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Accurate Indoor Positioning Using Temporal–Spatial Constraints Based on Wi-Fi Fine Time Measurements

Wenhua Shao, Haiyong Luo, Fang Zhao, Hui Tian, Shuo Yan, Antonino Crivello

2020IEEE Internet of Things Journal50 citationsDOIOpen Access PDF

Abstract

The IEEE 802.11mc-2016 protocol enables certified devices to obtain precise ranging information using time-of-flight-based techniques. The ranging error increases in indoor environments due to the multipath effect. Traditional methods utilize only the ranging measurements of the current location, thus limiting the abilities to reduce the influence of multipath problems. This article introduces a robust positioning method that leverages the constraints of multiple positioning nodes at different positions. We transfer a sequence of temporal ranging measurements into multiple virtual positioning clients (VPCs) in the spatial domain by considering their spatial constraints. Defining an objective function and the spatial constraints of the VPCs as Karush-Kuhn-Tucker conditions, we solve the positioning estimation with nonconvex optimization. We propose an iterative weight estimation method for the time of flight ranging and the VPC to optimize the positioning model. An extensive experimental campaign demonstrates that our proposal can remarkably improve the positioning accuracy in complex indoor environments.

Topics & Concepts

RangingComputer scienceMultipath propagationReal-time computingMultipath mitigationPositioning systemChannel (broadcasting)TelecommunicationsPoint (geometry)MathematicsGeometryIndoor and Outdoor Localization TechnologiesTarget Tracking and Data Fusion in Sensor NetworksGNSS positioning and interference
Accurate Indoor Positioning Using Temporal–Spatial Constraints Based on Wi-Fi Fine Time Measurements | Litcius