Home > Research > RITA/UTC Funded Research > 2-D Optical Sensor for DGPS Augmentation

2-D Optical Sensor for DGPS Augmentation

Principal Investigator:

• Craig Shankwitz, Director, Intelligent Vehicles Laboratory

Co-Investigator(s):

• Michael Rakauskas, Research Associate, HumanFIRST Program

Project Summary

DGPS positioning is susceptible to outages due to blocked or missing satellite signals and/or blocked or missing DGPS correction messages. Outages arise primarily due to environmental reasons: passing under bridges, passing under overhead highway signs, adjacent foliage, etc. Generally, these outages are spatially deterministic, and can be accurately predicted. These outages distract drivers using DGPS-based driver assistive systems, and limit the system robustness.

Inertial measurements have been proposed as an augmentation for DGPS. Tests have shown that error rates for even emerging technologies are still too high; a vehicle can maintain lane position for less than three to four seconds. Ring laser gyros can do the job, but $100K per axis is still too expensive for road-going vehicles.

To provide robust vehicle positioning in the face of DGPS outages, the IV Lab has developed a (patent applied for) technique by which a non-contact, 2-D true ground velocity sensor is used to guide the vehicle. Although far from fully developed, the system can maintain vehicle position within a lane for more than 20 seconds.

Proposed herein is basic research which may lead to the development of an inexpensive, 2-D, non-contact velocity sensor optimized for vehicle guidance during periods of DGPS outages.

Sponsor(s):

• ITS Institute (RITA)