ASAR-WSM based Time Series Analyses, Remote Sensing 5 (doi:10.3390/rs5020687), 687-715 - KUENZER, C., GUO, H., SCHLEGEL, I., VO, Q.T., LI, X., DECH, S., 2013: Scale and the Capability of Envisat ASAR-WSM, TerraSAR-X Scansar, and TerraSAR-X Stripmap Data to assess urban Flood Situations: A Case Study in Can Tho Province of the Mekong Delta, Remote Sensing, 5, 5122-5142; doi:10.3390/rs5105122 - KUENZER, C., HUTH, J., MARTINIS, S., LU, L., DECH, S., 2015: SAR Time Series for the Analysis of Inundation Patterns in the Yellow River Delta, China. In: Kuenzer, C., Dech, S., Wagner, W. (eds.), 2015: Remote Sensing Time Series Analyses revealing Land Surface Dynamics. In print, will be published in April, Springer, The Netherlands - MARTINIS, S., KUENZER, C., WENDLEDER, A., HUTH, J., TWELE, A., ROTH, A., DECH, S., 2015: Comparing four different approaches for operational SAR-based water and flood detection. Submitted to International Journal of Remote Sensing - HUTH, et al., 2015: Deriving Water Surfaces with WaMaPro – Observations of Water Surface Dynamics of the Yellow River Delta, China. Accepted oral presentation at ISRSE36, Berlin Ausbreitung von Aquakulturflächen 1995-2010 1995 2004 2010 Global WaterPack -Slide 30 Processed Data for 2013 Used Data for Classification Input Workflow: water detection 1. Preprocessing MODIS daily data (09GQ) Terra + Aqua NIR MODIS daily data (10A1) Terra + Aqua Thematic info: cloud, lake ice, ocean Ancillary Data Filter to remove misclassification MODIS Water (MOD44W) DTM Static Water Mask (training areas) Calculates the NIR mean for individual tile within training areas (excluding NIR > 20%, cloud covered or no data pixel) 2. Water detection Dynamic upper threshold for individual tile: mean + 2std Slope to remove misclassification due to relief DT classification Intermediate result Thematic product for each tile of Terra and Aqua: water, land, cloud*, lake ice* -----> combination of both for each day (*from 10A1 product) 3. Temporal scan and remove of clouds and no data 1. Temporal filter to remove cloud shadows (logical scan of pixel within the temporal stack) End result Mosaiking, resampling and tiling to MODIS extent and 250-m resolution -> Slope calculation 2. Temporal filter to remove clouds/no data and replace by values before/after the cloud Cloud free product (water, land) for each day Water Cover Duration Min & Max extent Confidence layer with amount of cloud per pixel Global WaterPack 2013 High intra-annual variability Lake Poyang (China) Lake Dongting (China) Hydropower dams and water reservoirs Koksaray Reservoir American Falls Reservoir Shardara Reservoir DOY Publications related to Global WaterPack - Klein, I., Dietz, A.J., Gessner, U., Galayeva, A., Myrzakhmetov, A., Kuenzer, C., 2014. Evaluation of seasonal water body extents in Central Asia over the past 27 years derived from mediumresolution remote sensing data. Int. J. Appl. Earth Obs. Geoinf. 26, 335–349. - Klein, I., Dietz, A., Gessner, U., Dech, S., Kuenzer, C. 2015. Results of the Global WaterPack: a novel product to assess inland water body dynamics on a daily basis. In: Remote Sensing Letters (6), 78-87 Software to share: WaMaPro Tool contact: juliane.huth@dlr.de Thank you very much for your attention! juliane.huth@dlr.de
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