A robust asymmetry in loudness between rising- and falling-intensity tones

Ponsot, Emmanuel; Susini, Patrick; Meunier, Sabine

doi:10.3758/s13414-014-0824-y

Cited by 15 publications

(12 citation statements)

References 59 publications

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“…The predicted asymmetry was1.3 dB for WN, 2.1 dB for MT,1 .5 dB for RWNa nd PT.T he observed asymmetry wasq uite well explained by the model for the sound that does not elicit pitch (WN) whereas it wasunderestimated for the sounds that elicit pitch (RWN and PT). ForMT, the loudness model slightly overestimated the asymmetry.Our results are in agreement with those of Ries et al [3] who found that LTLpredicted well the loudness asymmetry for white noise of 500 ms, and with those of Ponsot et al [6], who predicted an asymmetry of 1.24 dB for a1-kHz pure tone of 2sv arying between 55 and 70 dB, using the LTL model.…”

Section: Discussionsupporting

confidence: 93%

“…Their global loudness (that is, the overall loudness of the sound overits entire duration)isalso greater than the global loudness of afalling sound. At the point of subjective equality (PSE), a falling 1-kHz pure tone varying over15-dB has arms level that is 4dBhigher than that of its symmetrical rising version [6] .This global loudness difference is usually called loudness asymmetry.V arious studies have attempted to explain and model the global loudness asymmetry [7,6]. Ponsot et al [7] showed alarger loudness asymmetry for pure tones than for broadband noises.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Pitch on the Asymmetry in Global Loudness Between Rising- and Falling-Intensity Sounds

Meunier¹,

Chatron²,

Abs³

et al. 2018

Acta Acustica united with Acustica

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The global loudness of av arying intensity sound is greater when the intensity increases than when it decreases. This global loudness asymmetry wasfound to be larger for pure tones than for broadband noises. In this study, our aim wastodetermine whether this difference between pure tones and noises is due to the difference in bandwidth between sounds or to the difference in the strength of the sensation of pitch. The loudness asymmetry was measured for broadband and for narrow-band signals that do or do not elicit asensation of pitch. The asymmetry wasg reater for sounds that elicit as ensation of pitch whatevert heir bandwidth. The loudness model for time varying sounds [1] predicted well the asymmetry for the broadband noise that does not elicit asensation of pitch and for am ulti-tonal sound. Fort he other sounds the asymmetry wasg reater than predicted. It is known that loudness and pitch interact. The difference in asymmetry between sounds that elicit pitch and sounds that do not elicit pitch might be due to this interaction.

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Section: Discussionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Effect of Pitch on the Asymmetry in Global Loudness Between Rising- and Falling-Intensity Sounds

Meunier¹,

Chatron²,

Abs³

et al. 2018

Acta Acustica united with Acustica

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“…Numerous psychophysical experiments have shown that sounds whose intensity is ramping up with time (up-ramps) are globally perceived as louder or changing more in loudness than their time-symmetric opposites (down-ramps). This perceptual asymmetry has been observed for a wide range of sound durations 10 11 12 13 and is proposed to emphasize approaching sound sources relative to sources moving away 10 to favour threat detection. The physiological bases of this perceptual asymmetry are yet unknown, but several studies found the activity correlates in later stages of the auditory system.…”

mentioning

confidence: 88%

Temporal asymmetries in auditory coding and perception reflect multi-layered nonlinearities

et al. 2016

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Sound recognition relies not only on spectral cues, but also on temporal cues, as demonstrated by the profound impact of time reversals on perception of common sounds. To address the coding principles underlying such auditory asymmetries, we recorded a large sample of auditory cortex neurons using two-photon calcium imaging in awake mice, while playing sounds ramping up or down in intensity. We observed clear asymmetries in cortical population responses, including stronger cortical activity for up-ramping sounds, which matches perceptual saliency assessments in mice and previous measures in humans. Analysis of cortical activity patterns revealed that auditory cortex implements a map of spatially clustered neuronal ensembles, detecting specific combinations of spectral and intensity modulation features. Comparing different models, we show that cortical responses result from multi-layered nonlinearities, which, contrary to standard receptive field models of auditory cortex function, build divergent representations of sounds with similar spectral content, but different temporal structure.

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“…Specifically, global loudness significantly increased in magnitude as the region of each up-ramp increased from 45-60 dB SPLt o 75-90 dB SPLfor 15 dB ranges, and 45-75 dB SPL to 60-90 dB SPLfor 30 dB ranges. This result is not surprising, as aglobal loudness impression in response to an up-ramp is expected to increase as the ramp'saverage intensity,region of change, and end-levelincreases [6,23,31]. However,w hen as eparate group of participants rated global loudness change, very similar results were observed to the group that rated global loudness.…”

Section: Discussionmentioning

confidence: 63%

The Effects of Acoustic Intensity, Spectrum, and Duration on Global Loudness Change

Olsen

Herff

2015

Acta Acustica united with Acustica

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Global loudness change is apost-stimulus retrospective judgement that measures listeners' overall impressions of loudness change in response to stimuli with continuous increases (up-ramps)a nd decreases (down-ramps) of acoustic intensity that are otherwise acoustically identical. Past results indicate that global loudness change is significantly greater in response to up-ramps relative to down-ramps for tonal stimuli (e.g., vowel)b ut not white-noise. An adaptive perceptual bias for up-ramp tonal stimuli has been proposed as afunctional ecological explanation. However, global loudness change may also be influenced by stimulus duration and an end-level recency-in-memory mechanism that biases retrospective global judgements on aramp'send-levelintensity,rather than its entire magnitude of intensity change. The present within-subjects experiment (N = 34)w as designed to systematically investigate the effects of intensity,s pectrum, and duration on global loudness change when end-levelrecencyiscontrolled. Up-ramps and down-ramps were embedded within twospectral conditions (tonal vowel /@/a nd white-noise)a nd presented over three durations (1.8 s, 3.6 s, 7.2 s) and twor egions of intensity change (45-65 dB SPL, 65-85 dB SPL).E nd-levelr ecencyr esponse bias wasc ontrolled through the use of balanced end-levelc omparisons between 45-65 dB SPL up-ramps and 85-65 dB SPL down-ramps that both converged on 65 dB SPL. Overall, global loudness change wass ignificantly greater in response to vowel and white-noise up-ramps, relative to their corresponding down-ramps. However, with end-levelrecencycontrolled, global loudness change wass ignificantly greater for up-ramps relative to down-ramps in 3.6 sa nd 7.2 sv owel conditions only.T his wasf acilitated by an up-ramp-specifice ff ect of duration, where the magnitude of global loudness change increased as vowel up-ramp duration increased from 3.6 sto7.2 s. The findings are discussed in the context of psychoacoustics and ecological acoustics.

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A robust asymmetry in loudness between rising- and falling-intensity tones

Cited by 15 publications

References 59 publications

Effect of Pitch on the Asymmetry in Global Loudness Between Rising- and Falling-Intensity Sounds

Effect of Pitch on the Asymmetry in Global Loudness Between Rising- and Falling-Intensity Sounds

Temporal asymmetries in auditory coding and perception reflect multi-layered nonlinearities

The Effects of Acoustic Intensity, Spectrum, and Duration on Global Loudness Change

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