Your search keyword '"Indoor Pedestrian Navigation"' showing total 16 results

1. ZUPT-Aided INS Bypassing Stance Phase Detection by Using Foot-Instability-Based Adaptive Covariance.

Author

Jao, Chi-Shih and Shkel, Andrei M.

Abstract

In this paper, we propose a Foot-Instability-Based Adaptive (FIBA) covariance to dynamically adjust the covariance matrix for the pseudo-zero-velocity measurements in the Zero velocity UPdaTe (ZUPT)-aided Inertial Navigation Systems (INS). The proposed ZUPT-aided INS using the FIBA covariance is implemented in an Extended Kalman Filter (EKF) framework, which utilizes a time-varying measurement covariance matrix that is updated in each iteration according to the FIBA covariance. The FIBA covariance is designed to have a very high value during the swing phases in a gait cycle, and the value significantly decreases during the stance phases. As a result, the proposed method eliminates a need to use a binary stance phase detector in implementation of the ZUPT-aided INS. Properties of EKF innovation sequences in the algorithm were studied, and two series of indoor pedestrian navigation experiments were conducted to demonstrate the navigation performance of the proposed system. In the first series of experiments, which included cases of walking and running, localization solutions produced by the system using the FIBA covariance demonstrated 36% and 64% improvements in navigation accuracy along the horizontal and vertical directions, respectively. In the second series of experiments, which included a pedestrian walking on different indoor terrains, such as flat planes, stairs, and ramps, the navigation accuracy of the system using the FIBA covariance reduced horizontal and vertical position errors by 12% and 45%, respectively, as compared to the conventional ZUPT-aided INS. [ABSTRACT FROM AUTHOR]

Published

2021

2. A New Quaternion Kalman Filter Based Foot-Mounted IMU and UWB Tightly-Coupled Method for Indoor Pedestrian Navigation.

Author

Wen, Kai, Yu, Kegen, Li, Yingbing, Zhang, Shubi, and Zhang, Wanwei

Subjects

*KALMAN filtering, *QUATERNIONS, *INERTIAL navigation systems, *MICROELECTROMECHANICAL systems

Abstract

In the field of indoor pedestrian navigation (IPN), the orientation information of a pedestrian is often obtained by means of strap-down inertial navigation system (SINS). To deal with the problem of divergence in SINS based orientation estimates, additional orientation sensors, such as a camera, are needed to provide external orientation observations, resulting in increased cost and complexity of system. Although a low-cost magnetometer (or compass) can be used, it is significantly affected by geomagnetic disturbances indoors. Besides, the magnetometer can only give the heading observation which is insufficient to correct orientation errors in all three directions. In this paper, we propose a novel IPN method based on shoe-mounted micro-electro-mechanical systems inertial measurement unit and ultra-wideband. The biggest advantage of this method is able to obtain high-precision position and orientation estimates at low cost. In addition, in the proposed method, the data fusion is implemented by a quaternion Kalman filter which does not involve any complex linearization and hence the system complexity is reduced. Experimental results show that a decimeter level position accuracy is achieved and the orientation drifts can be limited to 0.066 radians in indoor environments. [ABSTRACT FROM AUTHOR]

Published

2020

3. Indoor Map Aiding/Map Matching Smartphone Navigation Using Auxiliary Particle Filter

Author

Yu, Chunyang, Lan, Haiyu, Liu, Zhenbo, El-Sheimy, Naser, Yu, Fei, Sun, Jiadong, editor, Liu, Jingnan, editor, Fan, Shiwei, editor, and Wang, Feixue, editor

Published

2016

4. Indoor Pedestrian Navigation with Shoe-Mounted Inertial Sensors

Author

Zheng, Xianchao, Yang, Hui, Tang, Weiwei, Pu, Shuxiang, Zheng, Lingxiang, Zheng, Huiru, Liao, Bruce, Wang, Jolly, Park, James J. (Jong Hyuk), editor, Chen, Shu-Ching, editor, Gil, Joon-Min, editor, and Yen, Neil Y., editor

Published

2014

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

Author

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

Subjects

PDR/INS/WiFi integration, PDR/INS integration, pseudo-velocity update, indoor pedestrian navigation, smartphone, motion constraints, Mechanical engineering and machinery, TJ1-1570

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

6. 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

7. Map-Based Indoor Pedestrian Navigation Using an Auxiliary Particle Filter.

Author

Chunyang Yu, El-Sheimy, Naser, Haiyu Lan, and Zhenbo Liu

Subjects

MICROELECTROMECHANICAL systems, KALMAN filtering

Abstract

In this research, a non-infrastructure-based and low-cost indoor navigation method is proposed through the integration of smartphone built-in microelectromechanical systems (MEMS) sensors and indoor map information using an auxiliary particle filter (APF). A cascade structure Kalman particle filter algorithm is designed to reduce the computational burden and improve the estimation speed of the APF by decreasing its update frequency and the number of particles used in this research. In the lower filter (Kalman filter), zero velocity update and non-holonomic constraints are used to correct the error of the inertial navigation-derived solutions. The innovation of the design lies in the combination of upper filter (particle filter) map-matching and map-aiding methods to further constrain the navigation solutions. This proposed navigation method simplifies indoor positioning and makes it accessible to individual and group users, while guaranteeing the system's accuracy. The availability and accuracy of the proposed algorithm are tested and validated through experiments in various practical scenarios. [ABSTRACT FROM AUTHOR]

Published

2017

8. An improved inertial/wifi/magnetic fusion structure for indoor navigation.

Author

Li, You, Zhuang, Yuan, Zhang, Peng, Lan, Haiyu, Niu, Xiaoji, and El-Sheimy, Naser

Subjects

*WIRELESS Internet, *DEAD reckoning (Navigation), *QUALITY control, *STANDARD deviations, *SMARTPHONES

Abstract

This paper proposes a dead-reckoning (DR)/WiFi fingerprinting/magnetic matching (MM) integration structure that uses off-the-shelf sensors in consumer portable devices and existing WiFi infrastructures. One key improvement of this structure over previous DR/WiFi/MM fusion structures is the introduction of a three-level quality-control (QC) mechanism based on the interaction between different techniques. On QC Level #1, several criteria are applied to filter out blunders or unreliable measurements in each separate technology. Then, on Level #2, a threshold-based approach is used to set the weight of WiFi results automatically through the investigation of the EKF innovation sequence. Finally, on Level #3, DR/WiFi results are utilized to limit the MM search space and in turn reduce both mismatch rate and computational load. The proposed structure reduced the root mean square (RMS) of position errors in the range of 13.3 to 55.2% in walking experiments with two smartphones, under four motion conditions, and in two indoor environments. Furthermore, the proposed structure reduced the rate of mismatches (i.e., matching to an incorrect point that is geographically located over 15 m away from the true position) rate by over 75.0% when compared with previous DR/WiFi/MM integration structures. [ABSTRACT FROM AUTHOR]

Published

2017

9. 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

10. Pedestrian Simultaneous Localization and Mapping in Multistory Buildings Using Inertial Sensors.

Author

Garcia Puyol, Maria, Bobkov, Dmytro, Robertson, Patrick, and Jost, Thomas

Abstract

Pedestrian navigation is an important ingredient for efficient multimodal transportation, such as guidance within large transportation infrastructures. A requirement is accurate positioning of people in indoor multistory environments. To achieve this, maps of the environment play a very important role. FootSLAM is an algorithm based on the simultaneous localization and mapping (SLAM) principle that relies on human odometry, i.e., measurements of a pedestrian's steps, to build probabilistic maps of human motion for such environments and can be applied using crowdsourcing. In this paper, we extend FootSLAM to multistory buildings following a Bayesian derivation. Our approach employs a particle filter and partitions the map space into a grid of adjacent hexagonal prisms with eight faces. We model the vertical component of the odometry errors using an autoregressive integrated moving average (ARIMA) model and extend the geographic tree-based data structure that efficiently stores the probabilistic map, allowing real-time processing. We present the multistory FootSLAM maps that were created from three data sets collected in different buildings (one large office building and two university buildings). Hereby, the user was only carrying a single foot-mounted inertial measurement unit (IMU). We believe the resulting maps to be strong evidence of the robustness of FootSLAM. This paper raises the future possibility of crowdsourced indoor mapping and accurate navigation using other forms of human odometry, e.g., obtained with the low-cost and nonintrusive sensors of a handheld smartphone. [ABSTRACT FROM PUBLISHER]

Published

2014

11. Indoor Navigation with MEMS sensors.

Author

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

Subjects

PRESSURE transducers, MICROELECTROMECHANICAL systems, ACCELEROMETERS, ATMOSPHERIC pressure, PHYSICS instruments

Abstract

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. [Copyright &y& Elsevier]

Published

2009

12. 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

13. 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

14. Map-Based Indoor Pedestrian Navigation Using an Auxiliary Particle Filter

Author

Naser El-Sheimy, Zhenbo Liu, Haiyu Lan, and Chunyang Yu

Subjects

Engineering, Inertial frame of reference, map aiding, lcsh:Mechanical engineering and machinery, indoor pedestrian navigation, 02 engineering and technology, Map matching, Simultaneous localization and mapping, 01 natural sciences, Article, Computer Science::Robotics, lcsh:TJ1-1570, Electrical and Electronic Engineering, Simulation, Auxiliary particle filter, auxiliary particle filter, business.industry, Mechanical Engineering, 010401 analytical chemistry, map information, MEMS sensors, map matching, cascade structure algorithm, Kalman filter, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Control and Systems Engineering, Cascade, Filter (video), 0210 nano-technology, Particle filter, business

Abstract

In this research, a non-infrastructure-based and low-cost indoor navigation method is proposed through the integration of smartphone built-in microelectromechanical systems (MEMS) sensors and indoor map information using an auxiliary particle filter (APF). A cascade structure Kalman particle filter algorithm is designed to reduce the computational burden and improve the estimation speed of the APF by decreasing its update frequency and the number of particles used in this research. In the lower filter (Kalman filter), zero velocity update and non-holonomic constraints are used to correct the error of the inertial navigation-derived solutions. The innovation of the design lies in the combination of upper filter (particle filter) map-matching and map-aiding methods to further constrain the navigation solutions. This proposed navigation method simplifies indoor positioning and makes it accessible to individual and group users, while guaranteeing the system's accuracy. The availability and accuracy of the proposed algorithm are tested and validated through experiments in various practical scenarios.

Published

2017

15. Simultaneous Localization and Mapping for Pedestrians using Distortions of the Local Magnetic Field Intensity in Large Indoor Environments

Author

Martin Frassl, Marek Doniec, Maria Garcia Puyol, Michael Angermann, Luigi Bruno, Mohammed Khider, Brian J. Julian, Patrick Robertson, and Michael Lichtenstern

Subjects

Ground truth, business.industry, Computer science, Simultaneous localization and mapping, Simultaneous Localization and Mapping, Magnetic field, Odometry, Factorization, Scalability, SLAM, FootSLAM, A priori and a posteriori, Computer vision, Artificial intelligence, Indoor Pedestrian Navigation, business, Particle filter, Magnetic Navigation

Abstract

We present a Simultaneous Localization and Mapping (SLAM) algorithm based on measurements of the ambient magnetic field strength (MagSLAM) that allows quasi-real-time mapping and localization in buildings, where pedestrians with foot-mounted sensors are the subjects to be localized. We assume two components to be present: firstly a source of odometry (human step measurements), and secondly a sensor of the local magnetic field intensity. Our implementation follows the FastSLAM factorization using a particle filter. We augment the hexagonal transition map used in the pre-existing FootSLAM algorithm with local maps of the magnetic field strength, binned in a hierarchical hexagonal structure. We performed extensive experiments in a number of different buildings and present the results for five data sets for which we have ground truth location information. We consider the results obtained using MagSLAM to be strong evidence that scalable and accurate localization is possible without an a priori map.

Published

2013

16. Map-Based Indoor Pedestrian Navigation Using an Auxiliary Particle Filter.

Author

Yu C, El-Sheimy N, Lan H, and Liu Z

Abstract

In this research, a non-infrastructure-based and low-cost indoor navigation method is proposed through the integration of smartphone built-in microelectromechanical systems (MEMS) sensors and indoor map information using an auxiliary particle filter (APF). A cascade structure Kalman particle filter algorithm is designed to reduce the computational burden and improve the estimation speed of the APF by decreasing its update frequency and the number of particles used in this research. In the lower filter (Kalman filter), zero velocity update and non-holonomic constraints are used to correct the error of the inertial navigation-derived solutions. The innovation of the design lies in the combination of upper filter (particle filter) map-matching and map-aiding methods to further constrain the navigation solutions. This proposed navigation method simplifies indoor positioning and makes it accessible to individual and group users, while guaranteeing the system's accuracy. The availability and accuracy of the proposed algorithm are tested and validated through experiments in various practical scenarios., Competing Interests: The authors declare no conflict of interest.

Published

2017