Transformation of a temporal speech cue to a spatial neural code in human auditory cortex
Neal P. Fox, Matthew K. Leonard, Matthias J. Sjerps, Edward F. Chang
Abstract
In speech, listeners extract continuously-varying spectrotemporal cues from the acoustic signal to perceive discrete phonetic categories. Spectral cues are spatially encoded in the amplitude of responses in phonetically-tuned neural populations in auditory cortex. It remains unknown whether similar neurophysiological mechanisms encode temporal cues like voice-onset time (VOT), which distinguishes sounds like / b / and/ p /. We used direct brain recordings in humans to investigate the neural encoding of temporal speech cues with a VOT continuum from / ba / to / pa /. We found that distinct neural populations respond preferentially to VOTs from one phonetic category, and are also sensitive to sub-phonetic VOT differences within a population’s preferred category. In a simple neural network model, simulated populations tuned to detect either temporal gaps or coincidences between spectral cues captured encoding patterns observed in real neural data. These results demonstrate that a spatial/amplitude neural code underlies the cortical representation of both spectral and temporal speech cues.