Integration of GNSS-receivers with dual foot-mounted INS in urban and indoor environments

In safety-critical applications, including firefighter and law enforcement operations, infrastructure-free localization systems are typically required. These systems must provide accurate localization in all scenarios. Seamless indoor and outdoor localization and navigation, including in dense urban...

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Bibliographic Details
Main Authors: Rantakokko, Jouni, Nygards, Jonas, Stromback, Peter, Andersson, Peter, Nilsson, John-Olof, Handel, Peter
Format: Conference Proceeding
Language:English
Subjects:
Algorithms
Dead reckoning
Foot-mounted INS
GNSS
Indoor environments
Inertial navigation
Infrastructure-free localization
Localization
Navigation
outdoor-indoor transitions
Position (location)
Position measurement
Robustness
Sensor fusion
Sensors
Strategy
Uncertainty
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Summary:In safety-critical applications, including firefighter and law enforcement operations, infrastructure-free localization systems are typically required. These systems must provide accurate localization in all scenarios. Seamless indoor and outdoor localization and navigation, including in dense urban environments, are needed. Multi-sensor fusion algorithms constitute an integral part in all state-of-the-art indoor positioning systems. GNSS-receivers typically provide poor estimates of their own position uncertainty in dense urban and indoor environments, where significant position errors can be expected, which makes the design of a robust sensor fusion algorithm a challenge. Sensor fusion strategies for integration of a GNSS-receiver with foot-mounted inertial navigation systems (INS) are described and evaluated in this work. For a loosely coupled integration strategy, we suggest to use a cut-off criteria that governs when to discard the GNSS-positions and demonstrate that it can improve the position and heading accuracy in outdoor/indoor transition regions. Similarly, for a tightly coupled integration strategy, we suggest an approach with heavy-tailed measurement noise and demonstrate its capability to suppress inconsistent data and improve performance in the same regions.
ISSN:2153-3598
DOI:10.1109/PLANS.2016.7479750