Characterising menotactic behaviours in movement data using hidden Markov models

Togunov, Ron R.; Derocher, Andrew E.; Lunn, Nicholas J.; Auger‐Méthé, Marie

doi:10.1111/2041-210x.13681

Cited by 6 publications

(49 citation statements)

References 102 publications

(209 reference statements)

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“…To avoid interpolating large gaps, we segmented the location data into separate bouts whenever missing locations spanned more than 6 h (i.e., we interpolated a maximum of three missing locations). To remove data-sparse bouts, we removed segments spanning less than 24 h or those with fewer than eight locations (as in Togunov et al, 2021). Any missing locations in the remaining bouts were interpolated using the R Package crawl (Johnson et al, 2008;Johnson and London, 2018).…”

Section: Study Area and Telemetry Datamentioning

confidence: 99%

“…We extracted two variables from the tracking data: step length l t ∈ (0, ∞) (the distance between consecutive locations) and turning angle ϕ t ∈ (−π, π] (change in bearing between consecutive steps; Langrock et al, 2012;McClintock and Michelot, 2018;Togunov et al, 2021). Following Togunov et al (2021), we assumed step lengths followed a gamma distribution:…”

Section: Behavior Analysismentioning

confidence: 99%

“…Recent advances in data acquisition (Nathan et al, 2022) and analytical methods (e.g., McClintock and Michelot, 2018; Togunov et al, 2021) have enabled the identification of more intricate behaviors and research at an increasingly large scale and resolution. Pagano et al (2017) described the use of accelerometers to identify up to ten fine-scale behaviors, and Pagano et al (2020) used a combination of accelerometer data and conductivity sensors to identify resting, walking, and swimming.…”

Section: Introductionmentioning

confidence: 99%

“…Unfortunately, most existing telemetry datasets do not lend themselves to many of the newer analytical methods because they lack necessary auxiliary data (i.e., they only estimate tag location). However, Togunov et al (2021) described the use of location data in combination with wind to identify up to three behavioral states, a method readily applicable to most existing polar bear movement data.…”

Section: Introductionmentioning

confidence: 99%

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Drivers of polar bear behavior, and the possible effects of prey availability on foraging strategy

Togunov

Derocher

Lunn

et al. 2022

Preprint

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Change in behavior is one of the earliest measurable responses to variation in habitat suitability, making the study of factors that promote behaviors particularly important in areas undergoing environmental change. We applied hidden Markov models to remote movement data of 14 polar bears, Ursus maritimus, from Western Hudson Bay, Canada between 2011 and 2021 during the foraging season (January--June) when bears inhabit the sea ice. The model incorporated bear movement and orientation relative to wind to classify three behaviors (stationary/drifting, area-restricted search, and olfactory search), and investigated 11 factors to identify conditions that may promote these behaviors. In contrast to other polar bear populations, we found high levels of evening activity, with active behaviors peaking around 20:00. We identified an increase in activity as the ice-covered season progressed. This apparent shift in foraging strategy from still-hunting to active search corresponds to a shift in prey availability (i.e., increase in haul-out behavior from early winter to the spring pupping and molting seasons). Last, we described spatial patterns of distribution with respect to season and ice concentration that may be indicative of variation in habitat quality and segregation by bear age that may reflect competitive exclusion. Our observations were generally consistent with predictions of the marginal value theorem, and differences between our findings compared to other populations could be explained by variation in regional or temporal variation in resource abundance or distribution. Our findings and methodology can help identify periods, locations, and environmental conditions associated with habitat quality and can improve our understanding polar bear behavioral ecology and aid conservation.

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Section: Study Area and Telemetry Datamentioning

confidence: 99%

Section: Behavior Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Drivers of polar bear behavior, and the possible effects of prey availability on foraging strategy

Togunov

Derocher

Lunn

et al. 2022

Preprint

Self Cite

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“…As in recent developments in standard continuous time models, there are opportunities to improve the fit of the model by accounting for geographic features/barriers, social encounters, atmospheric conditions, etc. (Togunov et al, 2021). Random walk schematics have shown great potential improving the modeling of animal movement, and these methods should be adapted to the FDA paradigm.…”

Section: Extension To Higher-order Interactionsmentioning

confidence: 99%

Smoothing splines of apex predator movement: Functional modeling strategies for exploring animal behavior and social interactions

Whetten

2021

Ecology and Evolution

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Technological advancements in remote sensing of animal movement, referred to as animal telemetry, have revolutionized the discipline of movement ecology. Animal movement data provides critical information about ecological processes, and it can be a vital asset to conservation efforts of species and ecosystems. The increased feasibility of tracking and collecting animal movement information has yielded large reservoirs of fine-scale spatio-temporal data, and the challenges of meaningfully modeling animal behavior have resulted in the expansion of holistic machine learning methodology that appropriately considers animal psychology and cognition (Buderman

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A Deep Learning and Hidden Hierarchical Markov Model based analysis of Polar Ice Depletions and effects on Movements of Vulnerable Polar Animals

Mukherjee,

Barone

2023

SoutheastCon 2023

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Characterising menotactic behaviours in movement data using hidden Markov models

Cited by 6 publications

References 102 publications

Drivers of polar bear behavior, and the possible effects of prey availability on foraging strategy

Drivers of polar bear behavior, and the possible effects of prey availability on foraging strategy

Smoothing splines of apex predator movement: Functional modeling strategies for exploring animal behavior and social interactions

A Deep Learning and Hidden Hierarchical Markov Model based analysis of Polar Ice Depletions and effects on Movements of Vulnerable Polar Animals

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