Horizon 2020 (2014 - 2020)

Software Defined Space Optical Data Highway: SODaH

Last update: Sep 30, 2021 Last update: Sep 30, 2021

Details

Locations:France, Netherlands, Spain, UK
Start Date:Nov 1, 2018
End Date:Oct 31, 2020
Contract value: EUR 3,106,085
Sectors:Telecommunications Telecommunications
Categories:Grants
Date posted:Sep 30, 2021

Associated funding

Associated experts

Description

Programme:

  • H2020-EU.2.1.6.1. - Enabling European competitiveness, non-dependence and innovation of the European space sector
  • H2020-EU.2.1.6.2. - Enabling advances in space technology

Topic: SPACE-15-TEC-2018 - Satellite communication technologies

Call for proposal: H2020-SPACE-2018

Funding Scheme: RIA - Research and Innovation action

Grant agreement ID: 821878

Objective

The objectives of SODaH (Software Defined Space Optical Data Highway) are to mature the key photonic technologies in order to enable the implementation of an OISL (Optical Inter Satellites Links) based “Fiber like Network” in the sky for next generation satellites constellations. In such architectures, satellites are the nodes of a moving network interconnected by OISL, that have to address end users (citizens, corporate users, governmental, machines) with an ubiquitous and reliable coverage at high throughput (100 Mbps). If the Laser Communication Terminal (LCT) are now a mature and flight proven technology for high end applications, their efficient use and integration in transparent, reconfigurable and smart miniaturized telecom payload is still a challenge.

A Photonic Modulation, Routing and Digitalization (P_MRD) Unit which performs the interface between the satellites OISLs (typically four per satellite) and the payload digital processor (connected to end users and gateway via RF antennas) is key to enable flexibility, efficient routing, redundancy, and advanced multiplexing of signals. In the frame of SODaH, the photonic equipment of a miniaturized P_MRD unit (photonic sources using DWDM standard, MUX/DEMUX, an optical switch matrix, Low noise amplifier, and photonic receiver) will be developed in a design to cost and design to manufacture approach. This will assure their market relevance and readiness, by leveraging high performances terrestrial communication photonic components on one hand and radiation screened reliable automotive EEE components on the other hands.

Eventually demonstrators of each device will be manufactured and environmentally tested before to be assembled and tested together to demonstrate the added value and maturity of the P_MRD Unit. The demonstrator will be made available for showcase to the communication satellite community for paving the way for a short path from lab to market.

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