Vocal tract articulation revisited: the case of the monk parakeet

Ohms, Verena R.; Beckers, Gabriël J. L.; Cate, Carel ten; Suthers, Roderick A.

doi:10.1242/jeb.064717

Cited by 26 publications

(23 citation statements)

References 35 publications

(43 reference statements)

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“…Short-duration calls are consistent with the fact that air cavities and respiratory organs were likely still small and undergoing substantial growth during this period (Vleck and Bucher, 1998). High frequencies are synonymous with short wavelengths of sound and are predicted from the resonant properties of small vocal tracts (Podos, 1996;Brittan-Powell et al, 1997;Hoese et al, 2000;Suthers and Zollinger, 2004;Beckers et al, 2004;Bradbury and Vehrencamp, 2011;Ohms et al, 2012). Broadband noise has been…”

Section: Early Noisy Stagementioning

confidence: 99%

“…The latter characteristic suggests an advantage to calling while flapping. Because downstroke phases are often synchronized with expiratory phases (Tucker, 1968;Boggs, 1997;Tobalske and Dial, 1994), and vocal production requires a build-up of positive expiratory pressure at the sub-syringeal aperture (Suthers, 1997;Cooper and Goller, 2004;Ohms et al, 2012), contact call emission may be more economical during flapping phases and less so during non-flapping phases when inspiration is likely more economical. In support of this explanation, nestling call durations showed an abrupt decrease shortly after they began using wings to aid locomotor displacements inside the nest cavity.…”

Section: Reasons For Short Contact-call Durationsmentioning

confidence: 99%

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Factors shaping the ontogeny of vocal signals in a wild parrot

Berg

Beissinger

Bradbury

2012

Journal of Experimental Biology

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SUMMARYParrots rely heavily on vocal signals to maintain their social and mobile lifestyles. We studied vocal ontogeny in nests of wild green-rumped parrotlets (Forpus passerinus) in Venezuela. We identified three successive phases of vocal signaling that corresponded closely to three independently derived phases of physiological development. For each ontogenetic phase, we characterized the relative importance of anatomical constraints, motor skills necessary for responding to specific contexts of the immediate environment, and the learning of signals that are necessary for adult forms of communication. We observed shifts in the relative importance of these three factors as individuals progressed from one stage to the next; there was no single fixed ratio of factors that applied across the entire ontogenetic sequence. The earliest vocalizations were short in duration, as predicted from physical constraints and under-developed motor control. Calls became longer and frequency modulated during intermediate nestling ages in line with motor skills required for competitive begging. In the week before fledging, calls drastically shortened in accordance with the flight-constrained short durations of adult contact calls. The latter constraints were made evident by the demonstrated links between wing-assisted incline running, a widespread prelude to avian flight, just before the shift from longduration begging calls to short-duration contact calls. At least in this species, the shifting emphases of factors at different ontogenetic stages precluded the morphing of intermediate-stage begging calls into adult contact calls; as shown previously, the latter are influenced by sample templates provided by parents. Supplementary material available online at

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Section: Early Noisy Stagementioning

confidence: 99%

Section: Reasons For Short Contact-call Durationsmentioning

confidence: 99%

Factors shaping the ontogeny of vocal signals in a wild parrot

Berg

Beissinger

Bradbury

2012

Journal of Experimental Biology

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“…A high-low placement of the tongue changes the frequency of the first formant, and a front-back placement changes the frequency of the second formant. Although little is known about their importance in avian communication, formants or harmonic-rich formant-like structures are also observed in the vocalizations of various bird species, including zebra finches (Ohms et al, 2010), mynah birds (Klatt and Stefanski, 1974), African gray parrots (Pepperberg, 2010) and monk parakeets (Beckers et al, 2004;Ohms et al, 2012). The ability of mynah birds and parrots to modify formants contributes to their ability to imitate human speech, although the production mechanism may not be identical to that found in humans.…”

Section: Introductionmentioning

confidence: 99%

“…In an experiment in which the syrinx of a euthanized monk parakeet was replaced with a speaker, Beckers et al (2004) found that artificially manipulating front-back tongue placement caused changes in formant frequency and amplitude, and manipulating high-low placement caused changes in amplitude. Ohms et al (2012) used Xray cineradiography to measure tongue height in naturally vocalizing monk parakeets. Changes in tongue height were observed during the production of various natural call notes.…”

Section: Introductionmentioning

confidence: 99%

Lingual articulation in songbirds

Suthers

Rothgerber

Jensen

2015

Journal of Experimental Biology

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Lingual articulation in humans is one of the primary means of vocal tract resonance filtering that produces the characteristic vowel formants of speech. In songbirds, the function of the tongue in song has not been thoroughly examined, although recent research has identified the oropharyngeal-esophageal cavity as a resonance filter that is actively tuned to the frequency of the song. In northern cardinals (Cardinalis cardinalis), the volume of this cavity is inversely proportional to the frequency of the song above 2 kHz. However, cardinal song extends below this range, leaving the question of whether and how the vocal tract is tracking these low frequencies. We investigated the possible role of the tongue in vocal tract filtering using X-ray cineradiography of northern cardinals. Below 2 kHz, there was prominent tongue elevation in which the tip of the tongue was raised until it seemed to touch the palate. These results suggest that tongue elevation lowers the resonance frequency below 2 kHz by reducing the area of the passage from the oral cavity into the beak. This is consistent with a computational model of the songbird vocal tract in which resonance frequencies are actively adjusted by both changing the volume of the oropharyngeal-esophageal cavity and constricting the opening into the beak.

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“…), in the open‐mouth vocalizing species monk parakeet ( Myiopsitta monachus ; Ohms et al. ), or in the open‐mouth vocalizations of songbirds (Riede and Suthers ; Ohms et al. ; Riede and Goller ; Riede et al.…”

Section: Morphological and Biomechanical Aspects Of Inflation Of The mentioning

confidence: 99%

Coos, booms, and hoots: The evolution of closed‐mouth vocal behavior in birds

et al. 2016

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Most birds vocalize with an open beak, but vocalization with a closed beak into an inflating cavity occurs in territorial or courtship displays in disparate species throughout birds. Closed-mouth vocalizations generate resonance conditions that favor low-frequency sounds. By contrast, open-mouth vocalizations cover a wider frequency range. Here we describe closed-mouth vocalizations of birds from functional and morphological perspectives and assess the distribution of closed-mouth vocalizations in birds and related outgroups. Ancestral-state optimizations of body size and vocal behavior indicate that closed-mouth vocalizations are unlikely to be ancestral in birds and have evolved independently at least 16 times within Aves, predominantly in large-bodied lineages. Closed-mouth vocalizations are rare in the small-bodied passerines. In light of these results and body size trends in nonavian dinosaurs, we suggest that the capacity for closed-mouth vocalization was present in at least some extinct nonavian dinosaurs. As in birds, this behavior may have been limited to sexually selected vocal displays, and hence would have co-occurred with open-mouthed vocalizations.

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Vocal tract articulation revisited: the case of the monk parakeet

Cited by 26 publications

References 35 publications

Factors shaping the ontogeny of vocal signals in a wild parrot

Factors shaping the ontogeny of vocal signals in a wild parrot

Lingual articulation in songbirds

Coos, booms, and hoots: The evolution of closed‐mouth vocal behavior in birds

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