Your search keyword '"Munden, Rhys"' showing total 5 results

1. Dude, where's my cow? : using high-frequency movement data to quantify animal space use

Author

Munden, Rhys, Potts, Jonathan, Borger, Luca, and Wilson, Rory

Abstract

In this thesis I investigate the use of high frequency (≥1Hz) location data for examining animal movements. This high frequency means that an animal's movement path can often be considered pseudo-continuous, which removes the necessity for interpolating between successive recordings. On the other hand, many existing techniques used to analyse animal movement data are either too computationally expensive or not directly applicable to high frequency data. I introduce novel adaptations of two techniques, namely the residence time metric and Step Selection Analysis (SSA), which I tailor for use on high frequency data. The residence time metric is used to estimate how long an animal spends in different areas. I explain how using high frequency data enables us to accurately calculate how much time an animal spends in a clearly delimited area. I also show how, through adaptations to the existing method used to calculate residence times, we can greatly reduce its computational time. Furthermore, this adapted method enables us to identify specific areas that are extensively used by an animal, which provides further opportunities to examine why an animal chooses to use those areas so much. SSA enables a user to infer the reasons underpinning an animal's decisions to move from one location to another. I explain how it is not useful to apply SSA directly to high frequency data, since there is often little interesting information contained in movements between consecutive recordings that are a second or less apart. Therefore, I first show how high frequency data can be rarefied such that the rarefied points represent times when the animal has made key movement decisions. I then adapt the SSA method for use with such rarefied paths. In comparing the existing and adapted SSA methods I find that the previous SSA method can lead to inaccurate results.

Published

2020

2. Why did the animal turn? Time‐varying step selection analysis for inference between observed turning‐points in high frequency data

Author

Munden, Rhys, primary, Börger, Luca, additional, Wilson, Rory P., additional, Redcliffe, James, additional, Brown, Rowan, additional, Garel, Mathieu, additional, and Potts, Jonathan R., additional

Published

2021

3. Why did the animal turn? Time-varying step selection analysis for inference between observed turning points in high frequency data

Author

Munden, Rhys, primary, Börger, Luca, additional, Wilson, Rory P., additional, Redcliffe, James, additional, Brown, Rowan, additional, Garel, Mathieu, additional, and Potts, Jonathan R., additional

Published

2020

4. Making sense of ultrahigh-resolution movement data: A new algorithm for inferring sites of interest

Author

Munden, Rhys, primary, Börger, Luca, additional, Wilson, Rory P., additional, Redcliffe, James, additional, Loison, Anne, additional, Garel, Mathieu, additional, and Potts, Jonathan R., additional

Published

2018

5. Making sense of ultrahigh‐resolution movement data: A new algorithm for inferring sites of interest.

Author

Munden, Rhys, Börger, Luca, Wilson, Rory P., Redcliffe, James, Loison, Anne, Garel, Mathieu, and Potts, Jonathan R.

Subjects

*ANIMAL behavior, *ECOLOGY, *ANIMAL mechanics, *FORAGING behavior, *MARKOV processes

Abstract

Decomposing the life track of an animal into behavioral segments is a fundamental challenge for movement ecology. The proliferation of high‐resolution data, often collected many times per second, offers much opportunity for understanding animal movement. However, the sheer size of modern data sets means there is an increasing need for rapid, novel computational techniques to make sense of these data. Most existing methods were designed with smaller data sets in mind and can thus be prohibitively slow. Here, we introduce a method for segmenting high‐resolution movement trajectories into sites of interest and transitions between these sites. This builds on a previous algorithm of Benhamou and Riotte‐Lambert (2012). Adapting it for use with high‐resolution data. The data's resolution removed the need to interpolate between successive locations, allowing us to increase the algorithm's speed by approximately two orders of magnitude with essentially no drop in accuracy. Furthermore, we incorporate a color scheme for testing the level of confidence in the algorithm's inference (high = green, medium = amber, low = red). We demonstrate the speed and accuracy of our algorithm with application to both simulated and real data (Alpine cattle at 1 Hz resolution). On simulated data, our algorithm correctly identified the sites of interest for 99% of "high confidence" paths. For the cattle data, the algorithm identified the two known sites of interest: a watering hole and a milking station. It also identified several other sites which can be related to hypothesized environmental drivers (e.g., food). Our algorithm gives an efficient method for turning a long, high‐resolution movement path into a schematic representation of broadscale decisions, allowing a direct link to existing point‐to‐point analysis techniques such as optimal foraging theory. It is encoded into an R package called SitesInterest, so should serve as a valuable tool for making sense of these increasingly large data streams. We have constructed a new method for identifying sites of interest, tailored specifically for use with high resolution data. This allows for a complicated movement trajectory to be simplified into a "Markov chain‐like" description of behavioural choices, highlighting the animal's broadscale decisions. [ABSTRACT FROM AUTHOR]

Published

2019