A perceptual model for eccentricity-dependent spatio-temporal flicker fusion and its applications to foveated graphics

Virtual and augmented reality (VR/AR) displays strive to provide a resolution, framerate and field of view that matches the perceptual capabilities of the human visual system, all while constrained by limited compute budgets and transmission bandwidths of wearable computing systems. Foveated graphic...

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Veröffentlicht in:	ACM transactions on graphics 2021-08, Vol.40 (4), p.1-11, Article 47
Hauptverfasser:	Krajancich, Brooke, Kellnhofer, Petr, Wetzstein, Gordon
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Sprache:	eng
Schlagworte:	Communication hardware, interfaces and storage Computer graphics Computing methodologies Displays and imagers Graphics systems and interfaces Hardware Mixed / augmented reality
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creator	Krajancich, Brooke Kellnhofer, Petr Wetzstein, Gordon
description	Virtual and augmented reality (VR/AR) displays strive to provide a resolution, framerate and field of view that matches the perceptual capabilities of the human visual system, all while constrained by limited compute budgets and transmission bandwidths of wearable computing systems. Foveated graphics techniques have emerged that could achieve these goals by exploiting the falloff of spatial acuity in the periphery of the visual field. However, considerably less attention has been given to temporal aspects of human vision, which also vary across the retina. This is in part due to limitations of current eccentricity-dependent models of the visual system. We introduce a new model, experimentally measuring and computationally fitting eccentricity-dependent critical flicker fusion thresholds jointly for both space and time. In this way, our model is unique in enabling the prediction of temporal information that is imperceptible for a certain spatial frequency, eccentricity, and range of luminance levels. We validate our model with an image quality user study, and use it to predict potential bandwidth savings 7X higher than those afforded by current spatial-only foveated models. As such, this work forms the enabling foundation for new temporally foveated graphics techniques.
doi_str_mv	10.1145/3450626.3459784
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subjects	Communication hardware, interfaces and storage Computer graphics Computing methodologies Displays and imagers Graphics systems and interfaces Hardware Mixed / augmented reality
title	A perceptual model for eccentricity-dependent spatio-temporal flicker fusion and its applications to foveated graphics
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