Investigating the potential use of Sentinel-1 data for monitoring wetland water level changes in China’s Momoge National Nature Reserve

Chen, Yueqing; Qiao, Si-Jia; Zhang, Guangxin; Xu, Yijun; Chen, Liwen; Lili, Walim

doi:10.7717/peerj.8616

Cited by 21 publications

(16 citation statements)

References 46 publications

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“…1). It was established in 1981 and listed in the National Nature Reserves of China in 1997 and the Ramsar site in 2013 [32]. There are 193 recorded bird species, and over 10 species of national class I protected birds in the MNNR.…”

Section: A Study Areamentioning

confidence: 99%

Mapping Wetland Plant Communities Using Unmanned Aerial Vehicle Hyperspectral Imagery by Comparing Object/Pixel-Based Classifications Combining Multiple Machine-Learning Algorithms

Mao

Wang

et al. 2021

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Understanding the spatial patterns of plant communities is important for sustainable wetland ecosystem management and biodiversity conservation. With the rapid development of unmanned aerial vehicle (UAV) technology, UAV-borne hyperspectral data with high spatial resolution have become ideal for accurate classification of wetland plant communities. In this study, four dominant plant communities (Phragmites australis, Typha orientalis, Suaeda glauca, and Scirpus triqueter) and two unvegetated cover types (water and bare land) in the Momoge Ramsar wetland site were classified. This was achieved using UAV hyperspectral images and three object-and pixel-based machine-learning classification algorithms [random forest (RF), convolutional neural network (CNN), and support vector machine (SVM)]. First, spectral derivative analysis, logarithmic analysis, and continuum removal analysis identified the wavelength at which the greatest difference in reflectance occurs. Second, dimensionality reduction of hyperspectral images was conducted using principal component analysis. Subsequently, an optimal feature combination for community mapping was formed based on data transformation (spectral features, vegetation indices, and principal components). Image objects were

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Section: A Study Areamentioning

confidence: 99%

Mapping Wetland Plant Communities Using Unmanned Aerial Vehicle Hyperspectral Imagery by Comparing Object/Pixel-Based Classifications Combining Multiple Machine-Learning Algorithms

Mao

Wang

et al. 2021

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…The Momoge National Nature Reserve (45 • 42 25 -46 • 18 00 N, 123 • 27 00 -124 • 04 33.7 E) covering an area of 1440 km 2 is located in Zhenlai County, west Jilin Province, Northeast China ( Figure 1). The reserve is known as the main stopover site for rare and endangered migratory birds, such as the Siberian crane (Grus leucogeranus) and oriental white stork (Ciconia ciconia) and was included on the List of Wetlands of International Importance (Ramsar sites) in 2013 [28]. Two large rivers flow through the reserve, the Nenjiang River in the east and the Tao'er River in the south.…”

Section: Study Areamentioning

confidence: 99%

“…The second latest C-band VV polarized SAR mission, Sentinel-1, was launched in 2014. It provides free SAR datasets with a repeat cycle as short as 6-12 days, a coverage range as wide as 250 km, and a spatial resolution as high as 10 m [28], which can greatly improve the spatial and temporal resolution of hydrological connectivity detection, at least relative to MODIS and Landsat. However, so far, few studies have investigated the potential use of backscattering coefficient information of SAR data (e.g., Sentinel-1) in observing surface hydrological connectivity.…”

Section: Introductionmentioning

confidence: 99%

Assessment of Surface Hydrological Connectivity in an Ungauged Multi-Lake System with a Combined Approach Using Geostatistics and Spaceborne SAR Observations

Chen

Lili

Zhang

et al. 2020

Water

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Connectivity metrics for surface water are important for predicting floods and droughts, and improving water management for human use and ecological integrity at the landscape scale. The integrated use of synthetic aperture radar (SAR) observations and geostatistics approach can be useful for developing and quantifying these metrics and their changes, including geostatistical connectivity function (GCF), maximum distance of connection (MDC), surface water extent (SWE), and connection frequency. In this study, we conducted a geostatistical analysis based on 52 wet and dry binary state (i.e., water and non-water) rasters derived from Sentinel-1 A/B GRD products acquired from 2015 to 2019 for China’s Momoge National Nature Reserve to investigate applicability and dynamics of the hydrologic connectivity metrics in an ungauged (i.e., data such as flow and water level are scarce) multi-lake system. We found: (1) generally, the change of GCF in North–South and Northeast–Southwest directions was greater than that in the West–East and Northwest–Southeast directions; (2) MDC had a threshold effect, generally at most 25 km along the W–E, NW–SE and NE–SW directions, and at most 45 km along the N–S direction; (3) the flow paths between lakes are diverse, including channelized flow, diffusive overbank flow, over-road flow and “fill-and-merge”; (4) generally, the values of the three surface hydrological connectivity indicators (i.e., the MDC, the SWE, and the conneciton frequency) all increased from May to August, and decreased from August to October; (5) generally, the closer the distance between the lakes, the greater the connection frequency, but it is also affected by the dam and road barrier. The study demonstrates the usefulness of the geostatistical method combining Sentinel-1 SAR image analysis in quantifying surface hydrological connectivity in an ungagged area. This approach should be applicable for other geographical regions, in order help resource managers and policymakers identify changes in surface hydrological connectivity, as well as address potential impacts of these changes on water resources for human use and/or ecological integrity at the landscape level.

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“…Wetland InSAR is the use of the InSAR technology to detect changes in elevation of aquatic surfaces. This technique works where vegetation emerges above the water surface due to the double bounce effect in which radar pulse is backscattered twice from the water surface and vegetation (Chen et al, 2020; Richards, Woodgate, & Skidmore, 1987). Since interferogram observations are not absolute but relative in value, absolute changes of water level in wetlands can only be computed when combined with stage monitoring or altimeter observations (Hong & Wdowinski, 2014; Kim et al, 2009).…”

Section: Methodsmentioning

confidence: 99%

“…A remote sensing technique termed Wetland interferometric synthetic aperture radar (Wetland InSAR; Wdowinski, Amelung, Miralles-Wilhelm, Dixon, & Carande, 2004) is a complementary radar-based tool of high spatial resolution used to monitor surface hydrological processes in wetlands. Water level changes, sheet flow and water flow have been studied in different regions of the world with this methodology (Chen et al, 2020;Hong, Wdowinski, & Kim, 2010;Kim et al, 2014;Lee, Yuan, Jung, & Beighley, 2015;Palomino-Angel, Anaya-Acevedo, Simard, Liao, & Jaramillo, 2019;Xie, Shao, Xu, Wan, & Fang, 2013;Zhou, Bin, & Li, 2009). Wetland InSAR generates maps representing changes in the water surface, over time, from differences in the phase-path length of two satellite acquisitions, taken from the same orbital position, at the same resolution and over the same region.…”

Section: Introductionmentioning

confidence: 99%

Using InSAR to identify hydrological connectivity and barriers in a highly fragmented wetland

Liu

Wang

Aminjafari

et al. 2020

Hydrological Processes

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Hydrological connectivity is a critical determinant of wetland functions and health, especially in wetlands that have been heavily fragmented and regulated by human activities. However, investigating hydrological connectivity in these wetlands is challenging due to the costs of high-resolution and large-scale monitoring required in order to identify hydrological barriers within the wetlands. To overcome this challenge, we here propose an interferometric synthetic aperture radar (InSAR)-based methodology to map hydrologic connectivity and identify hydrological barriers in fragmented wetlands. This methodology was applied along 70 transects across the Baiyangdian, the largest freshwater wetland in northern China, using Sentinel 1A and 1B data, covering the period 2016-2019. We generated 58 interferograms providing information on relative water level changes across the transects that showed the high coherence needed for the assessment of hydrological connectivity. We mapped the permanent and conditional (temporary) barriers affecting connectivity. In total, 11% of all transects are permanently disconnected by hydrological barriers across all interferograms and 58% of the transects are conditionally disconnected. Areas covered by reed grasslands show the most undisturbed hydrological connectivity while some of these barriers are the result of ditches and channels within the wetland and low water levels during different periods of the year. This study highlights the potential of the application of Wetland InSAR to determine hydrological connectivity and location of hydrological barriers in highly fragmented wetlands, and facilitates the study of hydrological processes from large spatial scales and long-time scales using remote sensing technique.

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Investigating the potential use of Sentinel-1 data for monitoring wetland water level changes in China’s Momoge National Nature Reserve

Cited by 21 publications

References 46 publications

Mapping Wetland Plant Communities Using Unmanned Aerial Vehicle Hyperspectral Imagery by Comparing Object/Pixel-Based Classifications Combining Multiple Machine-Learning Algorithms

Mapping Wetland Plant Communities Using Unmanned Aerial Vehicle Hyperspectral Imagery by Comparing Object/Pixel-Based Classifications Combining Multiple Machine-Learning Algorithms

Assessment of Surface Hydrological Connectivity in an Ungauged Multi-Lake System with a Combined Approach Using Geostatistics and Spaceborne SAR Observations

Using InSAR to identify hydrological connectivity and barriers in a highly fragmented wetland

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