TRAINING SYSTEM FOR IMPROVING SPATIAL SOUND LOCALIZATION
TRAINING SYSTEM FOR IMPROVING SPATIAL SOUND LOCALIZATION

Summary/Abstract: This paper presents a training system for 3D audio space localization, based on the Head Related Transfer Function- a physical propagation characteristic that describes how the ear perceives the sound coming from a particular point in space. This system is part of a more complex project, Sound of Vision, which is intended to be an object recognition and navigation aid system for visually-impaired people. As a large number of people are suffering from a visual handicap which impedes them from normally accomplishing their daily chores, there is need for an assistive device that replaces sight with another sense, for instance, hearing. The most important aspect in the sound localization techniques is the human capacity to discriminate between different sounds playing at various locations in space.The aim of the presented audio system is to train and test the subjects’ space localization ability, hence to develop and improve their 3D recognition skills. The acoustic signals represent short (20ms long) noise sounds, externalized with non-individualized HRTFs recorded in an anechoic chamber at MIT Research Laboratories. Thus, from a monaural noise sound, through the process of mathematical convolution with the corresponding angular HRTF impulse for both the left and right channels, we obtained a 3D binaural sound which is perceived as coming from the particular direction specified by the angular value of the convoluted HRTF. Hence, the static and dynamic objects from the environment are modeled into acoustic signals, conveyed to the user through a pair of stereophonic headphones. The program is composed of a training module, where the user moves the mouse cursor inside a circle and hears a continuous binaural sound that corresponds to the azimuth angle indicated on the circle- ranging from 0 to 355 degrees, and a test module- where the subject is presented 10 different sounds that correspond to 10 different locations, being required to point out on the circle the presumed emitting location of the sound, as he perceives it. Through learning and training, the users performed various auditory tasks- identification, recognition, discrimination- and improved their sound localization capacity.

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