Abstract
A quickly growing location-based services area has led to increased demand for indoor positioning and localization. Undoubtedly, Wi-Fi fingerprint-based localization is one of the promising indoor localization techniques, yet the variation of received signal strength is a major problem for accurate localization. Magnetic field-based localization has emerged as a new player and proved a potential indoor localization technology. However, one of its major limitations is degradation in localization accuracy when various smartphones are used. The localization performance is different from various smartphones even with the same localization technique. This research leverages the use of a deep neural network-based ensemble classifier to perform indoor localization with heterogeneous devices. The chief aim is to devise an approach that can achieve a similar localization accuracy using various smartphones. Features extracted from magnetic data of Galaxy S8 are fed into neural networks (NNs) for training. The experiments are performed with Galaxy S8, LG G6, LG G7, and Galaxy A8 smartphones to investigate the impact of device dependence on localization accuracy. Results demonstrate that NNs can play a significant role in mitigating the impact of device heterogeneity and increasing indoor localization accuracy. The proposed approach is able to achieve a localization accuracy of 2.64 m at 50% on four different devices. The mean error is 2.23 m, 2.52 m, 2.59 m, and 2.78 m for Galaxy S8, LG G6, LG G7, and Galaxy A8, respectively. Experiments on a publicly available magnetic dataset of Sony Xperia M2 using the proposed approach show a mean error of 2.84 m with a standard deviation of 2.24 m, while the error at 50% is 2.33 m. Furthermore, the impact of devices on various attitudes on the localization accuracy is investigated.
Highlights
Indoor localization has become one of the potential research areas in the last decade
This study presents the use of deep neural networks (NN) to perform magnetic field-based indoor localization using heterogeneous devices
Wi-Fi based indoor positioning systems are unable to meet the requirements of fast-paced location-based services due to intrinsic limitations and dynamic environmental factors
Summary
Indoor localization has become one of the potential research areas in the last decade. The inception and penetration of location-based services (LBS) further accelerated the research in the field of indoor localization. The global positioning system (GPS) can achieve localization accuracy ranging from 17 m to better than a few meters [2]. This accuracy depends upon many factors including the number and geometry of collected observations, mode, and type of observation, measurement model, level of used biases, design of GPS receiver, and receiving land structure like obstacles or no obstacles [2,3]. The GPS is used for outdoor positioning, yet its sensitivity to occlusions including ceilings and walls makes it inappropriate and inefficient for indoor localization.
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