Open AccessUWB-based Indoor Navigation with Uncertain Anchor Nodes Positioning
Author(s) -
Gaël Pagès,
Jordi VilàValls
Publication year - 2019
Publication title -
proceedings of the satellite division's international technical meeting (online)/proceedings of the satellite division's international technical meeting (cd-rom)
Language(s) - English
Resource type - Conference proceedings
eISSN - 2331-5954
pISSN - 2331-5911
DOI - 10.33012/2019.17060
Subject(s) - gnss applications , computer science , position (finance) , trajectory , key (lock) , ranging , satellite navigation , satellite system , real time computing , global positioning system , wideband , simulation , engineering , electronic engineering , telecommunications , computer security , physics , finance , astronomy , economics
Global Navigation Satellite Systems (GNSS) is the positioning technology of choice outdoors, but its performance clearly degrades in harsh propagation conditions, or even more critical for the applications of interest here, these systems are not available in GNSS-denied environments such as indoors. Among the different alternatives for autonomous indoor localization and navigation, Ultra-WideBand ranging is a promising solution to achieve high positioning accuracy. The key points impacting such performance are i) anchors' geometry, and ii) a perfectly known anchors' position. In this contribution, we provide an analysis on the navigation performance loss induced by a possible anchor's position mismatch, and propose a method to estimate both the mobile trajectory (position and velocity) and the uncertain anchor's position. A numerical simulation study is given to support the discussion.
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