Towards the Acoustic Monitoring of Birds Migrating at Night

Pamuła, Hanna; Pocha, Agnieszka; Kłaczyński, Maciej

doi:10.3897/biss.3.36589

Cited by 8 publications

(6 citation statements)

References 7 publications

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“…There were only two studies for which transfer learning did not improve results as opposed to training the CNN from randomly initialised weights (Morgan and Braasch, 2021;Pamula et al, 2020). There are also studies in the literature for which the authors implement their own CNN from randomly initialised weights and do not make use of transfer learning (Ruff et al, 2020;Dufourq et al, 2021;Nolasco et al, 2019) and other studies for which the authors make use of existing architectures but did not use transfer learning (Bergler et al, 2019;Jiang et al, 2019).…”

Section: Related Literaturementioning

confidence: 99%

Passive acoustic monitoring of animal populations with transfer learning

Dufourq

Batist

Foquet³

et al. 2022

Ecological Informatics

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Section: Related Literaturementioning

confidence: 99%

Passive acoustic monitoring of animal populations with transfer learning

Dufourq

Batist

Foquet³

et al. 2022

Ecological Informatics

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“…Deep learning holds enormous promise for automating the labelling of bioacoustic data. The number of applications is growing (Christin et al., 2019), but the majority of datasets are still labelled manually (Fairbrass et al., 2019; Kiskin et al., 2020; Pamula et al., 2019), even as the rate of data collection makes this approach increasingly unsustainable. The mismatch between the potential of deep learning approaches and their actual uptake among practitioners occurs because getting models to perform as well as an experienced human is difficult.…”

Section: Introductionmentioning

confidence: 99%

Automated detection of Hainan gibbon calls for passive acoustic monitoring

Dufourq

Durbach

Hansford

et al. 2021

Remote Sens Ecol Conserv

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Extracting species calls from passive acoustic recordings is a common preliminary step to ecological analysis. For many species, particularly those occupying noisy, acoustically variable habitats, the call extraction process continues to be largely manual, a time-consuming and increasingly unsustainable process. Deep neural networks have been shown to offer excellent performance across a range of acoustic classification applications, but are relatively underused in ecology. We describe the steps involved in developing an automated classifier for a passive acoustic monitoring project, using the identification of calls of the Hainan gibbon Nomascus hainanus, one of the world's rarest mammal species, as a case study. This includes preprocessing-selecting a temporal resolution, windowing and annotation; data augmentation; processing-choosing and fitting appropriate neural network models; and post-processing-linking model predictions to replace, or more likely facilitate, manual labelling. Our best model converted acoustic recordings into spectrogram images on the mel frequency scale, using these to train a convolutional neural network. Model predictions were highly accurate, with per-second false positive and false negative rates of 1.5% and 22.3%. Nearly all false negatives were at the fringes of calls, adjacent to segments where the call was correctly identified, so that very few calls were missed altogether. A post-processing step identifying intervals of repeated calling reduced an 8-h recording to, on average, 22 min for manual processing, and did not miss any calling bouts over 72 h of test recordings. Gibbon calling bouts were detected regularly in multi-month recordings from all selected survey points within Bawangling National Nature Reserve, Hainan. We demonstrate that passive acoustic monitoring incorporating an automated classifier represents an effective tool for remote detection of one of the world's rarest and most threatened species. Our study highlights the viability of using neural networks to automate or greatly assist the manual labelling of data collected by passive acoustic monitoring projects. We emphasize that model development and implementation be informed and guided by ecological objectives, and increase accessibility of these tools with a series of notebooks that allow users to build and deploy their own acoustic classifiers.

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“…Likewise, in the spatial domain, North American passerines cover a territory of about 10 13 square meters yet their flight calls can only be heard over an area of about 10 4 square meters [18, 26]. The gap between these orders of magnitude implies that bioacoustic sensor networks for bird migration monitoring cannot realistically seek an exhaustive acquisition of all flight calls from Passeriformes [27]. Although they can provide relevant information about species abundance on their own, their ultimate purpose is to serve a complementary source of information to radar aeroecology and crowdsourced observations [28].…”

Section: Introductionmentioning

confidence: 99%

BirdVox: Machine listening for bird migration monitoring

Lostanlen

Cramer

Farnsworth

et al. 2022

Preprint

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The steady decline of avian populations worldwide urgently calls for a cyber-physical system to monitor bird migration at the continental scale. Compared to other sources of information (radar and crowdsourced observations), bioacoustic sensor networks combine low latency with a high taxonomic specificity. However, the scarcity of flight calls in bioacoustic monitoring scenes (below 0.1% of total recording time) requires the automation of audio content analysis. In this article, we address the problem of scaling up the detection and classification of flight calls to a full-season dataset: 6672 hours across nine sensors, yielding around 480 million neural network predictions. Our proposed pipeline, BirdVox, combines multiple machine learning modules to produce per-species flight call counts. We evaluate BirdVox on an annotated subset of the full season (296 hours) and discuss the main sources of estimation error which are inherent to a real-world deployment: mechanical sensor failures, sensitivity to background noise, misdetection, and taxonomic confusion. After developing dedicated solutions to mitigate these sources of error, we demonstrate the usability of BirdVox by reporting a species-specific temporal estimate of flight call activity for the Swainson's Thrush (Catharus ustulatus).

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Towards the Acoustic Monitoring of Birds Migrating at Night

Cited by 8 publications

References 7 publications

Passive acoustic monitoring of animal populations with transfer learning

Passive acoustic monitoring of animal populations with transfer learning

Automated detection of Hainan gibbon calls for passive acoustic monitoring

BirdVox: Machine listening for bird migration monitoring

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