The duplex sonar model of humpback whale song proposes that broadband units within songs function differently from narrowband units. Specifically, this model suggests that singing humpback whales interleave constant frequency (CF) units, which can generate prolonged reverberation focused at specific frequencies, with less reverberant broadband units that minimally overlap with the focal frequencies of preceding and following CF units (referred to as spectral interleaving) to increase the efficacy of song as a sonar source. Here, it is shown that singers recorded off the coast of Hawaii in 2015 devoted most of their time singing to spectrally interleaving broadband elements of units around quasi-CF components that consistently generated persistent reverberant tails. Singers maintained reverberant CF streams in specific frequency bands when units contained broadband elements and when singers switched from producing pairs of alternating reverberant units to producing a single reverberant unit. Additionally, singers showed the ability to flexibly control where acoustic energy was concentrated within broadband components in ways that minimized spectral overlap with the focal frequencies of reverberant tails. The consistency and precision with which singing humpback whales interleaved broadband and reverberant CF elements of units confirm two novel predictions of the duplex sonar model.
References
1.
Adam
, O.
, Cazau
, D.
, Gandilhon
, N.
, Fabre
, B.
, Laitman
, J. T.
, and Reidenberg
, J. S.
(2013
). “ New acoustic model for humpback whale sound production
,” Appl. Acoust.
74
, 1182
–1190
.2.
Allen
, A. N.
, Harvey
, M.
, Harrell
, L.
, Jansen
, A.
, Merkens
, K. P.
, Wall
, C. C.
, Cattiau
, J.
, and Oleson
, E. M.
(2021
). “ A convolutional neural network for automated detection of humpback whale song in a diverse, long-term passive acoustic dataset
,” submitted for publication.3.
Au
, W. W. L.
, Frankel
, A. S.
, Helweg
, D. A.
, and Cato
, D. H.
(2001
). “ Against the humpback whale sonar hypothesis
,” IEEE J. Oceanic Eng.
26
, 295
–300
.4.
Au
, W. W. L.
, Pack
, A. A.
, Lammers
, M. O.
, Herman
, L. M.
, Deakos
, M. H.
, and Andrews
, K.
(2006
). “ Acoustic properties of humpback whale songs
,” J. Acoust. Soc. Am.
120
, 1103
–1110
.5.
Bregman
, A. S.
(1978
). “ Auditory streaming: Competition among alternative organizations
,” Percept. Psychophys.
23
, 391
–398
.6.
Cato
, D. H.
(1991
). “ Songs of humpback whales: The Australian perspective
,” Mem. Queensl. Mus.
30
, 277
–290
.7.
Cholewiak
, D.
, Sousa-Lima
, R.
, and Cerchio
, S.
(2013
). “ Humpback whale song hierarchical structure: Historical context and discussion of current classification issues
,” Mar. Mamm. Sci.
29
, E312
–E332
.8.
Darling
, J. D.
, and Berube
, M.
(2001
). “ Interactions of singing humpback whales with other males
,” Mar. Mamm. Sci.
17
, 570
–584
.9.
Fenton
, M. B.
, Jensen
, F. B.
, Kalko
, E. K.
, and Tyack
, P. L.
(2014
). “ Sonar signals of bats and toothed whales
,” in Biosonar
, edited by A.
Surlykke
, P. E.
Nachtigall
, R. R.
Fay
, and A. N.
Popper
(Springer
, New York
), pp. 11
-60
.10.
Frazer
, L. N.
, and Mercado
, E.
III (2000
). “ A sonar model for humpback whale song
,” IEEE J. Oceanic Eng.
25
, 160
–182
.11.
Green
, S. R.
, Mercado
, E.
III , Pack
, A. A.
, and Herman
, L. M.
(2011
). “ Recurring patterns in the songs of humpback whales (Megaptera novaeangliae)
,” Behav. Processes
86
, 284
–294
.12.
Guinee
, L. N.
, Chu
, K.
, and Dorsey
, E. M.
(1983
). “ Changes over time in the songs of known individual humpback whales (Megaptera novaeangliae)
,” in Communication and Behavior of Whales
, edited by R. S.
Payne
(Westview Press
, Boulder, CO
), pp. 59
-80
.13.
Jensen
, F. B.
, and Kuperman
, W. A.
(1983
). “ Optimum frequency of propagation in shallow water environments
,” J. Acoust. Soc. Am.
73
, 813
–819
.14.
Ketten
, D. R.
(1997
). “ Structure and function in whale ears
,” Bioacoustics
8
, 103
–135
.15.
Maeda
, H.
, Koido
, T.
, and Takemura
, A.
(2000
). “ Principal component analysis of song units produced by humpback whales (Megaptera novaeangliae) in the Ryukyu region of Japan
,” Aquat. Mamm.
26
, 202
–211
.16.
Magnúsdóttir
, E. E.
, Miller
, P. J.
, Lim
, R.
, Rasmussen
, M. H.
, Lammers
, M. O.
, and Svavarsson
, J.
(2015
). “ Humpback whale (Megaptera novaeangliae) song unit and phrase repertoire progression on a subarctic feeding ground
,” J. Acoust. Soc. Am.
138
, 3362
–3374
.17.
Mercado
, E.
III (2016
). “ Acoustic signaling by singing humpback whales (Megaptera novaeangliae): What role does reverberation play?
” PLoS One
11
, e0167277
.18.
Mercado
, E.
III (2018a
). “ Recurrent acoustic patterns produced by a singing humpback whale (Megaptera novaeangliae)
,” West. Indian Ocean J. Mar. Sci.
1
, 41
–51
.19.
Mercado
, E.
III (2018b
). “ The sonar model for humpback whale song revised
,” Front. Psychol.
9
, 1156
.20.
Mercado
, E.
III (2020
). “ Humpback whale (Megaptera novaeangliae) sonar: Ten predictions
,” J. Comp. Psychol.
134
, 123
–131
.21.
Mercado
, E.
III , and Frazer
, L. N.
(1999
). “ Environmental constraints on sound transmission by humpback whales
,” J. Acoust. Soc. Am.
106
, 3004
–3016
.22.
Mercado
, E.
III , and Frazer
, L. N.
(2001
). “ Humpback whale song or humpback whale sonar? A reply to Au et al.
,” IEEE J. Oceanic Eng.
26
, 406
–415
.23.
Mercado
, E.
III , Herman
, L. M.
, and Pack
, A. A.
(2003
). “ Stereotypical sound patterns in humpback whale songs: Usage and function
,” Aquat. Mamm.
29
, 37
–52
.24.
Mercado
, E.
III , Herman
, L. M.
, and Pack
, A. A.
(2005
). “ Song copying by humpback whales: Themes and variations
,” Anim. Cogn.
8
, 93
–102
.25.
Mercado
, E.
III , Michalopoulou
, Z.-H.
, and Frazer
, L. N.
(2000
). “ A possible relationship between waveguide properties and bandwidth utilization in humpback whales
,” OCEANS 2000, MTS/IEEE Conference Proceedings
, September 11–14, Providence, RI, pp. 1743
-1747
.26.
Mercado
, E.
III , and Perazio
, C. E.
(2021
). “ Similarities in composition and transformations of songs by humpback whales (Megaptera novaeangliae) over time and space
,” J. Comp. Psychol.
(in press).27.
Mercado
, E.
III , Schneider
, J. N.
, Green
, S. R.
, Wang
, C.
, Rubin
, R. D.
, and Banks
, P. N.
(2007
). “ Acoustic cues available for ranging by humpback whales
,” J. Acoust. Soc. Am.
121
, 2499
–2502
.28.
Pace
, F.
, Benard
, F.
, Glotin
, H.
, Adam
, O.
, and White
, P.
(2010
). “ Subunit definition and analysis for humpback whale call classification
,” Appl. Acoust.
71
, 1107
–1112
.29.
Payne
, K.
, and Payne
, R. S.
(1985
). “ Large scale changes over 19 years in songs of humpback whales in Bermuda
,” Z. Tierpsychol.
68
, 89
–114
.30.
Payne
, K.
, Tyack
, P.
, and Payne
, R. S.
(1983
). “ Progressive changes in the songs of humpback whales (Megaptera novaeangliae): A detailed analysis of two seasons in Hawaii
,” in Communication and Behavior of Whales
, edited by R.
Payne
(Westview Press
, Boulder, CO
), pp. 9
–57
.31.
32.
Payne
, R. S.
, and McVay
, S.
(1971
). “ Songs of humpback whales
,” Science
173
, 585
–597
.33.
Perazio
, C. E.
, and Mercado
, E.
(2018
). “ Singing humpback whales, Megaptera novaeanglie, favor specific frequency bands
,” Proc. Mtgs. Acoust.
35
, 010004
.34.
Ryan
, J. P.
, Cline
, D. E.
, Joseph
, J. E.
, Margolina
, T.
, Santora
, J. A.
, Kudela
, R. M.
, Chavez
, F. P.
, Pennington
, J. T.
, Wahl
, C.
, Michisaki
, R.
, Benoit-Bird
, K.
, Forney
, K. A.
, Stimpert
, A. K.
, DeVogelaere
, A.
, Black
, N.
, and Fischer
, M.
(2019
). “ Humpback whale song occurrence reflects ecosystem variability in feeding and migratory habitat of the northeast Pacific
,” PLoS One
14
, e0222456
.35.
Schneider
, J. N.
, Lloyd
, D. R.
, Banks
, P. N.
, and Mercado
, E.
III (2014
). “ Modeling the utility of binaural cues for underwater sound localization
,” Hearing Res.
312
, 103
–113
.36.
Schneider
, J. N.
, and Mercado
, E.
III (2019
). “ Characterizing the rhythm and tempo of sound production by singing whales
,” Bioacoustics
28
, 239
–256
.37.
Schnitzler
, H. U.
, Kalko
, E.
, Miller
, L.
, and Surlykke
, A.
(1987
). “ The echolocation and hunting behavior of the bat, Pipistrellus kuhli
,” J. Comp. Physiol. A
161
, 267
–274
.38.
Simmons
, J. A.
, and Stein
, R. A.
(1980
). “ Acoustic imaging in bat sonar: Echolocation signals and the evolution of echolocation
,” J. Comp. Physiol.
135
, 61
–84
.39.
Slabbekoorn
, H.
, Ellers
, J.
, and Smith
, T. B.
(2002
). “ Birdsong and sound transmission: The benefits of reverberations
,” Condor
104
, 564
–573
.40.
Tyack
, P. L.
(1981
). “ Interactions between singing Hawaiian humpback whales and conspecifics nearby
,” Behav. Ecol. Sociobiol.
8
, 105
–116
.41.
Wiggins
, S. M.
, and Hildebrand
, J. A.
(2007
). “ High-frequency Acoustic Recording Package (HARP) for broad-band, long-term marine mammal monitoring
,” in Proceedings of the International Symposium on Underwater Technology 2007 and International Workshop on Scientific Use of Submarine Cables and Related Technologies
, April 17–20, Tokyo, Japan, pp. 551
–557
.42.
Winn
, H. E.
, and Winn
, L. K.
(1978
). “ The song of the humpback whale Megaptera novaeangliae in the West Indies
,” Mar. Biol.
47
, 97
–114
.© 2021 Acoustical Society of America.
2021
Acoustical Society of America
You do not currently have access to this content.
