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Sustainable Water Resources Management

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01-12-2023 | Original Article

Intercomparison between sentinel-1, sentinel-2, and landsat-8 on reservoir water level estimation

Authors: Manikandan Sathianarayanan, Ajay Saraswat, A. S. Mohammed Abdul Athick, Hung-Ming Lin

Published in: Sustainable Water Resources Management | Issue 6/2023

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Abstract

Remote sensing technology has made it possible for the surface water level to be updated accurately and often to prepare against water scarcity and drought events under the influence of anthropogenic activities. This research provides deeper insights into the detection and estimates of the surface water level with Sentinel-1 Synthetic Aperture Radar (SAR) data, Sentinel-2/MSI, and Landsat-8/OLI data in the Shimen Reservoir, located in northern Taiwan. This research uses data from Sentinel-1A, Sentinel-2, and Landsat-8 missions to demonstrate how well different water indices, such as the Normalized Difference Water Index (NDWI), the Normalized Difference Vegetation Index (NDVI), and the Modified Normalized Difference Water Index (MNDWI), can be used to estimate Water and water surface area. Estimated water levels from the multispectral and SAR images directly compared with DEM elevation cross-section profiles. Assessment of water level and surface water area results shows that the accuracy of SAR is comparable to that of NDWI/Landsat-8. Due to land interaction, multispectral water indices’ accuracy was better in detecting the inlet branches than either SAR Sentinel-1A VH or VV polarization. The results reconfirmed that SAR sentinel-1A data can be the best alternative for monitoring water levels in the reservoir when multispectral images were not available. Sentinel-1 data could provide similar accuracy on surface water delineation like multispectral images.

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Acharya TD, Lee DH, Yang IT, Lee JK (2016) Identification of water bodies in a Landsat 8 OLI image using a J48 decision tree. Sensors 16:1075CrossRef

Andreoli R, Yesou H, Li J, Desnos Y-L (2007) Inland lake monitoring using low and medium resolution ENVISAT ASAR and optical data: case study of Poyang Lake (Jiangxi, PR China). In: 2007 IEEE international geoscience and remote sensing symposium. IEEE, pp 4578–4581

Baghdadi N, Bernier M, Gauthier R, Neeson I (2001) Evaluation of C-band SAR data for wetlands mapping. Int J Remote Sens 22:71–88CrossRef

Bolanos S, Stiff D, Brisco B, Pietroniro A (2016) Operational surface water detection and monitoring using Radarsat 2. Remote Sens 8:285CrossRef

Brisco B, Short N, van der Sanden J, Landry R, Raymond D (2009) A semi-automated tool for surface water mapping with RADARSAT-1. Can J Remote Sens 35:336–344CrossRef

Busker T, de Roo A, Gelati E, Schwatke C, Adamovic M, Bisselink B, Pekel J-F, Cottam A (2019) A global lake and reservoir volume analysis using a surface water dataset and satellite altimetry. Hydrol Earth Syst Sci 23:669–690CrossRef

Du Z, Li W, Zhou D, Tian L, Ling F, Wang H, Gui Y, Sun B (2014) Analysis of landsat-8 OLI imagery for land surface water mapping. Remote Sens Lett 5:672–681CrossRef

Du Y, Zhang Y, Ling F, Wang Q, Li W, Li X (2016) Water bodies’ mapping from Sentinel-2 imagery with modified normalized difference water index at 10-m spatial resolution produced by sharpening the SWIR band. Remote Sens 8:354CrossRef

Feyisa GL, Meilby H, Fensholt R, Proud SR (2014) Automated water extraction index: a new technique for surface water mapping using Landsat imagery. Remote Sens Environ 140:23–35CrossRef

Filipponi F (2019) Sentinel-1 GRD preprocessing workflow. Proceedings 18:11

Frappart F, Zeiger P, Betbeder J, Gond V, Bellot R, Baghdadi N, Blarel F, Darrozes J, Bourrel L, Seyler F (2021) Automatic detection of inland water bodies along altimetry tracks for estimating surface water storage variations in the Congo Basin. Remote Sens 13:3804CrossRef

Gulácsi A, Kovács F (2020) Sentinel-1-imagery-based high-resolution water cover detection on wetlands, aided by google earth engine. Remote Sens 12:1614CrossRef

Jiang H, Feng M, Zhu Y, Lu N, Huang J, Xiao T (2014) An automated method for extracting rivers and lakes from landsat imagery. Remote Sens 6:5067–5089CrossRef

Karpatne A, Khandelwal A, Chen X, Mithal V, Faghmous J, Kumar V (2016) Global monitoring of inland water dynamics: State-of-the-art, challenges, and opportunities. In: Lässig J, Kersting K, Morik K (eds) Computational sustainability. Springer International Publishing, Cham, pp 121–147CrossRef

Kuehn, S, Benz U, Hurley J (2002) Efficient flood monitoring based on RADARSAT-1 images data and information fusion with object-oriented technology. In: IEEE international geoscience and remote sensing symposium. IEEE, pp 2862–2864

Lee JK, Acharya TD, Lee DH (2018) Exploring land cover classification accuracy of Landsat 8 image using spectral index layer stacking in hilly region of South Korea. Sens Mater 30:2927–2941

Lu S, Wu B, Yan N, Wang H (2011) Water body mapping method with HJ-1A/B satellite imagery. Int J Appl Earth Obs Geoinf 13:428–434

Ma J, Song X, Li X, Leng P, Zhou F, Li S (2014) A Novel approach to extract water body from ASAR dual-polarized data. IOP Conf Ser Earth Environ Sci 17:012099CrossRef

Malahlela OE (2016) Inland waterbody mapping: towards improving discrimination and extraction of inland surface water features. Int J Remote Sens 37:4574–4589CrossRef

Manikandan S (2018) Spatial and temporal dynamics of urban sprawl Using multi-temporal images and relative Shannon entropy model in Adama, Ethiopia. J Adv Res Geo Sci Remote Sens 5:48–57

McFeeters SK (1996) The use of the normalized difference water index (NDWI) in the delineation of open water features. Int J Remote Sens 17:1425–1432CrossRef

Melesse AM, Weng Q, Thenkabail PS, Senay GB (2007) Remote sensing sensors and applications in environmental resources mapping and modelling. Sensors 7:3209–3241CrossRef

Menarguez MA (2015) Global water body mapping from 1984 to 2015 using global high resolution multispectral satellite imagery. University of Oklahoma, Norman, OK, USA

Mohammed Abdul Athick AS, Lee S-Y (2022a) A combination of spatial domain filters to detect surface ocean current from multi-sensor remote sensing data. Remote Sens 14:332CrossRef

Mohammed Abdul Athick AS, Lee S-Y (2022b) Comprehensive analysis of ocean current and sea surface temperature trend under global warming hiatus of Kuroshio extent delineated using a combination of spatial domain filters. Geomatics 2(4):415–434. https://doi.org/10.3390/geomatics2040023CrossRef

Mohammed AAA, Lee S-Y (2022) The trend of SST, SSS, ocean current, and comparison of Kuroshio strength to weather events in Taiwan. In: IGARSS 2022—2022 IEEE international geoscience and remote sensing symposium, Kuala Lumpur, Malaysia, pp 7103–7106. https://doi.org/10.1109/IGARSS46834.2022.9883210.

Nath RK, Deb SK (2010) Water-body area extraction from high resolution satellite images—an introduction, review, and comparison. Int J Image Process (IJIP) 3:265–384

Olthof I (2017) Mapping seasonal inundation frequency (1985–2016) along the St-John River, New Brunswick, Canada using the Landsat archive. Remote Sens 9:143CrossRef

Pekel J-F, Cottam A, Gorelick N, Belward AS (2016) High-resolution mapping of global surface water and its long-term changes. Nature 540:418–422CrossRef

Pham-Duc B, Prigent C, Aires F (2017) Surface water monitoring within Cambodia and the Vietnamese Mekong Delta over a year, with Sentinel-1 SAR observations. Water 9:366CrossRef

Qing W, Jing-Juan L (2010) Water area extraction and change detection of the Poyang Lake using SAR data. Remote Sens Land Resour 22:91–97

Rogers AS, Kearney MS (2004) Reducing signature variability in unmixing coastal marsh thematic mapper scenes using spectral indices. Int J Remote Sens 25:2317–2335CrossRef

Ryu J-H, Won J-S, Min KD (2002) ‘Waterline extraction from Landsat TM data in a tidal flat: a case study in Gomso Bay, Korea. Remote Sens Environ 83:442–456CrossRef

Santoro M, Wegmüller U (2013) Multi-temporal synthetic aperture radar metrics applied to map open water bodies. IEEE J Sel Top Appl Earth Observ Remote Sens 7:3225–3238CrossRef

Sarp G, Ozcelik M (2017) Water body extraction and change detection using time series: a case study of Lake Burdur, Turkey. J Taibah Univ Sci 11:381–391CrossRef

Sathianarayanan M (2018) Assessment of surface water dynamics using multiple water indices around Adama woreda, Ethiopia. ISPRS Ann Photogram Remote Sens Spat Inf Sci 4:181–188CrossRef

Sathianarayanan M, Hsu P-H (2023) Spatial downscaling of GPM IMERG V06 gridded precipitation using machine learning algorithms. Int Archiv Photogramm Remote Sens Spat Inf Sci XLVIII-4/W6-2022:327–332. https://doi.org/10.5194/isprs-archives-XLVIII-4-W6-2022-327-2023CrossRef

Sekertekin A, Cicekli SY, Arslan N (2018) Index-based identification of surface water resources using Sentinel-2 satellite imagery. In: 2018 2nd International symposium on multidisciplinary studies and innovative technologies (ISMSIT). IEEE, pp 1–5

Sethre PR, Rundquist BC, Todhunter PE (2005) Remote detection of prairie pothole ponds in the Devils Lake Basin, North Dakota. GIScience Remote Sens 42:277–296CrossRef

Shen G, Fu W (2020) Water body extraction using GF-3 Polsar data—a case study in Poyang Lake. In: IGARSS 2020—2020 IEEE international geoscience and remote sensing symposium, pp 4762–4765

Shen G, Guo H, Liao J (2008) Object oriented method for detection of inundation extent using multi-polarized synthetic aperture radar image. J Appl Remote Sens 2:023512CrossRef

Souza WdO, de Moura Reis LG, Ruiz-Armenteros AM, Veleda D, Neto AR, Fragoso CR Jr, da Silva Pereira Cabral JJ, Montenegro SMGL (2022) Analysis of environmental and atmospheric influences in the use of SAR and optical imagery from sentinel-1, landsat-8, and sentinel-2 in the operational monitoring of reservoir water level. Remote Sens 14:2218CrossRef

Tsyganskaya V, Martinis S, Marzahn P (2019) Flood monitoring in vegetated areas using multitemporal Sentinel-1 data: impact of time series features. Water 11:1938CrossRef

Tulbure MG, Broich M (2013) Spatiotemporal dynamic of surface water bodies using landsat time-series data from 1999 to 2011. ISPRS J Photogramm Remote Sens 79:44–52CrossRef

Wang X, Xie S, Zhang X, Chen C, Guo H, Du J, Duan Z (2018) A robust multi-band water index (MBWI) for automated extraction of surface water from Landsat 8 OLI imagery. Int J Appl Earth Obs Geoinf 68:73–91

Water Resources Agency Ministry of Economic Affairs (2019) Northern Region Water Resources Office. Shimen reservoir introduction. https://www.wranb.gov.tw/. Accessed 4 Nov 2020

Williamson CE, Saros JE, Vincent WF, Smol JP (2009) Lakes and reservoirs as sentinels, integrators, and regulators of climate change. Limnol Oceanogr 54:2273–2282CrossRef

Xie L, Zhang H, Wang C (2015) Water-body types classification using Radarsat-2 fully polarimetric SAR data. In: 2015 IEEE international conference on aerospace electronics and remote sensing technology (ICARES). IEEE, pp 1–5

Xu H (2006) Modification of normalised difference water index (NDWI) to enhance open water features in remotely sensed imagery. Int J Remote Sens 27:3025–3033CrossRef

Title: Intercomparison between sentinel-1, sentinel-2, and landsat-8 on reservoir water level estimation
Authors: Manikandan Sathianarayanan
Ajay Saraswat
A. S. Mohammed Abdul Athick
Hung-Ming Lin
Publication date: 01-12-2023
Publisher: Springer International Publishing
Published in: Sustainable Water Resources Management / Issue 6/2023
Print ISSN: 2363-5037
Electronic ISSN: 2363-5045
DOI: https://doi.org/10.1007/s40899-023-00974-4

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