Vehicle Localization Using Doppler Shift and Time of Arrival Measurements in a Tunnel Environment

Halili, Rreze; BniLam, Noori; Yusuf, Marwan; Tanghe, Emmeric; Joseph, Wout; Weyn, Maarten; Berkvens, Rafael

doi:10.3390/s22030847

Cited by 11 publications

(2 citation statements)

References 59 publications

(91 reference statements)

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“…Moreover, the authors observed a relationship between vehicle velocity and range and they explain it as a consequence of the Doppler effect. This can also be observed in [13]. The inverse case is, however, observed in [14], where the OD is greater than the ID; however, the authors explain that this is due to the time needed for the mechanism of signal validation in the Wi-Fi access points during a first connection.…”

Section: Anomaly Detectionmentioning

confidence: 94%

Road-Side Unit Anomaly Detection

Benzagouta,

Aniss,

Fouchal

et al. 2023

Vehicles

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Actors of the Cooperative Intelligent Transport Systems (C-ITS) generate various amounts of data. Useful information on various issues such as anomalies, failures, road profiles, etc., could be revealed from the analysis of these data. The analysis, could be managed by operators and vehicles, and its output could be very helpful for future decision making. In this study, we collected real data extracted from road operators. We analyzed these streams in order to verify whether abnormal behaviors could be observed in the data. Our main target was a very sensitive C-ITS failure, which is when a road-side unit (RSU) experiences transmission failure. The detection of such failure is to be achieved by end users (vehicles), which in turn would inform road operators which would then recover the failure. The data we analyzed were collected from various roads in Europe (France, Germany, and Italy) with the aim of studying the RSUs’ behavior. Our mechanism offers compelling results regarding the early detection of RSU failures. We also proposed a new C-ITS message dedicated to raise alerts to road operators when required.

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Section: Anomaly Detectionmentioning

confidence: 94%

Road-Side Unit Anomaly Detection

Benzagouta,

Aniss,

Fouchal

et al. 2023

Vehicles

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“…Subsequently, its neighbors can build a positioning table of the neighboring nodes [28]. The second approach depends on the physical parameters such as received signal strength (RSS) [29], angle of arrival (AoA) [30], and time of arrival (ToA) [31] in obtaining the jammer location. These RSS-based solutions achieve quite a low accuracy in estimating the jammer's position.…”

Section: B Localizationmentioning

confidence: 99%

An Efficient Localization and Avoidance Method of Jammers in Vehicular Ad Hoc Networks

et al. 2022

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Jamming is a terrifying attack that could harm 802.11p-based vehicular communications by occupying the communication channels by overwhelming the network with jamming packets, especially for self-driving cars, as it is essential to send/receive messages without any interruptions to control the vehicles remotely. In wireless vehicular ad hoc networks (VANET), the attacker's mission is more accessible due to the network's open nature, way of communication, and lack of security measures. Most of the existing studies have focused on jamming detection approaches. However, few of them have addressed the jammer localization challenge. Moreover, even in these limited studies, the solutions' assumptions, the proposed countermeasures, and their complexity were also missing. Therefore, this paper introduces a new approach to detecting, localizing, and avoiding jamming attacks in VANETs with high efficiency in terms of accuracy, implementation and complexity. The proposed approach uses the signal strength of the jammer for estimating only the distance between jammer and receiver, while then a less complex algorithm is proposed for localizing the jammer and then redirecting the vehicles away from the roads the attacker is using. This approach was simulated using real-life maps and specialized network environments. Additionally, the performance of the new approach was evaluated using different metrics. These evaluation metrics include (1) the estimated position of the jammer, (2) the handling of the jammer by announcing its location to normal vehicles (3) the avoidance of the jammed routes by increasing their weight, which forces the cars to reroute and evade the jamming area. The high localization accuracy, measured by the Euclidean distance, and the successful communication of the attacker's position and its avoidance have highly increased the packet delivery ratio (PDR) and the signal-to-interference-plus-noise ratio (SINR). This was noticed significantly before and after avoiding the jamming area when for example, the PDR increased from 0% to 100% before and after bypassing the jammer's routes.

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