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

1. 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

2. Indoor Navigation with MEMS sensors

Author

M. Dobler, G. Lammel, Johannes Gutmann, and L. Marti

Subjects

Barometric Pressure Sensor, Chemistry(all), business.industry, Computer science, Real-time computing, Wind triangle, General Medicine, Mems sensors, Accelerometer, Pressure sensor, Dead reckoning, Chemical Engineering(all), Global Positioning System, Step count, Indoor Pedestrian Navigation, Step Counter, Altimeter, Location-based Services, business, Floor Detection, Remote sensing

Abstract

Accurate positioning becomes extremely important for modern application like indoor navigation and location-based services. Standalone GPS cannot meet this accuracy. In this paper a method to couple GPS and a high resolution MEMS pressure sensor is presented to improve vertical as well as horizontal (in urban canyon environment) positioning. Further, a step counter based on an accelerometer is improved with an altimeter for stair detection and automatic step length adaptation for dead reckoning inside buildings. Finally, a stand-alone system accurately tracks floor levels inside buildings, using only a pressure sensor.

Published

2009

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