Graph Theoretical Models for Enhancing Highway Connectivity and Safety in Vehicular Networks

Shivangni Jat, R. S. Tomar, Santosh Narayankhedkar
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Abstract

Vehicular networks play a crucial role in modern transportation systems, significantly impacting connectivity and safety on highways. This paper explores the application of graph theoretical models to enhance both connectivity and safety in vehicular networks. Graph theory, a branch of discrete mathematics, provides a robust framework for modeling and analyzing complex networks, including those formed by vehicles on highways. Our study begins by defining the vehicular network as a graph where nodes represent vehicles, and edges denote communication links between them. We employ various graph theoretical concepts such as connectivity, centrality, and network flow to evaluate and improve the network's performance. Key metrics, including the degree of nodes, clustering coefficients, and shortest path lengths, are utilized to quantify network connectivity and identify critical nodes and edges that influence overall network efficiency. One of the primary objectives is to ensure uninterrupted connectivity in the presence of dynamic and often unpredictable vehicular movement. To this end, we analyze the network's resilience to node failures and propose strategies to enhance robustness using redundancy and alternative routing paths. By incorporating concepts like k-connectivity and network diameter, we develop models that maintain high levels of connectivity despite the removal or failure of multiple nodes or edges. Safety is addressed through the lens of network stability and reliability. We investigate the impact of vehicular density, speed, and communication range on the network's ability to sustain reliable communication channels. Techniques such as dynamic topology management and adaptive power control are proposed to mitigate the risks associated with network fragmentation and communication delays. Furthermore, we introduce optimization algorithms that leverage graph partitioning and community detection to improve the management of vehicular clusters, facilitating efficient data dissemination and reducing the likelihood of congestion-related incidents. The proposed models are validated through simulations that mimic real-world highway conditions, demonstrating significant improvements in both connectivity and safety metrics. In conclusion, the application of graph theoretical models offers a promising approach to enhancing highway connectivity and safety in vehicular networks
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增强车联网公路连通性和安全性的图论模型
车辆网络在现代交通系统中发挥着至关重要的作用,对高速公路的连通性和安全性产生了重大影响。本文探讨了如何应用图论模型来增强车辆网络的连通性和安全性。图论是离散数学的一个分支,它为复杂网络的建模和分析提供了一个强大的框架,包括高速公路上车辆形成的网络。我们的研究首先将车辆网络定义为一个图,其中节点代表车辆,边代表车辆之间的通信链路。我们采用各种图论概念,如连通性、中心性和网络流,来评估和改进网络的性能。我们利用节点度、聚类系数和最短路径长度等关键指标来量化网络连通性,并识别影响整体网络效率的关键节点和边。我们的主要目标之一是确保在动态且经常不可预测的车辆移动情况下的不间断连接。为此,我们分析了网络对节点故障的恢复能力,并提出了利用冗余和替代路由路径来增强鲁棒性的策略。通过结合 k 连接性和网络直径等概念,我们开发出了在多个节点或边缘被移除或失效的情况下仍能保持高水平连接性的模型。我们从网络稳定性和可靠性的角度来探讨安全性问题。我们研究了车辆密度、速度和通信范围对网络维持可靠通信通道能力的影响。我们提出了动态拓扑管理和自适应功率控制等技术,以降低与网络分裂和通信延迟相关的风险。此外,我们还引入了优化算法,利用图分割和群落检测来改善车辆集群的管理,促进数据的有效传播,降低拥堵相关事故发生的可能性。通过模拟现实世界的高速公路状况,对所提出的模型进行了验证,结果表明连接性和安全性指标均有显著改善。总之,图论模型的应用为提高高速公路的连通性和车辆网络的安全性提供了一种前景广阔的方法。
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