At the start of 2017, 6 projects including TERRANOVA were granted funding to answer the European Commission’s challenge to “support European scientific excellence notably in the DSP domain, and to bring the most promising long term research coming from the labs closer to fruition, which included perspectives for the full exploitation of the spectrum potential, notably above 90Ghz, with new waves of technologies and knowledge, bringing wireless systems to the speed of optical technologies, and for new applications. It included interaction with photonic systems as well as new cooperation networking and protocols, notably in the mobility context”.
DREAM: D-band Radio solution Enabling up to 100 Gbps reconfigurable Approach for Meshed beyond 5G networks
The project, through the exploitation of the radio spectrum in D-band (130-174.8 GHz) with beam steering functionality, will enable wireless links with data rate exceeding current V-band and E-band wireless backhaul solutions by at least a factor of 10 and thus, it will bring wireless systems to the speed of optical systems. The DREAM project vision and objectives rely on a power efficient and silicon based BiCMOS transceiver analog front end, operating in D-band and enabling cost efficient deployment of meshed networks with seamless fiber performance. A beam steering integrated antenna array using an intelligent low-cost packaging technology prototype will be developed for the implementation of the beyond 5G network proof of concept in a realistic environment.
EPIC: Enabling Practical Wireless Tb/s Communications with Next Generation Channel Coding
The project aims to improve cooperation in the area of information and communication technologies between Europe and three partner countries in the Asia-Pacific (Australia, New Zealand, Singapore). EPIC will foster cooperation in ICT research, technology development and innovation-related topics at the policy and the researcher level. The initiative builds on cooperation policy dialogues, the analysis of research capabilities, and on recommendations from previous projects involving these countries. The project follows a topically expanding methodology: cooperation will start from a small set of joint and/or global challenges and continue to expand areas as the project progresses. Initial topics include: smart nations, resilient and sustainable cities, open and digital science.
TERAPOD: Terahertz based Ultra High Bandwidth Wireless Access Networks
The aim TERAPOD is to investigate and demonstrate the feasability of ultra high bandwidth wireless access networks operating in the Terahertz band. The project will focus on end to end demonstration of the THz wireless link within a Data Centre Proof of Concept deployment, while also investigating other use cases applicable to beyond 5G such as wireless personal area networks, wireless local area networks and high bandwidth broadcasting. The project seeks to bring THz communication a leap closer to industry uptake through leveraging recent advances in THz components, a thorough measurement and characterization study of components and devices, coupled with specification and validation of higher layer communication protocol specification.
WORTECS: Wireless Optical/Radio TErabit CommunicationS
WORTECS focuses on the goal of ultra-high data rate wireless. High-frequency mm-wave (in the band above 90 GHz) radio communications will be combined with optical wireless communications in the infrared and visible regions of the optical spectrum, using novel heterogeneous networking concepts. A compelling virtual reality application will be used to showcase the capability of the WORTECS network. The project will deliver two Proof-of-Concept demonstrations. An ultra-high density LiFi/Radio network providing multi-Gbps to virtual reality terminals will be developed, and an ultra-high data rate Proof-of-Concept capable of Tbps networking will also be targeted.
ULTRAWAVE:Ultra capacity wireless layer beyond 100 GHz based on millimeter wave Traveling Wave Tubes
UTRAWAVE responds to the challenge of high capacity, high cell density backhaul by proposing, for the first time, the exploitation of the whole millimeter wave spectrum beyond 100 GHz. This will be used to create an ultra capacity layer providing more than 100 Gbps per kilometer square in Point to Multi point at D-band (141 – 174.8 GHz) over 500 m radius of coverage, fed by novel G-band (300 GHz) Point to Point high capacity links with more than 600 m range. The ULTRAWAVE system is empowered by the convergence of three main technologies: vacuum electronics, solid-state electronics and photonics in a unique wireless system, with transmission power at Watt level at millimeter waves, generated by novel traveling wave tubes.