Terahertz (THz) wireless systems for space applications

2013 IEEE Sensors Applications Symposium Proceedings Pub Date : 2013-04-04 DOI:10.1109/SAS.2013.6493580

S. Hwu, K. Desilva, Cindy T. Jih

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引用次数: 54

Abstract

NASA has been leading the Terahertz (THz) technology development for the sensors and instruments in astronomy in the past 20 years. THz technologies are expanding into much broader applications in recent years. Due to the vast available multiple gigahertz (GHz) broad bandwidths, THz radios offer the possibility for wireless transmission of high data rates. Multi-Gigabits per second (MGbps) broadband wireless access based on THz waves are closer to reality. The THz signal high atmosphere attenuation could significantly decrease the communication ranges and transmittable data rates for the ground systems. Contrary to the THz applications on the ground, the space applications in the atmosphere free environment do not suffer the atmosphere attenuation. The manufacturing technologies for the THz electronic components are advancing and maturing. There is great potential for the NASA future high data wireless applications in environments with difficult cabling and size/weight constraints. In this study, the THz wireless systems for potential space applications were investigated. The applicability of THz systems for space applications was analyzed. The link analysis indicates that MGbps data rates are achievable with compact sized high gain antennas.

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空间应用的太赫兹(THz)无线系统

在过去的20年里，NASA一直引领着天文学传感器和仪器的太赫兹(THz)技术的发展。近年来，太赫兹技术正在扩展到更广泛的应用领域。由于大量可用的千兆赫(GHz)宽带，太赫兹无线电为高数据速率的无线传输提供了可能性。基于太赫兹波的每秒千兆比特(MGbps)宽带无线接入更接近现实。太赫兹信号的高大气衰减会显著降低地面系统的通信距离和可传输数据速率。与地面上的太赫兹应用相反，无大气环境下的空间应用不受大气衰减的影响。太赫兹电子元件的制造技术正在不断进步和成熟。在布线困难和尺寸/重量限制的环境中，NASA未来的高数据无线应用具有很大的潜力。在本研究中，对潜在的空间应用太赫兹无线系统进行了研究。分析了太赫兹系统在空间应用中的适用性。链路分析表明，MGbps的数据速率是可以实现的紧凑尺寸的高增益天线。

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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2013 IEEE Sensors Applications Symposium Proceedings

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