Auditory and visual localization performance in a sequential discrimination task

Perrott, David R.; Costantino, Brian L.; Cisneros, John

doi:10.1121/1.406675

Cited by 27 publications

(20 citation statements)

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“…This probably is due to a more refined capability for discriminating between adjacent sound sources centrally than in the periphery. On the basis of earlier studies in cats (Jenkins & Masterton, 1982), it was found that humans can discriminate adjacent sound sources directly in front of them when separated by only 2°_3°, whereas discrimination between peripheral sounds (e.g., at 40°azimuth) was markedly inferior (Perrott, Constantino, & Cisneros, 1993; see also Oldfield & Parker, 1984). Clearly, the sharpness of attentional allocation to a particular sound source among nearby competing sources depends in part on the ability to discriminate the location of the attended source from those of its neighbors.…”

Section: Time Course Analysismentioning

confidence: 98%

The gradient of spatial auditory attention in free field: An event-related potential study

Teder‐Salejarvi

Hillyard

1998

Perception & Psychophysics

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Young adult subjects attended selectively to brief noise bursts delivered in free field via a horizontal array of seven loudspeakers spaced apart by 9°of angle. Frequent "standard" stimuli (90%) and infrequent "target/deviant" stimuli (100,6) of increased bandwidth were delivered at a fast rate in a random sequence equiprobably from each speaker. In separate runs, the subjects' task was to selectively attend to the leftmost, center, or rightmost speaker and to press a button to the infrequent "target" stimuli occurring at the designated spatial location. Behavioral detection rates and concurrently recorded event-related potentials (ERPs) indicated that auditory attention was deployed as a finely tuned gradient around the attended sound source, thus providing support for gradient models of auditory spatial attention. Furthermore, the ERP data suggested that the spatial focusing of attention was achieved in two distinct stages, with an early more broadly tuned filtering of inputs occurring over the first msec after stimulus onset, followed by a more narrowly focused selection of attended-location deviants that began at around 250 msec and closely resembled the behavioral gradient of target detections.

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Section: Time Course Analysismentioning

confidence: 98%

The gradient of spatial auditory attention in free field: An event-related potential study

Teder‐Salejarvi

Hillyard

1998

Perception & Psychophysics

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“…Few studies have attempted to directly compare spatial acuity for auditory and visual stimuli throughout the visual field and focus instead on the spatial capture observed when spatially separated auditory-visual signals are presented (Howard and Templeton, 1966; Bertelson and Radeau, 1981). Two exceptions to this are Perrot et al (1993) and Charbonneau et al (2013). Both determined that both visual and auditory localisation judgments declined as stimuli move from central to peripheral space.…”

Section: Introductionmentioning

confidence: 99%

“…Both auditory (Mills, 1958; Makous and Middlebrooks, 1990; Charbonneau et al , 2013; Wood and Bizley, 2015; Carlile et al , 2016) and visual localisation acuity declines with eccentricity (Mateeff and Gourevich, 1984; Perrott et al , 1993; Charbonneau et al , 2013). Few studies have attempted to directly compare spatial acuity for auditory and visual stimuli throughout the visual field and focus instead on the spatial capture observed when spatially separated auditory-visual signals are presented (Howard and Templeton, 1966; Bertelson and Radeau, 1981).…”

Section: Introductionmentioning

confidence: 99%

Multisensory stimuli improve relative localisation judgments compared to unisensory auditory or visual stimuli

Freeman

Wood

Bizley

2018

The Journal of the Acoustical Society of America

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Observers performed a relative localisation task in which they reported whether the second of two sequentially presented signals occurred to the left or right of the first. Stimuli were detectability-matched auditory, visual, or auditory-visual signals and the goal was to compare changes in performance with eccentricity across modalities. Visual performance was superior to auditory at the midline, but inferior in the periphery, while auditory-visual performance exceeded both at all locations. No such advantage was seen when performance for auditory-only trials was contrasted with trials in which the first stimulus was auditory-visual and the second auditory only.

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“…While auditory localization also decreases (Makous and Middlebrooks, 1990;Perrott and Saberi, 1990), spatial resolution degrades more slowly than vision (Perrott et ai, 1993). Perrott et al (1993) measured the minimum audible angles (MAA) and minimum visible angles (MVA) over a wide horizontal area (0°-80°) and found that the MAA was equal to or larger than the MVA for all regions beyond a 20°-periphery of the fovea. If the most likely location of an audio-visual target depends on uncertainties individually associated with auditory and visual cues, the dominant modality in localization must be changed by eccentricity.…”

Section: Introductionmentioning

confidence: 99%

Relative Localization of Auditory and Visual Events Presented in Peripheral Visual Field

et al. 2014

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The brain apparently remaps the perceived locations of simultaneous auditory and visual events into a unified audio-visual space to integrate and/or compare multisensory inputs. However, there is little qualitative or quantitative data on how simultaneous auditory and visual events are located in the peripheral visual field (i.e., outside a few degrees of the fovea). We presented a sound burst and a flashing light simultaneously not only in the central visual field but also in the peripheral visual field and measured the relative perceived locations of the sound and flash. The results revealed that the sound and flash were perceptually located at the same location when the sound was presented at a 5°p eriphery of the flash, even when the participants' eyes were fixed. Measurements of the unisensory locations of each sound and flash in a pointing task demonstrated that the perceived location of the sound shifted toward the front, while the perceived location of the flash shifted toward the periphery. As a result, the discrepancy between the perceptual location of the sound and the flash was around 4°. This suggests that the brain maps the unisensory locations of auditory and visual events into a unified audio-visual space, enabling it to generate unisensory spatial information about the events.

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Auditory and visual localization performance in a sequential discrimination task

Cited by 27 publications

References 0 publications

The gradient of spatial auditory attention in free field: An event-related potential study

The gradient of spatial auditory attention in free field: An event-related potential study

Multisensory stimuli improve relative localisation judgments compared to unisensory auditory or visual stimuli

Relative Localization of Auditory and Visual Events Presented in Peripheral Visual Field

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