时变听觉、视觉和振动刺激感知分离的临界重复率

Carlos Jurado, Marcelo Larrea, David Rosero, Juan Vizuete, T. Marquardt
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引用次数: 1

摘要

在传统听力范围内,是什么音质导致次声被排除在声音之外?我们研究了压力脉冲的时间分离是否是一种独特的性质,并通过对纯音和不同包络的载波的自适应心理物理学程序来评估这种感知极限。此外,为了检查该极限的跨域相似性和个体协变,这里称为临界分离率(CSR),还对各种周期性视觉和振动触觉刺激进行了测量。结果表明,连续的听觉或振动触觉刺激至少间隔~80-90 ms(~11-12Hz的重复率),将被感知为在感知上彼此分离。虽然这两种模式之间的这一极限在统计学上没有差异,但它明显低于~150 ms是在感知上分离连续视觉刺激所必需的。对于三种感觉模式,刺激周期性是决定CSR的主要因素,CSR明显反映了不同感觉系统的神经恢复时间。在所有实验条件中,尽管视觉CSR(平均值:6.8Hz)显著低于其他两种模式,但观察到了显著的模态内和模态间个体CSR相关性。听觉CSR被发现显著低于正弦曲线开始引发音调质量的频率(19Hz;最近针对相同受试者发表)。回到我们最初的问题,后者表明,音调质量的停止——而不是压力波动的分离——是导致将次声(频率<20 Hz的声音)排除在传统听力范围之外的感知质量。
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Critical Repetition Rates for Perceptual Segregation of Time-Varying Auditory, Visual and Vibrotactile Stimulation
What sound quality has led to exclude infrasound from sound in the conventional hearing range? We examined whether temporal segregation of pressure pulses is a distinctive property and evaluated this perceptual limit via an adaptive psychophysical procedure for pure tones and carriers of different envelopes. Further, to examine across-domain similarity and individual covariation of this limit, here called the critical segregation rate (CSR), it was also measured for various periodic visual and vibrotactile stimuli. Results showed that sequential auditory or vibrotactile stimuli separated by at least ~80‒90 ms (~11‒12-Hz repetition rates), will be perceived as perceptually segregated from one another. While this limit did not statistically differ between these two modalities, it was significantly lower than the ~150 ms necessary to perceptually segregate successive visual stimuli. For the three sensory modalities, stimulus periodicity was the main factor determining the CSR, which apparently reflects neural recovery times of the different sensory systems. Among all experimental conditions, significant within- and across-modality individual CSR correlations were observed, despite the visual CSR (mean: 6.8 Hz) being significantly lower than that of both other modalities. The auditory CSR was found to be significantly lower than the frequency above which sinusoids start to elicit a tonal quality (19 Hz; recently published for the same subjects). Returning to our initial question, the latter suggests that the cessation of tonal quality — not the segregation of pressure fluctuations — is the perceptual quality that has led to exclude infrasound (sound with frequencies < 20 Hz) from the conventional hearing range.
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来源期刊
CiteScore
1.60
自引率
14.30%
发文量
23
期刊介绍: Timing & Time Perception aims to be the forum for all psychophysical, neuroimaging, pharmacological, computational, and theoretical advances on the topic of timing and time perception in humans and other animals. We envision a multidisciplinary approach to the topics covered, including the synergy of: Neuroscience and Philosophy for understanding the concept of time, Cognitive Science and Artificial Intelligence for adapting basic research to artificial agents, Psychiatry, Neurology, Behavioral and Computational Sciences for neuro-rehabilitation and modeling of the disordered brain, to name just a few. Given the ubiquity of interval timing, this journal will host all basic studies, including interdisciplinary and multidisciplinary works on timing and time perception and serve as a forum for discussion and extension of current knowledge on the topic.
期刊最新文献
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