Using Head-Mounted Virtual Reality to Measure Dynamic Driver Sight Distances and Blind Spots

In highway and road design, accurately measuring a driver’s line of sight is critical to ensuring unobstructed views that allow drivers to detect, respond to, and safely stop their vehicles before colliding with an object or pedestrian. This safe stopping distance, referred to as Stopping Sight Distance (SSD), is a key design control variable, especially when determining appropriate vehicle speeds on roadway segments with curves, grades, or intersections. At intersections, sight distance becomes even more vital due to frequent interactions between vehicles, pedestrians, and bicyclists. These interactions, occurring across multiple directions—straight, right turns, and left turns—significantly increase the potential for conflicts, esp. the conflicts between vehicles and pedestrians or bicyclists. Traditional methods for measuring sight distance are, however, time-consuming, labor-intensive, and prone to variability based on the engineer’s experience. A driver’s blind spots, or blind zones—areas outside their field of view—can further complicate sight distance measurement. These blind spots are influenced by factors such as the driver’s eye height and the vehicle’s design. For example, large A-pillars and oversized rear mirrors in taller vehicles can obstruct a driver’s view, particularly during turning maneuvers. Properly evaluating both sight distance and blind zones is crucial for selecting design speeds and optimizing roadway features to improve safety and functionality. Virtual Reality (VR) and Augmented Reality (AR) technologies offer promising solutions for addressing these challenges and improving the state-of-the-art technology for measuring and understanding drivers’ SSDs and blind spots. By combining realistic driving simulations with real-time eye and head tracking, VR/AR can enable efficient and accurate assessments of sight distance and driver blind zones more efficiently and more comprehensively than is currently done. This project seeks to explore the following research questions: 1. How does dynamic driver modeling differ from static driver modeling regarding the driver’s ability to observe the road, pedestrians, and their surrounding environment? 2. How does dynamic driver behavior affect sight distance and driver blind zones at intersections? 3. How will the choice of driving speed and path differ with and without driver blind spots and sight limitations? Answering these questions will provide a deeper understanding of driver blind spots and sight limitations, enabling engineers to optimize roadway designs for enhanced safety and efficiency. Furthermore, these insights can assist drivers in selecting appropriate speeds and navigation paths, reducing the likelihood of conflicts with pedestrians and bicyclists. By leveraging VR/AR technologies, this research aims to streamline the evaluation process and advance roadway design practices, ultimately contributing to safer, more efficient transportation systems.

• Record URL:
  • https://www.pedbikesafety.org/projects/25uwm01

Language

• English

Project

• Status: Active
• Funding: $71,364.00
• Contract Numbers:

  69A3552348336

• Sponsor Organizations:

  Office of the Assistant Secretary for Research and Technology

  University Transportation Centers Program
  Department of Transportation
  Washington, DC  United States  20590
• Managing Organizations:

  Office of the Assistant Secretary for Research and Technology

  Department of Transportation
  1200 New Jersey Avenue, SE
  Washington, DC  United States  20590
• Project Managers:

  Stearns, Amy

• Performing Organizations:

  University of Wisconsin-Milwaukee

  Department of Urban Planning/Institute for Physical Infrastructure and Transportation
  Milwaukee, WI  United States 
• Principal Investigators:

  Thomas, Jerald

• Start Date: 20251201
• Expected Completion Date: 20261130
• Actual Completion Date: 0
• USDOT Program: University Transportation Centers

Subject/Index Terms

• TRT Terms: Blind spots; Head up displays; Intersections; Pedestrian vehicle interface; Sight distance; Virtual reality
• Subject Areas: Highways; Operations and Traffic Management; Safety and Human Factors;

Filing Info

• Accession Number: 01971435
• Record Type: Research project
• Source Agency: Center for Pedestrian and Bicyclist Safety
• Contract Numbers: 69A3552348336
• Files: UTC, RIP
• Created Date: Nov 17 2025 2:56PM