Resource allocation for Vehicle‐to‐Everything communications: A survey

Brahmi, Ibtissem; Koubaa, Hend; Zarai, Faouzi

doi:10.1049/ntw2.12078

Cited by 8 publications

(2 citation statements)

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“…While the study [11] covers D2D resource allocation algorithms, our survey goes beyond LTE to focus on the evolving landscape of the 6G V2X Sidelink. The research [12] explores efficient resource allocation methods for V2X communications in 4G and 5G networks, whereas our survey investigates advancements and challenges leading to 6G V2X Sidelink. The study [13] presents a comprehensive survey on resource allocation for vehicular networks, including DSRC and cellular-based networks.…”

Section: Related Workmentioning

confidence: 99%

Towards 6G V2X Sidelink: Survey of Resource Allocation—Mathematical Formulations, Challenges, and Proposed Solutions

Annu,

Rajalakshmi

2024

IEEE Open J. Veh. Technol.

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The advent of 6G marks a transformative phase in wireless communication, ushering in a hyperconnected experience. This paper explores optimizing sidelink technologies in Vehicle-to-Everything (V2X) communication through integrating 6G capabilities. Emphasizing challenges in sidelink resource allocation, the study introduces mathematical solutions. The survey further investigates the evolution of Cellular-V2X (C-V2X) and sidelink standardization within the 6G V2X Sidelink context, highlighting key features and applications. Additionally, it examines inter-UE coordination, resource re-evaluation, and pre-emption operations in 5G-V2X Sidelink, addressing associated challenges and mathematical formulations. The paper focuses on power-based resource allocation in 5G-V2X, addressing challenges and proposing solutions for the 6G V2X Sidelink landscape. Encompassing direct communication, collision issues, spectrum compliance, resource fairness, uncertainty, and interference management, the survey comprehensively explores challenges and solutions in current sidelink resource allocation. It evaluates traditional and emerging techniques, such as cognitive radio, cooperative communication, power control, dynamic spectrum access, ML-aided allocation, blockchain-enabled allocation, and edge computing-driven allocation. The resource allocation requirements for diverse V2X services in 6G V2X Sidelink are outlined, explicitly focusing on Vehicular to Vehicular (V2V), Vehicular to Infrastructure (V2I), Vehicular to Pedestrian (V2P), and other V2X services, addressing their specific needs.

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Section: Related Workmentioning

confidence: 99%

Towards 6G V2X Sidelink: Survey of Resource Allocation—Mathematical Formulations, Challenges, and Proposed Solutions

Annu,

Rajalakshmi

2024

IEEE Open J. Veh. Technol.

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“…However, the transition to 6G communications introduces a formidable challenge to the resource-allocation system, particularly when autonomous distributed vehicles are in operation, given the stringent requirements for extremely high throughput, low latency, and unwavering dependability [18,19]. This necessitates a comprehensive reassessment of the resource-management strategies to ensure the seamless integration of these cutting-edge technologies into the future landscape of connected and autonomous vehicles [20,21].…”

Section: Introductionmentioning

confidence: 99%

Optimizing V2X Communication: Spectrum Resource Allocation and Power Control Strategies for Next-Generation Wireless Technologies

Ibrahim,

Chen,

Wang

et al. 2024

Applied Sciences

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The upcoming wireless technology developments in the next generations are expected to substantially transform the vehicle-to-everything (V2X) communication network. The challenge of limited spectrum resources in V2X communication, caused by the need for high data rates, necessitates a thorough analysis of spectrum resource allocation and power control. This complex problem falls under the domain of mixed-integer nonlinear programming; a strategic approach is implemented to overcome these issues, which divides the main challenge into two sub-problems. The issue of resource allocation is addressed by implementing a multiaccess spectrum allocation method, which is deliberately designed to optimize the utilization of the spectrum resources that are currently accessible. Concurrently, the power control issue is resolved by employing a continuous convex approximation technique, which effectively converts non-convex power-allocation issues into convex equivalents. This approach helps to alleviate interference between users. Finally, the simulation results prove that the proposed approaches can improve vehicle performance. The algorithms proposed in this article significantly improve the system throughput and access rate of vehicular user equipment (VUEs) while ensuring the data rate of cellular user equipment (CUEs).

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