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引用次数: 2

摘要

未来,随着物联网(IoT)、无线传感器和多种5G应用的出现,室内房间可能会堆满数千台设备。这些设备将具有不同的服务质量(QoS)需求和资源约束,例如移动性、硬件和效率需求。太赫兹波段有一个巨大的绿地频谱,被设想为满足这些密集的室内部署。然而,太赫兹有许多缺点,如高吸收率、有限的覆盖范围、低发射功率、对移动的敏感性和频繁的中断,使其部署具有挑战性。太赫兹可能会迫使网络依赖于额外的基础设施,这对网络运营商来说可能没有利润,甚至可能导致对低到中等数据速率要求的设备的资源利用效率低下。在太赫兹中使用分布式设备对设备(D2D)通信,我们可以在资源受限的情况下满足这些超密集低数据速率类型的应用程序。我们提出了一个2层分布式D2D模型,其中设备使用协调多智能体强化学习(MARL)来最大限度地提高室内密集部署的效率和用户覆盖率。我们探讨了训练算法所需的特征选择以及它如何影响系统效率。我们表明,网络中的致密化和移动性可以用来进一步扩大太赫兹设备的有限覆盖范围,而不需要额外的基础设施或资源。
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Ultra-dense low data rate (UDLD) communication in the THz
In the future, with the advent of the Internet of Things (IoT), wireless sensors, and multiple 5G applications yet to be developed, an indoor room might be filled with 1000s of devices. These devices will have different Quality of Service (QoS) demands and resource constraints, such as mobility, hardware, and efficiency requirements. The THz band has a massive greenfield spectrum and is envisioned to cater to these dense-indoor deployments. However, THz has multiple caveats, such as high absorption rate, limited coverage range, low transmit power, sensitivity to mobility, and frequent outages, making it challenging to deploy. THz might compel networks to be dependent on additional infrastructure, which might not be profitable for network operators and can even result in inefficient resource utilization for devices demanding low to moderate data rates. Using distributed Device-to-Device (D2D) communication in the THz, we can cater to these ultra-dense low data rate type applications in a constrained resource situation. We propose a 2-Layered distributed D2D model, where devices use coordinated multi-agent reinforcement learning (MARL) to maximize efficiency and user coverage for dense-indoor deployment. We explore the choice of features required to train the algorithms and how it impacts the system efficiency. We show that densification and mobility in a network can be used to further the limited coverage range of THz devices, without the need for extra infrastructure or resources.
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