Abstract
The specific objective of this study is to propose a low-cost indoor navigation framework with nonbasic equipment by combining inertial sensors and indoor map messages. The proposed pedestrian navigation framework consists of a lower filter and an upper filter. In the lower filter which is designed based on the Kalman filter, the adaptive zero velocity detection algorithm is used to detect the zero velocity interval at different motion speeds, and then, zero velocity update is applied to rectify the inertial navigation solutions’ errors. In the upper filter which is designed based on the nonrecursive Bayesian filter, the map matching method with nonrecursive Bayesian filter is adopted to fuse the map prior information and the lower filter estimation results to correct the errors of navigation. The position estimation presented in this study achieves an average position error of 0.53 m compared to the ZUPT-aided inertial navigation system (INS) method under different motion states. The proposed pedestrian navigation algorithm achieves an average position error of 0.54 m as compared to the ZUPT-aided INS method among the different tested distances. The proposed framework simplifies the indoor positioning system under multiple motion speed conditions by ensuring the accuracy and stability property. The effectiveness and accuracy of the proposed framework are experimentally verified in various real-world scenarios.
Highlights
In outdoor positioning systems, the preferred method for localization is the Global Positioning System (GPS) [1, 2]
The map matching method is used to improve the heading for the navigation solution from the zero velocity update (ZUPT)-aided inertial navigation system (INS)
This study proposes a completely noninfrastructure-based and low-cost indoor navigation system that is both cheaper and faster than existing methods
Summary
The preferred method for localization is the Global Positioning System (GPS) [1, 2]. The GPS is the most widely used positioning technology in the world, with the advantages of high accuracy, stability, reliability, and continuous provision of output 3D position. The main disadvantage of the GPS is that it almost loses its positioning function in areas where the satellite signal strength will be weakened in obscured environments such as urban buildings, mountains, forests, or underground buildings. The use of the GPS equipment for positioning is usually effective exclusively in outdoor environments. Studies have shown that over 80% of the human life will be spent indoors, so indoor positioning technology has great research value when the GPS is not available
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
