The role of low-frequency oscillations in three-dimensional perception with depth cues in virtual reality

Currently, vision-related neuroscience studies are undergoing a trend from simplified image stimuli toward more naturalistic stimuli. Virtual reality (VR), as an emerging technology for visual immersion, provides more depth cues for three-dimensional (3D) presentation than two-dimensional (2D) image. It is still unclear whether the depth cues used to create 3D visual perception modulate specific cortical activation. Here, we constructed two visual stimuli presented by stereoscopic vision in VR and graphical projection with 2D image, respectively, and used electroencephalography to examine neural oscillations and their functional connectivity during 3D perception. We find that neural oscillations are specific to delta and theta bands in stereoscopic vision and the functional connectivity in the two bands increase in cortical areas related to visual pathways. These findings indicate that low-frequency oscillations play an important role in 3D perception with depth cues.

Automated summary

This study investigates the role of low-frequency oscillations in 3D perception with depth cues, using visual stimuli presented by virtual reality technology. The findings suggest that low-frequency delta and theta bands are specific to stereoscopic vision and show increased functional connectivity in cortical areas related to visual pathways.