A JAR of Chirps: The Gymnotiform Chirp Can Function as Both a Communication Signal and a Jamming Avoidance Response

Field, Caitlin E; Petersen, Thiago Alexandre; Alves-Gomes, José Antônio; Braun, Christopher B.

doi:10.3389/fnint.2019.00055

Cited by 6 publications

(1 citation statement)

References 43 publications

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“… 2018 ; Allen and Marsat 2019 ; Field et al. 2019 ) and a method based on assumed chirp waveform (Eske et al. 2023 ) have been used for chirp detection.…”

Section: Introductionmentioning

confidence: 99%

Supervised learning algorithm for analysis of communication signals in the weakly electric fish Apteronotus leptorhynchus

Lehotzky,

Zupanc

2023

J Comp Physiol A

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Signal analysis plays a preeminent role in neuroethological research. Traditionally, signal identification has been based on pre-defined signal (sub-)types, thus being subject to the investigator’s bias. To address this deficiency, we have developed a supervised learning algorithm for the detection of subtypes of chirps—frequency/amplitude modulations of the electric organ discharge that are generated predominantly during electric interactions of individuals of the weakly electric fish Apteronotus leptorhynchus. This machine learning paradigm can learn, from a ‘ground truth’ data set, a function that assigns proper outputs (here: time instances of chirps and associated chirp types) to inputs (here: time-series frequency and amplitude data). By employing this artificial intelligence approach, we have validated previous classifications of chirps into different types and shown that further differentiation into subtypes is possible. This demonstration of its superiority compared to traditional methods might serve as proof-of-principle of the suitability of the supervised machine learning paradigm for a broad range of signals to be analyzed in neuroethology.

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“… 2018 ; Allen and Marsat 2019 ; Field et al. 2019 ) and a method based on assumed chirp waveform (Eske et al. 2023 ) have been used for chirp detection.…”

Section: Introductionmentioning

confidence: 99%

Supervised learning algorithm for analysis of communication signals in the weakly electric fish Apteronotus leptorhynchus

Lehotzky,

Zupanc

2023

J Comp Physiol A

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Why the brown ghost chirps at night

Oboti

Pedraja

Ritter

et al. 2022

Preprint

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Since the pioneering work by Moeller, Szabo and Bullock, weakly electric fish have been widely used as a model to approach the study of both spatial and social cognitive abilities in a vertebrate taxon typically less approachable than mammals or other terrestrial vertebrates. Through their electric organ, weakly electric fish generate low-intensity electric fields around their bodies with which they scan the environment and manage to orient themselves and interact with conspecifics even in complete darkness. The brown ghost knifefish is probably the most studied species due to the large repertoire of individually variable and sex-specific electric signals it produces. Their rich electric vocabulary is composed of brief frequency modulations - orchirps- of the oscillating dipole moment constantly emitted by their electric organ. Because chirps come in differenttypes, each carrying very specific and behaviorally salient information, they can be used as references to specific internal states during recordings - of either the brain or the electric organ - or during behavioral observations. Not surprisingly, this made the fortune of this model in neuroethology during the past 7 decades. Yet, truth is, this is not necessarily all true. Although established, to date this view has been supported only by correlative evidence and, to be fair, we still do not have a convincing framework to explain why these freshwater bottom dwellers emit electric chirps. Here we provide evidence for a previously unexplored role of chirps as specialized self-directed signals used to expand conspecific electrolocation ranges during social encounters.

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Communication with self, friends and foes in active-sensing animals

Jones

Allen

Moss

2021

Journal of Experimental Biology

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Animals that rely on electrolocation and echolocation for navigation and prey detection benefit from sensory systems that can operate in the dark, allowing them to exploit sensory niches with few competitors. Active sensing has been characterized as a highly specialized form of communication, whereby an echolocating or electrolocating animal serves as both the sender and receiver of sensory information. This characterization inspires a framework to explore the functions of sensory channels that communicate information with the self and with others. Overlapping communication functions create challenges for signal privacy and fidelity by leaving active-sensing animals vulnerable to eavesdropping, jamming and masking. Here, we present an overview of active-sensing systems used by weakly electric fish, bats and odontocetes, and consider their susceptibility to heterospecific and conspecific jamming signals and eavesdropping. Susceptibility to interference from signals produced by both conspecifics and prey animals reduces the fidelity of electrolocation and echolocation for prey capture and foraging. Likewise, active-sensing signals may be eavesdropped, increasing the risk of alerting prey to the threat of predation or the risk of predation to the sender, or drawing competition to productive foraging sites. The evolutionary success of electrolocating and echolocating animals suggests that they effectively counter the costs of active sensing through rich and diverse adaptive behaviors that allow them to mitigate the effects of competition for signal space and the exploitation of their signals.

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A JAR of Chirps: The Gymnotiform Chirp Can Function as Both a Communication Signal and a Jamming Avoidance Response

Cited by 6 publications

References 43 publications

Supervised learning algorithm for analysis of communication signals in the weakly electric fish Apteronotus leptorhynchus

Supervised learning algorithm for analysis of communication signals in the weakly electric fish Apteronotus leptorhynchus

Why the brown ghost chirps at night

Communication with self, friends and foes in active-sensing animals

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