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Next Generation Fire Severity Mapping (Image Service)
The geospatial products described and distributed here depict the probability of high-severity fire, if a fire were to occur, for several ecoregions in the contiguous western US. The ecological effects of wildland fire – also termed the fire severity – are often highly heterogeneous in space and time. This heterogeneity is a result of spatial variability in factors such as fuel, topography, and climate (e.g. mean annual temperature). However, temporally variable factors such as daily weather and climatic extremes (e.g. an unusually warm year) also may play a key role. Scientists from the US Forest Service Rocky Mountain Research Station and the University of Montana conducted a study in which observed data were used to produce statistical models describing the probability of high severity fire as a function of fuel, topography, climate, and fire weather. Observed data from over 2000 fires (from 2002-2015) were used to build individual models for each of 19 ecoregions in the contiguous US (see Parks et al. 2018, Figure 1). High severity fire was measured using a fire severity metric termed the relativized burn ratio, which uses pre- and post-fire Landsat imagery to measure fire-induced ecological change. Fuel included pre-fire metrics of live fuel amount such as NDVI. Topography included factors such as slope and potential solar radiation. Climate summarized 30-year averages of factors such as mean summer temperature that spatially vary across the study area. Lastly, fire weather incorporated temporally variable factors such as daily and annual temperature. In turn, these statistical models were used to generate "wall-to-wall" maps depicting the probability of high severity fire, if a fire were to occur, for 13 of the 19 ecoregions. Maps were not produced for ecoregions in which model quality was deemed inadequate. All maps use fuel data representing the year 2016 and therefore provide a fairly up-to-date assessment of the potential for high severity fire. For those ecoregions in which the relative influence of fire weather was fairly strong (n=6), two additional maps were produced, one depicting the probability of high severity fire under moderate weather and the other under extreme weather. An important consideration is that only pixels defined as forest were used to build the models; consequently maps exclude pixels considered non-forest.
Complete Metadata
| @type | dcat:Dataset |
|---|---|
| accessLevel | public |
| bureauCode |
[
"005:96"
]
|
| contactPoint |
{
"fn": "USFSEnterpriseContent",
"@type": "vcard:Contact",
"hasEmail": "mailto:SM.FS.data@usda.gov"
}
|
| description | <div style='text-align:Left;'><div><div><p><span>The geospatial products described and distributed here depict the probability of high-severity fire, if a fire were to occur, for several ecoregions in the contiguous western US. </span></p><p><span>The ecological effects of wildland fire – also termed the fire severity – are often highly heterogeneous in space and time. This heterogeneity is a result of spatial variability in factors such as fuel, topography, and climate (e.g. mean annual temperature). However, temporally variable factors such as daily weather and climatic extremes (e.g. an unusually warm year) also may play a key role. </span></p><p><span>Scientists from the US Forest Service Rocky Mountain Research Station and the University of Montana conducted a study in which observed data were used to produce statistical models describing the probability of high severity fire as a function of fuel, topography, climate, and fire weather. Observed data from over 2000 fires (from 2002-2015) were used to build individual models for each of 19 ecoregions in the contiguous US (see Parks et al. 2018, Figure 1). High severity fire was measured using a fire severity metric termed the relativized burn ratio, which uses pre- and post-fire Landsat imagery to measure fire-induced ecological change. Fuel included pre-fire metrics of live fuel amount such as NDVI. Topography included factors such as slope and potential solar radiation. Climate summarized 30-year averages of factors such as mean summer temperature that spatially vary across the study area. Lastly, fire weather incorporated temporally variable factors such as daily and annual temperature. </span></p><p><span>In turn, these statistical models were used to generate "wall-to-wall" maps depicting the probability of high severity fire, if a fire were to occur, for 13 of the 19 ecoregions. Maps were not produced for ecoregions in which model quality was deemed inadequate. All maps use fuel data representing the year 2016 and therefore provide a fairly up-to-date assessment of the potential for high severity fire. For those ecoregions in which the relative influence of fire weather was fairly strong (n=6), two additional maps were produced, one depicting the probability of high severity fire under moderate weather and the other under extreme weather. An important consideration is that only pixels defined as forest were used to build the models; consequently maps exclude pixels considered non-forest.</span></p></div></div></div> |
| distribution |
[
{
"@type": "dcat:Distribution",
"title": "ArcGIS Hub Dataset",
"format": "Web Page",
"accessURL": "https://data-usfs.hub.arcgis.com/datasets/usfs::next-generation-fire-severity-mapping-image-service",
"mediaType": "text/html"
},
{
"@type": "dcat:Distribution",
"title": "ArcGIS GeoService",
"format": "ArcGIS GeoServices REST API",
"accessURL": "https://imagery.geoplatform.gov/iipp/rest/services/Fire_Aviation/USFS_EDW_RMRS_NextGenerationFireSeverityMapping/ImageServer",
"mediaType": "application/json"
},
{
"@type": "dcat:Distribution",
"title": "ISO-19139 metadata",
"accessURL": "https://www.arcgis.com/sharing/rest/content/items/870b0a1777d5455faab124e7db96824b/info/metadata/metadata.xml?format=iso19139",
"mediaType": "text/xml",
"conformsTo": "https://www.isotc211.org/2005/gmi"
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|
| identifier | https://www.arcgis.com/home/item.html?id=870b0a1777d5455faab124e7db96824b |
| issued | 2019-03-26 |
| keyword |
[
"Apache Highlands",
"Arizona",
"Arizona-New Mexico Mountains",
"California",
"California North Coast",
"California South Coast",
"Canadian Rockies",
"Colorado",
"Colorado Plateau",
"Fire",
"Fire ecology",
"Fire effects in the environment",
"Great Basin",
"JFSP",
"Joint Fire Science Program",
"Middle Rockies",
"New Mexico",
"Southern Rockies",
"Utah",
"Utah High Plateaus",
"Utah-Wyoming Rockies",
"West Cascades",
"Wyoming",
"burn severity",
"environment",
"fire effects",
"fire severity",
"western contiguous United States",
"wildland fire"
]
|
| landingPage | https://data-usfs.hub.arcgis.com/datasets/usfs::next-generation-fire-severity-mapping-image-service |
| license | https://creativecommons.org/licenses/by/4.0/ |
| modified | 2025-08-29 |
| programCode |
[
"005:059"
]
|
| progressCode | onGoing |
| publisher |
{
"name": "U.S. Forest Service",
"source": "U.S. Forest Service"
}
|
| spatial | -125.2238,30.5511,-103.9652,50.5383 |
| theme |
[
"geospatial"
]
|
| title | Next Generation Fire Severity Mapping (Image Service) |
