Behind the Door: Practical Parameterization of Propagation Parameters for IEEE 802.11ad Use Cases

Luciano Ahumada, E. Carreño, A. Anglès, Diego Dujovne, Palacios Játiva Palacios Játiva
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Abstract

The integration of the 60 GHz band into the IEEE 802.11 standard has revolutionized indoor wireless services. However, this band presents unique challenges to indoor wireless communication infrastructure, originally designed to handle data traffic in residential and office environments. Estimating 60 GHz signal propagation in indoor settings is particularly complicated due to dynamic contextual factors, making it essential to ensure adequate coverage for all connected devices. Consequently, empirical channel modeling plays a pivotal role in understanding real-world behavior, which is characterized by a complex interplay of stationary and mobile elements. Given the highly directional nature of 60 GHz propagation, this study addresses a seemingly simple but important question: what is the impact of employing highly directive antennas when deviating from the line of sight? To address this question, we conducted an empirical measurement campaign of wireless channels within an office environment. Our assessment focused on power losses and distribution within an angular range while an indoor base station served indoor users, simulating the operation of an IEEE 802.11ad high-speed WLAN at 60 GHz. Additionally, we explored scenarios with and without pedestrian movement in the vicinity of wireless terminals. Our observations reveal the presence of significant antenna lobes even in obstructed links, indicating potential opportunities to use angular combiners or beamformers to enhance link availability and the data rate. This empirical study provides valuable information and channel parameters to simulate 60 GHz millimeter wave (mm-wave) links in indoor environments, paving the way for more efficient and robust wireless communication systems.
门背后:IEEE 802.11ad 用例传播参数的实用参数化
将 60 GHz 频段纳入 IEEE 802.11 标准后,室内无线服务发生了革命性的变化。然而,这一频段给室内无线通信基础设施带来了独特的挑战,因为这些基础设施最初是为处理住宅和办公环境中的数据流量而设计的。由于动态环境因素的影响,室内环境中 60 GHz 信号传播的估算尤其复杂,因此必须确保所有连接设备都能获得足够的覆盖范围。因此,经验信道建模在理解真实世界行为方面起着关键作用,而真实世界行为的特点是固定和移动元素之间复杂的相互作用。鉴于 60 GHz 传播的高度指向性,本研究探讨了一个看似简单却很重要的问题:在偏离视线时,采用高度指向性天线会产生什么影响?为了解决这个问题,我们对办公室环境中的无线信道进行了实证测量。我们的评估重点是室内基站为室内用户提供服务时,在一定角度范围内的功率损耗和分布情况,模拟 IEEE 802.11ad 高速 WLAN 在 60 GHz 频率下的运行情况。此外,我们还探索了无线终端附近有无行人活动的场景。我们的观察结果表明,即使在有障碍的链路中也存在明显的天线裂片,这表明有可能使用角度合路器或波束成形器来提高链路可用性和数据传输速率。这项实证研究为模拟室内环境中的 60 GHz 毫米波(mm-wave)链路提供了宝贵的信息和信道参数,为更高效、更稳健的无线通信系统铺平了道路。
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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