Camera traps with white flash are a minimally invasive method for long‐term bat monitoring

Krivek, Gabriella; Schulze, Brian; Pölöskei, P. Zs.; Frankowski, Karina; Mathgen, Xenia; Douwes, Aenne; Schaik, Jaap van

doi:10.1002/rse2.243

Cited by 10 publications

(10 citation statements)

References 38 publications

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“…At each hibernaculum, we collected 15 weeks of video data from August 1 to 4, December 2020 (here referred to as ‘autumn’), and another 15 weeks from 20 February to 4 June 2021 (here referred to as ‘spring’) using self‐built infrared video cameras (as described in Krivek et al, 2022; see https://gabik-bat.github.io/FlederCam/ for construction details). From the resulting 11 868 hours of raw infrared video recording, 6‐second‐long video clips were isolated for each event registered by the light barrier.…”

Section: Methodsmentioning

confidence: 99%

“…At each hibernaculum, we collected 15 weeks of video data from August 1 to 4, December 2020 (here referred to as 'autumn'), and another 15 weeks from 20 February to 4 June 2021 (here referred to as 'spring') using self-built infrared video cameras (as described in Krivek et al, 2022; see For each site, we indicate the type of underground structure and if it was accessible or not for visual surveys (roost type), the light barrier model installed at each entrance at the site (Liba-4/16/16k), and the positioning of the light barriers relative to the entrance (integrated within the opening, or mounted on the wall at the back of the opening). Species composition refers to the bat species recorded during the last winter count (NA: sites are inaccessible); bold species represent 25% of the visually counted population.…”

Section: Infrared Video Monitoring and Scoringmentioning

confidence: 99%

“…At sites with up to several thousand bats, a camera trap triggered by a light barrier can be used to obtain relative species abundances. Along these lines, we have previously shown that such custom-built camera traps are minimally invasive and do not noticeably affect bat behavior (Krivek et al, 2022). At large and remote sites, camera trap monitoring may not always be feasible due to power limitations and data volume.…”

Section: Future Challengesmentioning

confidence: 99%

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Counting in the dark: estimating population size and trends of bat assemblages at hibernacula using infrared light barriers

Krivek

Mahecha

Meier

et al. 2023

Animal Conservation

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Accurate population estimates are crucial to developing successful conservation policy, but the underlying data remain difficult to collect for many taxa. This is especially true for elusive species, such as temperate‐zone bats, where visual counts in hibernacula underestimate their population to an unknown extent. Infrared light barriers that count all entering and exiting bats at the entrance of a hibernaculum could offer a more accurate alternative for bat population monitoring. We used infrared video recordings to quantify light barrier accuracy (i.e., concordance between light barrier and video registration of entries and exits) at five hibernacula over 30 weeks during autumn and spring. Subsequently, we developed a standardized methodology to estimate light barrier‐based population sizes based on the number of emerging bats in spring, and compared these estimates to visual counts at 12 sites. Finally, we calculated confidence intervals around the estimated population sizes, and used these to evaluate population trends using 6‐year‐long light barrier datasets from four sites. Light barrier accuracy varied based on the model and precise location of the installation, with the best combination achieving near‐perfect accuracy across the entire emergence phase. When compared to the resulting light barrier‐based population estimates, winter hibernation counts markedly underestimated population totals, recovering less than 10% of the bats at the most complex sites. Moreover, light barrier‐based population trends showed regional patterns of growth and decline, which were not evident in the visual counts. This study demonstrates that light barriers can estimate the population size and trends of bat assemblages with unprecedented accuracy, even at large, complex, or inaccessible hibernacula that cannot be precisely assessed with visual hibernation counts. Installing light barriers at a representative network of sites, where their installation does not require large‐scale entrance modifications, has the potential to revolutionize bat monitoring and contribute to data‐driven conservation.

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Section: Methodsmentioning

confidence: 99%

Section: Infrared Video Monitoring and Scoringmentioning

confidence: 99%

Section: Future Challengesmentioning

confidence: 99%

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Counting in the dark: estimating population size and trends of bat assemblages at hibernacula using infrared light barriers

Krivek

Mahecha

Meier

et al. 2023

Animal Conservation

Self Cite

View full text Add to dashboard Cite

show abstract

“…1B–D). Moreover, bats do not change their behavior in response to the fast, white flash of such camera traps (1/5500 s, 1/16 power), making these photo‐monitoring systems suitable as a minimally invasive method for bat monitoring (Krivek et al., 2022). These camera traps can either be installed on the inner side of the light barrier and be triggered by each bat entering the hibernaculum (i.e., ‘entry’ camera), and/or on the outer side and be triggered by each bat leaving the hibernaculum (i.e., ‘exit’ camera).…”

Section: Introductionmentioning

confidence: 99%

BatNet: a deep learning‐based tool for automated bat species identification from camera trap images

Krivek,

Gillert,

Harder

et al. 2023

Remote Sens Ecol Conserv

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Automated monitoring technologies can increase the efficiency of ecological data collection and support data‐driven conservation. Camera traps coupled with infrared light barriers can be used to monitor temperate‐zone bat assemblages at underground hibernacula, where thousands of individuals of multiple species can aggregate in winter. However, the broad‐scale adoption of such photo‐monitoring techniques is limited by the time‐consuming bottleneck of manual image processing. Here, we present BatNet, an open‐source, deep learning‐based tool for automated identification of 13 European bat species from camera trap images. BatNet includes a user‐friendly graphical interface, where it can be retrained to identify new bat species or to create site‐specific models to improve detection accuracy at new sites. Model accuracy was evaluated on images from both trained and untrained sites, and in an ecological context, where community‐ and species‐level metrics (species diversity, relative abundance, and species‐level activity patterns) were compared between human experts and BatNet. At trained sites, model performance was high across all species (F1‐score: 0.98–1). At untrained sites, overall classification accuracy remained high (96.7–98.2%), when camera placement was comparable to the training images (<3 m from the entrance; <45° angle relative to the opening). For atypical camera placements (>3 m or >45° angle), retraining the detector model with 500 site‐specific annotations achieved an accuracy of over 95% at all sites. In the ecological case study, all investigated metrics were nearly identical between human experts and BatNet. Finally, we exemplify the ability to retrain BatNet to identify a new bat species, achieving an F1‐score of 0.99 while maintaining high classification accuracy for all original species. BatNet can be implemented directly to scale up the deployment of camera traps in Europe and enhance bat population monitoring. Moreover, the pretrained model can serve as a baseline for transfer learning to automatize the image‐based identification of bat species worldwide.

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“…The use of radar sensors in wildlife monitoring typically results in a lot of FP when there is wind or rain [9]. By using infrared light barriers to detect living beings, a detection occurs when the light barrier is crossed, limiting the camera's triggering to a very limited space [10].…”

Section: Introductionmentioning

confidence: 99%

Sensor Fusion of 3D Time-of-Flight and Thermal Infrared Camera for Presence Detection of Living Beings

et al. 2022

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Presence detection of living beings is a key processing step in many applications. To increase the detection accuracy, an algorithm that uses camera fusion of a 3D Time-of-Flight (3D ToF) and a Long-Wave Infrared (LWIR) camera is applied and characterized here. Different sensor fusion approaches and sensor data processing schemes are compared. The algorithms are applied to a typical wildlife detection dataset and their performance is evaluated. The detection accuracy is up to 10 % higher when combining 3D ToF and LWIR images compared to only 3D ToF or LWIR images. Additionally, the location and size of the living being can be determined using the 3D ToF image.

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Camera traps with white flash are a minimally invasive method for long‐term bat monitoring

Cited by 10 publications

References 38 publications

Counting in the dark: estimating population size and trends of bat assemblages at hibernacula using infrared light barriers

Counting in the dark: estimating population size and trends of bat assemblages at hibernacula using infrared light barriers

BatNet: a deep learning‐based tool for automated bat species identification from camera trap images

Sensor Fusion of 3D Time-of-Flight and Thermal Infrared Camera for Presence Detection of Living Beings

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