Self-location and Reorientation of Individuals Without Reading Maps: Increased Spatial Memory During GPS Navigation Using AR City Walls
Authors: 
Xiaoyu Zhang, Sunao IwakiAuthors Info & Claims
Pages 254 - 267
Abstract
Consulting a map on navigation assistance systems while navigating the real-world environment can reduce spatial memory. The current augmented reality (AR) view, which merges physical and virtual information spaces, facilitates wayfinding by overlaying route indications in the real-world environment. Traditionally, switching from the AR to the map view has been considered essential for encoding spatial representations in the brain constructing the cognitive map. However, we propose that the need for maps can be reduced by utilizing AR objects that simulate the environmental boundary surrounding the navigation area. Based on this concept, we designed a prototype, AR City Walls, and conducted an experiment to evaluate spatial memory and workload during Global Positioning System (GPS)-aided navigation without map exposure. Compared to the AR view displaying route indications only, the AR City Walls combining route indications significantly improved cognitive map construction and wayfinding while maintaining a low workload. Simulating real environmental cues crucial for spatial cognition during navigation embodies the simplicity, naturalness, and immediacy of virtual information displays.
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Jun 2024
300 pages
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.
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Springer-Verlag
Berlin, Heidelberg
Publication History
Published: 29 June 2024
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