Deploying Acoustic Detection Algorithms on Low-Cost, Open-Source Acoustic Sensors for Environmental Monitoring

Prince, P. Grace Kanmani; Hill, Andrew P.; Piña‐Covarrubias, Evelyn; Doncaster, C. Patrick; Snaddon, Jake L.; Rogers, Alex

doi:10.3390/s19030553

Cited by 58 publications

(36 citation statements)

References 40 publications

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“…This may entail processing data in a distributed fashion using small, inexpensive system-on-chip processing devices coupled to the recording device, or the use of purpose-made recording devices with software for onboard processing, e.g. AudioMoth (Hill et al 2017, Prince et al 2019. Such distributed processing nodes could communicate potential detections to biologists remotely over mobile data networks, streamlining the process of retrieving data from the field and allowing for very rapid responses to emergent issues at field sites (e.g.…”

Section: Discussionmentioning

confidence: 99%

A Convolutional Neural Network and R-Shiny App for Automated Identification and Classification of Animal Sounds

Ruff

Lesmeister

Appel

et al. 2020

Preprint

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The use of passive acoustic monitoring in wildlife ecology has increased dramatically in recent years as researchers take advantage of improvements in automated recording units and associated technologies. These technologies have allowed researchers to collect large quantities of acoustic data which must then be processed to extract meaningful information, e.g. target species detections. A persistent issue in acoustic monitoring is the challenge of processing these data most efficiently to automate the detection of species of interest, and deep learning has emerged as a powerful approach to achieve these objectives. Here we report on the development and use of a deep convolutional neural network for the automated detection of 14 forest-adapted species by classifying spectrogram images generated from short audio clips. The neural network has improved performance compared to models previously developed for some of the target classes. Our neural network performed well for most species and at least satisfactory for others. To improve portability and usability by field biologists, we developed a graphical interface for the neural network that can be run through RStudio using the Shiny package, creating a highly portable solution to efficiently process audio data closer to the point of collection and with minimal delays using consumer-grade computers.

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Section: Discussionmentioning

confidence: 99%

A Convolutional Neural Network and R-Shiny App for Automated Identification and Classification of Animal Sounds

Ruff

Lesmeister

Appel

et al. 2020

Preprint

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“…Undoubtedly, any sensor type related to the context of our application, such as microphones and vision cameras, have advantages and disadvantages [13,14]. Multispectral imaging has been suggested in a different context to our work in agriculture and entomology [15][16][17].…”

Section: Discussionmentioning

confidence: 99%

A Multispectral Backscattered Light Recorder of Insects’ Wingbeats

et al. 2019

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Most reported optical recorders of the wingbeat of insects are based on the so-called extinction light, which is the variation of light in the receiver due to the cast shadow of the insect’s wings and main body. In this type of recording devices, the emitter uses light and is placed opposite to the receiver, which is usually a single (or multiple) photodiode. In this work, we present a different kind of wingbeat sensor and its associated recorder that aims to extract a deeper representational signal of the wingbeat event and color characterization of the main body of the insect, namely: a) we record the backscattered light that is richer in harmonics than the extinction light, b) we use three different spectral bands, i.e., a multispectral approach that aims to grasp the melanization and microstructural and color features of the wing and body of the insects, and c) we average at the receiver’s level the backscattered signal from many LEDs that illuminate the wingbeating insect from multiple orientations and thus offer a smoother and more complete signal than one based on a single snapshot. We present all the necessary details to reproduce the device and we analyze many insects of interest like the bee Apis mellifera, the wasp Polistes gallicus, and some insects whose wingbeating characteristics are pending in the current literature, like Drosophila suzukii and Zaprionus, another member of the drosophilidae family.

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“…Research on those sounds has revealed that it is possible to obtain reliable information of a taxonomic classification and this could be used to measure the biodiversity of a habitat as presented in [5]. The development of tools to have knowledge of the biodiversity will give more information and indicators about the state of the biodiversity [6]. In particular, insects play an important role in ecological balance and biodiversity conservation [4,7].…”

Section: Introductionmentioning

confidence: 99%

Acoustic Classification of Singing Insects Based on MFCC/LFCC Fusion

et al. 2019

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This work introduces a new approach for automatic identification of crickets, katydids and cicadas analyzing their acoustic signals. We propose the building of a tool to identify this biodiversity. The study proposes a sound parameterization technique designed specifically for identification and classification of acoustic signals of insects using Mel Frequency Cepstral Coefficients (MFCC) and Linear Frequency Cepstral Coefficients (LFCC). These two sets of coefficients are evaluated individually as has been done in previous studies and have been compared with the fusion proposed in this work, showing an outstanding increase in identification and classification at species level reaching a success rate of 98.07% on 343 insect species.

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Deploying Acoustic Detection Algorithms on Low-Cost, Open-Source Acoustic Sensors for Environmental Monitoring

Cited by 58 publications

References 40 publications

A Convolutional Neural Network and R-Shiny App for Automated Identification and Classification of Animal Sounds

A Convolutional Neural Network and R-Shiny App for Automated Identification and Classification of Animal Sounds

A Multispectral Backscattered Light Recorder of Insects’ Wingbeats

Acoustic Classification of Singing Insects Based on MFCC/LFCC Fusion

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