A review of camera trapping for conservation behaviour research

Caravaggi, Anthony; Banks, Peter B.; Burton, A. Cole; Finlay, Caroline M. V.; Haswell, Peter M.; Hayward, Matt W.; Rowcliffe, J. Marcus; Wood, Michael D.

doi:10.1002/rse2.48

Cited by 214 publications

(175 citation statements)

References 136 publications

(123 reference statements)

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“…Compared to the often used pitfall traps, camera traps sample more individuals (Collett & Fisher, 2017;Halsall & Wratten, 1988), and cause no depletion of specimens or habitat destruction (Digweed, Currie, Carcamo, & Spence, 1995;Zaller et al, 2015). The average movement speed and various behavioral traits of a species can be directly measured between single frames of one camera trap (Caravaggi et al, 2017), allowing true abundance of species to be estimated based on their movement speed and range. The average movement speed and various behavioral traits of a species can be directly measured between single frames of one camera trap (Caravaggi et al, 2017), allowing true abundance of species to be estimated based on their movement speed and range.…”

Section: Introductionmentioning

confidence: 99%

Species‐level image classification with convolutional neural network enables insect identification from habitus images

Hansen

Svenning

Olsen

et al. 2019

Ecology and Evolution

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1. Changes in insect biomass, abundance, and diversity are challenging to track at sufficient spatial, temporal, and taxonomic resolution. Camera traps can capture habitus images of ground-dwelling insects. However, currently sampling involves manually detecting and identifying specimens. Here, we test whether a convolutional neural network (CNN) can classify habitus images of ground beetles to species level, and estimate how correct classification relates to body size, number of species inside genera, and species identity.2. We created an image database of 65,841 museum specimens comprising 361 carabid beetle species from the British Isles and fine-tuned the parameters of a pretrained CNN from a training dataset. By summing up class confidence values within genus, tribe, and subfamily and setting a confidence threshold, we trade-off between classification accuracy, precision, and recall and taxonomic resolution.3. The CNN classified 51.9% of 19,164 test images correctly to species level and 74.9% to genus level. Average classification recall on species level was 50.7%.Applying a threshold of 0.5 increased the average classification recall to 74.6% at the expense of taxonomic resolution. Higher top value from the output layer and larger sized species were more often classified correctly, as were images of species in genera with few species. 4. Fine-tuning enabled us to classify images with a high mean recall for the whole test dataset to species or higher taxonomic levels, however, with high variability.This indicates that some species are more difficult to identify because of properties such as their body size or the number of related species.5. Together, species-level image classification of arthropods from museum collections and ecological monitoring can substantially increase the amount of occurrence data that can feasibly be collected. These tools thus provide new opportunities in understanding and predicting ecological responses to environmental change. Jens-Christian Svenninghttps://orcid.

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Section: Introductionmentioning

confidence: 99%

Species‐level image classification with convolutional neural network enables insect identification from habitus images

Hansen

Svenning

Olsen

et al. 2019

Ecology and Evolution

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“…Ecological research is experiencing an explosion in the use of wildlife imagery. Camera trapping has become a common noninvasive survey technique (Burton et al, ; O'Connell, Nichols, & Karanth, ; Rowcliffe & Carbone, ), especially for rare and elusive forest‐dwelling species (Furnas, Landers, Callas, & Matthews, ; Stewart et al, ), and has been used to obtain crucial ecological information (Caravaggi et al, ). Landscape‐scale camera grids or transects are increasing across the globe (McShea, Forrester, Costello, He, & Kays, ), and such sampling may be used to monitor global biodiversity in the future (Rich et al, ; Steenweg et al, ).…”

Section: Introductionmentioning

confidence: 99%

Measuring agreement among experts in classifying camera images of similar species

Gooliaff

Hodges

2018

Ecology and Evolution

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Camera trapping and solicitation of wildlife images through citizen science have become common tools in ecological research. Such studies collect many wildlife images for which correct species classification is crucial; even low misclassification rates can result in erroneous estimation of the geographic range or habitat use of a species, potentially hindering conservation or management efforts. However, some species are difficult to tell apart, making species classification challenging—but the literature on classification agreement rates among experts remains sparse. Here, we measure agreement among experts in distinguishing between images of two similar congeneric species, bobcats (Lynx rufus) and Canada lynx (Lynx canadensis). We asked experts to classify the species in selected images to test whether the season, background habitat, time of day, and the visible features of each animal (e.g., face, legs, tail) affected agreement among experts about the species in each image. Overall, experts had moderate agreement (Fleiss’ kappa = 0.64), but experts had varying levels of agreement depending on these image characteristics. Most images (71%) had ≥1 expert classification of “unknown,” and many images (39%) had some experts classify the image as “bobcat” while others classified it as “lynx.” Further, experts were inconsistent even with themselves, changing their classifications of numerous images when they were asked to reclassify the same images months later. These results suggest that classification of images by a single expert is unreliable for similar‐looking species. Most of the images did obtain a clear majority classification from the experts, although we emphasize that even majority classifications may be incorrect. We recommend that researchers using wildlife images consult multiple species experts to increase confidence in their image classifications of similar sympatric species. Still, when the presence of a species with similar sympatrics must be conclusive, physical or genetic evidence should be required.

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“…Camera trapping is nowadays a widely-utilised method to address a variety of biological and ecological questions, especially in mammal research (O'Connell et al, 2011;Caravaggi et al, 2017). Currently, most research employing camera traps is focused on a single taxon, most frequently a species of conservation importance.…”

Section: Introductionmentioning

confidence: 99%

Biodiversity estimates from different camera trap surveys: a case study from Osogovo Mt., Bulgaria

Zlatanova¹,

Popova²

2018

Nat. Cons. Res.

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Inventorying mammal assemblages is vital for their conservation and management, especially when they include rare or endangered species. However, obtaining a correct estimation of the species diversity in a particular area can be challenging due to uncertainties regarding study design and duration. In this paper, we present the biodiversity estimates derived from three unrelated camera trap studies in Osogovo Mt., Bulgaria. They have different duration and positioning schemes of the camera trap locations: Study 1 -grid based, 34 days; Study 2 -random points based, 138 days; Study 3 -locations based on expert opinion, 1437 days. Utilising EstimateS, we compare a number of estimators (Shannon diversity index, Coleman rarefaction curve, ACE (Abundance-based Coverage Estimator), ICE (Incidence-based Coverage Estimator), Chao 1, Chao 2 and Jackknife estimators) to the number of present and confirmed and/or potentially present mammals (excluding bats) in the mountains. A total of 17 mammal species were registered in the three studies, which represents around 76% of the permanently present mammals in the mountain that inhabit its forested area and can be detected by a camera trap. The results point to some guidelines that can aid future camera trap research in temperate forested areas. A grid-based design works best for very short study periods (e.g. 10 days), while the opportunistic expert-based positioning scheme provides good results for longer studies (approx. a month). However, the grid-based design needs to be further tested for longer periods. Generally, the random points approach does not yield satisfactory results. In agreement with other studies, analysis based on the Jackknife procedure (Jack 2) appears to result in the best estimate of species richness. When performing camera trap studies, special care should be taken to minimise the number of unidentifiable photos and to take into account «trap-shy» individuals. The results from this study emphasise the need for careful preliminary planning of camera trap studies depending on aims, duration and target species.

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A review of camera trapping for conservation behaviour research

Cited by 214 publications

References 136 publications

Species‐level image classification with convolutional neural network enables insect identification from habitus images

Species‐level image classification with convolutional neural network enables insect identification from habitus images

Measuring agreement among experts in classifying camera images of similar species

Biodiversity estimates from different camera trap surveys: a case study from Osogovo Mt., Bulgaria

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