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The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters. / Cole, Emma-Louise; Waggitt, James; Hedenstrom, Anders et al.
Yn: Integrative Zoology, Cyfrol 14, Rhif 1, 01.2019, t. 4-16.

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HarvardHarvard

Cole, E-L, Waggitt, J, Hedenstrom, A, Piano, M, Holton, M, Borger, L & Shepard, E 2019, 'The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters', Integrative Zoology, cyfrol. 14, rhif 1, tt. 4-16. https://doi.org/10.1111/1749-4877.12327

APA

Cole, E.-L., Waggitt, J., Hedenstrom, A., Piano, M., Holton, M., Borger, L., & Shepard, E. (2019). The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters. Integrative Zoology, 14(1), 4-16. https://doi.org/10.1111/1749-4877.12327

CBE

MLA

VancouverVancouver

Cole EL, Waggitt J, Hedenstrom A, Piano M, Holton M, Borger L et al. The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters. Integrative Zoology. 2019 Ion;14(1):4-16. Epub 2018 Mai 31. doi: 10.1111/1749-4877.12327

Author

Cole, Emma-Louise ; Waggitt, James ; Hedenstrom, Anders et al. / The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters. Yn: Integrative Zoology. 2019 ; Cyfrol 14, Rhif 1. tt. 4-16.

RIS

TY - JOUR

T1 - The Ornithodolite as a tool to quantify animal space use and habitat selection; a case study with birds diving in tidal waters

AU - Cole, Emma-Louise

AU - Waggitt, James

AU - Hedenstrom, Anders

AU - Piano, Marco

AU - Holton, Mark

AU - Borger, Luca

AU - Shepard, Emily

PY - 2019/1

Y1 - 2019/1

N2 - Animal-attached technologies can be powerful means to quantify space-use and behaviour, however, there are also ethical implications associated with capturing and instrumenting animals. Furthermore, tagging approaches are not necessarily well-suited for examining the movements of multiple individuals within specific, local areas of interest. Here, we assess a method of quantifying animal space use based on a modified theodolite with an inbuilt laser rangefinder. Using a database of > 4,200 tracks of migrating birds, we show that detection distance increases with bird body mass (range 5 g - >10 kg). The maximum distance recorded to a bird was 5500 m and measurement error was ≤ 5 m for targets within this distance range; a level comparable to methods such as GPS tagging. We go on to present a case study where this method was used to assess habitat selection in seabirds operating in dynamic coastal waters close to a tidal turbine. Combining positional data with outputs from a hydrographic model revealed that great cormorants (Phalacrocorax carbo) appeared to be highly selective of current characteristics in space and time; exploiting areas where mean current speeds were < 0.8 m s-1, and diving at times when turbulent energy levels were low. These birds also orientated into tidal currents during dives. Taken together, this suggests that collision risks are low for cormorants at this site, as the two conditions avoided by cormorants (high mean current speeds and turbulence levels), are associated with operational tidal turbines. Overall, we suggest that this modified theodolite system is well-suited to the quantification of movement in small areas associated with particular development strategies, including sustainable energy devices.

AB - Animal-attached technologies can be powerful means to quantify space-use and behaviour, however, there are also ethical implications associated with capturing and instrumenting animals. Furthermore, tagging approaches are not necessarily well-suited for examining the movements of multiple individuals within specific, local areas of interest. Here, we assess a method of quantifying animal space use based on a modified theodolite with an inbuilt laser rangefinder. Using a database of > 4,200 tracks of migrating birds, we show that detection distance increases with bird body mass (range 5 g - >10 kg). The maximum distance recorded to a bird was 5500 m and measurement error was ≤ 5 m for targets within this distance range; a level comparable to methods such as GPS tagging. We go on to present a case study where this method was used to assess habitat selection in seabirds operating in dynamic coastal waters close to a tidal turbine. Combining positional data with outputs from a hydrographic model revealed that great cormorants (Phalacrocorax carbo) appeared to be highly selective of current characteristics in space and time; exploiting areas where mean current speeds were < 0.8 m s-1, and diving at times when turbulent energy levels were low. These birds also orientated into tidal currents during dives. Taken together, this suggests that collision risks are low for cormorants at this site, as the two conditions avoided by cormorants (high mean current speeds and turbulence levels), are associated with operational tidal turbines. Overall, we suggest that this modified theodolite system is well-suited to the quantification of movement in small areas associated with particular development strategies, including sustainable energy devices.

KW - GPS

KW - movement ecology

KW - seabird

KW - tidal turbine

KW - habitat use

U2 - 10.1111/1749-4877.12327

DO - 10.1111/1749-4877.12327

M3 - Article

VL - 14

SP - 4

EP - 16

JO - Integrative Zoology

JF - Integrative Zoology

SN - 1749-4869

IS - 1

ER -