Psychophysical Tuning Curve and Critical Band Determined by Masking in the Presence of FM Sounds

Abstract

Frequency modulation (FM) sounds were used as simultaneous maskers to estimate the psychophysical tuning curve (PTC). Maskers (800 ms duration) were FM sounds sweeping upward (1.2-->2.8 kHz) in Experiment I and downward (2.8-->1.2 kHz) in Experiment II. The signal was a pure tone of 2 kHz and the signal levels were 15-, 20-, 30-, and 35-dB SL. Masked PTCs were obtained as a function of masker frequency. The results were as follows: (i) When an upward-sweeping FM sound is used for high signal level, the slope of the PTC is shallower on the low frequency side and steeper on the high frequency side, and the 10-dB bandwidth of PTC coincides with that of the restricted PTC. (ii) When a downward-sweeping FM sound is used for the high signal level, the above relation for the PTC slope is reversed, and the 10-dB bandwidth for PTC coincides with that of unrestricted PTC. (iii) PTCs determined by masking in the presence of FM sounds apparently restrict the subject to listening to off-frequency, and it is shown that the bandwidth of PTC properly reflects the critical band. (iv) The properties of these PTCs can be easily explained by a neural network model of lateral inhibition, so we can accept a hypothesis that the hierarchical processing mechanism is incorporated within the inferior colliculus for parallel signal processing. (v) We conclude that the frequency resolution and the critical band filtering are, therefore, realized in a psychophysically relevant way in the auditory midbrain level.