Access Control in NB-IoT Networks: A Deep Reinforcement Learning Strategy

Y. Hadjadj-Aoul, Soraya Ait-Chellouche
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引用次数: 5

Abstract

The Internet of Things (IoT) is a key enabler of the digital mutation of our society. Driven by various services and applications, Machine Type Communications (MTC) will become an integral part of our daily life, over the next few years. Meeting the ITU-T requirements, in terms of density, battery longevity, coverage, price, and supported mechanisms and functionalities, Cellular IoT, and particularly Narrowband-IoT (NB-IoT), is identified as a promising candidate to handle massive MTC accesses. However, this massive connectivity would pose a huge challenge for network operators in terms of scalability. Indeed, the connection to the network in cellular IoT passes through a random access procedure and a high concentration of IoT devices would, very quickly, lead to a bottleneck. The latter procedure needs, then, to be enhanced as the connectivity would be considerable. With this in mind, we propose, in this paper, to apply the access class barring (ACB) mechanism to regulate the number of devices competing for the access. In order to derive the blocking factor, we formulated the access problem as a Markov decision process that we were able to solve using one of the most advanced deep reinforcement learning techniques. The evaluation of the proposed access control, through simulations, shows the effectiveness of our approach compared to existing approaches such as the adaptive one and the Proportional Integral Derivative (PID) controller. Indeed, it manages to keep the proportion of access attempts close to the optimum, despite the lack of accurate information on the number of access attempts.
NB-IoT网络中的访问控制:深度强化学习策略
物联网(IoT)是我们社会数字化突变的关键推动者。在各种服务和应用的推动下,机器类型通信(MTC)将在未来几年内成为我们日常生活中不可或缺的一部分。蜂窝物联网,特别是窄带物联网(NB-IoT)在密度、电池寿命、覆盖范围、价格以及支持的机制和功能方面满足ITU-T的要求,被认为是处理大规模MTC接入的有希望的候选者。然而,这种大规模的连接将在可扩展性方面对网络运营商构成巨大挑战。事实上,蜂窝物联网中的网络连接通过随机访问过程,高度集中的物联网设备将很快导致瓶颈。因此,后一种程序需要得到加强,因为连接性将是相当大的。考虑到这一点,本文提出应用访问类限制(ACB)机制来调节竞争访问的设备数量。为了推导出阻塞因子,我们将访问问题表述为一个马尔可夫决策过程,我们能够使用最先进的深度强化学习技术之一来解决这个决策过程。通过仿真对所提出的访问控制进行了评估,与现有的自适应方法和比例积分导数(PID)控制器相比,我们的方法是有效的。实际上,尽管缺乏关于访问尝试次数的准确信息,它仍设法使访问尝试的比例接近最佳值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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