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Main Authors: Ou, Wenzhan, Song, Zhongchang, Goertz, Caroline E C, Mooney, T Aran, Dennison, Sophie, Zhang, Chuang, Zhang, Yu, Castellote, Manuel
Format: Artículo científico
Language:en
Published: Bioinspiration & biomimetics 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40138799/
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author Ou, Wenzhan
Song, Zhongchang
Goertz, Caroline E C
Mooney, T Aran
Dennison, Sophie
Zhang, Chuang
Zhang, Yu
Castellote, Manuel
author_facet Ou, Wenzhan
Song, Zhongchang
Goertz, Caroline E C
Mooney, T Aran
Dennison, Sophie
Zhang, Chuang
Zhang, Yu
Castellote, Manuel
Ou, Wenzhan
Song, Zhongchang
Goertz, Caroline E C
Mooney, T Aran
Dennison, Sophie
Zhang, Chuang
Zhang, Yu
Castellote, Manuel
collection PubMed - marine biology
contents Directional sound transmission and reception of the beluga whale (). Ou, Wenzhan Song, Zhongchang Goertz, Caroline E C Mooney, T Aran Dennison, Sophie Zhang, Chuang Zhang, Yu Castellote, Manuel Animals Beluga Whale Sound Acoustics Computer Simulation Vocalization, Animal Echolocation Models, Biological Sound Localization The biosonar system of odontocetes enables directional sound transmission and reception. Beluga whales () are notable among odontocetes as they can alter the shape of their fatty melon during sound transmission, potentially suggesting distinct acoustic capabilities. In this study, we developed a biosonar model of a beluga whale using computed tomography scanning and structural reconstruction to examine directional transmission and reception in this species. This model could modulate sounds into a directional beam using either single or dual sources. Across frequencies from 5 to 60 kHz, the directivity indices for the left and right sound sources ranged from 4.83 to 15.2 dB and 4.81-14.7 dB, respectively. When both sound sources were used simultaneously, there was an average increase of at least 2.26 dB in energy and 0.68 dB in the directivity index compared to using a single source. Additionally, beam steering was achieved in the dual-source transmission by introducing a timing difference between the two sources. The simulations indicated that sound reception was frequency-dependent, with the greatest sensitivity to lateral sounds at low frequencies and to forward sounds at high frequencies. These results suggested that both transmission and reception in beluga whales were directional and frequency-dependent.
format Artículo científico
id pubmed_40138799
institution PubMed
language en
publishDate 2025
publisher Bioinspiration & biomimetics
record_format pubmed
spellingShingle Directional sound transmission and reception of the beluga whale ().
Ou, Wenzhan
Song, Zhongchang
Goertz, Caroline E C
Mooney, T Aran
Dennison, Sophie
Zhang, Chuang
Zhang, Yu
Castellote, Manuel
Animals
Beluga Whale
Sound
Acoustics
Computer Simulation
Vocalization, Animal
Echolocation
Models, Biological
Sound Localization
Directional sound transmission and reception of the beluga whale (). Ou, Wenzhan Song, Zhongchang Goertz, Caroline E C Mooney, T Aran Dennison, Sophie Zhang, Chuang Zhang, Yu Castellote, Manuel Animals Beluga Whale Sound Acoustics Computer Simulation Vocalization, Animal Echolocation Models, Biological Sound Localization The biosonar system of odontocetes enables directional sound transmission and reception. Beluga whales () are notable among odontocetes as they can alter the shape of their fatty melon during sound transmission, potentially suggesting distinct acoustic capabilities. In this study, we developed a biosonar model of a beluga whale using computed tomography scanning and structural reconstruction to examine directional transmission and reception in this species. This model could modulate sounds into a directional beam using either single or dual sources. Across frequencies from 5 to 60 kHz, the directivity indices for the left and right sound sources ranged from 4.83 to 15.2 dB and 4.81-14.7 dB, respectively. When both sound sources were used simultaneously, there was an average increase of at least 2.26 dB in energy and 0.68 dB in the directivity index compared to using a single source. Additionally, beam steering was achieved in the dual-source transmission by introducing a timing difference between the two sources. The simulations indicated that sound reception was frequency-dependent, with the greatest sensitivity to lateral sounds at low frequencies and to forward sounds at high frequencies. These results suggested that both transmission and reception in beluga whales were directional and frequency-dependent.
title Directional sound transmission and reception of the beluga whale ().
topic Animals
Beluga Whale
Sound
Acoustics
Computer Simulation
Vocalization, Animal
Echolocation
Models, Biological
Sound Localization
url https://pubmed.ncbi.nlm.nih.gov/40138799/