2017
DOI: 10.17743/jaes.2017.0038
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Localization Experiments with Reporting by Head Orientation: Statistical Framework and Case Study

Abstract: This paper is concerned with sound localization experiments in which subjects report the position of an active sound source by turning toward it. A statistical framework for the analysis of the data from this type of experiment is presented together with a case study from a largescale listening experiment. The statistical framework is based on a model that is robust to the presence of front/back confusions and random errors. Closed-form natural estimators are derived, and one-sample and two-sample statistical … Show more

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Cited by 4 publications
(5 citation statements)
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“…However, considering the ensemble of responses under this assumption, the angular data contained a mixture of guess answers uniformly distributed across all possible angles, obtained when participants did not detect the reflection, answers located around the true location, obtained when participants detected the reflection, or even answers located at a mirrored location behind the participant in case of front-back mistakes. Given this kind of data, it is particularly suitable to use the model for azimuth localization proposed in [42], where the probability of responses is modeled with a probability density function f ⇥ :…”
Section: Emission Propertiesmentioning
confidence: 99%
See 3 more Smart Citations
“…However, considering the ensemble of responses under this assumption, the angular data contained a mixture of guess answers uniformly distributed across all possible angles, obtained when participants did not detect the reflection, answers located around the true location, obtained when participants detected the reflection, or even answers located at a mirrored location behind the participant in case of front-back mistakes. Given this kind of data, it is particularly suitable to use the model for azimuth localization proposed in [42], where the probability of responses is modeled with a probability density function f ⇥ :…”
Section: Emission Propertiesmentioning
confidence: 99%
“…where f 1,⇥ (✓; µ, ) is the probability density function of the correctly de- In the model proposed in [42], f 1,⇥ (✓; µ, ) is a von Mises distribution [43], which among the circular distributions is the one having properties similar to the normal distribution in the linear domain. The von Mises distribution has a probability density function…”
Section: Emission Propertiesmentioning
confidence: 99%
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“…This is particularly advantageous in the context of real-time binaural rendering as it avoids the need to cull reflections to keep computational complexity bounded (Hacıhabiboğlu and Murtagh, 2008). Indeed, the method used here to generate a binaural output is to spatialise only the six directions associated with the firstorder reflections directly (De Sena et al, 2017), using the HTB renderer described above. The reverberation tail is thus spatialised according to the direction of the first-order reflections.…”
Section: Audio Renderingmentioning
confidence: 99%