Extending Near Field Communication Range for Ultra-Dense Internet of Things

IF 2.3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Omar Ansari;Hongzhi Guo
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Abstract

The advent of 6G wireless systems promises a digital world that blends physical and virtual elements, revolutionizing our interaction with the physical environment. A critical step towards this digital world is the creation of digital twins of physical systems and objects. The Internet of Things (IoT) plays an important role in connecting and monitoring these physical entities. However, connecting all objects in our daily life is challenging due to high density and large number of devices. Near Field Communication (NFC), utilizing High Frequency (HF) band signals, emerges as a promising solution. NFC has a short communication range and high penetration efficiency, with a reliable wireless channel that does not compete for spectrum with typical cellular and local area networks. Nevertheless, its extremely short range limits its use in autonomous IoT applications. This paper explores two techniques to extend NFC’s communication range and reliability: the use of high-quality factor transmit/receive coils and high-quality factor relay coils. Additionally, the effect of tag coil coupling in a multi-tag IoT environment is examined. Analytical models are developed to evaluate these approaches, and the results are validated using COMSOL Multiphysics. The findings demonstrate a significant increase in NFC’s communication range, i.e., up to 0.9 – 1.3 m for 1 – 10 W transmit power, making it suitable for ultra-dense battery-free IoT operations.
为超密集物联网扩展近场通信范围
6G 无线系统的出现将带来一个融合物理和虚拟元素的数字世界,彻底改变我们与物理环境的互动。实现这一数字世界的关键一步是创建物理系统和物体的数字双胞胎。物联网(IoT)在连接和监控这些物理实体方面发挥着重要作用。然而,由于设备密度高、数量多,连接日常生活中的所有物体具有挑战性。利用高频(HF)波段信号的近场通信(NFC)成为一种前景广阔的解决方案。NFC 通信距离短,穿透效率高,具有可靠的无线信道,不会与典型的蜂窝网络和局域网争夺频谱。然而,极短的通信距离限制了它在自主物联网应用中的使用。本文探讨了扩展 NFC 通信范围和可靠性的两种技术:使用高质量因子发射/接收线圈和高质量因子中继线圈。此外,本文还研究了多标签物联网环境中标签线圈耦合的影响。为评估这些方法开发了分析模型,并使用 COMSOL Multiphysics 对结果进行了验证。研究结果表明,NFC 的通信范围大幅增加,即在发射功率为 1 - 10 W 的情况下,通信范围可达 0.9 - 1.3 m,使其适用于超高密度的无电池物联网操作。
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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来源期刊
CiteScore
5.70
自引率
0.00%
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