Dataset Identification:
Resource Abstract:
- description: This raster represents a continuous surface of sage-grouse habitat suitability index (HSI, created using ArcGIS
10.2.2) values for Nevada during spring, which is a surrogate for habitat conditions during the sage-grouse breeding and nesting
period. Summary of steps to create Habitat Categories: HABITAT SUITABILITY INDEX: The HSI was derived from a generalized linear
mixed model (specified by binomial distribution) that contrasted data from multiple environmental factors at used sites (telemetry
locations) and available sites (random locations). Predictor variables for the model represented vegetation communities at
multiple spatial scales, water resources, habitat configuration, urbanization, roads, elevation, ruggedness, and slope. Vegetation
data was derived from various mapping products, which included NV SynthMap (Petersen 2008, SageStitch (Comer et al. 2002,
LANDFIRE (Landfire 2010), and the CA Fire and Resource Assessment Program (CFRAP 2006). The analysis was updated to include
high resolution percent cover within 30 x 30 m pixels for Sagebrush, non-sagebrush, herbaceous vegetation, and bare ground
(C. Homer, unpublished; based on the methods of Homer et al. 2014, Xian et al. 2015 ) and conifer (primarily pinyon-juniper,
P. Coates, unpublished). The pool of telemetry data included the same data from 1998 - 2013 used by Coates et al. (2014);
additional telemetry location data from field sites in 2014 were added to the dataset. The dataset was then split according
calendar date into three seasons (spring, summer, winter). Summer included telemetry locations (n = 14,058) from mid-March
to June. All age and sex classes of marked grouse were used in the analysis. Sufficient data (i.e., a minimum of 100 locations
from at least 20 marked Sage-grouse) for modeling existed in 10 subregions for spring and summer, and seven subregions in
winter, using all age and sex classes of marked grouse. It is important to note that although this map is composed of HSI
values derived from the seasonal data, it does not explicitly represent habitat suitability for reproductive females (i.e.,
nesting and with broods). Insufficient data were available to allow for estimation of this habitat type for all seasons throughout
the study area extent. A Resource Selection Function (RSF) was calculated using R Software (v 3.13) for each subregion and
using generalized linear models to derive model-averaged parameter estimates for each covariate across a set of additive models.
Subregional RSFs were transformed into Habitat Suitability Indices, and averaged together to produce an overall statewide
HSI whereby a relative probability of occurrence was calculated for each raster cell during the spring. In order to account
for discrepancies in HSI values caused by varying ecoregions within Nevada, the HSI was divided into north and south extents
using a slightly modified flood region boundary (Mason 1999) that was designed to represent respective mesic and xeric regions
of the state. North and south HSI rasters were each relativized according to their maximum value to rescale between zero and
one, then mosaicked once more into a state-wide extent. REFERENCES: California Forest and Resource Assessment Program (CFRAP).
2006. Statewide Land Use / Land Cover Mosaic. [Geospatial data.] California Department of Forestry and Fire Protection, http://frap.cdf.ca.gov/data/frapgisdata-sw-rangeland-assessment_data.php
Census 2010. TIGER/Line Shapefiles. Urban Areas [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html
Census 2014. TIGER/Line Shapefiles. Roads [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html
Census 2015. TIGER/Line Shapefiles. Blocks [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html
Coates, P.S., Casazza, M.L., Brussee, B.E., Ricca, M.A., Gustafson, K.B., Overton, C.T., Sanchez-Chopitea, E., Kroger, T.,
Mauch, K., Niell, L., Howe, K., Gardner, S., Espinosa, S., and Delehanty, D.J. 2014, Spatially explicit modeling of greater
sage-grouse (Centrocercus urophasianus) habitat in Nevada and northeastern CaliforniaA decision-support tool for management:
U.S. Geological Survey Open-File Report 2014-1163, 83 p., http://dx.doi.org/10.3133/ofr20141163. ISSN 2331-1258 (online) Comer,
P., Kagen, J., Heiner, M., and Tobalske, C. 2002. Current distribution of sagebrush and associated vegetation in the western
United States (excluding NM). [Geospatial data.] Interagency Sagebrush Working Group, http://sagemap.wr.usgs.gov Homer, C.G.,
Aldridge, C.L., Meyer, D.K., and Schell, S.J. 2014. Multi-Scale Remote Sensing Sagebrush Characterization with Regression
Trees over Wyoming, USA; Laying a Foundation for Monitoring. International Journal of Applied Earth Observation and Geoinformation
14, Elsevier, US. LANDFIRE. 2010. 1.2.0 Existing Vegetation Type Layer. [Geospatial data.] U.S. Department of the Interior,
Geological Survey, http://landfire.cr.usgs.gov/viewer/ Mason, R.R. 1999. The National Flood-Frequency ProgramMethods For Estimating
Flood Magnitude And Frequency In Rural Areas In Nevada U.S. Geological Survey Fact Sheet 123-98 September, 1999, Prepared
by Robert R. Mason, Jr. and Kernell G. Ries III, of the U.S. Geological Survey; and Jeffrey N. King and Wilbert O. Thomas,
Jr., of Michael Baker, Jr., Inc. http://pubs.usgs.gov/fs/fs-123-98/ Peterson, E. B. 2008. A Synthesis of Vegetation Maps for
Nevada (Initiating a 'Living' Vegetation Map). Documentation and geospatial data, Nevada Natural Heritage Program,
Carson City, Nevada, http://www.heritage.nv.gov/gis Xian, G., Homer, C., Rigge, M., Shi, H., and Meyer, D. 2015. Characterization
of shrubland ecosystem components as continuous fields in the northwest United States. Remote Sensing of Environment 168:286-300.
NOTE: This file does not include habitat areas for the Bi-State management area and the spatial extent is modified in comparison
to Coates et al. 2014; abstract: This raster represents a continuous surface of sage-grouse habitat suitability index (HSI,
created using ArcGIS 10.2.2) values for Nevada during spring, which is a surrogate for habitat conditions during the sage-grouse
breeding and nesting period. Summary of steps to create Habitat Categories: HABITAT SUITABILITY INDEX: The HSI was derived
from a generalized linear mixed model (specified by binomial distribution) that contrasted data from multiple environmental
factors at used sites (telemetry locations) and available sites (random locations). Predictor variables for the model represented
vegetation communities at multiple spatial scales, water resources, habitat configuration, urbanization, roads, elevation,
ruggedness, and slope. Vegetation data was derived from various mapping products, which included NV SynthMap (Petersen 2008,
SageStitch (Comer et al. 2002, LANDFIRE (Landfire 2010), and the CA Fire and Resource Assessment Program (CFRAP 2006). The
analysis was updated to include high resolution percent cover within 30 x 30 m pixels for Sagebrush, non-sagebrush, herbaceous
vegetation, and bare ground (C. Homer, unpublished; based on the methods of Homer et al. 2014, Xian et al. 2015 ) and conifer
(primarily pinyon-juniper, P. Coates, unpublished). The pool of telemetry data included the same data from 1998 - 2013 used
by Coates et al. (2014); additional telemetry location data from field sites in 2014 were added to the dataset. The dataset
was then split according calendar date into three seasons (spring, summer, winter). Summer included telemetry locations (n
= 14,058) from mid-March to June. All age and sex classes of marked grouse were used in the analysis. Sufficient data (i.e.,
a minimum of 100 locations from at least 20 marked Sage-grouse) for modeling existed in 10 subregions for spring and summer,
and seven subregions in winter, using all age and sex classes of marked grouse. It is important to note that although this
map is composed of HSI values derived from the seasonal data, it does not explicitly represent habitat suitability for reproductive
females (i.e., nesting and with broods). Insufficient data were available to allow for estimation of this habitat type for
all seasons throughout the study area extent. A Resource Selection Function (RSF) was calculated using R Software (v 3.13)
for each subregion and using generalized linear models to derive model-averaged parameter estimates for each covariate across
a set of additive models. Subregional RSFs were transformed into Habitat Suitability Indices, and averaged together to produce
an overall statewide HSI whereby a relative probability of occurrence was calculated for each raster cell during the spring.
In order to account for discrepancies in HSI values caused by varying ecoregions within Nevada, the HSI was divided into north
and south extents using a slightly modified flood region boundary (Mason 1999) that was designed to represent respective mesic
and xeric regions of the state. North and south HSI rasters were each relativized according to their maximum value to rescale
between zero and one, then mosaicked once more into a state-wide extent. REFERENCES: California Forest and Resource Assessment
Program (CFRAP). 2006. Statewide Land Use / Land Cover Mosaic. [Geospatial data.] California Department of Forestry and Fire
Protection, http://frap.cdf.ca.gov/data/frapgisdata-sw-rangeland-assessment_data.php Census 2010. TIGER/Line Shapefiles. Urban
Areas [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html Census
2014. TIGER/Line Shapefiles. Roads [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html
Census 2015. TIGER/Line Shapefiles. Blocks [Geospatial data.] U.S. Census Bureau, Washington D.C., https://www.census.gov/geo/maps-data/data/tiger-line.html
Coates, P.S., Casazza, M.L., Brussee, B.E., Ricca, M.A., Gustafson, K.B., Overton, C.T., Sanchez-Chopitea, E., Kroger, T.,
Mauch, K., Niell, L., Howe, K., Gardner, S., Espinosa, S., and Delehanty, D.J. 2014, Spatially explicit modeling of greater
sage-grouse (Centrocercus urophasianus) habitat in Nevada and northeastern CaliforniaA decision-support tool for management:
U.S. Geological Survey Open-File Report 2014-1163, 83 p., http://dx.doi.org/10.3133/ofr20141163. ISSN 2331-1258 (online) Comer,
P., Kagen, J., Heiner, M., and Tobalske, C. 2002. Current distribution of sagebrush and associated vegetation in the western
United States (excluding NM). [Geospatial data.] Interagency Sagebrush Working Group, http://sagemap.wr.usgs.gov Homer, C.G.,
Aldridge, C.L., Meyer, D.K., and Schell, S.J. 2014. Multi-Scale Remote Sensing Sagebrush Characterization with Regression
Trees over Wyoming, USA; Laying a Foundation for Monitoring. International Journal of Applied Earth Observation and Geoinformation
14, Elsevier, US. LANDFIRE. 2010. 1.2.0 Existing Vegetation Type Layer. [Geospatial data.] U.S. Department of the Interior,
Geological Survey, http://landfire.cr.usgs.gov/viewer/ Mason, R.R. 1999. The National Flood-Frequency ProgramMethods For Estimating
Flood Magnitude And Frequency In Rural Areas In Nevada U.S. Geological Survey Fact Sheet 123-98 September, 1999, Prepared
by Robert R. Mason, Jr. and Kernell G. Ries III, of the U.S. Geological Survey; and Jeffrey N. King and Wilbert O. Thomas,
Jr., of Michael Baker, Jr., Inc. http://pubs.usgs.gov/fs/fs-123-98/ Peterson, E. B. 2008. A Synthesis of Vegetation Maps for
Nevada (Initiating a 'Living' Vegetation Map). Documentation and geospatial data, Nevada Natural Heritage Program,
Carson City, Nevada, http://www.heritage.nv.gov/gis Xian, G., Homer, C., Rigge, M., Shi, H., and Meyer, D. 2015. Characterization
of shrubland ecosystem components as continuous fields in the northwest United States. Remote Sensing of Environment 168:286-300.
NOTE: This file does not include habitat areas for the Bi-State management area and the spatial extent is modified in comparison
to Coates et al. 2014
Citation
- Title Spring Season Habitat Suitability Index raster.
-
- creation Date
2018-05-21T09:30:00.912554
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Metadata data stamp:
2018-08-06T20:52:49Z
Resource Maintenance Information
- maintenance or update frequency:
- notes: This metadata record was generated by an xslt transformation from a dc metadata record; Transform by Stephen M. Richard, based
on a transform by Damian Ulbricht. Run on 2018-08-06T20:52:49Z
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pointOfContact
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CINERGI Metadata catalog
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eng
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ISO 19139 Geographic Information - Metadata - Implementation Specification
standard version:
2007
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urn:dciso:metadataabout:55460d2c-a95e-48e8-9e13-45eeeb6b4893
Metadata record format is ISO19139 XML (MD_Metadata)