Responses of "lower-spontaneous-rate" auditory-nerve fibers to speech syllables presented in noise. I: General characteristics.

Responses of auditory-nerve fibers in anesthetized cats to nine different spoken stop- and nasal-consonant/vowel syllables presented at 70 dB SPL in various levels of speech-shaped noise [signal-to-noise (S/N) ratios of 30, 20, 10, and 0 dB] are reported. The temporal aspects of speech encoding were analyzed using spectrograms. The responses of the "lower-spontaneous-rate" fibers (less than 20/s) were found to be more limited than those of the high-spontaneous-rate fibers. The lower-spontaneous-rate fibers did not encode noise-only portions of the stimulus at the lowest noise level (S/N = 30 dB) and only responded to the consonant if there was a formant or major spectral peak near its characteristic frequency. The fibers' responses at the higher noise levels were compared to those obtained at the lowest noise level using the covariance as a quantitative measure of signal degradation. The lower-spontaneous-rate fibers were found to preserve more of their initial temporal encoding than high-spontaneous-rate fibers of the same characteristic frequency. The auditory-nerve fibers' responses were also analyzed for rate-place encoding of the stimuli. The results are similar to those found for temporal encoding.

Responses of "lower-spontaneous-rate" auditory-nerve fibers to speech syllables presented in noise. II: Glottal-pulse periodicities.

The responses of single cat auditory-nerve fibers to naturally spoken voiced sounds (the vowels [a, i, u] and the murmur [m]) presented at normal intensity (70 dB SPL) in various levels of speech-shaped noise were analyzed for the encoding of the glottal-pulse (fundamental) period. To quantify the strength of this fundamental-period encoding, selected segments of the response histograms were autocorrelated, rectified, and fitted with the best-fitting sinusoid of the fundamental frequency. The magnitude of this best-fitting sinusoid was taken as the magnitude of synchronization. In most cases, it was found that the "lower-SR" fibers (those with spontaneous discharge rates less than 20/s) encoded the fundamental periodicity more strongly and more robustly than did the "high-SR" fibers (those with spontaneous discharge rates greater than 20/s). When either a single strong spectral peak or a relatively "flat" spectrum excited a fiber, it showed poor synchronization to the fundamental period, regardless of its spontaneous-rate class. Judging from a few examples, the glottal-pulse synchronization appears to be intensity dependent, with the relative performance of the high-SR fibers improving at lower intensities. A conceptual model is given which accounts for the general characteristics of the data.