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Hauptverfasser: Ahmed, Nahian, Roth, Mark, Hallman, Tyler A., Robinson, W. Douglas, Hutchinson, Rebecca A.
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2412.15559
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author Ahmed, Nahian
Roth, Mark
Hallman, Tyler A.
Robinson, W. Douglas
Hutchinson, Rebecca A.
author_facet Ahmed, Nahian
Roth, Mark
Hallman, Tyler A.
Robinson, W. Douglas
Hutchinson, Rebecca A.
contents Citizen science biodiversity data present great opportunities for ecology and conservation across vast spatial and temporal scales. However, the opportunistic nature of these data lacks the sampling structure required by modeling methodologies that address a pervasive challenge in ecological data collection: imperfect detection, i.e., the likelihood of under-observing species on field surveys. Occupancy modeling is an example of an approach that accounts for imperfect detection by explicitly modeling the observation process separately from the biological process of habitat selection. This produces species distribution models that speak to the pattern of the species on a landscape after accounting for imperfect detection in the data, rather than the pattern of species observations corrupted by errors. To achieve this benefit, occupancy models require multiple surveys of a site across which the site's status (i.e., occupied or not) is assumed constant. Since citizen science data are not collected under the required repeated-visit protocol, observations may be grouped into sites post hoc. Existing approaches for constructing sites discard some observations and/or consider only geographic distance and not environmental similarity. In this study, we compare ten approaches for site construction in terms of their impact on downstream species distribution models for 31 bird species in Oregon, using observations recorded in the eBird database. We find that occupancy models built on sites constructed by spatial clustering algorithms perform better than existing alternatives.
format Preprint
id arxiv_https___arxiv_org_abs_2412_15559
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Spatial Clustering of Citizen Science Data Improves Downstream Species Distribution Models
Ahmed, Nahian
Roth, Mark
Hallman, Tyler A.
Robinson, W. Douglas
Hutchinson, Rebecca A.
Machine Learning
Citizen science biodiversity data present great opportunities for ecology and conservation across vast spatial and temporal scales. However, the opportunistic nature of these data lacks the sampling structure required by modeling methodologies that address a pervasive challenge in ecological data collection: imperfect detection, i.e., the likelihood of under-observing species on field surveys. Occupancy modeling is an example of an approach that accounts for imperfect detection by explicitly modeling the observation process separately from the biological process of habitat selection. This produces species distribution models that speak to the pattern of the species on a landscape after accounting for imperfect detection in the data, rather than the pattern of species observations corrupted by errors. To achieve this benefit, occupancy models require multiple surveys of a site across which the site's status (i.e., occupied or not) is assumed constant. Since citizen science data are not collected under the required repeated-visit protocol, observations may be grouped into sites post hoc. Existing approaches for constructing sites discard some observations and/or consider only geographic distance and not environmental similarity. In this study, we compare ten approaches for site construction in terms of their impact on downstream species distribution models for 31 bird species in Oregon, using observations recorded in the eBird database. We find that occupancy models built on sites constructed by spatial clustering algorithms perform better than existing alternatives.
title Spatial Clustering of Citizen Science Data Improves Downstream Species Distribution Models
topic Machine Learning
url https://arxiv.org/abs/2412.15559