Solid-State Terahertz Circuits for 6G: A Review

IF 1.6 4区计算机科学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Chinese Journal of Electronics Pub Date : 2025-03-01 DOI:10.23919/cje.2023.00.279

Zhongqian Niu;Bo Zhang;Yihan Zhang;Yinian Feng;Zhi Chen;Yihong Su;Yong Fan;Yongxin Guo

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引用次数: 0

Abstract

Terahertz communication is anticipated to play a pivotal role in applications like super-capacity data retrieval, ultra-high-speed short-distance transmission, holographic communication, and micro-sized communication. Emerging scenarios such as the sixth generation (6G), integrated sensing and communication, the metaverse, and autonomous agent networking are also poised to benefit. Additionally, it promises high-precision positioning and high-resolution perceptual imaging for networks and terminal devices. This paper provides a comprehensive overview of the current performance, developmental trends, and measurement techniques associated with solid-state terahertz circuits and communication systems. Regarding circuits, the research and development of single-function circuits in the terahertz band have reached maturity. Traditional single-function circuits continue to evolve towards higher frequency bands (exceeding 1 THz), with reduced loss and improved efficiency. Concurrently, building upon these traditional circuits, researchers have introduced innovative integrated circuit designs and layout techniques to minimize system volume. Solid-state terahertz communication systems are also progressing towards elevated carrier frequencies, faster communication rates, phased arrays, and full-duplex communication. Through collaborative efforts, the global academic and industrial communities are intensifying their focus on terahertz key technologies and prototype system validation, aiming to bolster industrial growth and ecosystem development.

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6G固态太赫兹电路综述

太赫兹通信预计将在超大容量数据检索、超高速短距离传输、全息通信和微型通信等应用中发挥关键作用。第六代（6G）、集成传感和通信、元宇宙和自主代理网络等新兴场景也有望从中受益。此外，它还有望为网络和终端设备提供高精度定位和高分辨率感知成像。本文全面概述了固态太赫兹电路和通信系统的当前性能、发展趋势和测量技术。在电路方面，太赫兹频段单功能电路的研究和开发已经成熟。传统的单功能电路继续向更高的频段（超过1太赫兹）发展，降低了损耗，提高了效率。同时，在这些传统电路的基础上，研究人员引入了创新的集成电路设计和布局技术，以最大限度地减少系统体积。固态太赫兹通信系统也在朝着更高的载波频率、更快的通信速率、相控阵和全双工通信的方向发展。通过共同努力，全球学术界和工业界正在加强对太赫兹关键技术和原型系统验证的关注，旨在促进工业增长和生态系统发展。

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

Chinese Journal of Electronics 工程技术-工程：电子与电气

CiteScore

3.70

自引率

16.70%

发文量

342

审稿时长

12.0 months

期刊介绍： CJE focuses on the emerging fields of electronics, publishing innovative and transformative research papers. Most of the papers published in CJE are from universities and research institutes, presenting their innovative research results. Both theoretical and practical contributions are encouraged, and original research papers reporting novel solutions to the hot topics in electronics are strongly recommended.