Abstract
This paper proposes a scheme for indoor positioning by fusing floor map, WiFi and smartphone sensor data to provide meter-level positioning without additional infrastructure. A topology-constrained K nearest neighbor (KNN) algorithm based on a floor map layout provides the coordinates required to integrate WiFi data with pseudo-odometry (P-O) measurements simulated using a pedestrian dead reckoning (PDR) approach. One method of further improving the positioning accuracy is to use a more effective multi-threshold step detection algorithm, as proposed by the authors. The “go and back” phenomenon caused by incorrect matching of the reference points (RPs) of a WiFi algorithm is eliminated using an adaptive fading-factor-based extended Kalman filter (EKF), taking WiFi positioning coordinates, P-O measurements and fused heading angles as observations. The “cross-wall” problem is solved based on the development of a floor-map-aided particle filter algorithm by weighting the particles, thereby also eliminating the gross-error effects originating from WiFi or P-O measurements. The performance observed in a field experiment performed on the fourth floor of the School of Environmental Science and Spatial Informatics (SESSI) building on the China University of Mining and Technology (CUMT) campus confirms that the proposed scheme can reliably achieve meter-level positioning.
Highlights
Indoor navigation has become an essential technique that can be applied in a number of settings, such as in a supermarket as a shopping guide, for a fire emergency service for navigation, or for a hospital patient for tracking
An electromyography (EMG) method was presented and compared with a traditional method based on accelerometers in several field tests, and the results demonstrated that the EMG-based method was effective and that its performance in combination with a pedestrian dead reckoning (PDR) algorithm can be comparable to that of accelerometer-based methods [24,25]
This paper investigated several positioning algorithms for indoor navigation systems
Summary
Indoor navigation has become an essential technique that can be applied in a number of settings, such as in a supermarket as a shopping guide, for a fire emergency service for navigation, or for a hospital patient for tracking. Some techniques that have been successfully used that are similar to the Global Navigation Satellite System (GNSS) [1,2,3] are not suitable for indoor navigation. Real-time indoor positioning using existing techniques remains a challenge, and this is a bottleneck in the development of indoor location-based services (LBSs) [4]. The solution for indoor positioning is increasingly regarded as being based on the integration of multiple technologies, e.g., WiFi, ZigBee, inertial navigation systems (INSs), and laser scanning systems (LSSs). Pahlavan and Li reviewed the technical aspects of the existing technologies for wireless indoor location systems [5]. There are two main hardware layouts that can be used in an indoor situation:
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