毫米波 DBF 系统的直接数字 RF 收发器技术

IF 1.6 4区地球科学 Q3 ASTRONOMY & ASTROPHYSICS

Radio Science Pub Date : 2024-03-30 DOI:10.1029/2023RS007802

Noriharu Suematsu

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引用次数: 0

摘要

数字射频技术已被开发并应用于 6 GHz 以下的无线应用。通过用数字信号处理器和电路取代消耗集成电路芯片的射频/模拟电路块，可以实现富数字/小型收发器。由于这项技术的基础是奈奎斯特理论，因此电路的工作频率受到奈奎斯特频率（=采样时钟频率的 1/2）的限制。因此，现有数字射频技术的最高工作射频频率低于 6 GHz。本文介绍了一种利用高阶奈奎斯特区的新型直接数字 RF 技术。该技术可处理奈奎斯特频率范围以外的射频信号，即 6 GHz 以上的射频信号。本文回顾了 26/28 GHz 波段发射器/接收器的制造结果。由于采用所提技术的收发器架构不需要射频本地振荡器和上/下转换器，因此适用于微波/毫米波多天线系统，如下一代卫星机载数字波束成形和 Beyond 5G 全数字大规模多输入多输出系统。

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Direct digital RF transceiver technology for millimeter-wave DBF systems

Digital RF technology has been developed and has been applied to below 6 GHz wireless applications. By replacing the IC die consumptive RF/analog circuit blocks by digital signal processor and circuit, digital rich/small transceivers can be realized. Since the foundation of this technology is based on the Nyquist theory, the operational frequency of the circuit has been limited by the Nyquist frequency (=1/2 of sampling clock frequency). As a result, the maximum operational RF frequency of existing digital RF technology was below 6 GHz. In this paper, a new direct digital RF technology that utilizes the higher-order Nyquist zones is introduced. This technology enables handling RF signal in beyond Nyquist frequency range which means over 6 GHz range. The results of fabricated 26/28 GHz-band transmitter/receiver are reviewed. Since the transceiver architecture with the proposed technologies does not require an RF local oscillator and up/down converters, it is suitable for microwave/millimeter-wave multi-antenna systems such as next generation satellite on-board digital beam forming and Beyond 5G fully digital Massive multiple-input multiple-output systems.

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来源期刊

Radio Science 工程技术-地球化学与地球物理

CiteScore

3.30

自引率

12.50%

发文量

112

审稿时长

1 months

期刊介绍： Radio Science (RDS) publishes original scientific contributions on radio-frequency electromagnetic-propagation and its applications. Contributions covering measurement, modelling, prediction and forecasting techniques pertinent to fields and waves - including antennas, signals and systems, the terrestrial and space environment and radio propagation problems in radio astronomy - are welcome. Contributions may address propagation through, interaction with, and remote sensing of structures, geophysical media, plasmas, and materials, as well as the application of radio frequency electromagnetic techniques to remote sensing of the Earth and other bodies in the solar system.