Ecological niche models improve home range estimations

Ecological niche models improve home range estimations

Home ranges in animals can be estimated by different methods like minimum convex polygons, characteristic hulls or kernels while correlative ecological niche models (ENMs) are commonly employed for forecasting species' ranges. However, ENMs can also model the distribution of individuals if envi...

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Veröffentlicht in:Journal of zoology (1987) 2021-02, Vol.313 (2), p.145-157
Hauptverfasser: Sillero, N., dos Santos, R., Teodoro, A. C., Carretero, M. A.
Format: Artikel
Sprache:eng
Schlagworte:
Aerial photography
Algorithms
Animals
Cameras
Conspecifics
correlative niche models
Data
data‐loggers
digital surface models
Distance
Ecological distribution
ecological niche models
Ecological niches
Home range
Hulls
Humidity
Kernels
Land cover
Lizards
Mesocosms
Microclimate
Niches
Pixels
Podarcis bocagei
Remote sensing
Resolution
Spatial data
Spatial discrimination
Spatial resolution
Statistical inference
Temperature
very high spatial resolution
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container_issue 2
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container_title Journal of zoology (1987)
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creator Sillero, N.
dos Santos, R.
Teodoro, A. C.
Carretero, M. A.
description Home ranges in animals can be estimated by different methods like minimum convex polygons, characteristic hulls or kernels while correlative ecological niche models (ENMs) are commonly employed for forecasting species' ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Indeed, remote sensing (RS) can provide images with pixel sizes of few centimetres. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. We recorded lizards’ positions in a 20 × 20 m mesocosm with a high precision GPS device (~10 cm of error), multiple times per day throughout the whole period of daily activity. We built an orthophoto map (pixels of 20 cm2) from camera pictures, a digital surface model, and a land‐cover supervised classification map. We recreated climate‐like variables by combining data‐logger data. For each individual, we calculated the distance to males and females, excluding the focal lizard. We computed individual realized niche models with Bioclim, GAM, GLM, Maxent and random forest. Models attained a very high evaluation score in most cases. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. Our very high spatial resolution models provided robust information on how space is used by each lizard. Correlative models can identify the most suitable areas inside the home range, similar to core areas estimated from kernel algorithms, but allowed better statistical inference. Overall, RS tools generated high‐quality environmental data, and when combined with ENMs, improved the robustness of the predictions on spatial patterns of small terrestrial animals. Ecological niche models (ENMs) can be used to estimate home ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. The most contributing variables were related to microclimate (isothermality, minimum temperat
doi_str_mv 10.1111/jzo.12844
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We recorded lizards’ positions in a 20 × 20 m mesocosm with a high precision GPS device (~10 cm of error), multiple times per day throughout the whole period of daily activity. We built an orthophoto map (pixels of 20 cm2) from camera pictures, a digital surface model, and a land‐cover supervised classification map. We recreated climate‐like variables by combining data‐logger data. For each individual, we calculated the distance to males and females, excluding the focal lizard. We computed individual realized niche models with Bioclim, GAM, GLM, Maxent and random forest. Models attained a very high evaluation score in most cases. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. Our very high spatial resolution models provided robust information on how space is used by each lizard. Correlative models can identify the most suitable areas inside the home range, similar to core areas estimated from kernel algorithms, but allowed better statistical inference. Overall, RS tools generated high‐quality environmental data, and when combined with ENMs, improved the robustness of the predictions on spatial patterns of small terrestrial animals. Ecological niche models (ENMs) can be used to estimate home ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. 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C.</creatorcontrib><creatorcontrib>Carretero, M. A.</creatorcontrib><title>Ecological niche models improve home range estimations</title><title>Journal of zoology (1987)</title><description>Home ranges in animals can be estimated by different methods like minimum convex polygons, characteristic hulls or kernels while correlative ecological niche models (ENMs) are commonly employed for forecasting species' ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Indeed, remote sensing (RS) can provide images with pixel sizes of few centimetres. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. 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Correlative models can identify the most suitable areas inside the home range, similar to core areas estimated from kernel algorithms, but allowed better statistical inference. Overall, RS tools generated high‐quality environmental data, and when combined with ENMs, improved the robustness of the predictions on spatial patterns of small terrestrial animals. Ecological niche models (ENMs) can be used to estimate home ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. 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Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. We recorded lizards’ positions in a 20 × 20 m mesocosm with a high precision GPS device (~10 cm of error), multiple times per day throughout the whole period of daily activity. We built an orthophoto map (pixels of 20 cm2) from camera pictures, a digital surface model, and a land‐cover supervised classification map. We recreated climate‐like variables by combining data‐logger data. For each individual, we calculated the distance to males and females, excluding the focal lizard. We computed individual realized niche models with Bioclim, GAM, GLM, Maxent and random forest. Models attained a very high evaluation score in most cases. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. Our very high spatial resolution models provided robust information on how space is used by each lizard. Correlative models can identify the most suitable areas inside the home range, similar to core areas estimated from kernel algorithms, but allowed better statistical inference. Overall, RS tools generated high‐quality environmental data, and when combined with ENMs, improved the robustness of the predictions on spatial patterns of small terrestrial animals. Ecological niche models (ENMs) can be used to estimate home ranges. However, ENMs can also model the distribution of individuals if environmental very high spatial resolution data are available. Here, we modelled the distribution of individual lizards (Podarcis bocagei) combining aerial‐like photographs recorded with a compact camera and a matrix of temperature/humidity data‐loggers to obtain several environmental layers with very high spatial resolution. The most contributing variables were related to microclimate (isothermality, minimum temperature and humidity) and distance to conspecifics. Our very high spatial resolution models provided robust information on how space is used by each lizard. Correlative models can identify the most suitable areas inside the home range, similar to core areas estimated from kernel algorithms, but allowed better statistical inference. Overall, RS tools generated high‐quality environmental data, and when combined with ENMs, improved the robustness of the predictions on spatial patterns of small terrestrial animals.</abstract><cop>London</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1111/jzo.12844</doi><tpages>13</tpages><orcidid>https://orcid.org/0000-0002-3490-3780</orcidid><orcidid>https://orcid.org/0000-0002-2335-7198</orcidid><orcidid>https://orcid.org/0000-0002-8043-6431</orcidid></addata></record>
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source Wiley Online Library Journals Frontfile Complete
subjects Aerial photography
Algorithms
Animals
Cameras
Conspecifics
correlative niche models
Data
data‐loggers
digital surface models
Distance
Ecological distribution
ecological niche models
Ecological niches
Home range
Hulls
Humidity
Kernels
Land cover
Lizards
Mesocosms
Microclimate
Niches
Pixels
Podarcis bocagei
Remote sensing
Resolution
Spatial data
Spatial discrimination
Spatial resolution
Statistical inference
Temperature
very high spatial resolution
title Ecological niche models improve home range estimations
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