The relative contribution of interaural time and magnitude cues to dynamic sound localization

This paper presents preliminary data from a study examining the relative contribution of interaural time differences (ITDs) and interaural level differences (ILDs) to the localization of virtual sound sources both with and without head motion. The listeners´ task was to estimate the apparent direction and distance of virtual sources presented over headphones. Stimuli were synthesized from minimum phase representations of nonindividualized directional transfer functions. During dynamic conditions, listeners were encouraged to move their heads; the position of the listener´s head was tracked and the stimuli were synthesized in real time using a Convolvotron to simulate a stationary external sound source. ILDs and ITDs were either correctly or incorrectly correlated with head motion: (1) both ILDs and ITDs correctly correlated, (2) ILDs correct, ITD fixed at 0° azimuth and 0° elevation, (3) ITDs correct, ILDs fixed at 0°, 0°. Similar conditions were run for static conditions except that none of the cues changed with head motion. The data indicated that, compared to static conditions, head movements helped listeners to resolve confusions primarily when ILDs were correctly correlated, although a smaller effect was also seen far correct ITDs. Together with the results for static conditions, the data suggest that localization tends to be dominated by the cue that is most reliable or consistent, when reliability is defined by consistency over time as well as across frequency