Corridor-Wide Surveillance Using Unmanned Aircraft Systems Phase III: Exploration of the Implementation of Using Unmanned Aircraft Systems for Freeway Incident Detection and Management: Part B

In the third phase of the project “Corridor-Wide Surveillance Using Unmanned Aircraft Systems,” the research team continued utilizing drone systems equipped with thermal cameras to enable real-time detection of traffic incidents and their resulting non-recurrent congestion on freeways, while distinguishing them from recurrent congestion. A comprehensive literature review on existing traffic incident detection methods was conducted. Building on insights from the literature and prior accomplishments, the team designed and implemented a drone-based incident detection framework. This framework first extracts vehicle trajectories at fixed intervals from thermal video data and generates corresponding trajectory images. A customized convolutional neural network (CNN) based deep learning model is then developed and trained to extract traffic features from these images and classify them into three categories: incident, recurrent congestion, and normal traffic. Real-time detection was achieved through continuous processing of incoming thermal video segments. Finally, the research team developed a drone-based, AI-powered, real-time freeway incident detection system, featuring a user-friendly web-based graphical user interface (GUI) for initiating and terminating detection process, visualizing results, and reviewing historical records. The system was tested in six detection flights across three different test sites in Florida. During an incident scenario, test results demonstrated that the system was able to accurately and promptly detect the incident approximately 12 minutes earlier than the local Transportation Management Center (TMC). The thermal video containing the incident scene was displayed on the GUI to support immediate verification and severity assessment by the TMC, thereby facilitating rapid emergency response and potentially saving lives. Additionally, the system extracted and displayed the length of the incident-induced non-recurrent congestion during each flight and its propagation speed across multiple flights, providing valuable information for the TMC to implement effective incident management strategies and mitigate the overall impact. This research was part of a larger three-phased effort. Phase I focused on the design and testing of the operations of multiple UAVs for collecting traffic information and the development of incident detection methodology. Phase II involved two separate but related research efforts by the University of Puerto Rico, Mayaguez (Part A), and the University of South Florida (Part B). In Phase III of this project, the research teams focused on the validation of the algorithms developed in the previous phases and implementation matters of Phase II.

• Record URL:
  • https://nicr.usf.edu/2024/12/18/4-7-2_freeway_incident_detection_uas_phase3/

Language

• English

Project

• Status: Completed
• Funding: $108,000.00
• Contract Numbers:

  69A3551947136

  79075-32

  79075-33

• 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:

  National Institute for Congestion Reduction

  University of South Florida
  Tampa, FL  United States  33620
• Project Managers:

  Zhang, Yu

• Performing Organizations:

  University of South Florida, Tampa

  Center for Urban Transportation Research
  3650 Spectrum Boulevard
  Tampa, FL  United States  33612-9446
• Principal Investigators:

  Zhang, Yu

• Start Date: 20220901
• Expected Completion Date: 20250531
• Actual Completion Date: 0
• USDOT Program: UTC

Subject/Index Terms

• TRT Terms: Deep learning; Drones; Image analysis; Incident detection; Literature reviews; Real time data processing; Thermal imagery; Traffic surveillance
• Geographic Terms: Florida
• Subject Areas: Data and Information Technology; Highways; Operations and Traffic Management; Safety and Human Factors;

Filing Info

• Accession Number: 01962455
• Record Type: Research project
• Source Agency: National Institute for Congestion Reduction
• Contract Numbers: 69A3551947136, 79075-32, 79075-33
• Files: UTC, RIP
• Created Date: Aug 1 2025 12:57PM