Sub-Pixel Waterline Extraction: Characterising Accuracy and Sensitivity to Indices and Spectra

Bishop‐Taylor, Robbi; Sagar, Stephen M.; Lymburner, Leo; Alam, Imam; Sixsmith, Joshua

doi:10.3390/rs11242984

Cited by 70 publications

(41 citation statements)

References 66 publications

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“…(b) Modeled tide levels associated with the satellite‐derived shorelines (black line). The gray shaded area indicates the overall tidal fluctuations, noting that the vertical bias here is due to the sun‐synchronous orbit of Landsat satellites (refer to Bishop‐Taylor, Sagar, Lymburner, Alam, & Sixsmith, 2019). (c) Ensemble of tidally corrected time series of shoreline change using slope values ranging from 0.01 (red) to 0.2 (green).…”

Section: Methodsmentioning

confidence: 99%

Beach Slopes From Satellite‐Derived Shorelines

Vos

Harley

Splinter

et al. 2020

Geophysical Research Letters

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The steepness of the beach face is a fundamental parameter for coastal morphodynamic research. Despite its importance, it remains extremely difficult to obtain reliable estimates of the beach‐face slope over large spatial scales (thousands of km of coastline). In this letter, a novel approach to estimate this slope from time series of satellite‐derived shoreline positions is presented. This new technique uses a frequency domain analysis to find the optimum slope that minimizes high‐frequency tidal fluctuations relative to lower‐frequency erosion/accretion signals. A detailed assessment of this new approach at eight locations spanning a range of tidal regimes, wave climates, and sediment grain sizes shows strong agreement (R2 = 0.93) with field measurements. The automated technique is then applied across thousands of beaches in eastern Australia and California, USA, revealing similar regional‐scale distributions along these two contrasting coastlines and highlights the potential for new global‐scale insight to beach‐face slope spatial distribution, variability, and trends.

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Section: Methodsmentioning

confidence: 99%

Beach Slopes From Satellite‐Derived Shorelines

Vos

Harley

Splinter

et al. 2020

Geophysical Research Letters

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“…This is because water management decisions are typically based on waterbodies (dams, lakes, river reaches, refugial pools) rather than pixels. Waterbody mapping with satellite imagery has almost exclusively been done on a pixel-by-pixel [12,13,18,20,21,23,24] (or sub-pixel [25][26][27][28] basis), with only a few studies delineating waterbodies as vector objects [29][30][31][32]. The delineation of waterbodies provides an object-based analysis, which characterises the dynamics of the whole waterbody, not its individual pixels.…”

Section: Introductionmentioning

confidence: 99%

“…Since DEA Waterbodies uses an automatic workflow utilising Landsat data to objectively map waterbodies, we have chosen to leave the final waterbody line work pixelated to transparently identify which Landsat pixels have been mapped inside (and outside) of each waterbody (Figure 12). Future iterations of DEA Waterbodies could make use of sub-pixel methods [25][26][27][28] or higher resolution imagery to better capture the true waterbody shape.…”

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confidence: 99%

Mapping and Monitoring the Multi-Decadal Dynamics of Australia’s Open Waterbodies Using Landsat

et al. 2021

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Water detection algorithms are now being routinely applied to continental and global archives of satellite imagery. However, water resource management decisions typically take place at the waterbody rather than pixel scale. Here, we present a workflow for generating polygons of persistent waterbodies from Landsat observations, enabling improved monitoring and management of water assets across Australia. We use Digital Earth Australia’s (DEA) Water Observations from Space (WOfS) product, which provides a water classified output for every available Landsat scene, to determine the spatial locations and extents of waterbodies across Australia. We generated a polygon set of waterbodies that identified 295,906 waterbodies ranging in size from 3125 m2 to 4820 km2. Each polygon was used to generate a time series of WOfS, providing a history of the change in surface area of each waterbody every ~16 days since 1987. We demonstrate the applications of this new dataset, DEA Waterbodies, to understanding local through to national-scale surface water spatio-temporal dynamics. DEA Waterbodies provides new insights into Australia’s water availability and enables the monitoring of important landscape features such as lakes and dams, improving our ability to use earth observation data to make meaningful decisions.

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“…Many methods are used to measure hydrologic variation in waterbodies smaller than a single Landsat pixel (i.e. sub‐pixel methods), including regression trees (Rover et al, 2010; Huang et al, 2014; Jin et al, 2017), discrete particle swarm optimization (Li et al, 2015), Dynamic Surface Water Extent (DeVries et al, 2017; Jones, 2019), and spectral unmixing methods (Halabisky et al, 2016; Liu et al, 2017; Bishop‐Taylor et al, 2019; Hong et al, 2019). Linear spectral mixture analysis, a spectral unmixing technique, estimates the relative abundance of individual components (spectral endmembers) on a pixel‐by‐pixel basis based on their unique spectral characteristics (Hu et al, 1999; Heinz and Chang, 2001), so fractional abundances can be converted to surface areas (Halabisky et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Estimating inundation of small waterbodies with sub‐pixel analysis of Landsat imagery: long‐term trends in surface water area and evaluation of common drought indices

Sall

Jarchow

Sigafus

et al. 2020

Remote Sens Ecol Conserv

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Small waterbodies are numerically dominant in many landscapes and provide several important ecosystem services, but automated measurement of waterbodies smaller than a standard Landsat pixel (0.09 ha) remains challenging. To further evaluate sub‐Landsat pixel techniques for estimating inundation extent of small waterbodies (basin area: 0.06–1.79 ha), we used a partial spectral unmixing method with matched filtering applied to September 1985–2018 Landsat 5 and eight imagery from southern Arizona, USA. We estimated trends in modeled surface water area each September and evaluated the ability of several common drought indices to explain variation in mean water area. Our methods accurately classified waterbodies as dry or inundated (Landsat 5: 91.3%; Landsat 8: 98.9%) and modeled and digitized surface water areas were strongly correlated (R2 = 0.70–0.92; bias = −0.024 to −0.015 ha). Estimated surface water area was best explained by the 3‐month seasonal standardized precipitation index (SPI03; July‒September). We found a wide range of estimated relationships between drought indices (e.g. SPI vs. Palmer Drought Severity Index) and estimated water area, even for different durations of the same drought index (e.g. SPI01 vs. SPI12). Mean waterbody surface area decreased by ~14% from September 1985 to September 2018, which matches declines in local annual precipitation and regional trends of reduced inundation extent of larger waterbodies. These results emphasize the importance of understanding local systems when relying on drought indices to infer variation in past or future surface water dynamics. Several challenges remain before widespread application of sub‐pixel methods is feasible, but our results provide further evidence that partial spectral unmixing with matched filtering provides reliable measures of inundation extent of small waterbodies.

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Sub-Pixel Waterline Extraction: Characterising Accuracy and Sensitivity to Indices and Spectra

Cited by 70 publications

References 66 publications

Beach Slopes From Satellite‐Derived Shorelines

Beach Slopes From Satellite‐Derived Shorelines

Mapping and Monitoring the Multi-Decadal Dynamics of Australia’s Open Waterbodies Using Landsat

Estimating inundation of small waterbodies with sub‐pixel analysis of Landsat imagery: long‐term trends in surface water area and evaluation of common drought indices

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