Abstract
Forward collision warning systems, lane change assistants, and cooperative adaptive cruise control are examples of safety relevant applications that rely on accurate relative positioning between vehicles. Current solutions estimate the position of an in-front driving vehicle by measuring the distance with a radar sensor, a laser scanner, or a camera system. The perception range of these sensors can be extended by the exchange of GNSS information between the vehicles using an intervehicle communication link. One possibility is to transmit GNSS pseudorange and carrier phase measurements and compute a highly accurate baseline vector that represents the relative position between two vehicles. Solving for the unknown integer ambiguity is specially challenging for low-cost single-frequency receivers. Using the well-known LAMBDA (Least-squares AMBiguity Decorrelation Adjustment) algorithm, in this paper, we present a method for tracking the ambiguity vector solution, which is able to detect and recover from cycle slips and cope with changing satellite constellations. In several test runs performed in real-world open-sky environments with two vehicles, the performance of the proposed Ambiguity Tracker approach is evaluated. The experiments revealed that it is in fact possible to track the position of another vehicle with subcentimeter accuracy over longer periods of time with low-cost single-frequency receivers.
Highlights
To make transportation more efficient and safer, today’s vehicles are already equipped with multiple Advanced Driver Assistance Systems
In this paper we proposed a new method to determine the relative position of two vehicles using a cooperative approach exchanging Global Navigation Satellite Systems (GNSS) raw measurements
The Ambiguity Tracker is based on single-epoch LAMBDA method to find the most likely integer ambiguity vector and be robust against cycle slips
Summary
To make transportation more efficient and safer, today’s vehicles are already equipped with multiple Advanced Driver Assistance Systems. Travis et al [6, 7] have worked on a trajectory duplication using carrier phase based relative positioning They perform a direct exchange of the measurements between the receivers to compute single differences and estimate the relative position by incorporating inertial measurements. Takasu and Yasuda worked on cycle-slip detection in automotive environments using dual-frequency high-graded receivers [8] They propose an integration of GNSS and inertial sensor inside a Kalman filter to exploit the complementary nature of both sensors. We analyze the possibility of only using lowcost single-frequency GPS receivers to precisely estimate the baseline between two vehicles by solving the integer ambiguity in the carrier phase measurements.
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