Mapping the annual area burned in the wetlands of the Okavango panhandle using a hierarchical classification approach

Cassidy, Lin

doi:10.1007/s11273-006-9026-2

Cited by 14 publications

(8 citation statements)

References 38 publications

(45 reference statements)

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“…In this effort, we used a machine learning algorithm, trained on wetland fires, to map burned area extent (2016-2019), using the Sentinel-2 archive across Florida, as well as parts of Alabama, Georgia, and South Carolina. Burned area in wetlands can go undetected when a burned area is visible but omitted by a burned area algorithm due to low burn severity, burnable wetlands being masked out, or an atypical burn signal [11,38]. Burned area in wetlands can also go undetected when the burned area was never visible during image collection dates because of rapid vegetation recovery and cloud cover [25,26].…”

Section: Discussionmentioning

confidence: 99%

“…In wetlands, using satellites that provide shortwave infrared bands may be especially important. As water levels rise in vegetated wetlands, the spectral reflectance in the NIR declines [38], meaning that saturated wetlands can look very similar to burned areas. Even NBR, however, tends to perform less consistently in unforested areas [73], where the index may respond more to soil wetness than plant coverage [12].…”

Section: Discussionmentioning

confidence: 99%

“…Even NBR, however, tends to perform less consistently in unforested areas [73], where the index may respond more to soil wetness than plant coverage [12]. Using Landsat satellites, indices that incorporated the thermal band were found to reduce confusion [34,38]. For sensors that lack the thermal band, such as Sentinel-2, we demon-strated that ancillary sources of data, such as GRIDMET standardized precipitation index can potentially help the algorithm identify when darker-than-normal ground conditions may be attributed to an increase in wetness instead of a burn event.…”

Section: Discussionmentioning

confidence: 99%

“…Efforts to remotely track wetland fires have predominantly mapped and tracked post-fire spectral recovery within known wetland burn perimeters [12,[35][36][37]. Meanwhile, efforts to find and map wetland fires with satellite imagery, alone, have been very limited and have primarily relied on unsupervised classification approaches [11,38]. The probability of mapping wetland fires will depend in part on the persistence of the burn signal, which can be much shorter for wetlands relative to upland forests, and shorter for wet and warm southeastern ecosystems, relative to drier western ecosystems (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Mapping Wetland Burned Area from Sentinel-2 across the Southeastern United States and Its Contributions Relative to Landsat-8 (2016–2019)

Vanderhoof

Hawbaker

Teske

et al. 2021

Fire

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Prescribed fires and wildfires are common in wetland ecosystems across the Southeastern United States. However, the wetland burned area has been chronically underestimated across the region due to (1) spectral confusion between open water and burned area, (2) rapid post-fire vegetation regrowth, and (3) high annual precipitation limiting clear-sky satellite observations. We developed a machine learning algorithm specifically for burned area in wetlands, and applied the algorithm to the Sentinel-2 archive (2016–2019) across the Southeastern US (>290,000 km2). Combining Landsat-8 imagery with Sentinel-2 increased the annual clear-sky observation count from 17 to 46 in 2016 and from 16 to 78 in 2019. When validated with WorldView imagery, the Sentinel-2 burned area had a 29% and 30% omission and commission rates of error for burned area, respectively, compared to the US Geological Survey Landsat-8 Burned Area Product (L8 BA), which had a 47% and 8% omission and commission rate of error, respectively. The Sentinel-2 algorithm and the L8 BA mapped burned area within 78% and 60% of wetland fire perimeters (n = 555) compiled from state and federal agencies, respectively. This analysis demonstrated the potential of Sentinel-2 to support efforts to track the burned area, especially across challenging ecosystem types, such as wetlands.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mapping Wetland Burned Area from Sentinel-2 across the Southeastern United States and Its Contributions Relative to Landsat-8 (2016–2019)

Vanderhoof

Hawbaker

Teske

et al. 2021

Fire

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“…Charcoal accumulations are lower from 400 to 500 yr BP to the present at both Kanderi and Tsavo (Gillson, 2004) and at Esambu, Amboseli (Githumbi et al, 2018b). The differing signals in charcoal accumulation highlight local-scale fuel and fire responses, the spatial heterogeneity of savannah fire regimes, the understudied complexities of fire regimes at savannah-wetland edges (Kirby et al, 1988; Kirkman, 1995; Casanova and Brock, 2000; Cassidy, 2007; Nielsen et al, 2013; Saintilan and Rogers, 2015), and more broadly the role of human activities in and around wetlands (Seki et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

A 3000-year record of vegetation changes and fire at a high-elevation wetland on Kilimanjaro, Tanzania

et al. 2020

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Kilimanjaro is experiencing the consequences of climate change and multiple land-use pressures. Few paleoenvironmental and archeological records exist to examine historical patterns of late Holocene ecosystem changes on Kilimanjaro. Here we present pollen, phytolith, and charcoal (>125 μm) data from a palustrine sediment core that provide a 3000-year radiocarbon-dated record collected from a wetland near the headwaters of the Maua watershed in the alpine and ericaceous vegetation zones. From 3000 to 800 cal yr BP, the pollen, phytolith, and charcoal records show subtle variability in ericaceous and montane forest assemblages with apparent multicentennial secular variability and a long-term pattern of increasing Poaceae and charcoal. From 800 to 600 cal yr BP, montane forest taxa varied rapidly, Cyperaceae abundances increased, and charcoal remained distinctly low. From 600 yr cal BP to the present, woody taxa decreased, and ericaceous taxa and Poaceae dominated, with a conspicuously increased charcoal influx. Uphill wetland ecosystems are crucial for ecological and socioeconomic resilience on and surrounding the mountain. The results were synthesized with the existing paleoenvironmental and archaeological data to explore the high spatiotemporal complexity of Kilimanjaro and to understand historical human-environment interactions. These paleoenvironmental records create a long-term context for current climate, biodiversity, and land-use changes on and around Kilimanjaro.

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Variable-source flood pulsing in a semi-arid transboundary watershed: the Chobe River, Botswana and Namibia

Pricope

2012

Environ Monit Assess

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The Chobe River, characterized by an unusual flood pulsing regime and shared between Botswana and Namibia, lies at the heart of the world's largest transfrontier conservation area (the Kavango-Zambezi Transfrontier Conservation Area). Significant ecological changes and vegetation conversions are occurring along its floodplains. Various scenarios for agricultural and urban water use are currently being proposed by the government of Botswana. However, the understanding of the river's annual flow regime and timing of the relative contributions of water from three different sources is relatively poor. In light of past and future climate change and variability, this means that allocating water between ecological flows and economic and domestic uses will become increasingly challenging. We reconstruct the inundation history in this basin to help ease this challenge. This paper presents a spatiotemporal approach to estimate the contribution of water from various sources and the magnitude of changes in the flooding extent in the basin between 1985 and 2010. We used time series analysis of bimonthly NOAA AVHRR and NASA MODIS data and climatologic and hydrologic records to determine the flooding timing and extent. The results indicate that between 12 and 62 % of the basin is flooded on an annual basis and that the spatial extent of the flooding varies throughout the year as a function of the timing of peak discharge in two larger basins. A 30-year trend analysis indicates a consistent decline in the average monthly flooded area in the basin. The results may prove useful in future water utilization feasibility studies, in determining measures for protecting ecological flows and levels, and in ecosystem dynamics studies in the context of current and future climate change and variability.

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Mapping the annual area burned in the wetlands of the Okavango panhandle using a hierarchical classification approach

Cited by 14 publications

References 38 publications

Mapping Wetland Burned Area from Sentinel-2 across the Southeastern United States and Its Contributions Relative to Landsat-8 (2016–2019)

Mapping Wetland Burned Area from Sentinel-2 across the Southeastern United States and Its Contributions Relative to Landsat-8 (2016–2019)

A 3000-year record of vegetation changes and fire at a high-elevation wetland on Kilimanjaro, Tanzania

Variable-source flood pulsing in a semi-arid transboundary watershed: the Chobe River, Botswana and Namibia

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