A Complexity-Entropy Based Approach for the Detection of Fish Choruses

A Complexity-Entropy Based Approach for the Detection of Fish Choruses

Automated acoustic indices to infer biological sounds from marine recordings have produced mixed levels of success. The use of such indices in complex marine environments, dominated by several anthropogenic and geophonic sources, have yet to be understood fully. In this study, we introduce a noise r...

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Bibliographic Details
Published in:Entropy (Basel, Switzerland) Vol. 21; no. 10; p. 977
Main Authors: Siddagangaiah, Shashidhar, Chen, Chi-Fang, Hu, Wei-Chun, Pieretti, Nadia
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-10-2019
MDPI
Subjects:
acoustic indices
Acoustic noise
Acoustics
Biodiversity
Complexity
Correlation
eastern taiwan strait
ecoacoustics
Entropy
Fish
fish choruses
Marine biology
Marine environment
marine environments
Noise
Noise levels
passive acoustic monitoring
Probability
Probability distribution
Shipping
Sound
Sound sources
Time series
Taiwan Strait
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Summary:Automated acoustic indices to infer biological sounds from marine recordings have produced mixed levels of success. The use of such indices in complex marine environments, dominated by several anthropogenic and geophonic sources, have yet to be understood fully. In this study, we introduce a noise resilient method based on complexity-entropy (hereafter named C-H) for the detection of biophonic sounds originating from fish choruses. The C-H method was tested on data collected in Changhua and Miaoli (Taiwan) during the spring in both 2016 and 2017. Miaoli was exposed to continual shipping activity, which led to an increase of ~10 dB in low frequency ambient noise levels (5–500 Hz). The acoustic dataset was successively analyzed via the acoustic complexity index, the acoustic diversity index and the bioacoustic index. The C-H method was found to be strongly correlated with fish chorusing (Pearson correlation: rH < −0.9; rC > 0.89), and robust to noise originating from shipping activity or natural sources, such as wind and tides (rH and rC were between 0.22 and −0.19). Other indices produced lower or null correlations with fish chorusing due to missed identification of the choruses or sensitivity to other sound sources. In contrast to most acoustic indices, the C-H method does not require a prior setting of frequency and amplitude thresholds, and is therefore, more user friendly to untrained technicians. We conclude that the use of the C-H method has potential implications in the efficient detection of fish choruses for management or conservation purposes and could help with overcoming the limitations of acoustic indices in noisy marine environments.
ISSN:1099-4300
1099-4300
DOI:10.3390/e21100977