Acoustic identification of Mexican bats based on taxonomic and ecological constraints on call design

Zamora‐Gutiérrez, Veronica; López‐González, Celia; González, Marcela Hebe; Fenton, Brock; Jones, Gareth; Kalko, Elisabeth K. V.; Puechmaille, Sébastien J.; Stathopoulos, Vassilios; Jones, Kate

doi:10.1111/2041-210x.12556

Cited by 54 publications

(42 citation statements)

References 46 publications

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“…Recently, different automated approaches, typically employing multivariate sets of spectral and temporal variables of bat calls, have been attempted with variable results (e.g. Parsons and Jones, 2000;Walters et al, 2012;Zamora-Gutierrez et al, 2016). Freeware and commercial software used to speed up the screening of long recordings, select echolocation calls and identify species have recently appeared and are used extensively.…”

Section: Introductionmentioning

confidence: 99%

Testing the performances of automated identification of bat echolocation calls: A request for prudence

Rydell

Nyman

Eklöf

et al. 2017

Ecological Indicators

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105

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Section: Introductionmentioning

confidence: 99%

Testing the performances of automated identification of bat echolocation calls: A request for prudence

Rydell

Nyman

Eklöf

et al. 2017

Ecological Indicators

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105

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“…Many bats use echolocation, an active sensory system (Nelson & MacIver, 2006), as main remote sense for perceiving their environment. Researchers take advantage of this continuous stream of echolocation calls to acoustically monitor bat presence/absence, activity and behavior and, in certain cases, to identify species (Andreassen, Surlykke, & Hallam, 2014;Walters et al, 2012;Zamora-Gutierrez et al, 2016). Beyond academic research, these data are used for risk assessment (e.g., at wind turbines; e.g., Newson et al, 2017), to infer population density, diversity, and vulnerability of bats (Clement, Rodhouse, Ormsbee, Szewczak, & Nichols, 2014;Meyer et al, 2011), and to inform risk mitigation and conservation strategies (Meyer, 2015), often based on automatic call analysis software (Russo & Voigt, 2016;Rydell, Nyman, Eklöf, Jones, & Russo, 2017).…”

Section: Introductionmentioning

confidence: 99%

Weather conditions determine attenuation and speed of sound: Environmental limitations for monitoring and analyzing bat echolocation

Goerlitz

2018

Ecology and Evolution

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Echolocating bats are regularly studied to investigate auditory‐guided behaviors and as important bioindicators. Bioacoustic monitoring methods based on echolocation calls are increasingly used for risk assessment and to ultimately inform conservation strategies for bats. As echolocation calls transmit through the air at the speed of sound, they undergo changes due to atmospheric and geometric attenuation. Both the speed of sound and atmospheric attenuation, however, are variable and determined by weather conditions, particularly temperature and relative humidity. Changing weather conditions thus cause variation in analyzed call parameters, limiting our ability to detect, and correctly analyze bat calls. Here, I use real‐world weather data to exemplify the effect of varying weather conditions on the acoustic properties of air. I then present atmospheric attenuation and speed of sound for the global range of weather conditions and bat call frequencies to show their relative effects. Atmospheric attenuation is a nonlinear function of call frequency, temperature, relative humidity, and atmospheric pressure. While atmospheric attenuation is strongly positively correlated with call frequency, it is also significantly influenced by temperature and relative humidity in a complex nonlinear fashion. Variable weather conditions thus result in variable and unknown effects on the recorded call, affecting estimates of call frequency and intensity, particularly for high frequencies. Weather‐induced variation in speed of sound reaches up to about ±3%, but is generally much smaller and only relevant for acoustic localization methods of bats. The frequency‐ and weather‐dependent variation in atmospheric attenuation has a threefold effect on bioacoustic monitoring of bats: It limits our capability (1) to monitor bats equally across time, space, and species, (2) to correctly measure frequency parameters of bat echolocation calls, particularly for high frequencies, and (3) to correctly identify bat species in species‐rich assemblies or for sympatric species with similar call designs.

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“…Perhaps the most fundamental knowledge gap for PAM is the limited availability of comprehensive, expert‐verified species call databases for reference and training data. Much remains unknown about the intra‐ and interspecific call diversity of even well‐studied taxa (Kershenbaum et al., ), and ground‐truthed call databases are difficult and laborious to assemble, requiring the collection of high‐quality audio recordings of animals identified to species either visually or through capture (e.g., Zamora‐Gutierrez et al., ). Where such verified datasets exist they are biased towards vertebrates (particularly cetaceans, bats, and birds), with especially scarce resources for anurans and invertebrates (Lehmann, Frommolt, Lehmann, & Riede, ; Penone et al., ) and regions outside Europe and North America, despite the urgent need for tools to facilitate monitoring of subtropical and tropical habitats (Zamora‐Gutierrez et al., ).…”

Section: Detecting and Classifying Acoustic Signals Within Audio Datamentioning

confidence: 99%

“…Much remains unknown about the intra‐ and interspecific call diversity of even well‐studied taxa (Kershenbaum et al., ), and ground‐truthed call databases are difficult and laborious to assemble, requiring the collection of high‐quality audio recordings of animals identified to species either visually or through capture (e.g., Zamora‐Gutierrez et al., ). Where such verified datasets exist they are biased towards vertebrates (particularly cetaceans, bats, and birds), with especially scarce resources for anurans and invertebrates (Lehmann, Frommolt, Lehmann, & Riede, ; Penone et al., ) and regions outside Europe and North America, despite the urgent need for tools to facilitate monitoring of subtropical and tropical habitats (Zamora‐Gutierrez et al., ). These gaps translate into equivalent biases in classifier availability, and to our knowledge no widely available tools exist for distinguishing intraspecific acoustic behaviours (e.g., social from echolocation calls in cetaceans and bats) (Figure e), although machine learning methods have successfully been applied to analysis of bat acoustic social behaviour (Prat et al., ).…”

Section: Detecting and Classifying Acoustic Signals Within Audio Datamentioning

confidence: 99%

Emerging opportunities and challenges for passive acoustics in ecological assessment and monitoring

et al. 2018

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High‐throughput environmental sensing technologies are increasingly central to global monitoring of the ecological impacts of human activities. In particular, the recent boom in passive acoustic sensors has provided efficient, noninvasive, and taxonomically broad means to study wildlife populations and communities, and monitor their responses to environmental change. However, until recently, technological costs and constraints have largely confined research in passive acoustic monitoring (PAM) to a handful of taxonomic groups (e.g., bats, cetaceans, birds), often in relatively small‐scale, proof‐of‐concept studies. The arrival of low‐cost, open‐source sensors is now rapidly expanding access to PAM technologies, making it vital to evaluate where these tools can contribute to broader efforts in ecology and biodiversity research. Here, we synthesise and critically assess the current emerging opportunities and challenges for PAM for ecological assessment and monitoring of both species populations and communities. We show that terrestrial and marine PAM applications are advancing rapidly, facilitated by emerging sensor hardware, the application of machine learning innovations to automated wildlife call identification, and work towards developing acoustic biodiversity indicators. However, the broader scope of PAM research remains constrained by limited availability of reference sound libraries and open‐source audio processing tools, especially for the tropics, and lack of clarity around the accuracy, transferability and limitations of many analytical methods. In order to improve possibilities for PAM globally, we emphasise the need for collaborative work to develop standardised survey and analysis protocols, publicly archived sound libraries, multiyear audio datasets, and a more robust theoretical and analytical framework for monitoring vocalising animal communities.

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Acoustic identification of Mexican bats based on taxonomic and ecological constraints on call design

Cited by 54 publications

References 46 publications

Testing the performances of automated identification of bat echolocation calls: A request for prudence

Testing the performances of automated identification of bat echolocation calls: A request for prudence

Weather conditions determine attenuation and speed of sound: Environmental limitations for monitoring and analyzing bat echolocation

Emerging opportunities and challenges for passive acoustics in ecological assessment and monitoring

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