Description

Every day human subjects rely on their vision to judge the absolute distances of objects around them to plan and guide their actions, such as walking and driving. This, way-finding, process of ascertaining one's position and planning for possible routes of actions cannot be accomplished without reliable perception of visual space in the intermediate distance range (~2-25m from the observer). Thus, the broad long-term objective of this project is to uncover the mechanisms underlying intermediate distance space perception that supports distance judgment.

Yet, less is known about the underlying mechanisms of intermediate distance space perception compared to those of near space perception (<2m). Moreover, extant knowledge is predominantly obtained from testing static observers, making it difficult to generalize to the more common situation where observers plan and execute self-motion. The latter situation is more complex because self-motion is accompanied by retinal image motion of static objects in the surrounding environment, potentially requiring the visual system to simultaneously track the locations of all objects in the environment. The visual system also requires more processing capacity because it has to simultaneously compute the visual space representation, explore the environment, implement motor controls, etc. Clearly, both challenges - coding complexity and capacity limitation - could pose as potential threats to our ability to efficiently judge absolute distances and implement actions. This project hypothesizes the visual system overcomes both challenges by: (a) spatially updating the moving observer's position using an allocentric, world-centered spatial coordinate system for representing visual space, and (b) use spatial working memory (spatial-image) during spatial updating. The investigators will examine both hypotheses in three specific aims.

Aim 1: Investigate the implementation of the allocentric, world-centered spatial coordinate system

Aim 2: Investigate the factors affecting the spatial updating of visual space

Aim 3: Investigate the role of spatial-image memory in visual space perception

The psychophysical experiments will measure human behavioral responses in the real 3D environment. This approach allows for understanding of how humans' natural ecological niche, namely, the ground surface, both constrains and supports space perception and action in the real world. The investigators will test human observers' ability to judge target locations in impoverished visual environments under various conditions, such as while manipulating the observers' cognitive load (attention and memory), or available visual and idiothetic (vestibular and proprioception) information, while they plan and/or execute self-motion (walking). The outcomes of this research will advance the space perception literature, bridge theoretical knowledge of visual space perception and memory-directed navigation (cognitive maps), as well as reveal the influence of vestibular and somatosensory signals. In turn, the theoretical advancements provide insights for better understanding of intermediate distance space perception related to eye and visual impairments and their impacts on mobility in the real 3D environment.