Abstract
Fusion of the Global Positioning System (GPS) and Inertial Navigation System (INS) for navigation of ground vehicles is an extensively researched topic for military and civilian applications. Micro-electro-mechanical-systems-based inertial measurement units (MEMS-IMU) are being widely used in numerous commercial applications due to their low cost; however, they are characterized by relatively poor accuracy when compared with more expensive counterparts. With a sudden boom in research and development of autonomous navigation technology for consumer vehicles, the need to enhance estimation accuracy and reliability has become critical, while aiming to deliver a cost-effective solution. Optimal fusion of commercially available, low-cost MEMS-IMU and the GPS may provide one such solution. Different variants of the Kalman filter have been proposed and implemented for integration of the GPS and the INS. This paper proposes a framework for the fusion of adaptive Kalman filters, based on Sage-Husa and strong tracking filtering algorithms, implemented on MEMS-IMU and the GPS for the case of a ground vehicle. The error models of the inertial sensors have also been implemented to achieve reliable and accurate estimations. Simulations have been carried out on actual navigation data from a test vehicle. Measurements were obtained using commercially available GPS receiver and MEMS-IMU. The solution was shown to enhance navigation accuracy when compared to conventional Kalman filter.
Highlights
The GPS (Global Positioning System) and the INS (Inertial Navigation System) can provide stand-alone navigation solutions; both are prone to intrinsic errors/biases which may limit the accuracy and productivity of each navigation technique
This paper proposes a novel framework based on adaptive Kalman filtering, implemented using the GPS-INS loose-coupling integration strategy due to its simplicity, robustness, and comparatively lesser computational load
Development of a reliable aided inertial navigation system depends on selecting an appropriate estimation method
Summary
The GPS (Global Positioning System) and the INS (Inertial Navigation System) can provide stand-alone navigation solutions; both are prone to intrinsic errors/biases which may limit the accuracy and productivity of each navigation technique. Sensors 2019, 19, 5357 completely independent of external disturbances, which can provide continuous estimates of position and velocity, and of orientation, at a high measurement output rate It offers only short-term accuracy due to an unbounded growth in error inherent to the inertial sensors. Low cost micro-electro-mechanical-systems-based inertial measurement units (MEMS-IMUs) have extremely poor accuracy and suffer adversely from intrinsic errors such as scale factor, drift, bias, and non-orthogonality. Their outputs contain high noise and large uncertainties. The proposed algorithm offers a balance between accuracy and strong convergence to optimum estimation for highly dynamic systems It is a practical algorithm and provides a reliable, accurate, and cost-effective solution, as shown by simulations on real vehicle navigation data.
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