Bat Detective - Deep Learning Tools for Bat Acoustic Signal Detection

Aodha, Oisin Mac; Gibb, Rory; Barlow, Kate E.; Browning, Ella; Firman, Michael; Freeman, Robin; Harder, Briana; Kinsey, Libby; Mead, Gary R.; Newson, Stuart E.; Pandourski, Ivan; Parsons, Stuart; Russ, Jon; Szodoray‐Paradi, Abigel; Szodoray‐Parádi, Farkas; Tilova, Elena; Brostow, Gabriel J.; Jones, Kate

doi:10.1101/156869

Cited by 35 publications

(57 citation statements)

References 56 publications

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“…An early use of this in bioacoustics can be seen in the work of Halkias et al (2013) 191 that demonstrated the ability of deep Boltzmann machines to distinguish mysticete species. Deep CNNs have been used for bat species identification 204 and have become one of the dominant types of recognizers for bird species identification since the successful introduction of CNNs in the LifeCLEF bird identification task. 205 Unsupervised ML has not been used as extensively in bioacoustics but is nonetheless present.…”

Section: Bioacousticsmentioning

confidence: 99%

Machine learning in acoustics: Theory and applications

Bianco

Gerstoft

Traer

et al. 2019

The Journal of the Acoustical Society of America

392

126

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Acoustic data provide scientific and engineering insights in fields ranging from biology and communications to ocean and Earth science. We survey the recent advances and transformative potential of machine learning (ML), including deep learning, in the field of acoustics. ML is a broad family of statistical techniques for automatically detecting and utilizing patterns in data. Relative to conventional acoustics and signal processing, ML is data-driven. Given sufficient training data, ML can discover complex relationships between features and desired labels or actions, or between features themselves. With large volumes of training data, ML can discover models describing complex acoustic phenomena such as human speech and reverberation. ML in acoustics is rapidly developing with compelling results and significant future promise. We first introduce ML, then highlight ML developments in five acoustics research areas: source localization in speech processing, source localization in ocean acoustics, bioacoustics, seismic exploration, and environmental sounds in everyday scenes.

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Section: Bioacousticsmentioning

confidence: 99%

Machine learning in acoustics: Theory and applications

Bianco

Gerstoft

Traer

et al. 2019

The Journal of the Acoustical Society of America

392

126

View full text Add to dashboard Cite

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“…Given a short audio-clip we want to classify it as containing a signal produced by the species of interest (in this case an elephant rumble) or not. This setting has been considered by many previous authors (Mac Aodha et al 2018;Nichols 2016;Bittle and Duncan 2013), and is a crucial stepping stone toward using PAM for population surveying and monitoring. A similar setting we consider is one of segmentation where we want to classify each discrete time step as belonging to an elephant call or not.…”

Section: Classification and Segmentationmentioning

confidence: 99%

“…Popular strategies include SVMs based upon MFCC (Dufour et al 2014), segmentation via deep learning (Koops, Van Balen, and Wiering 2015) and dictionary learning (Salamon et al 2017). Beyond birds, insects (Ganchev and Potamitis 2007), bats (Mac Aodha et al 2018) and monkeys (Turesson et al 2016) have all been considered. Elephants have been studied from a similar perspective to ours by Pleiss, Wrege, and Gomes.…”

Section: Related Work Bioacousticsmentioning

confidence: 99%

Automatic Detection and Compression for Passive Acoustic Monitoring of the African Forest Elephant

Björck

Rappazzo

Chen

et al. 2019

AAAI

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In this work, we consider applying machine learning to the analysis and compression of audio signals in the context of monitoring elephants in sub-Saharan Africa. Earths biodiversity is increasingly under threat by sources of anthropogenic change (e.g. resource extraction, land use change, and climate change) and surveying animal populations is critical for developing conservation strategies. However, manually monitoring tropical forests or deep oceans is intractable. For species that communicate acoustically, researchers have argued for placing audio recorders in the habitats as a costeffective and non-invasive method, a strategy known as passive acoustic monitoring (PAM). In collaboration with conservation efforts, we construct a large labeled dataset of passive acoustic recordings of the African Forest Elephant via crowdsourcing, compromising thousands of hours of recordings in the wild. Using state-of-the-art techniques in artificial intelligence we improve upon previously proposed methods for passive acoustic monitoring for classification and segmentation. In real-time detection of elephant calls, network bandwidth quickly becomes a bottleneck and efficient ways to compress the data are needed. Most audio compression schemes are aimed at human listeners and are unsuitable for low-frequency elephant calls. To remedy this, we provide a novel end-to-end differentiable method for compression of audio signals that can be adapted to acoustic monitoring of any species and dramatically improves over nive coding strategies.

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“…Convolutional neural networks (CNNs) have been used to predict the presence of a search-phase bat echolocation call in spectrograms. This binary classification problem was used to detect the presence of bats [2]. To our knowledge, the use of deep learning techniques to separate animal calls that overlap in both time and frequency space has yet to be reported.…”

Section: Introductionmentioning

confidence: 99%

“…The primary objective of this study is to develop a technique for separating two target signals (echolocation and socialization calls) from mixtures of acoustic sounds. Although deep leaning has been employed in the acoustic classification of multiple species, including nonhuman primates [28], birds [4], whales [5], and bats [2, 3], the goal of the present study is distinct from these previous cases in which deep neural networks were primarily used as classifiers.…”

Section: Introductionmentioning

confidence: 99%