Abstract
Pedestrian dead reckoning (PDR), enabled by smartphones’ embedded inertial sensors, is widely applied as a type of indoor positioning system (IPS). However, traditional PDR faces two challenges to improve its accuracy: lack of robustness for different PDR-related human activities and positioning error accumulation over elapsed time. To cope with these issues, we propose a novel adaptive human activity-aided PDR (HAA-PDR) IPS that consists of two main parts, human activity recognition (HAR) and PDR optimization. (1) For HAR, eight different locomotion-related activities are divided into two classes: steady-heading activities (ascending/descending stairs, stationary, normal walking, stationary stepping, and lateral walking) and non-steady-heading activities (door opening and turning). A hierarchical combination of a support vector machine (SVM) and decision tree (DT) is used to recognize steady-heading activities. An autoencoder-based deep neural network (DNN) and a heading range-based method to recognize door opening and turning, respectively. The overall HAR accuracy is over 98.44%. (2) For optimization methods, a process automatically sets the parameters of the PDR differently for different activities to enhance step counting and step length estimation. Furthermore, a method of trajectory optimization mitigates PDR error accumulation utilizing the non-steady-heading activities. We divided the trajectory into small segments and reconstructed it after targeted optimization of each segment. Our method does not use any a priori knowledge of the building layout, plan, or map. Finally, the mean positioning error of our HAA-PDR in a multilevel building is 1.79 m, which is a significant improvement in accuracy compared with a baseline state-of-the-art PDR system.
Highlights
The indoor positioning system (IPS) has been investigated for several decades for guiding pedestrians around complex buildings on multiple floors such as offices and shopping malls, mining tunnels, and subways, in emergency situations where first responders need to know immediately how to get to those in need when there is limited visibility due to smoke, mist, or having to wear a hazmat or firefighter mask
We proposed and demonstrated a new adaptive human activity-aided pedestrian dead reckoning (HAA-Pedestrian dead reckoning (PDR)) positioning system to improve the robustness and mitigate the error accumulation of traditional PDR systems
We proposed and demonstrated a novel autoencoder-based deep neural network and a heading range-based method to respectively recognize door opening and turning
Summary
The indoor positioning system (IPS) has been investigated for several decades for guiding pedestrians around complex buildings on multiple floors such as offices and shopping malls, mining tunnels, and subways, in emergency situations where first responders need to know immediately how to get to those in need when there is limited visibility due to smoke, mist, or having to wear a hazmat or firefighter mask. We postulate that human activities recognized by using smartphone sensor data can be used to improve the accuracy of PDR systems. After human activities are recognized, we can carry out certain optimization methods (e.g., trajectory optimization) to improve the PDR system’s positioning accuracy. Steady-heading activities are used to optimize the parameters in the methods of step counting and step length estimation, optimize the parameters in the methods of step counting and step length estimation, respectively, to improve the robustness of PDR PDR error accumulation by method of trajectory optimization proposed toismitigate error accumulation utilizing non-steady-heading activities.
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