Projects

The objective of the activity is to design, manufacture and test a TT&C diplexer at S-Band for small sat applications with a reduced volume and mass.

Satellite communications networks are critical infrastructure that are prone to interference, impairments, and other effects that impact their ability to deliver robust and reliable service. Qoherent is developing machine learning based radiofrequency impairment classifiers for improving satellite communications network operations.

An optimized QUIC protocol for SatCom.

DINoS5G project has developed an end-to-end platform from integration of High Throughput Satellite (HTS) system and 5G terrestrial infrastructure, enabling communications for an advanced diagnostic service in the railway environment. The platform provides communication interfaces to applications for real-time monitoring and “smart” predictive maintenance services of the railway infrastructure.

The DAWN project investigates network control, management and orchestration algorithms to enable data-driven SatCom network and resources management and configuration in future integrated satellite-terrestrial networks. This includes data mining and analysis to optimize the performance of both the radio access and the network.

Neuromorphic computers are non-von Neumann computers whose structure and function are inspired by brains and are therefore composed of neurons and synapses. They have enormous potential for many different applications. In this project we explore and understand the current state-of-the-art of Neuromorphic Processor hardware and software technologies and assess their applicability to space applications.

The objective of the ESA project AIComS is to develop Artificial Intelligence (AI/ Machine Learning (ML)-based Software/ Hardware platforms for future products of an integrated satellite and 5G & beyond communication network. It focuses on the development of ML-based 5G New Radio (NR) physical layer components and investigates different functional splits. Furthermore, 5G & beyond compliant ML-based routing, network slicing, and security components will be investigated. The 3rd Generation Partnership Projects (3GPP) 5G specifications are tracked for these developments.

The Unified Communication Services Manager (UCSM) is a Pooling & Sharing Solution for safe/secure SATCOM-centric communication services. UCSM targets the community of IGO/NGO and private-sector users as well as commercial & governmental providers.

The project designed and developed the core components of this expert system / service broker. It paved the way for future tailoring and operationalisation on various scales, ranging from “single-provider, multiple user” to “multiple-provider, multiple-user, international deployment”.

A clear tendency of convergence of communication and sensing can be observed in the frame of 5G, beyond 5G and 6G. This offers a unique opportunity for the space industry, in particular in combination with the ongoing softwarisation (software defined networks, network functions virtualisation, cloud-based internet services etc.) to revolutionize Earth Observation and communication satellite payloads. The opportunity for change and improvement is similar and can be compared to the emergence and success of the all-purpose computers and data centers that opened up completely new efficiency dimensions and economies of scale.

In particular, the 5GEOSiS team sees the sharing and convergence (commonalisation) of the processing – yielding to the joint processing – between the Earth Observation and sensing part of a satellite payload, and the communication part of the payload that is something that can be and shall be considered immediately focusing on the dynamic on demand reallocation – repurposing – of payload resources.

Bx-WiFi technology enables broadcasting of uninterrupted audio or video content from multiple sources to thousands of smartphone or tablet devices, all connected to Wi-Fi access points, while simultaneously providing general internet access.

The astronomical Observatory at Skinakas, located at the Greek island of Crete, will be upgraded to an Optical Ground Station (OGS). The instrumentation for optical and quantum (QKD) telecommunication with LEO satellites will be designed and developed. 22SkinUp aims to evolve the technology that will lead to a national OGS network.

Designing and developing an ESA-community open-source satellite mission and communications analysis tool to be able to tackle the current issues that the industry faces efficiently. This project is expanded and built around a community, and its aim is to become a robust and trustworthy solution for the industry.

The objective of project DISCO is the development of a compact S-band diplexer with 30 MHz channels bandwidth and with 60% and 50% of volume/mass reduction in comparison to the state of the art. Engineering Models (EM) are planned to be designed, manufactured and tested experimentally. The target TRL is 6.

Project AO-RETINA is targeting advancement in optical ground stations (OGS) and in a free-space optical communication system. Unlike traditional OGS, beam tracking and data acquisition are both implemented using a single, long wavelength avalanche photodiode based receiver which enables high sensitivity operation up to 10 Gbps.
 

The future will be driven by data and our world powered by making data accessible to all. This project introduces the first IoT and SATCOM Education kit to classrooms throughout Europe, engaging young minds through hands-on learning and real-world scenarios. The objective is to ensure that the next generation has the skills to work, innovate and thrive in the fourth industrial revolution.

This ESA project is managed by TRAD with the collaboration of ONERA, OHB, AIRBUS and Thales Alenia Space. The goal of this project is to provide a new proton environment model and a new calculation tool in order to provide a better modelling of solar array degradation for the typical telecommunication satellite applications experiencing an EOR radiation environment.

The satellite broadcast market is under pressure.OTT is taking market share from DTH. Density and ease of use is more and more a requirement However, there are opportunities for innovative products that support the high-level quality standards of the satellite broadcast market as well as the upcoming OTT market.

The aim of this ARTES ATLAS project is to develop and demonstrate the functionality and performance a frequency and modulation flexible telecommand receiver with a CAN Bus, on the Eutelsat Konnect satellite. 

The objective of the project is to develop and validate AI-based signal processing techniques for satellite telecommunications such as signal identification, spectrum monitoring, spectrum sharing, signal demodulation etc. using Off-the-Shelf AI accelerator(s). This includes the development of a laboratory testbed to validate and demonstrate the developments in both on-ground and on-board scenarios.

Optimize the pointing and acquisition of the optical inter-satellite link in such a way that the ISL for ranging and data can be completed within a time frame of < 40 seconds. Maximize ranging accuracy and time and frequency transfer performance of the inter-satellite link.

Within this project a magnetic brake is designed, built and tested, which provides holding torque without mechanic contact and without constant energy consumption. The brake has no tribological layer and generates no debris. It is designed and tested in vacuum in a temperature span from -45°C to +100 °C. Locking / releasing the brake requires only a short current pulse.

Development of a competitive Miniature Release Actuator, having a preload capability of more than 1 kN, optimised for the use on small satellites.

CELEOS provides a cutting-edge channel emulator solution that boasts remarkable capabilities, all while maintaining an affordable price point. This is achieved through the strategic use of Software Defined Radio technology, which is readily accessible in the market.

The objective of ESA NGSO-Sense projects is to develop a ground terminal prototype, as well as the measurement procedure, for detecting and identifying interference; and measuring Radio Frequency (RF) characteristics from a NGSO satellite network.

In an increasingly data-driven global society, Free Space Optical Communication, FSOC, is a key technology, overcoming the bandwidth bottleneck of radio technology. The market for a widespread exploitation of FSOC requires 24/7 operability of reliable optical channels. ALASCA project aims to prove the effectiveness of 24/7 optical feeder links with Laser Guide Star Adaptive Optics to solve the Point-Ahead problem.

Beyond Gravity Sweden (BGS) C- and Ku-band converters and receivers have a proven commercial success for many years, but due to customer demands of smaller products, shorter lead times and lower cost, this activity targets the RF chain for the next generation of the BGS converter and receiver family. 

The performed activity is in response to an imminent market need for Agile Converters for Ka/IF and Q- and V-band, of which the proposed Agile synthesized LO and digital gain control (DCLO – Digital Control & LO) module is a key part. The DCLO is a generic function that is intended to be used in different applications, especially converters and receivers interfacing payload processors at different frequencies.

The main objective of the proposed activity is to develop and validate a solution to fully automate the commissioning of services in SatCom on-the-move mechanical terminals, without human intervention, addressing optimal radiofrequency performance and power transmission required by the Network Operations Center and minimizing interferences. It also enables remote recovery in many cases, removing the need for installers to revisit the site.

The NODES project regards the development of a ground network for space to ground data transfer using optical communication, to solve the data bottleneck resulting from the continuously increased need of downlink capacity of foremost Earth Observation satellites. The network is composed of a network management centre and optical ground stations to allow high volume data transfers efficiently.

System design exercise attempting to define a future SatCom system topology that exploits the benefits of space elements on multiple orbits, such as GEO, MEO, and LEO, with interoperability with HAPS, UAV, and terrestrial based networks.

Design and development of a high gain deployable antenna dedicated to small satellites (3 to 28 kg range). The overall architecture is simplified as much as possible to reduce any possible source of defective actuation/deployment.

Development of a flexible and scalable navigation and sensor platform based on COTS components for high-end space applications. Beyond Gravity exploits the heritage gained in the development of several generations of spaceborne high-reliability GNSS receivers to establish a COTS-based platform to integrate GNSS with other sensors. The first instantiation of the platform is a high-performance multi-frequency GNSS receiver.

This project aims to enable 5G satellites nodes by extending terrestrial 5G network functions, protocols and SDN/MEC/edge computing and storage and distributed control and management concepts to space. Mechanisms to address the secure instantiation, control and management of the network functions on 5G satellite nodes will be addressed in order to enable optimised connectivity, coverage and capacity allocations.

Realise a K/Ka-band self-tracking antenna breadboard using state-of-the-art retrodirective antenna techniques. The retrodirective antenna allows the transmitted signal to be automatically sent back in the same direction as the received one without prior knowledge of the target position. The tracking is carried out in real time using hybrid analogue/digital processing without power hungry DSP tracking hardware.

This technology phase study aims to design, develop, manufacture and test an Advanced sliP Ring for hIgh vOltage Mechanism (APRIOM). This new generation of slip ring will be able to operate at voltages up to 400V, without electrical breakdown, allowing a considerable power gain and efficiency for the next generation of High Power spacecraft.

SATis5 aims to build a large-scale real-time live end-to-end 5G integrated satellite terrestrial network proof-of-concept testbed. The demonstrator testbed implements, deploys and evaluates an integrated satellite-terrestrial 5G network, showcasing the benefits of the satellite integration with the terrestrial infrastructures as part of a comprehensive communication system.

Relevant satellite use cases for 5G to be demonstrated in SATis5 include enhanced mobile broadband (eMBB) and massive machine type communications (mMTC). The SATis5 demonstrator covers live, over-the-air GEO and MEO satellite field demonstrations in addition to laboratory emulations and simulations in a federation of testbeds. The demonstrator is an open federation of resources that can integrate or incorporate additional resources and testbeds in the future providing a more diverse set of experiments and demonstrations.

Through its activities, HELENA supports the satellite communication community to engage with 3GPP in order to develop contributions and advocate positions favourable to the SatCom sector within the 3GPP standardisation process such that they result in tangible industrial opportunities.

The project gathers organizations from the satellite communication community each holding key positions in 3GPP and ETSI as contributors, rapporteurs of study items or chairmanship of Working Group.

Space based network infrastructure will very soon complement the terrestrial mobile networks that are currently being deployed based on 5G technologies standardised by 3GPP. This will allow satellite communications to become an integral part of the global telecommunications ecosystem strongly contributing to the UN Sustainable Development Goals for a better society and supporting sustainable growth for various industry sectors.

5G-COSMO project studied how to enable direct 5G satellite connectivity in smartphones. This feature is important for extending cellular network coverage significantly. Current and planned satellite systems together with smartphone capabilities were used as a starting point in analysis. Furthermore, technological gaps and challenges were identified based on which required technology roadmap was formed and over-the-air demonstration approaches identified.

SSC Space UK Ltd, with the support and cooperation of strategic partners from the rapidly developing “NewSpace” industry proposed to develop Global NewSpace Network Evolution (GNNetE) to offer an advanced technical solution capable of addressing the NewSpace industry constraints by delivering a more efficient, flexible, and economically viable ground segment and network operations solution.