MRC Cognition and Brain Sciences Unit, 15 Chaucer Road, Cambridge, UK.
J Assoc Res Otolaryngol. 2011 Apr;12(2):253-60. doi: 10.1007/s10162-010-0250-3. Epub 2010 Nov 18.
A fundamental attribute of human hearing is the ability to extract a residue pitch from harmonic complex sounds such as those produced by musical instruments and the human voice. However, the neural mechanisms that underlie this processing are unclear, as are the locations of these mechanisms in the auditory pathway. The ability to extract a residue pitch corresponding to the fundamental frequency from individual harmonics, even when the fundamental component is absent, has been demonstrated separately for conventional pitches and for Huggins pitch (HP), a stimulus without monaural pitch information. HP is created by presenting the same wideband noise to both ears, except for a narrowband frequency region where the noise is decorrelated across the two ears. The present study investigated whether residue pitch can be derived by combining a component derived solely from binaural interaction (HP) with a spectral component for which no binaural processing is required. Fifteen listeners indicated which of two sequentially presented sounds was higher in pitch. Each sound consisted of two "harmonics," which independently could be either a spectral or a HP component. Component frequencies were chosen such that the relative pitch judgement revealed whether a residue pitch was heard or not. The results showed that listeners were equally likely to perceive a residue pitch when one component was dichotic and the other was spectral as when the components were both spectral or both dichotic. This suggests that there exists a single mechanism for the derivation of residue pitch from binaurally created components and from spectral components, and that this mechanism operates at or after the level of the dorsal nucleus of the lateral lemniscus (brainstem) or the inferior colliculus (midbrain), which receive inputs from the medial superior olive where temporal information from the two ears is first combined.
人类听觉的一个基本属性是能够从谐波复合声音中提取剩余音高,例如乐器和人声产生的声音。然而,这种处理所基于的神经机制尚不清楚,这些机制在听觉通路中的位置也不清楚。从单个谐波中提取与基频相对应的剩余音高的能力,即使基频成分不存在,也已经分别在常规音调和胡金斯音(HP)中得到了证明,HP 是通过向双耳呈现相同的宽带噪声来创建的,除了一个窄带频率区域,其中噪声在两个耳朵之间是去相关的。本研究探讨了是否可以通过将仅源自双耳相互作用的组件(HP)与不需要双耳处理的频谱组件结合起来,来得出剩余音高。15 名听众指出两个连续呈现的声音中哪一个音高更高。每个声音都由两个“谐波”组成,这两个谐波可以独立地是频谱或 HP 组件。选择组件频率,使得相对音高判断可以揭示是否听到了剩余音高。结果表明,当一个组件是双声道的,而另一个组件是频谱的,或者当两个组件都是频谱的或都是双声道的时,听众同样有可能感知到剩余音高。这表明存在一个单一的机制,可以从双耳产生的组件和频谱组件中得出剩余音高,并且该机制在或之后的外侧丘系背核(脑干)或下丘(中脑)的水平上运行,这些结构接收来自两个耳朵的时间信息首先在中脑的内侧上橄榄核中进行组合。
