How many seabirds do we need to track to define home-range area?

In recent years, marine predator and seabird tracking studies have become ever more popular. However, they are often conducted without first considering how many individuals should be tracked and for how long they should be tracked in order to make reliable predictions of a population's home-ra...

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Bibliographic Details
Main Authors: L Soanes, John Arnould, S Dodd, M Sumner, J Green
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2013
Subjects:
Ecology
central-place foragers
global positioning system
home-range area
marine protected area
Science & Technology
Life Sciences & Biomedicine
Biodiversity Conservation
Biodiversity & Conservation
Environmental Sciences & Ecology
MARINE PROTECTED AREAS
ANTARCTIC FUR SEALS
FORAGING BEHAVIOR
ELEPHANT SEALS
GPS TELEMETRY
SAMPLE-SIZE
HABITAT USE
CONSERVATION
MANAGEMENT
TECHNOLOGY
Antarctic
Antarc*
Antarctic Fur Seals
Elephant Seals
Online Access:http://hdl.handle.net/10536/DRO/DU:30055353
https://figshare.com/articles/journal_contribution/How_many_seabirds_do_we_need_to_track_to_define_home-range_area_/20960767
Description
Summary:In recent years, marine predator and seabird tracking studies have become ever more popular. However, they are often conducted without first considering how many individuals should be tracked and for how long they should be tracked in order to make reliable predictions of a population's home-range area. Home-range area analysis of two seabird-tracking data sets was used to define the area of active use (where birds spent 100% of their time) and the core foraging area (where birds spent 50% of their time). Analysis was conducted on the first foraging trip undertaken by the birds and then the first two, three and four foraging trips combined. Appropriate asymptotic models were applied to the data, and the calculated home-range areas were plotted as a function of an increasing number of individuals and trips included in the sample. Data were extrapolated from these models to predict the area of active use and the core foraging area of the colonies sampled. Significant variability was found in the home-range area predictions made by analysis of the first foraging trip and the first four foraging trips combined. For shags, the first foraging trip predicted a 56% smaller area of active use when compared to the predictions made by combining the first four foraging trips. For kittiwakes, a 43% smaller area was predicted when comparing the first foraging trip with the four combined trips. The number of individuals that would be required to predict the home range area of the colony depends greatly on the number of trips included in the analysis. This analysis predicted that 39 (confidence interval 29-73) shags and 83 (CI: 109-161) kittiwakes would be required to predict 95% of the area of active use when the first four foraging trips are included in the sample compared with 135 (CI 96-156) shags and 248 (164-484) kittiwakes when only the first trip is included in the analysis. Synthesis and applications. Seabird and marine mammal tracking studies are increasingly being used to aid the designation of marine conservation ...

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