Implementation of Parallel Cascade Identification at Various Phases for Integrated Navigation System

Global navigation satellite systems (GNSS) are widely used for the navigation of land vehicles. However, the positioning accuracy of GNSS, such as the global positioning system (GPS), deteriorates in urban areas due to signal blockage and multipath effects. GNSS can be integrated with a micro-electr...

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Bibliographic Details
Published inFuture internet Vol. 13; no. 8; p. 191
Main Authors Iqbal, Umar, Abosekeen, Ashraf, Georgy, Jacques, Umar, Areejah, Noureldin, Aboelmagd, Korenberg, Michael J.
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2021
Subjects
Accelerometers
Accuracy
Algorithms
Azimuth
Global navigation satellite system
GNSS
Identification
Inertial navigation
Inertial sensing devices
inertial sensors
Internet
Kalman filter
Kalman filters
land vehicle navigation
Maximum likelihood method
Microelectromechanical systems
Modelling
Navigation satellites
Navigation systems
Noise levels
parallel cascade identification
Parameter estimation
Satellites
Sensors
System identification
Two dimensional models
Unmanned aerial vehicles
Urban areas
Vehicles
Velocity
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Summary:Global navigation satellite systems (GNSS) are widely used for the navigation of land vehicles. However, the positioning accuracy of GNSS, such as the global positioning system (GPS), deteriorates in urban areas due to signal blockage and multipath effects. GNSS can be integrated with a micro-electro-mechanical system (MEMS)–based inertial navigation system (INS), such as a reduced inertial sensor system (RISS) using a Kalman filter (KF) to enhance the performance of the integrated navigation solution in GNSS challenging environments. The linearized KF cannot model the low-cost and small-size sensors due to relatively high noise levels and compound error characteristics. This paper reviews two approaches to employing parallel cascade identification (PCI), a non-linear system identification technique, augmented with KF to enhance the navigational solution. First, PCI models azimuth errors for a loosely coupled 2D RISS integrated system with GNSS to obtain a navigation solution. The experimental results demonstrated that PCI improved the integrated 2D RISS/GNSS performance by modeling linear, non-linear, and other residual azimuth errors. For the second scenario, PCI is utilized for modeling residual pseudorange correlated errors of a KF-based tightly coupled RISS/GNSS navigation solution. Experimental results have shown that PCI enhances the performance of the tightly coupled KF by modeling the non-linear pseudorange errors to provide an enhanced and more reliable solution. For the first algorithm, the results demonstrated that PCI can enhance the performance by 77% as compared to the KF solution during the GNSS outages. For the second algorithm, the performance improvement for the proposed PCI technique during the availability of three satellites was 39% compared to the KF solution.
ISSN:1999-5903
1999-5903
DOI:10.3390/fi13080191