Variance propagation for density surface models
Data from the SCANS-II project were supported by the EU LIFE Nature programme (project LIFE04NAT/GB/000245) and governments of range states: Belgium, Denmark, France, Germany, Ireland, Netherlands, Norway, Poland, Portugal, Spain, Sweden, and UK. This work was funded by OPNAV N45 and the SURTASS LFA...
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Online Access: | https://hdl.handle.net/10023/21564 https://doi.org/10.1007/s13253-021-00438-2 |
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ftstandrewserep:oai:research-repository.st-andrews.ac.uk:10023/21564 2024-04-21T08:04:13+00:00 Variance propagation for density surface models Bravington, Mark V. Miller, David Lawrence Hedley, Sharon Louise Office of Naval Research University of St Andrews. School of Mathematics and Statistics University of St Andrews. Centre for Research into Ecological & Environmental Modelling 2021-03-05T17:30:20Z 18 9881920 application/pdf https://hdl.handle.net/10023/21564 https://doi.org/10.1007/s13253-021-00438-2 eng eng Journal of Agricultural, Biological and Environmental Statistics 272862363 b2dab681-8595-473f-821a-0f798448b04d 000621066800001 85101412506 Bravington , M V , Miller , D L & Hedley , S L 2021 , ' Variance propagation for density surface models ' , Journal of Agricultural, Biological and Environmental Statistics , vol. First Online . https://doi.org/10.1007/s13253-021-00438-2 1085-7117 https://hdl.handle.net/10023/21564 doi:10.1007/s13253-021-00438-2 N00244-10-1-0057 Abundance estimation Distance sampling Generalized additive models Line transect sampling Point transect sampling Spatial modelling QA Mathematics QH301 Biology DAS QA QH301 Journal article 2021 ftstandrewserep https://doi.org/10.1007/s13253-021-00438-2 2024-03-27T15:07:39Z Data from the SCANS-II project were supported by the EU LIFE Nature programme (project LIFE04NAT/GB/000245) and governments of range states: Belgium, Denmark, France, Germany, Ireland, Netherlands, Norway, Poland, Portugal, Spain, Sweden, and UK. This work was funded by OPNAV N45 and the SURTASS LFA Settlement Agreement, and being managed by the US Navy’s Living Marine Resources program under Contract No. N39430-17-C-1982, US Navy, Chief of Naval Operations (Code N45), grant number N00244-10-1-0057 and the International Whaling Commission. Spatially explicit estimates of population density, together with appropriate estimates of uncertainty, are required in many management contexts. Density surface models (DSMs) are a two-stage approach for estimating spatially varying density from distance sampling data. First, detection probabilities—perhaps depending on covariates—are estimated based on details of individual encounters; next, local densities are estimated using a GAM, by fitting local encounter rates to location and/or spatially varying covariates while allowing for the estimated detectabilities. One criticism of DSMs has been that uncertainty from the two stages is not usually propagated correctly into the final variance estimates. We show how to reformulate a DSM so that the uncertainty in detection probability from the distance sampling stage (regardless of its complexity) is captured as an extra random effect in the GAM stage. In effect, we refit an approximation to the detection function model at the same time as fitting the spatial model. This allows straightforward computation of the overall variance via exactly the same software already needed to fit the GAM. A further extension allows for spatial variation in group size, which can be an important covariate for detectability as well as directly affecting abundance. We illustrate these models using point transect survey data of Island Scrub-Jays on Santa Cruz Island, CA, and harbour porpoise from the SCANS-II line transect survey of European waters. ... Article in Journal/Newspaper Harbour porpoise University of St Andrews: Digital Research Repository Journal of Agricultural, Biological and Environmental Statistics 26 2 306 323 |
institution |
Open Polar |
collection |
University of St Andrews: Digital Research Repository |
op_collection_id |
ftstandrewserep |
language |
English |
topic |
Abundance estimation Distance sampling Generalized additive models Line transect sampling Point transect sampling Spatial modelling QA Mathematics QH301 Biology DAS QA QH301 |
spellingShingle |
Abundance estimation Distance sampling Generalized additive models Line transect sampling Point transect sampling Spatial modelling QA Mathematics QH301 Biology DAS QA QH301 Bravington, Mark V. Miller, David Lawrence Hedley, Sharon Louise Variance propagation for density surface models |
topic_facet |
Abundance estimation Distance sampling Generalized additive models Line transect sampling Point transect sampling Spatial modelling QA Mathematics QH301 Biology DAS QA QH301 |
description |
Data from the SCANS-II project were supported by the EU LIFE Nature programme (project LIFE04NAT/GB/000245) and governments of range states: Belgium, Denmark, France, Germany, Ireland, Netherlands, Norway, Poland, Portugal, Spain, Sweden, and UK. This work was funded by OPNAV N45 and the SURTASS LFA Settlement Agreement, and being managed by the US Navy’s Living Marine Resources program under Contract No. N39430-17-C-1982, US Navy, Chief of Naval Operations (Code N45), grant number N00244-10-1-0057 and the International Whaling Commission. Spatially explicit estimates of population density, together with appropriate estimates of uncertainty, are required in many management contexts. Density surface models (DSMs) are a two-stage approach for estimating spatially varying density from distance sampling data. First, detection probabilities—perhaps depending on covariates—are estimated based on details of individual encounters; next, local densities are estimated using a GAM, by fitting local encounter rates to location and/or spatially varying covariates while allowing for the estimated detectabilities. One criticism of DSMs has been that uncertainty from the two stages is not usually propagated correctly into the final variance estimates. We show how to reformulate a DSM so that the uncertainty in detection probability from the distance sampling stage (regardless of its complexity) is captured as an extra random effect in the GAM stage. In effect, we refit an approximation to the detection function model at the same time as fitting the spatial model. This allows straightforward computation of the overall variance via exactly the same software already needed to fit the GAM. A further extension allows for spatial variation in group size, which can be an important covariate for detectability as well as directly affecting abundance. We illustrate these models using point transect survey data of Island Scrub-Jays on Santa Cruz Island, CA, and harbour porpoise from the SCANS-II line transect survey of European waters. ... |
author2 |
Office of Naval Research University of St Andrews. School of Mathematics and Statistics University of St Andrews. Centre for Research into Ecological & Environmental Modelling |
format |
Article in Journal/Newspaper |
author |
Bravington, Mark V. Miller, David Lawrence Hedley, Sharon Louise |
author_facet |
Bravington, Mark V. Miller, David Lawrence Hedley, Sharon Louise |
author_sort |
Bravington, Mark V. |
title |
Variance propagation for density surface models |
title_short |
Variance propagation for density surface models |
title_full |
Variance propagation for density surface models |
title_fullStr |
Variance propagation for density surface models |
title_full_unstemmed |
Variance propagation for density surface models |
title_sort |
variance propagation for density surface models |
publishDate |
2021 |
url |
https://hdl.handle.net/10023/21564 https://doi.org/10.1007/s13253-021-00438-2 |
genre |
Harbour porpoise |
genre_facet |
Harbour porpoise |
op_relation |
Journal of Agricultural, Biological and Environmental Statistics 272862363 b2dab681-8595-473f-821a-0f798448b04d 000621066800001 85101412506 Bravington , M V , Miller , D L & Hedley , S L 2021 , ' Variance propagation for density surface models ' , Journal of Agricultural, Biological and Environmental Statistics , vol. First Online . https://doi.org/10.1007/s13253-021-00438-2 1085-7117 https://hdl.handle.net/10023/21564 doi:10.1007/s13253-021-00438-2 N00244-10-1-0057 |
op_doi |
https://doi.org/10.1007/s13253-021-00438-2 |
container_title |
Journal of Agricultural, Biological and Environmental Statistics |
container_volume |
26 |
container_issue |
2 |
container_start_page |
306 |
op_container_end_page |
323 |
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1796943854334640128 |