Neuronal mechanisms for pitch analysis in the time domain

Abstract

Many units in the auditory midbrain nucleus (MLD) of the Guinea fowl are found to be tuned to amplitude modulated tones (AM). For a given response maximum the relationship of the period τ_m of the modulation frequency f_m and the period τ_c of the carrier frequency f_c may be given by an empirical equation: m · τ_m + n · τ_c = 1 · τ₁, where m, n and 1 are small integers typical for a unit. τ₁ is a time constant of 0.4 ms. The temporal pattern of the neuronal response support these findings. The averages of spike trains oscillate with periods multiple to τ₁. These oscillations are elicited by stimulus onsets and zero crossings of f_m and may be coupled strongly to f_m depending on f_c. Variation of f_m or f_c shifts the mean delay of the phase coupled activity proportional to m · τ_m and n · τ_c, respectively. These effects may be explained with activity phase coupled to f_c which coincides at the level of the recorded units with oscillations coupled to f_m. This is expressed by the above given periodicity equation. Psychophysical results with AM-stimuli indicate that the mechanisms described and the periodicity equation are adequate for the explanation of the analysis of periodicity pitch in humans. Hence the period corresponding to pitch is defined by m · τ_m + n · τ_c = 1 · τ₁, where n and 1 are integers and τ₁ = 0.4 ms. Plots of τ_p as a function of τ_c reveal steps at 0.4 ms intervals indicating that the neuronal time constant is the same in both species.