Receiver Autonomous Integrity Monitoring of GNSS Signals for Electronic Toll Collection

Salos, Daniel; Martineau, Anaïs; Macabiau, Christophe; Bonhoure, Bernard; Kubrak, Damien

doi:10.1109/tits.2013.2273829

Cited by 33 publications

(37 citation statements)

References 11 publications

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“…In addition to traffic monitoring, toll collection is also adopting GPS technology and benefits from GPS data. A notable example is the Toll Collect Project, which has operated in Germany since 2005 [7], [8]. Using GPS to identify when a vehicle is on a tolled road, this system outperforms traditional toll gates in terms of wide-area coverage and flexible toll fee calculation [9].…”

Section: Introductionmentioning

confidence: 99%

GPS Signal Authentication From Cooperative Peers

Heng

Work

Gao

2015

IEEE Trans. Intell. Transport. Syst.

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Section: Introductionmentioning

confidence: 99%

GPS Signal Authentication From Cooperative Peers

Heng

Work

Gao

2015

IEEE Trans. Intell. Transport. Syst.

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“…5. Finally, utilizing the estimated fault mode and overall state vector, we formulate the failure slope for the Graph-SLAM framework and subsequently, compute the protection levels using worst-case failure mode slope analysis [15,16]. The proposed SLAM-based IM algorithm using GPS and fish-eye camera consists of three main modules, namely measurement pre-processing, extended graph optimization and IM for Graph-SLAM.…”

Section: Slam-based Im Using Gps and Fish-eye Cameramentioning

confidence: 99%

“…where k denotes the number of redundant measurements, i.e., difference between the number of overall measurements, denoted by n and overall states, denoted by l, such that k = n − l. λ indicates the non-centrality parameter associated with the overall test statistic during faulty conditions. According to the worst-case failure mode slope analysis [15], as seen in Fig. 4, the protection level is calculated as the projection in the position domain of the measurement faults that would generate a non-centrality parameter λ = λ th in the overall test statistic ζ with the maximum slope.…”

Section: Gps Faultsmentioning

confidence: 99%

“…In particular, the non-centrality parameter λ th is estimated from the false-alarm, denoted by p F A and mis-detection rates, denoted by p M D , which are set according to the pre-defined integrity requirements. Figure 4: Protection levels computed as the intersection of worst-case failure mode slope and non-centrality parameter [15].…”

Section: Gps Faultsmentioning

confidence: 99%

“…We propose SLAM-based IM algorithm using GPS and fish-eye camera to compute the error bounds, termed as protection levels, of the estimated navigation solution by applying worst-case failure slope analysis [15,16] to the Graph-SLAM framework. In this work, we consider global landmarks as the GPS satellites and additional local landmarks as the key image pixels in the world frame.…”

Section: Introductionmentioning

confidence: 99%

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SLAM-based Integrity Monitoring Using GPS and Fish-eye Camera

Bhamidipati¹,

Gao²

2019

Proceedings of the 32nd International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS+ 201

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Urban navigation using GPS and fish-eye camera suffers from multipath effects in GPS measurements and data association errors in pixel intensities across image frames. We propose a Simultaneous Localization and Mapping (SLAM)-based Integrity Monitoring (IM) algorithm to compute the position protection levels while accounting for multiple faults in both GPS and vision. We perform graph optimization using the sequential data of GPS pseudoranges, pixel intensities, vehicle dynamics and satellite ephemeris to simultaneously localize the vehicle as well as the landmarks, namely GPS satellites and key image pixels in the world frame. We estimate the fault mode vector by analyzing the temporal correlation across the GPS measurement residuals and spatial correlation across the vision intensity residuals. In particular, to detect and isolate the vision faults, we developed a superpixel-based piecewise Random Sample Consensus (RANSAC) technique to perform spatial voting across image pixels. For an estimated fault mode, we compute the protection levels by applying worst-case failure slope analysis to the linearized Graph-SLAM framework.We perform ground vehicle experiments in the semi-urban area of Champaign, IL and have demonstrated the successful detection and isolation of multiple faults. We also validate tighter protection levels and lower localization errors achieved via the proposed algorithm as compared to SLAM-based IM that utilizes only GPS measurements.

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Integrity monitoring of Graph‐SLAM using GPS and fish‐eye camera

Bhamidipati

Gao

2020

Navigation

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We propose a Simultaneous Localization and Mapping (SLAM)‐based Integrity Monitoring (IM) algorithm using GPS and fish‐eye camera to compute the protection levels while accounting for multiple faults in GPS and vision. We perform graph optimization using GPS pseudoranges, pixel intensities, vehicle dynamics, and satellite ephemeris to simultaneously localize the vehicle, GPS satellites, and key image pixels in the world frame. We estimate the fault mode vector by analyzing the temporal correlation across pseudorange residuals and spatial correlation across pixel intensity residuals. To isolate the vision faults, we develop a superpixel‐based piecewise random sample consensus. For the estimated fault mode, we compute the protection levels by performing worst‐case failure slope analysis on the batch realization of linearized Graph‐SLAM formulation. We perform real‐world experiments in an alleyway in Stanford, California and a semi‐urban area in Champaign, Illinois. We demonstrate higher localization accuracy and tighter protection levels as compared to GPS‐only SLAM‐based IM.

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Receiver Autonomous Integrity Monitoring of GNSS Signals for Electronic Toll Collection

Cited by 33 publications

References 11 publications

GPS Signal Authentication From Cooperative Peers

GPS Signal Authentication From Cooperative Peers

SLAM-based Integrity Monitoring Using GPS and Fish-eye Camera

Integrity monitoring of Graph‐SLAM using GPS and fish‐eye camera

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