Simulating animal space use from fitted integrated <scp>Step‐Selection Functions</scp> (<scp>iSSF</scp>)

Signer, J.; Fieberg, J.; Reineking, B.; Schlägel, U.; Smith, B.; Balkenhol, N.; Avgar, T.

doi:10.1111/2041-210x.14263

Cited by 6 publications

(5 citation statements)

References 45 publications

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“…[72, 73, 74, 75, 76] are examples. Others represent movement in terms of partial differential equations some random components that switch between gradient following search (advection plus random noise) and random search [77] or discrete approaches using integrated step-selection functions [78]. In addition, machine learning methods have been shown to outperform SDE models for predicting the next location of individuals in some systems [79].…”

Section: Discussionmentioning

confidence: 99%

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The Statistical Building Blocks of Animal Movement Simulations

Getz,

Salter,

Sethi

et al. 2023

Preprint

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Animal movement plays a key role in many ecological processes and has a direct influence on the individual’s fitness. Movement tracks can be studied at various spatio-temporal scales, but the movement usually emerges from sequences of fundamental movement elements (FuMEs: e.g., a step or wing flap). The importance of movement in all aspects of the life history of mobile animals highlights the need to develop tools for generating realistic tracks. These individual movement elements are typically not extractable from relocation tracking data: a time series of sequential locations (e.g., GPS fixes) from which we can extract step-size or length (SL, aka velocity when sampling frequency is fixed) and turning-angle (TA) time series. The statistics of these extracted quantities (means, standard deviations, correlations), computed for fixed short segments of track (e.g., 10-30 point sequences), can then be used to categorize such segments into statistical movement elements (StaMEs; e.g. directed fast movement versus random slow movement elements). StaMEs from the same category can be used as a basis for constructing step-selection kernels of a particular movement type, referred to as a canonical activity mode (CAM; e.g. foraging, or commuting). Such CAM kernels can be used to simulate tracks from pure or characteristic mixtures of two or more CAMs, where such mixtures are recognized as a particular type of activity: e.g., foraging or directed walking with interruptions for vigilance or navigation bouts. These activity types in turn (e.g., interspersed sequences of resting, foraging, and directed movements) can then be organized into temporally fixed (24-hour) diel activity routines (DARs; e.g., a day of migration vs a day of local movement). We suggest that a simulator accounting specifically for the hierarchical nature of movement able to generate segments of tracks that may fit CAM length sections of real movement data. Hence, here we present a two-mode, step-selection kernel simulator (Numerus ANIMOVER_1), built using Numerus RAMP technology. We discuss methods for selecting kernel parameters that generate StaMEs comparable to those observed in empirical data, thereby providing a general tool for simulating animal movement in diverse contexts such as evaluation on animal response to landscape changes. We illustrate our methods for extracting StaMEs from both simulated and real data—in our case the latter is movement data of two barn owls (Tyto alba) in the Harod Valley, Israel. The methods described here may provide a way to fit fine scale simulations to empirical data to in ways that may allow us to identify stressed or diseased individuals.

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Section: Discussionmentioning

confidence: 99%

“…[52, 53, 54, 55] are examples. Others represent movement in terms of partial differential equations some random components that switch between gradient following search (advection plus random noise) and random search [56] or discrete approaches using integrated step-selection functions [57].…”

Section: Discussionmentioning

confidence: 99%

The Statistical Building Blocks of Animal Movement Simulations

Getz,

Salter,

Sethi

et al. 2023

Preprint

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“…Recently, SSFs have been gaining popularity for generating predictions, both for estimating utilisation distributions (UDs) of an individual (or set of individuals) in a given area (Signer et al, 2017; Potts, Börger, et al, 2022; Signer et al, 2023) and for predicting conservation-relevant measures such as connectivity and movement corridors (Osipova et al, 2019; Hooker et al, 2021; Whittington et al, 2022; Aiello et al, 2023; Hofmann et al, 2023; Sells et al, 2023). Using the estimated parameters of an SSF, several approaches have been developed to generate predictions, which include analytic and simulation-based approaches (Barnett & Moorcroft, 2008; Avgar et al, 2016; Signer et al, 2017; Potts & Schlägel, 2020; Potts, Börger, et al, 2022; Potts, Giunta, et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…For a review of approaches to ‘scale-up’ from step selection functions to spatiotemporal patterns, see Potts and Börger (2023). A flexible and robust approach that allows for several prediction outcomes is to generate trajectories from the inferred parameters of the SSF via stochastic simulation (Avgar et al, 2013; Duchesne et al, 2015; Avgar et al, 2016; Signer et al, 2017; Potts & Börger, 2023; Signer et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

“…Simulation-based models can include temporal dynamics on any scale, and they explicitly incorporate the animal’s movement dynamics. Step selection functions (SSFs) are particularly advantageous as they can be used to simulate trajectories (Signer et al, 2017; Potts & Börger, 2023; Signer et al, 2023), are straightforward to parameterise, and can incorporate temporal dynamics (Ager et al, 2003; Forester et al, 2009; Tsalyuk et al, 2019; Richter et al, 2020; Klappstein et al, 2024). An SSF combines a movement and a external selection kernel, can take a range of forms (Munden et al, 2021; Klappstein et al, 2022; Beumer et al, 2023; Eisaguirre et al, 2024; Pohle et al, 2024), and can accommodate a wide range of covariates including habitat, linear features, distance-to-feature variables, proximity to other animals (Potts et al, 2022; Ellison et al, 2024) and representations of previous space use (Schlägel & Lewis, 2014; Oliveira-Santos et al, 2016; Rheault et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

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Predicting fine-scale distributions and emergent spatiotemporal patterns from temporally dynamic step selection simulations

Forrest,

Pagendam,

Bode

et al. 2024

Preprint

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Abstract1.Context and purposeThere has been increasing interest in simulating stochastic movement paths from step selection models. Hitherto, models used to simulate trajectories have not included temporally dynamic co-efficients on both the movement and external selection processes, despite animals having temporally dynamic behaviour over daily or seasonal timescales.2.Approach and methodsHere, we focused on simulating stochastic trajectories from step selection functions (SSFs) that include temporal dynamics using harmonic terms, focusing on dynamic behaviour on a daily timescale. The models also incorporated home ranging behaviour through a decaying memory process, which was also interacted with the harmonic terms. We simulated trajectories of individual animals and assessed how they compared to observed data through animal-movement-informed summary statistics. We applied our methods to GPS-tracked water buffalo (Bubalus bubalis), which are an invasive species in Northern Australia’s tropical savannas.3.Main resultsThe temporally dynamic models allowed for more informative interpretation of animal behaviour, particularly when quadratic terms were included in the models, allowing for insights about buffalo behaviour. The simulations generated from the temporally dynamic models reproduced the movement and habitat selection behaviour that we observed in the GPS data, particularly crepuscular movement behaviour and selecting for high canopy cover and vegetation during the middle of the day for thermoregulation. When assessed over longer time-scales, models both with and without daily temporal dynamics generated simulations that performed similarly according to the summary statistics, and had geographical space use of similar area and monthly overlap to that the observed data.4.Conclusions and wider implicationsWe recommend fitting temporally dynamic SSFs when generating simulated trajectories to most closely represent the animal’s dynamic behaviour. We considered daily behavioural dynamics here, although any timescale of interest can be incorporated, with the potential for interacting multi scale temporal dynamics. Including temporal dynamics in SSFs for the purpose of simulating new data can address a wide range of ecological and behavioural questions and provide valuable information for conservation management, particularly for species with clear daily or seasonal behaviour patterns. We provide code to replicate all analyses presented.

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Combining animal interactions and habitat selection into models of space use: a case study with white‐tailed deer

Ellison,

Potts,

Strickland

et al. 2024

Wildlife Biology

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Animals determine their daily movement trajectories in response to a network of ecological processes, including interactions with other organisms, their memories of previous events, and the changing environment. These combine to cause the emergent space use patterns observed over longer periods of time, such as a whole season. Understanding which processes cause these patterns to emerge, and how, requires a process‐based modelling approach. Individual‐based decisions can be described as a system of partial‐differential equations (PDEs) to produce a dynamic description of space use built from the underlying movement process. Here we combine PDE‐based models with step‐selection analysis to investigate the combined effects of three established ecological processes that partially shape movement and space use: 1) a heterogeneous environment; 2) the environmental markings of moving conspecifics; and 3) the memory of direct interactions with conspecifics. We apply this framework to a large GPS‐based dataset of white‐tailed deer Odocoileus virginianus in the southeastern US. We fit models at the population level to provide predictive models, then tailor these to fit individual deer. We specifically incorporate relationships between each possible pair of deer and define each animal's responses to their unique local environments using separate integrated step‐selection analyses. We show how individual movements and decisions yield emergent patterns in animal distributions, and we provide a full generalised description of the framework so that it may be applied to any species simultaneously responding to multiple potentially interacting stimuli (e.g. sociality, morphology, etc.). We found that the population of bucks had highly varied preferences for vegetation, but were shaping their space use in response to conspecific interactions, dependent on the individual relationships between two deer. We advocate for increased consideration of individual‐based movement rules as determinants of realized animal space use, and particularly how these affect emergent distributions of entire species.

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Simulating animal space use from fitted integrated Step‐Selection Functions (iSSF)

Cited by 6 publications

References 45 publications

The Statistical Building Blocks of Animal Movement Simulations

The Statistical Building Blocks of Animal Movement Simulations

Predicting fine-scale distributions and emergent spatiotemporal patterns from temporally dynamic step selection simulations

Combining animal interactions and habitat selection into models of space use: a case study with white‐tailed deer

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