A pre-requisite for the design of wireless systems is the understanding of the propagation channel. While a wealth of propagation knowledge exists for bands below 6 GHz, the same can not be said for bands approaching millimeter-wave frequencies. In this paper, we present the design, implementation and measurement-based verification of a re-configurable 27.5-29.5 GHz channel sounder for measuring dynamic directional channels. Based on the switched array principle, our design is capable of characterizing 128$\times$256 dual-polarized channels with snapshot times of around 600 ms. This is in sharp contrast to measurement times on the order of tens-of-minutes with rotating horn antenna sounders. Our design lends itself to high angular resolution at both link ends with calibrated antenna arrays sampled at 2$^\circ$ and 5$^\circ$ intervals in the azimuth and elevation domains. This is complemented with a bandwidth of up to 2 GHz, enabling nanosecond-level delay resolution. The short measurement times and stable radio frequency design facilitates real-time processing and averaging of the received wavefronts to gain measurement signal-to-noise ratio and dynamic range. After disclosing the sounder design and implementation, we demonstrate its capabilities by presenting dynamic and static measurements at 28 GHz over a 1 GHz bandwidth in an office corridor environment.
翻译:设计无线系统的前提在于对传播频道的了解。 虽然在6千兆赫以下的波段存在丰富的传播知识, 但对于接近毫米波频率的波段来说, 却不能说同样的情况。 在本文中, 我们展示了可重新配置的27.5-29.5千兆赫频道声音的设计、 实施和基于测量的核查, 用于测量动态定向频道。 根据调换阵列原则, 我们的设计能够将28千兆赫的双极化频道描述为128美元/乘以256美元/乘以近600米的快照时间。 这与以旋转角天线声音为主的数十分钟为主的测量时间的测量时间形成鲜明对比。 我们的设计有助于在两端使用校准的天线阵列阵列取样为2 ⁇ circ$ 和 5 ⁇ crc$ 用于测量动态定向频道。 根据调换阵列的阵列原则, 我们的设计可以将宽度为2千兆赫兹, 促成纳米二度延迟延迟分辨率分辨率解析。 测量时间和稳定的无线电频率设计有助于实时处理和在接收的波端平面比率中, 显示我们进行动态测距的图像测距, 。