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Downscaling land-use data to provide global 30″ estimates of five land-use classes

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Downscaling land-use data to provide global 30″ estimates of five land-use classes. / Hoskins, Andrew J.; Bush, Alex; Gilmore, James et al.
In: Ecology and Evolution, Vol. 6, No. 9, 01.05.2016, p. 3040-3055.

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Harvard

Hoskins, AJ, Bush, A, Gilmore, J, Harwood, T, Hudson, LN, Ware, C, Williams, KJ & Ferrier, S 2016, 'Downscaling land-use data to provide global 30″ estimates of five land-use classes', Ecology and Evolution, vol. 6, no. 9, pp. 3040-3055. https://doi.org/10.1002/ece3.2104

APA

Hoskins, A. J., Bush, A., Gilmore, J., Harwood, T., Hudson, L. N., Ware, C., Williams, K. J., & Ferrier, S. (2016). Downscaling land-use data to provide global 30″ estimates of five land-use classes. Ecology and Evolution, 6(9), 3040-3055. https://doi.org/10.1002/ece3.2104

Vancouver

Hoskins AJ, Bush A, Gilmore J, Harwood T, Hudson LN, Ware C et al. Downscaling land-use data to provide global 30″ estimates of five land-use classes. Ecology and Evolution. 2016 May 1;6(9):3040-3055. Epub 2016 Mar 30. doi: 10.1002/ece3.2104

Author

Hoskins, Andrew J. ; Bush, Alex ; Gilmore, James et al. / Downscaling land-use data to provide global 30″ estimates of five land-use classes. In: Ecology and Evolution. 2016 ; Vol. 6, No. 9. pp. 3040-3055.

Bibtex

@article{6c547e4d9fd84f0fa7cb3d7391ebbd3a,
title = "Downscaling land-use data to provide global 30″ estimates of five land-use classes",
abstract = "Land‐use change is one of the biggest threats to biodiversity globally. The effects of land use on biodiversity manifest primarily at local scales which are not captured by the coarse spatial grain of current global land‐use mapping. Assessments of land‐use impacts on biodiversity across large spatial extents require data at a similar spatial grain to the ecological processes they are assessing. Here, we develop a method for statistically downscaling mapped land‐use data that combines generalized additive modeling and constrained optimization. This method was applied to the 0.5° Land‐use Harmonization data for the year 2005 to produce global 30″ (approx. 1 km2) estimates of five land‐use classes: primary habitat, secondary habitat, cropland, pasture, and urban. The original dataset was partitioned into 61 bio‐realms (unique combinations of biome and biogeographical realm) and downscaled using relationships with fine‐grained climate, land cover, landform, and anthropogenic influence layers. The downscaled land‐use data were validated using the PREDICTS database and the geoWiki global cropland dataset. Application of the new method to all 61 bio‐realms produced global fine‐grained layers from the 2005 time step of the Land‐use Harmonization dataset. Coarse‐scaled proportions of land use estimated from these data compared well with those estimated in the original datasets (mean R2: 0.68 ± 0.19). Validation with the PREDICTS database showed the new downscaled land‐use layers improved discrimination of all five classes at PREDICTS sites (P < 0.0001 in all cases). Additional validation of the downscaled cropping layer with the geoWiki layer showed an R2 improvement of 0.12 compared with the Land‐use Harmonization data. The downscaling method presented here produced the first global land‐use dataset at a spatial grain relevant to ecological processes that drive changes in biodiversity over space and time. Integrating these data with biodiversity measures will enable the reporting of land‐use impacts on biodiversity at a finer resolution than previously possible. Furthermore, the general method presented here could be useful to others wishing to downscale similarly constrained coarse‐resolution data for other environmental variables.",
keywords = "Constrained optimization, global change, land cover, land use, landscape modification, statistical downscaling",
author = "Hoskins, {Andrew J.} and Alex Bush and James Gilmore and Tom Harwood and Hudson, {Lawrence N.} and Chris Ware and Williams, {Kristen J.} and Simon Ferrier",
year = "2016",
month = may,
day = "1",
doi = "10.1002/ece3.2104",
language = "English",
volume = "6",
pages = "3040--3055",
journal = "Ecology and Evolution",
issn = "2045-7758",
publisher = "John Wiley and Sons Ltd",
number = "9",

}

RIS

TY - JOUR

T1 - Downscaling land-use data to provide global 30″ estimates of five land-use classes

AU - Hoskins, Andrew J.

AU - Bush, Alex

AU - Gilmore, James

AU - Harwood, Tom

AU - Hudson, Lawrence N.

AU - Ware, Chris

AU - Williams, Kristen J.

AU - Ferrier, Simon

PY - 2016/5/1

Y1 - 2016/5/1

N2 - Land‐use change is one of the biggest threats to biodiversity globally. The effects of land use on biodiversity manifest primarily at local scales which are not captured by the coarse spatial grain of current global land‐use mapping. Assessments of land‐use impacts on biodiversity across large spatial extents require data at a similar spatial grain to the ecological processes they are assessing. Here, we develop a method for statistically downscaling mapped land‐use data that combines generalized additive modeling and constrained optimization. This method was applied to the 0.5° Land‐use Harmonization data for the year 2005 to produce global 30″ (approx. 1 km2) estimates of five land‐use classes: primary habitat, secondary habitat, cropland, pasture, and urban. The original dataset was partitioned into 61 bio‐realms (unique combinations of biome and biogeographical realm) and downscaled using relationships with fine‐grained climate, land cover, landform, and anthropogenic influence layers. The downscaled land‐use data were validated using the PREDICTS database and the geoWiki global cropland dataset. Application of the new method to all 61 bio‐realms produced global fine‐grained layers from the 2005 time step of the Land‐use Harmonization dataset. Coarse‐scaled proportions of land use estimated from these data compared well with those estimated in the original datasets (mean R2: 0.68 ± 0.19). Validation with the PREDICTS database showed the new downscaled land‐use layers improved discrimination of all five classes at PREDICTS sites (P < 0.0001 in all cases). Additional validation of the downscaled cropping layer with the geoWiki layer showed an R2 improvement of 0.12 compared with the Land‐use Harmonization data. The downscaling method presented here produced the first global land‐use dataset at a spatial grain relevant to ecological processes that drive changes in biodiversity over space and time. Integrating these data with biodiversity measures will enable the reporting of land‐use impacts on biodiversity at a finer resolution than previously possible. Furthermore, the general method presented here could be useful to others wishing to downscale similarly constrained coarse‐resolution data for other environmental variables.

AB - Land‐use change is one of the biggest threats to biodiversity globally. The effects of land use on biodiversity manifest primarily at local scales which are not captured by the coarse spatial grain of current global land‐use mapping. Assessments of land‐use impacts on biodiversity across large spatial extents require data at a similar spatial grain to the ecological processes they are assessing. Here, we develop a method for statistically downscaling mapped land‐use data that combines generalized additive modeling and constrained optimization. This method was applied to the 0.5° Land‐use Harmonization data for the year 2005 to produce global 30″ (approx. 1 km2) estimates of five land‐use classes: primary habitat, secondary habitat, cropland, pasture, and urban. The original dataset was partitioned into 61 bio‐realms (unique combinations of biome and biogeographical realm) and downscaled using relationships with fine‐grained climate, land cover, landform, and anthropogenic influence layers. The downscaled land‐use data were validated using the PREDICTS database and the geoWiki global cropland dataset. Application of the new method to all 61 bio‐realms produced global fine‐grained layers from the 2005 time step of the Land‐use Harmonization dataset. Coarse‐scaled proportions of land use estimated from these data compared well with those estimated in the original datasets (mean R2: 0.68 ± 0.19). Validation with the PREDICTS database showed the new downscaled land‐use layers improved discrimination of all five classes at PREDICTS sites (P < 0.0001 in all cases). Additional validation of the downscaled cropping layer with the geoWiki layer showed an R2 improvement of 0.12 compared with the Land‐use Harmonization data. The downscaling method presented here produced the first global land‐use dataset at a spatial grain relevant to ecological processes that drive changes in biodiversity over space and time. Integrating these data with biodiversity measures will enable the reporting of land‐use impacts on biodiversity at a finer resolution than previously possible. Furthermore, the general method presented here could be useful to others wishing to downscale similarly constrained coarse‐resolution data for other environmental variables.

KW - Constrained optimization

KW - global change

KW - land cover

KW - land use

KW - landscape modification

KW - statistical downscaling

U2 - 10.1002/ece3.2104

DO - 10.1002/ece3.2104

M3 - Journal article

VL - 6

SP - 3040

EP - 3055

JO - Ecology and Evolution

JF - Ecology and Evolution

SN - 2045-7758

IS - 9

ER -