CBWF: A Lightweight Circular Boundary based WiFi Fingerprinting Localization System
As a promising indoor localization technology, WiFi fingerprint-based localization encounters many issues that need to be addressed urgently, such as high-overhead fingerprint map construction, device heterogeneity among either mobile devices or access points (APs), etc. In this paper, we present CB...
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| Veröffentlicht in: | IEEE internet of things journal 2024-04, Vol.11 (7), p.1-1 |
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| creator | Tao, Ye Huang, Baoqi Yan, Rong'en Zhao, Long Wang, Wei |
| description | As a promising indoor localization technology, WiFi fingerprint-based localization encounters many issues that need to be addressed urgently, such as high-overhead fingerprint map construction, device heterogeneity among either mobile devices or access points (APs), etc. In this paper, we present CBWF: a lightweight circular boundary based WiFi Fingerprinting localization system that is able to provide low-overhead, device calibration-free accurate indoor localization. CBWF achieves this by dividing a localization area into multiple sub-regions, and then leveraging the relation between the received signal strength (RSS) vectors from two different APs as fingerprints for localization. The key idea behind CBWF is that a superior division mechanism is attained to divide the localization area. Specifically, we propose the circle boundary mechanism to better approximate the real boundary of sub-regions, compared with the widely used linear boundary mechanism, and then sufficiently exploit the theoretical characteristics behind this novel mechanism. Extensive simulation and real-world experiments show that our lightweight system outperforms state-of-the-art approaches. Specifically, in a 40 m × 17 m real scenario with only 20 reference points (RPs) and 11 APs, CBWF achieves an average localization accuracy of 2.95 m and 4.15 m for two different mobile devices, respectively. Our codes are available at: https://github.com/dadadaray/circular-boundary. |
| doi_str_mv | 10.1109/JIOT.2023.3329825 |
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CBWF achieves this by dividing a localization area into multiple sub-regions, and then leveraging the relation between the received signal strength (RSS) vectors from two different APs as fingerprints for localization. The key idea behind CBWF is that a superior division mechanism is attained to divide the localization area. Specifically, we propose the circle boundary mechanism to better approximate the real boundary of sub-regions, compared with the widely used linear boundary mechanism, and then sufficiently exploit the theoretical characteristics behind this novel mechanism. Extensive simulation and real-world experiments show that our lightweight system outperforms state-of-the-art approaches. Specifically, in a 40 m × 17 m real scenario with only 20 reference points (RPs) and 11 APs, CBWF achieves an average localization accuracy of 2.95 m and 4.15 m for two different mobile devices, respectively. 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CBWF achieves this by dividing a localization area into multiple sub-regions, and then leveraging the relation between the received signal strength (RSS) vectors from two different APs as fingerprints for localization. The key idea behind CBWF is that a superior division mechanism is attained to divide the localization area. Specifically, we propose the circle boundary mechanism to better approximate the real boundary of sub-regions, compared with the widely used linear boundary mechanism, and then sufficiently exploit the theoretical characteristics behind this novel mechanism. Extensive simulation and real-world experiments show that our lightweight system outperforms state-of-the-art approaches. Specifically, in a 40 m × 17 m real scenario with only 20 reference points (RPs) and 11 APs, CBWF achieves an average localization accuracy of 2.95 m and 4.15 m for two different mobile devices, respectively. 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| subjects | Buildings circular boundary device calibration-free localization Electronic devices fingerprint Fingerprint recognition Fingerprinting Fingerprints Heterogeneity Indoor localization Internet of Things Lightweight Localization Location awareness low-overhead Mobile handsets Shape Signal strength Wireless fidelity |
| title | CBWF: A Lightweight Circular Boundary based WiFi Fingerprinting Localization System |
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