Your search keyword '"Indoor Pedestrian Navigation"' showing total 3 results

1. Online cubature Kalman filter Rauch–Tung–Striebel smoothing for indoor inertial navigation system/ultrawideband integrated pedestrian navigation.

Author

Xu, Yuan and Chen, Xiyuan

Abstract

Accurate position information of the pedestrians is required in many applications such as healthcare, entertainment industries, and military field. In this work, an online Cubature Kalman filter Rauch–Tung–Striebel smoothing algorithm for people’s location in indoor environment is proposed using inertial navigation system techniques with ultrawideband technology. In this algorithm, Cubature Kalman filter is employed to improve the filtering output accuracy; then, the Rauch–Tung–Striebel smoothing is used between the ultrawideband measurements updates; finally, the average value of the corrected inertial navigation system error estimation is output to compensate the inertial navigation system position error. Moreover, a real indoor test has been done for assessing the performance of the proposed model and algorithm. Test results show that the proposed model is able to reduce the sum of the absolute position error between the east direction and the north direction by about 32% compared with only the ultrawideband model, and the performance of the online Cubature Kalman filter Rauch–Tung–Striebel smoothing algorithm is slightly better than the off-line mode. [ABSTRACT FROM AUTHOR]

Published

2018

2. Two-mode navigation method for low-cost inertial measurement unit-based indoor pedestrian navigation.

Author

Xu, Yuan, Chen, Xiyuan, and Wang, Yimin

Subjects

*INERTIAL navigation systems, *DEAD reckoning (Navigation), *GLOBAL Positioning System, *DATA fusion (Statistics), *PERFORMANCE evaluation

Abstract

The traditional inertial navigation system-based indoor pedestrian navigation method is not suitable to all the conditions, since its data fusion model is designed only for a single condition. In order to achieve better performance, a two-mode navigation method for indoor pedestrian navigation is proposed in this work, which includes the stance mode and the swing mode. When the person’s foot is in a stance phase, the stance mode is used to correct the velocity error and yaw error. When the person’s foot is in a swing phase, the swing mode works and only the yaw error is able to be corrected. For verification, a real indoor test has been done to assess the performance of the proposed two-mode method. The position root-mean-square error (RMSE) value is 1.9265 m during a 176-m traverse, and the RMSE of yaw is 0.20734 rad. These results demonstrate that our method is effective to reduce the error compared with the conventional schemes. [ABSTRACT FROM AUTHOR]

Published

2016

3. PDR/INS/WiFi Integration Based on Handheld Devices for Indoor Pedestrian Navigation

Author

You Li, Haiyu Lan, Naser El-Sheimy, and Yuan Zhuang

Subjects

Microelectromechanical systems, pseudo-velocity update, Computer science, Mechanical Engineering, lcsh:Mechanical engineering and machinery, Real-time computing, indoor pedestrian navigation, motion constraints, smartphone, Control and Systems Engineering, Inertial measurement unit, GNSS applications, Dead reckoning, TJ1-1570, PDR/INS integration, Satellite, lcsh:TJ1-1570, Mechanical engineering and machinery, Electrical and Electronic Engineering, Trilateration, Mobile device, PDR/INS/WiFi integration, Inertial navigation system, Simulation

Abstract

Providing an accurate and practical navigation solution anywhere with portable devices, such as smartphones, is still a challenge, especially in environments where global navigation satellite systems (GNSS) signals are not available or are degraded. This paper proposes a new algorithm that integrates inertial navigation system (INS) and pedestrian dead reckoning (PDR) to combine the advantages of both mechanizations for micro-electro-mechanical systems (MEMS) sensors in pedestrian navigation applications. In this PDR/INS integration algorithm, a pseudo-velocity-vector, which is composed of the PDR-derived forward speed and zero lateral and vertical speeds from non-holonomic constraints (NHC), works as an update for the INS to limit the velocity errors. To further limit the drift of MEMS inertial sensors, trilateration-based WiFi positions with small variances are also selected as updates for the PDR/INS integrated system. The experiments illustrate that positioning error is decreased by 60%–75% by using the proposed PDR/INS integrated MEMS solution when compared with PDR. The positioning error is further decreased by 15%–55% if the proposed PDR/INS/WiFi integrated solution is implemented. The average accuracy of the proposed PDR/INS/WiFi integration algorithm achieves 4.5 m in indoor environments.

Published

2015