Abstract

Abstract To prevent further global declines in biodiversity, identifying and understanding key habitats is crucial for successful conservation strategies. For example, globally, seabird populations are under threat and animal movement data can identify key at‐sea areas and provide valuable information on the state of marine ecosystems. To date, in order to locate these areas, studies have used global positioning system (GPS) to record position and are sometimes combined with time–depth recorder (TDR) devices to identify diving activity associated with foraging, a crucial aspect of at‐sea behaviour. However, the use of additional devices such as TDRs can be expensive, logistically difficult and may adversely affect the animal. Alternatively, behaviours may be resolved from measurements derived from the movement data alone. However, this behavioural analysis frequently lacks validation data for locations predicted as foraging (or other behaviours). Here, we address these issues using a combined GPS and TDR dataset from 108 individuals by training deep learning models to predict diving in European shags, common guillemots and razorbills. We validate our predictions using withheld data, producing quantitative assessment of predictive accuracy. The variables used to train these models are those recorded solely by the GPS device: variation in longitude and latitude, altitude and coverage ratio (proportion of possible fixes acquired within a set window of time). Different combinations of these variables were used to explore the qualities of different models, with the optimum models for all species predicting non‐diving and diving behaviour correctly over 94% and 80% of the time, respectively. We also demonstrate the superior predictive ability of these supervised deep learning models over other commonly used behavioural prediction methods such as hidden Markov models. Mapping these predictions provides useful insights into the foraging activity of a range of seabird species, highlighting important at sea locations. These models have the potential to be used to analyse historic GPS datasets and further our understanding of how environmental changes have affected these seabirds over time.

Highlights

  • Marine ecosystems are under threat from anthropogenic pressures such as climate change, ocean acidification and overfishing (Frederiksen, Edwards, Richardson, Halliday, & Wanless, 2006; Furness & Camphuysen, 1997; Halpern et al, 2008)

  • Using the combined information from global positioning system (GPS) and time–depth recorder (TDR) devices, we were able to train deep neural networks to predict the diving behaviour of shags, guillemots and razorbills

  • The predictions are strong and well validated with known dive locations collected by TDR loggers

Read more

Summary

Introduction

Marine ecosystems are under threat from anthropogenic pressures such as climate change, ocean acidification and overfishing (Frederiksen, Edwards, Richardson, Halliday, & Wanless, 2006; Furness & Camphuysen, 1997; Halpern et al, 2008). Seabirds are valuable biological indicators for the marine environment, providing information on ecosystem health (Einoder, 2009; Furness & Camphuysen, 1997). The movements of these wide-­ranging birds can inform us about the condition of large parts of the often inaccessible ocean (Mallory, Robinson, Hebert, & Forbes, 2010), and seabirds are easy to monitor as during the breeding season, they return to the same colony (Einoder, 2009)

Objectives
Methods
Findings
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.