Spatiotemporal modelling of marine movement data using Template Model Builder (TMB)

Auger‐Méthé, Marie; Albertsen, Christoffer Moesgaard; Jonsen, Ian D.; Derocher, Andrew E.; Lidgard, Damian C.; Studholme, Katharine R.; Bowen, W. Don; Crossin, Glenn T.; Flemming, Joanna Mills

doi:10.3354/meps12019

Cited by 53 publications

(94 citation statements)

References 54 publications

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“…Comparing Bayesian and TMB versions of a location‐filtering model, Auger‐Méthé et al. () found a 30‐fold decrease in computation time for the TMB fit with no loss of accuracy. All code for fitting these models in R is available online ,…”

Section: Methodsmentioning

confidence: 99%

Movement responses to environment: fast inference of variation among southern elephant seals with a mixed effects model

Jonsen

McMahon

Patterson

et al. 2018

Ecology

157

119

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Like many species, movement patterns of southern elephant seals (Mirounga leonina) are being influenced by long‐term environmental change. These seals migrate up to 4,000 km from their breeding colonies, foraging for months in a variety of Southern Ocean habitats. Understanding how movement patterns vary with environmental features and how these relationships differ among individuals employing different foraging strategies can provide insight into foraging performance at a population level. We apply new fast‐estimation tools to fit mixed effects within a random walk movement model, rapidly inferring among‐individual variability in southern elephant seal environment–movement relationships. We found that seals making foraging trips to the sea ice on or near the Antarctic continental shelf consistently reduced speed and directionality (move persistence) with increasing sea‐ice coverage but had variable responses to chlorophyll a concentration, whereas seals foraging in the open ocean reduced move persistence in regions where circumpolar deep water shoaled. Given future climate scenarios, open‐ocean foragers may encounter more productive habitat but sea‐ice foragers may see reduced habitat availability. Our approach is scalable to large telemetry data sets and allows flexible combinations of mixed effects to be evaluated via model selection, thereby illuminating the ecological context of animal movements that underlie habitat usage.

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Section: Methodsmentioning

confidence: 99%

Movement responses to environment: fast inference of variation among southern elephant seals with a mixed effects model

Jonsen

McMahon

Patterson

et al. 2018

Ecology

157

119

View full text Add to dashboard Cite

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“…Irregular observations are often handled in the observation equation in a state-space model; however, with GPS data, we can typically assume negligible observation error and save considerable model complexity by modeling the observations directly with the movement equation (Patterson et al, 2008, 2017; Hooten et al, 2017). Notably, parameterizing a CRW in terms of displacement vectors allows for straightforward relationships with time without an observation equation (Auger-Méthé et al, 2017; Gurarie et al, 2017; Eisaguirre et al, 2019; Jonsen et al, 2019).…”

Section: Methodsmentioning

confidence: 99%

“…To account for behavioral heterogeneity, its predictors, and irregular observations, we implemented our SSF with the following movement model representing ϕ ( · ) (Auger-Méthé et al, 2017; Eisaguirre et al, 2019; Jonsen et al, 2019): Where Here, Δ t i = t i − t i− 1 represents the time interval between Cartesian coordinate vectors x i and x i− 1 for the observed locations of the animal at times t i and t i− 1 , and i = 1, 2, …, N for a track with N observations. Note that the movement parameters in equation 1 are θ i = ( γ i , Σ i ).…”

Section: Methodsmentioning

confidence: 99%

Novel step selection analyses on energy landscapes reveal how linear features alter migrations of soaring birds

Eisaguirre

Booms

Barger

et al. 2019

Preprint

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Human modification of landscapes includes extensive addition of linear features, such as roads and transmission lines. These can alter animal movement and space use and affect the intensity of interactions among species, including predation and competition. Effects of linear features on animal movement have seen relatively little research in avian systems, despite ample evidence of their effects in mammalian systems and that some types of linear features, including both roads and transmission lines, are substantial sources of mortality. Here, we used satellite telemetry combined with step-selection functions (SSFs) designed to explicitly incorporate the energy landscape to investigate the effects of linear features and habitat on movements and space use of a large soaring bird, the golden eagle Aquila chrysaetos, during migration. Our sample consisted of 32 adult eagles tracked for 45 spring and 39 fall migrations from 2014-2017. Fitted SSFs indicated eagles had a strong general preference for south-facing slopes, where thermal uplift develops predictably, and that these areas are likely important aspects of migratory pathways. SSFs also revealed that roads and railroads affected movement during both spring and fall migrations, but eagles selected areas near roads to a greater degree in spring compared to fall and at higher latitudes compared to lower latitudes. During spring, time spent near linear features often occurred during slower-paced or stopover movements, perhaps in part to access carrion produced by vehicle collisions. Regardless of the behavioral mechanism of selection, use of these features could expose eagles and other soaring species to elevated risk via collision with vehicles and/or transmission lines. Linear features have been previously documented to affect the ecology of terrestrial species (e.g., large mammals) by modifying individuals' movement patterns; our work shows these effects on movement extend to avian taxa.

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“…Because of large data sets for each species with ARGOS data and computational limitations restricting the fit of one large hierarchical SSM per species, we grouped ~20 individuals per species per model run. Models were run in r v. 3.3.2 (R Development Core Team, ) and jags v 4.2.0 (Plummer, ) using bsam v. 1.1.1 (Jonsen, ) for ARGOS data and in TMB v. 1.7.4 (Kristensen, Nielsen, Berg, Skaug, & Bell, ) for GLS data using modified code (Auger‐Méthé et al., ). In bsam , two Markov chain Monte Carlo chains were run for 40,000 iterations with a 20,000‐sample burn‐in and thinned every 20 samples.…”

Section: Methodsmentioning

confidence: 99%

Abundance and species diversity hotspots of tracked marine predators across the North American Arctic

Yurkowski

Auger‐Méthé

Mallory

et al. 2018

Diversity and Distributions

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Aim Climate change is altering marine ecosystems worldwide and is most pronounced in the Arctic. Economic development is increasing leading to more disturbances and pressures on Arctic wildlife. Identifying areas that support higher levels of predator abundance and biodiversity is important for the implementation of targeted conservation measures across the Arctic. Location Primarily Canadian Arctic marine waters but also parts of the United States, Greenland and Russia. Methods We compiled the largest data set of existing telemetry data for marine predators in the North American Arctic consisting of 1,283 individuals from 21 species. Data were arranged into four species groups: (a) cetaceans and pinnipeds, (b) polar bears Ursus maritimus (c) seabirds, and (d) fishes to address the following objectives: (a) to identify abundance hotspots for each species group in the summer–autumn and winter–spring; (b) to identify species diversity hotspots across all species groups and extent of overlap with exclusive economic zones; and (c) to perform a gap analysis that assesses amount of overlap between species diversity hotspots with existing protected areas. Results Abundance and species diversity hotpots during summer–autumn and winter–spring were identified in Baffin Bay, Davis Strait, Hudson Bay, Hudson Strait, Amundsen Gulf, and the Beaufort, Chukchi and Bering seas both within and across species groups. Abundance and species diversity hotpots occurred within the continental slope in summer–autumn and offshore in areas of moving pack ice in winter–spring. Gap analysis revealed that the current level of conservation protection that overlaps species diversity hotspots is low covering only 5% (77,498 km2) in summer–autumn and 7% (83,202 km2) in winter–spring. Main conclusions We identified several areas of potential importance for Arctic marine predators that could provide policymakers with a starting point for conservation measures given the multitude of threats facing the Arctic. These results are relevant to multilevel and multinational governance to protect this vulnerable ecosystem in our rapidly changing world.

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Spatiotemporal modelling of marine movement data using Template Model Builder (TMB)

Cited by 53 publications

References 54 publications

Movement responses to environment: fast inference of variation among southern elephant seals with a mixed effects model

Movement responses to environment: fast inference of variation among southern elephant seals with a mixed effects model

Novel step selection analyses on energy landscapes reveal how linear features alter migrations of soaring birds

Abundance and species diversity hotspots of tracked marine predators across the North American Arctic

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