LTE for Vehicular Communications

Lottermann, Christian; Botsov, Mladen; Fertl, Peter; Mullner, R.; Araniti, Giuseppe; Campolo, Claudia; Condoluci, Massimo; Molinaro, Antonella

doi:10.1007/978-3-319-15497-8_16

Cited by 14 publications

(5 citation statements)

References 28 publications

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“…Connected vehicles are at the heart of the VANETs, equipped with embedded communication modules that enable Vehicle-to-Vehicle (V2V) and Vehicle-to-Infrastructure (V2I) communication [8]. Through V2V and V2I communication, connected vehicles can exchange critical information, such as speed, location, and road conditions, enabling features such as collision avoidance, adaptive cruise control, and realtime traffic management [9]. Additionally, connected vehicles can benefit from cloud-based services, leveraging the IoT to access data, perform complex analytics, and enable various personalized in-car services [10].…”

Section: Vanetsmentioning

confidence: 99%

A Fuzzy-Based Approach for the Assessment of the Edge Layer Processing Capability in SDN-VANETs: A Comparation Study of Testbed and Simulation System Results

Qafzezi,

Bylykbashi,

Higashi

et al. 2023

Vehicles

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Vehicular Ad Hoc Networks (VANETs) have gained significant attention due to their potential to enhance road safety, traffic efficiency, and passenger comfort through vehicle-to-vehicle and vehicle-to-infrastructure communication. However, VANETs face resource management challenges due to the dynamic and resource constrained nature of vehicular environments. Integrating cloud-fog-edge computing and Software-Defined Networking (SDN) with VANETs can harness the computational capabilities and resources available at different tiers to efficiently process and manage vehicular data. In this work, we used this paradigm and proposed an intelligent approach based on Fuzzy Logic (FL) to evaluate the processing and storage capability of vehicles for helping other vehicles in need of additional resources. The effectiveness of the proposed system is evaluated through extensive simulations and a testbed. Performance analysis between the simulation results and the testbed offers a comprehensive understanding of the proposed system and its performance and feasibility.

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Section: Vanetsmentioning

confidence: 99%

A Fuzzy-Based Approach for the Assessment of the Edge Layer Processing Capability in SDN-VANETs: A Comparation Study of Testbed and Simulation System Results

Qafzezi,

Bylykbashi,

Higashi

et al. 2023

Vehicles

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“…To access remote servers while moving on the road, vehicles must remain connected to the Internet via thirdparty networks or telecommunication networks such as 3 G or LTE. e use of telecommunication networks for Internet access is not free, and the required data rate and latency must not be greater than the threshold value (as defined in [17]).…”

Section: Related Workmentioning

confidence: 99%

Aiding Traffic Prediction Servers through Self‐Localization to Increase Stability in Complex Vehicular Clustering

et al. 2021

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The integration of cellular networks and vehicular networks is complex and heterogeneous. Synchronization among vehicles in heterogeneous vehicular clusters plays an important role in effective data sharing and the stability of the cluster. This synchronization depends on the smooth exchange of information between vehicles and remote servers over the Internet. The remote servers predict road traffic patterns by adopting deep learning methods to help drivers on the roads. At the same time, local data processing at the vehicular cluster level may increase the capabilities of remote servers. However, global positioning system (GPS) signal interruption, especially in the urban environment, plays a big part in the detritions of synchronization among the vehicles that lead to the instability of the cluster. Instability of connections is a major hurdle in developing cost-effective solutions for deriving assistance and route planning applications. To solve this problem, a self-localization scheme within the vehicular cluster is proposed. The proposed self-localization scheme handles GPS signal interruption to the vehicle within the cluster. A unique clustering criterion and a synchronization mechanism for sharing traffic information system (TIS) data among multiple vehicles are developed. The developed scheme is simulated and compared with existing known approaches. The results show the better performance of our proposed scheme over others.

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“…The value of the counter is determined via Line 22-25. If the value of β is less than 35%, then the standard value of counter S c (Std) is used, which is [5][6][7][8][9][10][11][12][13][14][15]; otherwise, Equation ( 9) is used to set up the counter value. At Line 27, transmission is performed on the selected RB.…”

Section: Algorithmmentioning

confidence: 99%

“…More recently, the Long-Term Evolution (LTE)-based Vehicle-to-Everything (V2X) proposal has shown potential to improve upon the channel saturation experienced in the WAVE [4][5][6][7][8][9][10][11]. Explicitly, Release 14 of the Third Generation Partnership Project (3GPP) includes support for Vehicle-to-Vehicle (V2V) services [12,13].…”

Section: Introductionmentioning

confidence: 99%

TARS: A Novel Mechanism for Truly Autonomous Resource Selection in LTE-V2V Mode 4

Khan

Shah

Akhunzada

et al. 2021

Sensors

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Effective communication in vehicular networks depends on the scheduling of wireless channel resources. There are two types of channel resource scheduling in Release 14 of the 3GPP, i.e., (1) controlled by eNodeB and (2) a distributed scheduling carried out by every vehicle, known as Autonomous Resource Selection (ARS). The most suitable resource scheduling for vehicle safety applications is the ARS mechanism. ARS includes (a) counter selection (i.e., specifying the number of subsequent transmissions) and (b) resource reselection (specifying the reuse of the same resource after counter expiry). ARS is a decentralized approach for resource selection. Therefore, resource collisions can occur during the initial selection, where multiple vehicles might select the same resource, hence resulting in packet loss. ARS is not adaptive towards vehicle density and employs a uniform random selection probability approach for counter selection and reselection. As a result, it can prevent some vehicles from transmitting in a congested vehicular network. To this end, the paper presents Truly Autonomous Resource Selection (TARS) for vehicular networks. TARS considers resource allocation as a problem of locally detecting the selected resources at neighbor vehicles to avoid resource collisions. The paper also models the behavior of counter selection and resource block reselection on resource collisions using the Discrete Time Markov Chain (DTMC). Observation of the model is used to propose a fair policy of counter selection and resource reselection in ARS. The simulation of the proposed TARS mechanism showed better performance in terms of resource collision probability and the packet delivery ratio when compared with the LTE Mode 4 standard and with a competing approach proposed by Jianhua He et al.

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LTE for Vehicular Communications

Cited by 14 publications

References 28 publications

A Fuzzy-Based Approach for the Assessment of the Edge Layer Processing Capability in SDN-VANETs: A Comparation Study of Testbed and Simulation System Results

A Fuzzy-Based Approach for the Assessment of the Edge Layer Processing Capability in SDN-VANETs: A Comparation Study of Testbed and Simulation System Results

Aiding Traffic Prediction Servers through Self‐Localization to Increase Stability in Complex Vehicular Clustering

TARS: A Novel Mechanism for Truly Autonomous Resource Selection in LTE-V2V Mode 4

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