With the rapid advancement of Intelligent Transportation Systems (ITS) and vehicular communications, Vehicular Edge Computing (VEC) is emerging as a promising technology to support low-latency ITS applications and services. In this paper, we consider the computation offloading problem from mobile vehicles/users in a heterogeneous VEC scenario, and focus on the network- and base station selection problems, where different networks have different traffic loads. In a fast-varying vehicular environment, computation offloading experience of users is strongly affected by the latency due to the congestion at the edge computing servers co-located with the base stations. However, as a result of the non-stationary property of such an environment and also information shortage, predicting this congestion is an involved task. To address this challenge, we propose an on-line learning algorithm and an off-policy learning algorithm based on multi-armed bandit theory. To dynamically select the least congested network in a piece-wise stationary environment, these algorithms predict the latency that the offloaded tasks experience using the offloading history. In addition, to minimize the task loss due to the mobility of the vehicles, we develop a method for base station selection. Moreover, we propose a relaying mechanism for the selected network, which operates based on the sojourn time of the vehicles. Through intensive numerical analysis, we demonstrate that the proposed learning-based solutions adapt to the traffic changes of the network by selecting the least congested network, thereby reducing the latency of offloaded tasks. Moreover, we demonstrate that the proposed joint base station selection and the relaying mechanism minimize the task loss in a vehicular environment.
翻译:随着智能运输系统(ITS)和车辆通信的快速推进,车辆电磁计算系统(VEC)正在成为支持低延迟ITS应用程序和服务的一个大有希望的技术。在本文中,我们考虑在一个混杂的VEC情景中计算移动车辆/用户的卸载问题,并侧重于网络和基地站选择问题,因为不同的网络有不同的交通负荷。在快速变化的车辆环境中,用户的卸载经验受到与基地站共用的边端计算服务器的拥堵所造成的潜值的强烈影响。然而,由于这种环境的非固定性质和信息短缺,因此预测这种拥堵是一个涉及的任务。为了应对这一挑战,我们建议采用在线学习算法和基于多臂土匪理论的离政策学习算法。为了动态地选择一个在轻便的固定环境中最不调的网络,这些算法预测了使用卸载的轨道服务器与基地站点的倾斜度。此外,我们通过这种递卸式计算,我们用下轨道选择了一个基于轨道的轨道选择方法,从而最大限度地展示了我们所选择的轨道选择的轨道,从而显示我们所选择的轨道的轨道选择的轨道系统。</s>