Indoor Localization for Visually Impaired Travelers Using Computer Vision on a Smartphone

Overview

Journal Proc 17th Int Web All Conf (2020)

Publisher Association for Computing Machinery

Date 2020 Nov 9

PMID 33163996

Citations 8

Authors

Giovanni Fusco

James M Coughlan

Affiliations

Soon will be listed here.

Abstract

Wayfinding is a major challenge for visually impaired travelers, who generally lack access to visual cues such as landmarks and informational signs that many travelers rely on for navigation. Indoor wayfinding is particularly challenging since the most commonly used source of location information for wayfinding, GPS, is inaccurate indoors. We describe a computer vision approach to indoor localization that runs as a real-time app on a conventional smartphone, which is intended to support a full-featured wayfinding app in the future that will include turn-by-turn directions. Our approach combines computer vision, existing informational signs such as Exit signs, inertial sensors and a 2D map to estimate and track the user's location in the environment. An important feature of our approach is that it requires no new physical infrastructure. While our approach requires the user to either hold the smartphone or wear it (e.g., on a lanyard) with the camera facing forward while walking, it has the advantage of not forcing the user to aim the camera towards specific signs, which would be challenging for people with low or no vision. We demonstrate the feasibility of our approach with five blind travelers navigating an indoor space, with localization accuracy of roughly 1 meter once the localization algorithm has converged.

Citing Articles

Human-AI Collaboration for Remote Sighted Assistance: Perspectives from the LLM Era.

Yu R, Lee S, Xie J, Billah S, Carroll J Future Internet. 2025; 16(7).

PMID: 40051468 PMC: 11884418. DOI: 10.3390/fi16070254.

Iterative Design and Prototyping of Computer Vision Mediated Remote Sighted Assistance.

Xie J, Reddie M, Lee S, Billah S, Zhou Z, Tsai C ACM Trans Comput Hum Interact. 2025; 29(4).

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All the Way There and Back: Inertial-Based, Phone-in-Pocket Indoor Wayfinding and Backtracking Apps for Blind Travelers.

Tsai C, Elyasi F, Ren P, Manduchi R ACM Trans Access Comput. 2025; 17(4):1-35.

PMID: 39866849 PMC: 11758990. DOI: 10.1145/3696005.

Opportunities for Human-AI Collaboration in Remote Sighted Assistance.

Lee S, Yu R, Xie J, Billah S, Carroll J IUI. 2025; 2022():63-78.

PMID: 39850496 PMC: 11755352. DOI: 10.1145/3490099.3511113.

Enhancing the Travel Experience for People with Visual Impairments through Multimodal Interaction: NaviGPT, A Real-Time AI-Driven Mobile Navigation System.

Zhang H, Falletta N, Xie J, Yu R, Lee S, Billah S GROUP ACM SIGCHI Int Conf Support Group Work. 2025; 2025(Companion):29-35.

PMID: 39807354 PMC: 11727231. DOI: 10.1145/3688828.3699636.

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