Spatial Capture-Recapture with Partial Identity: An Application to Camera Traps

Augustine, Ben C.; Royle, J. Andrew; Kelly, Marcella J.; Satter, Christopher B.; Alonso, Robert S.; Boydston, Erin E.; Crooks, Kevin R.

doi:10.1101/056804

Cited by 16 publications

(22 citation statements)

References 30 publications

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“…When marked and unmarked individuals cannot be reconciled with certainty, density will be overestimated—as observed here—because the number of unmarked individuals is inflated by misidentification of marked animals. Extending partial identity models (Augustine et al., ) that address irreconcilability of two individual identities produced by the same individual (e.g. DNA and individual markings) to address correlation among spatially proximate marked and unmarked detections might reduce this bias, while preserving gains in precision from incorporating individual detections.…”

Section: Discussionmentioning

confidence: 99%

Evaluating spatially explicit density estimates of unmarked wildlife detected by remote cameras

Evans

Rittenhouse

2018

Journal of Applied Ecology

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Remote cameras have become a promising, cost‐effective tool for monitoring wildlife populations. Yet, for species where individuals are indistinguishable, remote cameras’ ability to provide robust and precise density estimates has been limited without the use of invasive marking. Using the American black bear as a model species, we evaluated methods for estimating wildlife densities using remote camera detections of unmarked individuals against estimates from spatial capture–recapture (SCR) models using individual detections. We also tested the effect of incorporating varying proportions of marked individuals on model accuracy and precision. Spatial count (SC) models using unmarked individuals produced estimates of bear density within 0.6% of those from SCR. We extended SC models to incorporate variation in density as a function of land use/land cover, and identified identical relationships between variation in bear densities and housing density as obtained using SCR. Incorporating individual detection data from simultaneous non‐invasive genetic sampling lead to more precise, but biased estimates. Synthesis and applications. Our results identify contexts in which camera count data can be used as an alternative to spatial capture–recapture (SCR) when individual identification is prohibitive. Spatial count models provided an accurate, but less precise replication of spatial capture–recapture density estimates and may provide consistent insights into spatial variation in density. Mixed samples of camera counts and auxiliary individual detections are likely to be of limited use, but fitting spatial count models to populations with partial visual markings could improve their precision.

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Section: Discussionmentioning

confidence: 99%

Evaluating spatially explicit density estimates of unmarked wildlife detected by remote cameras

Evans

Rittenhouse

2018

Journal of Applied Ecology

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“…u | n u , y obs ), but the latent encounter histories can be sampled from their posterior distribution using Markov chain Monte Carlo (MCMC) sampling (see Appendix ). This flexible approach for updating encounter histories can be easily expanded to include other covariates such as sex or age of marked, unknown or unmarked animals that can be used to further limit the pool of potential individuals and thus increase precision of parameter estimates (Augustine et al., ). Conditional on the partially observed encounter histories, y R can be modelled with σ and resighting encounter rates

λ_{0}^{R}

using standard SCR observation models.…”

Section: Methodsmentioning

confidence: 99%

Generalized spatial mark–resight models with an application to grizzly bears

Whittington

Hebblewhite

Chandler

2017

Journal of Applied Ecology

126

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Abstract1. The high cost associated with capture-recapture studies presents a major challenge when monitoring and managing wildlife populations. Recently developed spatial mark-resight (SMR) models were proposed as a cost-effective alternative because they only require a single marking event. However, existing SMR models ignore the marking process and make the tenuous assumption that marked and unmarked populations have the same encounter probabilities. This assumption will be violated in most situations because the marking process results in different spatial distributions of marked and unmarked animals.2. We developed a generalized SMR model that includes sub-models for the marking and resighting processes, thereby relaxing the assumption that marked and unmarked populations have the same spatial distributions and encounter probabilities.3. Our simulation study demonstrated that conventional SMR models produce biased density estimates with low credible interval coverage (CIC) when marked and unmarked animals had differing spatial distributions. In contrast, generalized SMR models produced unbiased density estimates with correct CIC in all scenarios.4. We applied our SMR model to grizzly bear (Ursus arctos) data where the marking process occurred along a transportation route through Banff and Yoho National Parks, Canada. Twenty-two grizzly bears were trapped, fitted with radiocollars and then detected along with unmarked bears on 214 remote cameras. Closed population density estimates (posterior median ± 1 SD) averaged from 2012 to 2014 were much lower for conventional SMR models (7.4 ± 1.0 bears per 1,000 km 2 ) than for generalized SMR models (12.4 ± 1.5). When compared to previous DNA-based estimates, conventional SMR estimates erroneously suggested a 51% decline in density. Conversely, generalized SMR estimates were similar to previous estimates, indicating that the grizzly bear population was relatively stable. Synthesis and applications.Mark-resight studies often cost less than capture-recapture studies, but require that marked and unmarked animals have equal encounter rates. Generalized spatial mark-resight models relax this assumption by including sub-models for both the marking and resighting processes. They produce unbiased density estimates even when marked and unmarked animals have differing spatialThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…Both Mexican gray wolves and red wolves are annually radiomonitored and attempts to estimate their population densities and abundances have either failed because of sparse detection data or resulted in imprecise and possibly biased estimates (Adams et al 2003, Piaggio et al 2016, Seamster et al 2016, Hinton et al 2017. Spatial partial identity models that probabilistically link spatial detections of partial individuality to improve precision of spatial capture-recapture density estimates (Augustine et al 2018a) have been recently extended to incorporate partial genotypes from noninvasive genetic detection data (Augustine et al 2018b). Spatial partial identity models that probabilistically link spatial detections of partial individuality to improve precision of spatial capture-recapture density estimates (Augustine et al 2018a) have been recently extended to incorporate partial genotypes from noninvasive genetic detection data (Augustine et al 2018b).…”

Section: Notesmentioning

confidence: 99%