Abstract
Modern indoor positioning system services are important technologies that play vital roles in modern life, providing many services such as recruiting emergency healthcare providers and for security purposes. Several large companies, such as Microsoft, Apple, Nokia, and Google, have researched location-based services. Wireless indoor localization is key for pervasive computing applications and network optimization. Different approaches have been developed for this technique using WiFi signals. WiFi fingerprinting-based indoor localization has been widely used due to its simplicity, and algorithms that fingerprint WiFi signals at separate locations can achieve accuracy within a few meters. However, a major drawback of WiFi fingerprinting is the variance in received signal strength (RSS), as it fluctuates with time and changing environment. As the signal changes, so does the fingerprint database, which can change the distribution of the RSS (multimodal distribution). Thus, in this paper, we propose that symmetrical Hölder divergence, which is a statistical model of entropy that encapsulates both the skew Bhattacharyya divergence and Cauchy–Schwarz divergence that are closed-form formulas that can be used to measure the statistical dissimilarities between the same exponential family for the signals that have multivariate distributions. The Hölder divergence is asymmetric, so we used both left-sided and right-sided data so the centroid can be symmetrized to obtain the minimizer of the proposed algorithm. The experimental results showed that the symmetrized Hölder divergence consistently outperformed the traditional k nearest neighbor and probability neural network. In addition, with the proposed algorithm, the position error accuracy was about 1 m in buildings.
Highlights
The global positioning system (GPS) is the world’s most utilized location system, but it cannot be used to accurately identify indoor locations due to the lack of line-of-sight between GPS receivers and satellites
indoor positioning systems (IPSs) incorporate the power of GPS and indoor mapping and have many potential applications that make them very important in modern life
Cluster methods can be used to reduce the impact of time variation by clustering the fingerprinting radio map into multiple partitions and choosing the cluster that has the lowest distance error
Summary
The global positioning system (GPS) is the world’s most utilized location system, but it cannot be used to accurately identify indoor locations due to the lack of line-of-sight between GPS receivers and satellites. Many technologies have been used instead of GPS, such as radiofrequency identification, Bluetooth, magnetic field variations, ultrasound, light-emitting diode light bulbs, ZigBee, and WiFi signals, to create high-accuracy indoor localization-based systems These technologies are considered from a cost perspective. Lateration methods calculate the absolute or relative position of an object by measuring distances from multiple reference points using geometry information such as angle of arrival, time of arrival, and time difference of arrival from the signals of APs. lateration-based techniques suffer from inaccurate location estimation; for example, it was reported in Reference [6] that the average localization distance error is 24.73 ft with a width of 80 ft and a length of 200 ft in a typical office scenario. The symmetrized k-means-Bregman can be geometrically interpreted as a unique intersection of the linking between the two-sided centroid and the mixed-type bisector, and that generalized the two-sided centroid for a symmetrized k-means-Bregman
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