PhLEXSAT - A Very High Throughput Photo-Digital Communication Satellite Payload

2022 IEEE International Conference on Space Optical Systems and Applications (ICSOS) Pub Date : 2022-03-28 DOI:10.1109/icsos53063.2022.9749722

Madhubrata Chatterjee, C. Palla, Edem Fiamanya, M. Beltrán, M. Piqueras, A. Cervello, Laurent Roux, P. Runge, Jakub Zverina, N. Cameron

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Abstract

Photonic components offer an advantage of minimizing the size, weight and power consumption (Swap) of a satellite communication payload. This paper presents how this can be utilized in Increasing the capacity of Very High Throughput Satellites (VHTS) while reducing the cost at the same time. Photonics is capable of offering a limitless bandwidth in THz range at the band around 1550 nm while offering high data rates and frequencies with almost lossless propagation in an optical fibre. However, at present only a few demonstrations of photonic devices in non-critical equipment with limited degree of integration can be found in the satcom industry as we as in literature. With the advancement of the photonic technology, it is now possible to develop Tbps-like software defined photonic payload. PhLEXSAT project, funded under the European Union H2020, is led by DAS Photonics in cooperation with MDA UK, Eutelsat, Axenic, HHI Fraunhofer and Argotech.

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PhLEXSAT -一个非常高吞吐量的照片-数字通信卫星有效载荷

光子元件提供了一个优势，最大限度地减少卫星通信有效载荷的尺寸，重量和功耗(Swap)。本文介绍了如何利用这一点来提高甚高通量卫星(VHTS)的容量，同时降低成本。光子学能够在1550纳米左右的波段提供太赫兹范围内的无限带宽，同时在光纤中提供几乎无损传播的高数据速率和频率。然而，目前在卫星通信行业和文献中，仅能找到一些在非关键设备中集成程度有限的光子器件的演示。随着光子技术的进步，现在可以开发类似tps的软件定义光子有效载荷。PhLEXSAT项目由欧盟H2020资助，由DAS Photonics与MDA UK、Eutelsat、Axenic、HHI Fraunhofer和Argotech合作领导。

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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2022 IEEE International Conference on Space Optical Systems and Applications (ICSOS)

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