Abstract
Indoor wireless local area network (WLAN) based positioning technologies have boomed recently because of the huge demands of indoor location-based services (ILBS) and the wide deployment of commercial Wi-Fi devices. Channel state information (CSI) extracted from Wi-Fi signals could be calibrated and utilized as a fine-grained positioning feature for indoor fingerprinting localization. One of the main factors that would restrict the positioning accuracy of fingerprinting systems is the spatial resolution of fingerprints (SRF). This paper mainly focuses on the improvement of SRF for indoor CSI-based positioning and a calibrated CSI feature (CCF) with high SRF is established based on the preprocess of both measured amplitude and phase. In addition, a similarity calculation metric for the proposed CCF is designed based on modified dynamic time warping (MDTW). An indoor fingerprinting method based on CCF and MDTW, named CC-DTW, is then proposed to improve the positioning accuracy in indoors. Experiments are conducted in two indoor office testbeds, and the performances of the proposed CC-DTW, one time-reversal (TR) based approach and one Euclidean distance (ED) based approach are evaluated and discussed. The results show that the SRF of CC-DTW outperforms the TR-based one and the ED-based one in both two testbeds in terms of the receiver operating characteristic (ROC) curve metric, and the area under curve (AUC) metric.
Highlights
With an increase in the demand for ubiquitous location-based services (LBS), localization and navigation applications have become more important in daily life [1]
The results show that the modified dynamic time warping (MDTW) metric has about 17.6% and 9.9% improvement of spatial resolution of fingerprints (SRF) in receiver operating characteristic (ROC) when compared with time reversal resonating strength (TRRS) metric and Euclidean distance (ED) metric in Test-bed 1, and has about 3.6% and 1.8% improvement in Test-bed 2, respectively
In the aspect of SRF improvement, we evaluated the performance of the proposed calibrated CSI feature (CCF) feature over Channel state information (CSI) amplitude and phase features, the performance of the proposed MDTW metric over TRRS
Summary
With an increase in the demand for ubiquitous location-based services (LBS), localization and navigation applications have become more important in daily life [1]. Considering the fact that people today spend more than 80% of their time in indoor environments [2], indoor location-based services have gained considerable attention recently, with a market value predicted to reach US $10 billion by. Widely used global navigation satellite systems (GNSS) could provide a relatively high positioning accuracy outdoors, it does not perform well indoors due to the coverage limitation of satellite signals. Various indoor positioning technologies have been proposed in order to enable high-accuracy localization in indoors over the past two decades, including infrared [4], ultrasonic [5], ultra-wideband (UWB) [6], pseudolite [7], acoustic signals [8], Wi-Fi [9,10], Bluetooth [11], etc.
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