在混响环境中的空间听觉:包络在猫头鹰中的作用。
Spatial hearing in echoic environments: the role of the envelope in owls.
机构信息
Institute of Neuroscience, University of Oregon, Eugene, OR 97403, USA.
出版信息
Neuron. 2010 Aug 26;67(4):643-55. doi: 10.1016/j.neuron.2010.07.014.
Abstract
In the precedence effect, sounds emanating directly from the source are localized preferentially over their reflections. Although most studies have focused on the delay between the onset of a sound and its echo, humans still experience the precedence effect when this onset delay is removed. We tested in barn owls the hypothesis that an ongoing delay, equivalent to the onset delay, is discernible from the envelope features of amplitude-modulated stimuli and may be sufficient to evoke this effect. With sound pairs having only envelope cues, owls localized direct sounds preferentially, and neurons in their auditory space-maps discharged more vigorously to them, but only if the sounds were amplitude modulated. Under conditions that yielded the precedence effect, acoustical features known to evoke neuronal discharges were more abundant in the envelopes of the direct sounds than of the echoes, suggesting that specialized neural mechanisms for echo suppression were unnecessary.
摘要
在优先效应中,直接来自声源的声音比其反射声更优先定位。尽管大多数研究都集中在声音起始和回声之间的延迟上,但当消除这种起始延迟时,人类仍然会体验到优先效应。我们在仓鸮中测试了一个假设,即与起始延迟相当的持续延迟可以从调制刺激的包络特征中辨别出来,并且可能足以引起这种效果。对于只有包络线索的声音对,仓鸮优先定位直接声音,并且它们的听觉空间图中的神经元对其放电更强烈,但前提是声音是调幅的。在产生优先效应的条件下,已知会引起神经元放电的声学特征在直接声音的包络中比在回声的包络中更为丰富,这表明专门用于抑制回声的神经机制是不必要的。
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Neuron. 2009 Apr 16;62(1):123-34. doi: 10.1016/j.neuron.2009.02.018.
2
Independence of echo-threshold and echo-delay in the barn owl.仓鸮中回声阈值与回声延迟的独立性。
PLoS One. 2008;3(10):e3598. doi: 10.1371/journal.pone.0003598. Epub 2008 Oct 31.
3
Psychophysical and physiological evidence for fast binaural processing.快速双耳处理的心理物理学和生理学证据。
J Neurosci. 2008 Feb 27;28(9):2043-52. doi: 10.1523/JNEUROSCI.4488-07.2008.
4
The precedence effect in sound localization.声音定位中的优先效应。
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5
Auditory spatial acuity approximates the resolving power of space-specific neurons.听觉空间辨别力近似于空间特异性神经元的分辨能力。
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6
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7
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