Abstract
In this paper, we propose a cost-effective localization solution for land vehicles, which can simultaneously adapt to the uncertain noise of inertial sensors and bridge Global Positioning System (GPS) outages. First, three Unscented Kalman filters (UKFs) with different noise covariances are introduced into the framework of Interacting Multiple Model (IMM) algorithm to form the proposed IMM-based UKF, termed as IMM-UKF. The IMM algorithm can provide a soft switching among the three UKFs and therefore adapt to different noise characteristics. Further, two IMM-UKFs are executed in parallel when GPS is available. One fuses the information of low-cost GPS, in-vehicle sensors, and micro electromechanical system (MEMS)-based reduced inertial sensor systems (RISS), while the other fuses only in-vehicle sensors and MEMS-RISS. The differences between the state vectors of the two IMM-UKFs are considered as training data of a Grey Neural Network (GNN) module, which is known for its high prediction accuracy with a limited amount of samples. The GNN module can predict and compensate position errors when GPS signals are blocked. To verify the feasibility and effectiveness of the proposed solution, road-test experiments with various driving scenarios were performed. The experimental results indicate that the proposed solution outperforms all the compared methods.
Highlights
Accurate and reliable vehicle ego-position is important and necessary information in more and more Intelligent Transportation System (ITS) applications [1,2,3]
Since the vehicle was equipped with Antilock Brake System (ABS) and ESP, the information about steering angle and forward speed could be directly obtained from the in-vehicle CAN bus
12of of19 maneuvers, such as lane-changes, accelerations and decelerations etc., were conducted according to only execute the measurement update associated with in-vehicle sensors during Global Positioning System (GPS) outages and actual driving conditions
Summary
Accurate and reliable vehicle ego-position is important and necessary information in more and more Intelligent Transportation System (ITS) applications [1,2,3]. The most popular technique is Global Positioning System (GPS), which can provide satisfactory localization performance in open areas [4,5], but in modern urban environments, more and more tall buildings or overpasses may affect the GPS signals and cause the failure of GPS. To improve the GPS localization performance, it is usually integrated with Inertial Navigation System (INS), which is a self-contained system and is not affected by external disturbances [4]. In order to further lower the cost of vehicle localization systems, research efforts have recently been made to investigate the applicability of reduced inertial sensor systems (RISS) [10,11]. RISS involves a single-axis gyroscope and two-axis accelerometers
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