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FocusFlow: 3D Gaze-Depth Interaction in Virtual Reality Leveraging Active Visual Depth Manipulation

Chenyang Zhang, T. Chen, Eric Shaffer, Elahe Soltanaghai

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Abstract

Gaze interaction presents a promising avenue in Virtual Reality (VR) due to its intuitive and efficient user experience. Yet, the depth control inherent in our visual system remains underutilized in current methods. In this study, we introduce FocusFlow, a hands-free interaction method that capitalizes on human visual depth perception within the 3D scenes of Virtual Reality. We first develop a binocular visual depth detection algorithm to understand eye input characteristics. We then propose a layer-based user interface and introduce the concept of “Virtual Window” that offers an intuitive and robust gaze-depth VR interaction, despite the constraints of visual depth accuracy and precision spatially at further distances. Finally, to help novice users actively manipulate their visual depth, we propose two learning strategies that use different visual cues to help users master visual depth control. Our user studies on 24 participants demonstrate the usability of our proposed virtual window concept as a gaze-depth interaction method. In addition, our findings reveal that the user experience can be enhanced through an effective learning process with adaptive visual cues, helping users to develop muscle memory for this brand-new input mechanism. We conclude the paper by discussing potential future research topics of gaze-depth interaction.

Topics & Concepts

Computer scienceGazeHuman–computer interactionVirtual realityUsabilityDepth perceptionPerceptionProcess (computing)Eye trackingWindow (computing)Interface (matter)3D interactionVisualizationArtificial intelligenceUser interfaceComputer visionSensory cueUser experience designPsychologyNeuroscienceParallel computingBubbleMaximum bubble pressure methodOperating systemGaze Tracking and Assistive TechnologyTactile and Sensory InteractionsVisual perception and processing mechanisms