Abstract
Abstract. INS/GPS integration scheme can overcome the shortcoming of GPS or INS alone to provide superior performance, thus this study implements a tightly-coupled INS/GPS integration scheme using AKF as the core estimator by tuning the measurement noise matrix R adaptively. The AKF is based on the maximum likelihood criterion for choosing the most appropriate weight and thus the Kalman gain factors. The conventional EKF implementation suffers uncertain results while the update measurement noise matrix R and/or the process noise matrix Q does not meet the case. The primary advantage of AKF is that the filter has less relationship with the priori statistical information because R and/or Q vary with time. The innovation sequence is used to derive the measurement weights through the covariance matrices, innovation-based adaptive estimation (IAE) in this study. The covariance matrices R are adapted in the study when measurements update with time. A window based approach is implemented to update the quality of GPS pseudo-range measurements by adaptively replace the measurement weights through the latest estimated covariance matrices R. The use of odometer is particularly recommended when a low cost and precise vehicle localization system has to be implemented and there is the risk of GPS coverage failure, which is prone to happen when the vehicle enters a tunnel or cross deep valleys. Odometers are applied in land-vehicle navigation to provide augmented host velocity observations for standalone INS system in this study. There are two non-holonomic constraints (NHC) available for land vehicles. Land vehicles will not jump off the ground or slid on the ground under normal condition. Using these constraints, the velocity of the vehicle in the plane perpendicular to the forward direction is almost zero. EKF and AKF based tightly-coupled scheme with NHC is implemented in the study. To validate the performance of AKF based tightly-coupled INS/GPS integration scheme with odometer and NHC, field scenarios were conducted in the downtown area of Tainan city. The data fusion of INS/GPS/Odometer/NHC can be used as stand-alone positioning tool during GPS outages of over 1 minute, and AKF based tightly-coupled INS/GPS integration scheme can be more stable combined with odometer and NHC during GPS outages of over 1 minute likewise.
Highlights
Global Positioning System (GPS) receivers require direct line of sight signals to the GPS satellite to provide navigation solutions with long-term stability; it is capable of providing continuous navigation solutions with uninterrupted signal reception
To validate the performance of proposed algorithm, the field scenario of the land vehicle was conducted in the downtown area of Tainan
The geodetic GPS receiver with double frequency board and the low-cost GPS receiver with single frequency board were applied in the field scenario
Summary
Global Positioning System (GPS) receivers require direct line of sight signals to the GPS satellite to provide navigation solutions with long-term stability; it is capable of providing continuous navigation solutions with uninterrupted signal reception. GPS leaves two scenarios to be considered in the land environment. The first one is intermittent signal reception, as for instance in heavily forested areas or in urban canyons. The other one is no signal reception at all, as for instance in buildings, tunnel or underground. GPS has to be integrated with other sensors to bridge periods of no signal reception. GPS has to be replaced by another navigation system that can provide continuous navigation solutions in above environments during no GPS signal reception
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
