A simple cloud-filling approach for remote sensing water cover assessments

Mullen, Connor; Penny, Gopal; Müller, Marc F.

doi:10.5194/hess-25-2373-2021

Cited by 12 publications

(7 citation statements)

References 38 publications

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“…Numerous algorithms and datasets have been developed over the last decade focusing on the accurate estimation of surface water dynamics from optical satellite imagery 18 , 58 – 63 . A key requirement to use those algorithms that can classify water where it is occluded due to clouds 24 , 64 , 65 . To detect water mask in every satellite image that intersects with a given reservoir geometry, we first discriminate surface water using NDWI spectral index by applying the method of local thresholding based on the Canny edge detector and a binary version of the Otsu thresholding algorithm 61 , 66 .…”

Section: Methodsmentioning

confidence: 99%

High-resolution surface water dynamics in Earth’s small and medium-sized reservoirs

Donchyts

Winsemius

Baart

et al. 2022

Sci Rep

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Small and medium-sized reservoirs play an important role in water systems that need to cope with climate variability and various other man-made and natural challenges. Although reservoirs and dams are criticized for their negative social and environmental impacts by reducing natural flow variability and obstructing river connections, they are also recognized as important for social and economic development and climate change adaptation. Multiple studies map large dams and analyze the dynamics of water stored in the reservoirs behind these dams, but very few studies focus on small and medium-sized reservoirs on a global scale. In this research, we use multi-annual multi-sensor satellite data, combined with cloud analytics, to monitor the state of small (10–100 ha) to medium-sized (> 100 ha, excluding 479 large ones) artificial water reservoirs globally for the first time. These reservoirs are of crucial importance to the well-being of many societies, but regular monitoring records of their water dynamics are mostly missing. We combine the results of multiple studies to identify 71,208 small to medium-sized reservoirs, followed by reconstructing surface water area changes from satellite data using a novel method introduced in this study. The dataset is validated using 768 daily in-situ water level and storage measurements (r2 > 0.7 for 67% of the reservoirs used for the validation) demonstrating that the surface water area dynamics can be used as a proxy for water storage dynamics in many cases. Our analysis shows that for small reservoirs, the inter-annual and intra-annual variability is much higher than for medium-sized reservoirs worldwide. This implies that the communities reliant on small reservoirs are more vulnerable to climate extremes, both short-term (within seasons) and longer-term (across seasons). Our findings show that the long-term inter-annual and intra-annual changes in these reservoirs are not equally distributed geographically. Through several cases, we demonstrate that this technology can help monitor water scarcity conditions and emerging food insecurity, and facilitate transboundary cooperation. It has the potential to provide operational information on conditions in ungauged or upstream riparian countries that do not share such data with neighboring countries. This may help to create a more level playing field in water resource information globally.

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Section: Methodsmentioning

confidence: 99%

High-resolution surface water dynamics in Earth’s small and medium-sized reservoirs

Donchyts

Winsemius

Baart

et al. 2022

Sci Rep

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“…The accuracy of unsupervised classification is sensitive to the relative number of pixels assigned to each of the two clusters, so the automatic identification of a segmentation threshold can be problematic for images dominated by either land or open water. Following Mullen et al (2021), we addressed this issue by (i) automatically classifying each image using k‐means, (ii) recording the segmentation threshold (i.e., the MNDWI level above which a pixel is classified as water) for each image and (iii) using the median value of the obtained segmentation thresholds to segment all the images.…”

Section: Methodsmentioning

confidence: 99%

“…Yet cloud cover and image quality issues have limited their use for the short spatial and temporal scales that are ecologically relevant for wetlandscapes with ephemeral wetlands. More recently, new gap‐filling algorithms have been proposed with promising ability to detect open water on Landsat images in cloudy weather (Mullen et al, 2021; Schwatke et al, 2019; Zhao & Gao, 2018), but their potential to improve the monitoring of wetlandscape dynamics at the relevant spatial and temporal scales remains to be evaluated. This paper fills this gap by comparing gap‐filled water cover estimates from Landsat to two alternative data sources—namely in situ observations and metric‐resolution imagery—each time focusing on a key application and the most relevant tradeoff.…”

Section: Introductionmentioning

confidence: 99%

“…threshold can be problematic for images dominated by either land or open water. FollowingMullen et al (2021), we addressed this issue by (i) automatically classifying each image using k-means, (ii) recording the segmentation threshold (i.e., the MNDWI level above which a pixel is classified as water) for each image and (iii) using the median value of the obtained segmentation thresholds to segment all the images.We then used the approach described inMullen et al (2021) to transform the three-class images ('masked', 'dry' and 'wet') into binary water extent images('dry' and 'wet'). Note that the 'masked' pixel class includes both the pixels masked by clouds and the pixels with no data due to the scanline corrector failure on Landsat 7 images taken after September 2003.…”

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confidence: 99%

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From wetlands to wetlandscapes: Remote sensing calibration of process‐based hydrological models in heterogeneous landscapes

Mullen

Bertassello

Rao

et al. 2022

Hydrological Processes

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Wetlands are vital components of landscapes that sustain a range of important ecosystem services. Understanding how wetland‐rich landscapes—or wetlandscapes—will evolve under a changing climate and increasing anthropogenic encroachment is urgent. Wetlandscapes are highly heterogeneous, and scaling local modelling insights from individual instrumented wetlands to characterize landscape‐scale dynamics has been a pervasive challenge. We investigate the potential to use water extent information from satellite imagery to calibrate landscape‐scale process‐based hydrological models. Applications to wetlandscapes in the Prairie Pothole Region (PPR) in North Dakota and the Texas Playa Lakes (TPL) shed light on two important trade‐offs. First, in‐situ monitoring provides accurate water extent information on an arbitrary subset of wetlands, whereas satellite imagery captures landscape‐scale hydrological dynamics but suffers persistent water‐detection challenges. Satellite imagery is a superior source of data for model calibration in sparsely monitored and spatially heterogeneous landscapes like the PPR, where the sampling uncertainty of monitored wetlands exceeds the water detection uncertainty of remote sensing. The two data sources are equivalent for more homogeneous landscapes like the TPL. The second tradeoff concerns the spatial resolution and temporal coverage of satellite imagery. In that regard, the 20 years of bi‐weekly images captured by Landsat 7 provides unprecedented insights into the dynamic nature of the ecohydrological characteristics of wetlandscapes, such as seasonal and inter‐annual changes of their metapopulation capacity. In the PPR, the amplitude of these dynamics far exceeds the bias introduced by Landsat's inability to capture ecologically important connectivity details due to its coarse spatial resolution compared to more recent imagery.

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“…Thirdly, the pattern of the temporal filtering from frequency maps in this study can be further extended and applied on different study areas such as vegetation extraction and cloud removal using different datasets such as Landsat series and Sentinel-2 data. The filtering method can be conversely utilized as filling method in cases where the images are missing or severely contaminated, which has been explored in former work [79,80]. Lastly, all the methods can be integrated into an automatic surface water mapping software in order to supply near-real-time and high-quality water inundation products for monitoring.…”

Section: Future Workmentioning

confidence: 99%

Monitoring Surface Water Inundation of Poyang Lake and Dongting Lake in China Using Sentinel-1 SAR Images

et al. 2022

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High-temporal-resolution inundation maps play an important role in surface water monitoring, especially in lake sites where water bodies change tremendously. Synthetic Aperture Radar (SAR) that guarantees a full time-series in monitoring surface water due to its cloud-penetrating capability is preferred in practice. To date, the methods of extracting and analyzing inundation maps of lake sites have been widely discussed, but the method of extracting surface water maps refined by inundation frequency map and the distinction of inundation frequency map from different datasets have not been fully explored. In this study, we leveraged the Google Earth Engine platform to compare and evaluate the effects of a method combining a histogram-based algorithm with a temporal-filtering algorithm in order to obtain high-quality surface water maps. Both algorithms were conducted on Sentinel-1 images over Poyang Lake and Dongting Lake, the two largest lakes in China, respectively. High spatiotemporal time-series analyses of both lakes were implemented between 2017 and 2021, while the inundation frequency maps extracted from Sentinel-1 data were compared with those extracted from Landsat images. It was found that Sentinel-1 can monitor water inundation with a substantially higher accuracy, although minor differences were found between the two sites, with the overall accuracy for Poyang Lake (95.38–98.69%) being higher than that of Dongting Lake (95.05–97.5%). The minimum and maximum water areas for five years were 1232.96 km2 and 3828.36 km2 in Poyang Lake, and 624.7 km2 and 2189.17 km2 in Dongting Lake. Poyang Lake was frequently inundated with 553.03 km2 of permanent water and 3361.39 km2 of seasonal water while Dongting Lake was less frequently inundated with 320.09 km2 of permanent water and 2224.53 km2 of seasonal water. The inundation frequency maps from different data sources had R2 values higher than 0.8, but there were still significant differences between them. The overall inundation frequency values of the Sentinel-1 inundation frequency maps were lower than those of the Landsat inundation frequency maps due to the severe contamination from cloud cover in Landsat imagery, which should be paid attention in practical application.

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A simple cloud-filling approach for remote sensing water cover assessments

Cited by 12 publications

References 38 publications

High-resolution surface water dynamics in Earth’s small and medium-sized reservoirs

High-resolution surface water dynamics in Earth’s small and medium-sized reservoirs

From wetlands to wetlandscapes: Remote sensing calibration of process‐based hydrological models in heterogeneous landscapes

Monitoring Surface Water Inundation of Poyang Lake and Dongting Lake in China Using Sentinel-1 SAR Images

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