Drawn out of the shadows: Surveying secretive forest species with camera trap distance sampling

Bessone, Mattia; Kühl, Hjalmar S.; Hohmann, Gottfried; Herbinger, Ilka; N’Goran, Kouamé Paul; Asanzi, Papy; Costa, Pedro Beschoren da; Dérozier, Violette; Fotsing, Ernest D. B.; Beka, Bernard Ikembelo; Iyomi, Mpongo D.; Iyatshi, Iyomi B.; Kafando, Pierre; Kambere, Mbangi A.; Moundzoho, Dissondet B.; Wanzalire, Musubaho L. K.; Fruth, Barbara

doi:10.1111/1365-2664.13602

Cited by 65 publications

(96 citation statements)

References 34 publications

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“…The performance of CTDS, however, remains to be tested in various field situations (Moeller et al 2018, but see Bessone et al 2020). Furthermore, although the use of videos or long 'bursts' of images is recommended to align observations to predetermined snapshot moments at specific times of day (Howe et al 2017), researchers and wildlife managers might find this set-up inconvenient and may prefer to use single still images recorded when the camera is triggered (e.g.…”

mentioning

confidence: 99%

A field test of unconventional camera trap distance sampling to estimate abundance of marmot populations

Corlatti

Sivieri²,

Sudolska

et al. 2020

Wildlife Biology

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mentioning

confidence: 99%

A field test of unconventional camera trap distance sampling to estimate abundance of marmot populations

Corlatti

Sivieri²,

Sudolska

et al. 2020

Wildlife Biology

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“…Interestingly, Howe et al [57] used distance sampling on camera trapping data, by placing distance markers in the field of view of the cameras. They and others report a behavioural response to the cameras similar to the one we describe [56,57]. This strongly suggests that the 2D methodology is necessary to apply distance sampling to camera trapping data.…”

Section: Brief Overview Of the Alternatives To Distance Samplingmentioning

confidence: 58%

“…The frequency of animal pictures taken by automatic "camera traps" has also been proposed as an index of abundance [55], including in a context very similar to ours [56,57]. However, the camera-trapping approach may be jeopardized by camera failures and high maintenance costs in the rainforest environment, by poachers, and remains relatively imprecise in the absence of information about the individual identity of the photographed animals, and their local fine-scale microhabitat selection and daily range [40,41,55].…”

Section: Brief Overview Of the Alternatives To Distance Samplingmentioning

confidence: 99%

Distance sampling of duikers in the rainforest: Dealing with transect avoidance

Bonenfant¹,

Péron²

2020

PLoS ONE

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Bushmeat is a major source of protein and income in tropical regions but is often over-harvested. A better monitoring of bushmeat stocks could help achieve sustainability. We used a combination of simulations and transect survey data collected from blue duikers (Philantomba monticola) in the Lomako wildlife reserve, Democratic Republic of the Congo, to investigate the use of transect-based distance sampling to monitor bushmeat stocks. The comparison of dung piles and direct observations of duikers evidenced that animals avoided both the transects in the absence of observers, and the observers themselves. This type of behavioural response appeared common in a literature survey. It causes a negative bias in the estimates of population densities from the standard distance sampling methodology. This negative bias would lead to over-pessimistic predictions of population viability, especially if the behavioural response is more intense in the locations where the animals are hunted. In turn, this would lead to excessively conservative management recommendations. To correct for the effect of the behavioural response of the animals to either the transects or the observers, we recommend recording both the forward and perpendicular distances to the observers (2D distance sampling), not just the perpendicular distance. We also recommend multiple-observer protocols. As a cautionary note, we also demonstrate a scenario where the intensity of the behavioural response is too high to reliably estimate the abundance of the population. As a perspective, we outline the general principles of a local stakeholder-based program combining distance sampling with less intensive types of ecological indicators to monitor wildlife populations.

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“…As a case study, the model was developed for classifying terrestrial forest mammals and birds in Central Africa (see Table S1 for further details on species and groups), where camera traps are now frequently deployed over large spatial scales to survey secretive birds and mammals in remote and inaccessible landscapes (11)(12)(13). Training data were obtained from multiple countries and sources (c.1.6 million images; reduced to n = 347120 images after data processing; Table 1).…”

Section: Data Preparationmentioning

confidence: 99%

“…High performance machine learning models can fully automate labeling of camera trap images for ecological analyses Robin Whytock 1,2 * †, Jędrzej Świeżewski 3 †, Joeri A. Zwerts 4 , Tadeusz Bara-Słupski 4 , Aurélie Flore Koumba Pambo 2 , Marek Rogala 3 , Laila Bahaa-el-din 5 , Kelly Boekee 6,7 , Stephanie Brittain 8,9 , Anabelle W. Cardoso 10 , Philipp Henschel 11,12 , David Lehmann 2,1 , Brice Momboua 2 , Cisquet Hector Ror Kiebou Opepa 13 , Christopher Orbell 11,1 , Ross T. Pitman 11 , Hugh S. Robinson 11,14 , Katharine A. Abernethy 1,12 † These authors contributed equally to the manuscript. *Corresponding author: Robin C. Whytock, robbie.whytock1@stir.ac.uk…”

Section: Supplementary Information Formentioning

confidence: 99%

High performance machine learning models can fully automate labeling of camera trap images for ecological analyses

Whytock

Świeżewski²,

Zwerts

et al. 2020

Preprint

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Ecological data are increasingly collected over vast geographic areas using arrays of digital sensors. Camera trap arrays have become the "gold standard" method for surveying many terrestrial mammals and birds, but these arrays often generate millions of images that are challenging to process. This causes significant latency between data collection and subsequent inference, which can impede conservation at a time of ecological crisis. To address this, machine learning algorithms have been developed to improve data processing speeds, but these models are not considered accurate enough for fully automated labeling. Here, we present a new approach to building and testing a high performance machine learning model for fully automated labeling of camera trap images. As a case-study, the model classifies 26 Central African forest mammal and bird species (or groups). The model was trained on a relatively small dataset (c.300,000 images) but generalizes to fully independent data and outperforms humans in several respects (e.g. detecting "invisible" animals). We show how the model's precision and accuracy can be evaluated in an ecological modeling context by comparing species richness, activity patterns and occupancy derived from machine learning labels with the same estimates derived from expert labels. Results show that fully automated labels can be equivalent to expert labels when calculating these widely-used ecological metrics. We provide the user-community with a multi-platform user interface for running the model offline, and conclude that high performance machine learning models can fully automate labeling of camera trap data.

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Drawn out of the shadows: Surveying secretive forest species with camera trap distance sampling

Cited by 65 publications

References 34 publications

A field test of unconventional camera trap distance sampling to estimate abundance of marmot populations

A field test of unconventional camera trap distance sampling to estimate abundance of marmot populations

Distance sampling of duikers in the rainforest: Dealing with transect avoidance

High performance machine learning models can fully automate labeling of camera trap images for ecological analyses

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