Ambient noise induces independent shifts in call frequency and amplitude within the Lombard effect in echolocating bats

Hage, Steffen R.; Jiang, Tinglei; Berquist, Sean; Feng, Jiang; Metzner, Walter

doi:10.1073/pnas.1211533110

Cited by 122 publications

(116 citation statements)

References 55 publications

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“…Thus, the Lombard effect is fundamentally different from the Fletcher effect and does not require a comparison of internal forward model predictions with the sensory feedback. Our results are in line with the data from an earlier study on another bat species (Rhinolophus ferrumequinum) that exhibited the Lombard effect in the first call after noise onset (26). However, the term reflex should not be interpreted as that the Lombard effect is a fixed response to background noise.…”

Section: Discussionsupporting

confidence: 92%

“…The Lombard effect was first described over a century ago and is among the most widely studied audio-vocal integration phenomena. The response latency of the Lombard effect was estimated to be about 150-175 ms for humans (23,24), 150 ms for birds (25), and less than 150 ms for bats (26). There are at least two possible explanations for the overestimation.…”

Section: Discussionmentioning

confidence: 99%

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Sensorimotor integration on a rapid time scale

Luo

Kothari

Moss

2017

Proc. Natl. Acad. Sci. U.S.A.

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Sensing is fundamental to the control of movement: From grasping objects to speech production, sensing guides action. So far, most of our knowledge about sensorimotor integration comes from visually guided reaching and oculomotor integration, in which the time course and trajectories of movements can be measured at a high temporal resolution. By contrast, production of vocalizations by humans and animals involves complex and variable actions, and each syllable often lasts a few hundreds of milliseconds, making it difficult to infer underlying neural processes. Here, we measured and modeled the transfer of sensory information into motor commands for vocal amplitude control in response to background noise, also known as the Lombard effect. We exploited the brief vocalizations of echolocating bats to trace the time course of the Lombard effect on a millisecond time scale. Empirical studies revealed that the Lombard effect features a response latency of a mere 30 ms and provided the foundation for the quantitative audiomotor model of the Lombard effect. We show that the Lombard effect operates by continuously integrating the sound pressure level of background noise through temporal summation to guide the extremely rapid vocal-motor adjustments. These findings can now be extended to models and measures of audiomotor integration in other animals, including humans.S ensing plays a critical role in the control of movement. In humans, natural behaviors, from grasping a coffee mug to producing intelligible speech, all rely on the guidance of sensing. Similarly, sensory signals lie at the core of most animal behaviors. However, the brain mechanisms underlying sensorimotor integration are not well understood. This is particularly true regarding the control of vocalizations, which are used by a wide range of animal species for communication. At present, a dominant model for motor control is derived from the state feedback control (SFC) theory, which successfully accounts for a wide range of motor behaviors, such as visually guided arm movement (1) and speech production (2). SFC models posit that motor control is based on a comparison of sensory prediction generated from an internal forward model with actual sensory feedback, and sensory feedback is used to train and update the internal forward model. According to this SFC model, sensory feedback is not directly used to guide motor commands, due to its noisy and delayed characteristics, and this notion has been supported by a large body of experimental and theoretical work (1-7). These stand in contrast to motor reflexes, which are movements in direct response to sensory signals. Note, motor reflexes can be graded in response magnitude and can be modulated by cognitive processes (8, 9). One well-known example is the pupillary light reflex, an adjustment in pupil diameter in response to light intensity (10).The Lombard effect refers to an animal's increase in vocal signal amplitude in response to an increase in background noise (11). Evidence of the Lombard effect comes from s...

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Section: Discussionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Sensorimotor integration on a rapid time scale

Luo

Kothari

Moss

2017

Proc. Natl. Acad. Sci. U.S.A.

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“…In species that display vocal plasticity, such as birds, bats and cetaceans, shifts in call frequency can help achieve this and geographical variation in these call parameters has been linked to natural variation in ambient noise levels from biotic and abiotic factors (Brumm & Slabbekoorn, 2005;Foote & Nystuen, 2008;Hage, Jiang, Berquist, Feng, & Metzner, 2013;Mossbridge, Shedd, & Thomas, 1999). Elevated anthropogenic noise levels may also promote these frequency shifts (Ansmann et al, 2007;Lesage, Barrette, Kingsley, & Sjare, 1999;Luís, most noise in the low-to mid-frequency ranges (Jensen et al, 2009;Lemon et al, 2006;Lesage et al, 1999) and several studies focused on cetacean vocal parameters have identified an upward frequency shift or increase in minimum or mean frequency associated with boat presence (Lesage et al, 1999;Luís et al, 2014;Parks et al, 2007).…”

Section: Discussionmentioning

confidence: 99%

Changes in bottlenose dolphin whistle parameters related to vessel presence, surface behaviour and group composition

et al. 2016

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Cetacean watching from tour boats has increased in recent years and has been promoted as an ethically viable alternative to cetacean viewing in captive facilities or directed take. However, short-and long-term impacts of this industry on the behaviour and energetic expenditure of cetaceans have been documented. Although multiple studies have investigated the acoustic 1 response of dolphins to marine tourism, there are several covariates that could also explain some of these results and should be considered simultaneously. Here, we investigated whether common bottlenose dolphins, Tursiops truncatus, inhabiting Walvis Bay, Namibia vary their whistle parameters in relation to boat presence, surface behaviour and/or group composition. We detected an upward shift of up to 1.99 kHz in several whistle frequency parameters when dolphins were in the presence of one or more tour boats and the research vessel. No changes were demonstrated in the frequency range, number of inflection points or duration of whistles. A similar, although less pronounced difference was observed in response to engine noise generated by the research vessel when idling, suggesting that noise alone plays an important role in driving this shift in whistle frequency. Additionally, a strong effect of surface behaviour was observed, with the greatest difference in whistle parameters detected between resting and other behavioural states that are associated with higher degrees of emotional arousal. Group composition also contributed to the variation observed, with the impact of boats dependent on whether calves were present or not. Overall these results demonstrate high natural variation in the frequency parameters of whistles utilized by dolphins over varying behavioural states and group composition. Anthropogenic impact in the form of marine tour boats can influence the vocalization parameters of dolphins and such changes could have a long-term impact if they reduce the communication range of whistles or increase energy expenditure. Key wordsbottlenose dolphin, marine tourism, Namibia, Tursiops truncatus, vocal behaviour Wildlife tourism involving cetacean (whale, dolphin and porpoise) watching has experienced rapid growth since the 1990s (Hoyt, 2001;O'Connor, Campbell, Cortez, & Knowles, 2009). 2Globally, boat-based cetacean watching generates an estimated 2.2 billion US dollars annually (IWC, 2014). Revenue can provide a valuable subsidy to fishing communities and in some cases wild cetacean viewing has replaced direct hunting of whales and dolphins (Amir & Jiddawi, 2001;Berggren et al., 2007). Compared with captive facilities, responsible boatbased cetacean watching has been promoted as an ethically acceptable option for observing dolphins, providing a valuable forum for environmental education and promotion of conservation efforts (IFAW, 1997). However, a considerable body of work has shown that boats and boat-based cetacean watching can have multiple negative impacts on the behaviour of the focal individual, population or species (Parsons,...

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“…One potential limitation to plasticity is the tight coupling between RF and the acoustic fovea in high duty cycle bats, like R. damarensis , that use Doppler shift compensation (Neuweiler, 1984; Schnitzler & Denzinger, 2011). However, HDC bats are able to shift their RFs (up to 3.9 kHz) in response to both neighboring conspecifics and different ambient noise conditions (Hage, Jiang, Berquist, Feng, & Metzner, 2013; Hiryu et al., 2006). Although small, such shifts in frequency encompass the differences between the mean RFs of neighboring populations of R. damarensis and may allow bats to optimize their detection range under the local climatic conditions without a change in allele frequency.…”

Section: Discussionmentioning

confidence: 99%

Environmental correlates of geographic divergence in a phenotypic trait: A case study using bat echolocation

Maluleke

Jacobs

Winker

2017

Ecology and Evolution

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Divergence in phenotypic traits may arise from the interaction of different evolutionary forces, including different kinds of selection (e.g., ecological), genetic drift, and phenotypic plasticity. Sensory systems play an important role in survival and reproduction, and divergent selection on such systems may result in lineage diversification. Such diversification could be largely influenced by selection in different environments as a result of isolation by environment (IbE). We investigated this process using geographic variation in the resting echolocation frequency of the horseshoe bat species, Rhinolophus damarensis, as a test case. Bats were sampled along a latitudinal gradient ranging from 16°S to 32°S in the arid western half of southern Africa. We measured body size and peak resting frequencies (RF) from handheld individual bats. Three hypotheses for the divergence in RF were tested: (1) James’ Rule, (2) IbE, and (3) genetic drift through isolation by distance (IbD) to isolate the effects of body size, local climatic conditions, and geographic distance, respectively, on the resting frequency of R. damarensis. Our results did not support genetic drift because there was no correlation between RF variation and geographic distance. Our results also did not support James' Rule because there was no significant relationship between (1) geographic distances and RF, (2) body size and RF, or (3) body size and climatic variables. Instead, we found support for IbE in the form of a correlation between RF and both region and annual mean temperature, suggesting that RF variation may be the result of environmental discontinuities. The environmental discontinuities coincided with previously reported genetic divergence. Climatic gradients in conjunction with environmental discontinuities could lead to local adaptation in sensory signals and directed dispersal such that gene flow is restricted, allowing lineages to diverge. However, our study cannot exclude the role of processes like phenotypic plasticity in phenotypic variation.

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Ambient noise induces independent shifts in call frequency and amplitude within the Lombard effect in echolocating bats

Cited by 122 publications

References 55 publications

Sensorimotor integration on a rapid time scale

Sensorimotor integration on a rapid time scale

Changes in bottlenose dolphin whistle parameters related to vessel presence, surface behaviour and group composition

Environmental correlates of geographic divergence in a phenotypic trait: A case study using bat echolocation

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