GPS World

Tag: Galileo Second Generation

  • Galileo G2 navigation payloads begin testing

    Galileo G2 navigation payloads begin testing

    Testing on Galileo’s second-generation hardware has begun.

    Test versions of the satellites’ navigation payloads is undergoing evaluation by Airbus Defence and Space at its Ottobrunn facility in Germany and by Thales Alenia Space at the ESTEC technical center in the Netherlands of the European Space Agency (ESA).

    Known as the Galileo Payload Testbeds (GPLTBs), these are development models of the navigation payloads intended for the Galileo Second Generation (G2) satellites. The navigation antennas of the testbed payloads are being testing to check whether they meet the ambitious performance levels set for the G2 satellites.

    Instead of being assembled from space-ready components like an actual satellite payload, the GPLTBs are built from electronic parts placed in test racks, with a proof-of-concept version of a navigation antenna attached.

    “The goal with these test campaigns is to prove their design concepts early, and anticipate any technical issues that might arise as early as possible,” said Cédric Magueur, ESA’s payload manager for the Thales G2 satellites.

    “These campaigns also make it possible to develop and validate new performance measurements concepts for these new generation of complex navigation payloads,” said Dirk Hannes, ESA’s payload manager for the Airbus G2 satellites. “This will allow us to optimize the production efficiency of the flight model series.”

    The second satellite in the European Data Relay System (EDRS) undergoes tests at Airbus's Compact Antenna Test Range facility. (Photo: ESA)
    The second satellite in the European Data Relay System (EDRS) undergoes tests at Airbus’s Compact Antenna Test Range facility. (Photo: ESA)

    “Results from the testing will feed into the up-coming Preliminary Design Review for the new satellites, backing up the analyses by the companies with solid measurements,” Cédric said. “Such early testing also supports the ambitious timescale for the development and construction of G2 satellites, with the first satellites planned to reach orbit by the middle of this decade.”

    There are 26 Galileo satellites now in orbit; deployment of 12 more will begin by the end of this year. Next will come the first 12 G2 satellites, featuring enhanced navigation signals and fully digital payloads. The new generation will be made up of two independent families of satellites meeting the same performance requirements, produced by Thales Alenia Space in Italy and Airbus Defence and Space in Germany.

    Airbus Defence and Space’s GPLTB is undergoing radiated testing at the company’s Ottobrunn facility, inside a Compact Antenna Test Range (CATR). Meanwhile, the Thales Alenia Space GPLTB is about to start testing inside ESTEC’s own Hybrid European Radio Frequency and Antenna Test Zone (Hertz) chamber. The metal-walled chambers are isolated from external radio interference, with inner walls studded with foam pyramids to minimize radio-frequency signal reflections, mimicking the void of space.

    “Up until now all GPLTB testing has taken place by plugging them into test boards,” Cédric said. “These test campaigns mark the first time that their performances will be confirmed in terms of radiating signals. In our first phase we will perform near-field measurements directly around the antenna to measure all the characteristics of the signal shape, to check it matches previous conductance tests. Then, via computation, we can derive its far-field performance.”

    In the second test phase, the actual far-field measurements will be performed using another feature of the chambers, a pair of paraboloid reflectors. In this way, the signal from the testbed can be reshaped as if it had traveled the long distance that actual Galileo signals need to travel, from an altitude of 23,222 km down to Earth’s surface.

    At Airbus, the testing is being undertaken in reverse order, with the far-field measurements taking place before performing the near-field measurements.

  • Orolia selected to deliver next-gen Galileo GNSS simulator

    Orolia selected to deliver next-gen Galileo GNSS simulator

    The European Commission and the European Space Agency (ESA) have selected Orolia to provide the core GNSS simulation engine for the Galileo Second Generation (G2G) RF Constellation Simulator (G2G RFCS).

    While the first launched Galileo satellites are reaching the end of their theoretical operational life, the G2G initiative includes the preparation of a future generation of Galileo global infrastructure, from satellites to ground segments, to maintain current services as well as provide improved performance and Required Navigation Performance (RNP) features to all users.

    In this context, Orolia has been selected to participate in the G2G RFCS activity, which will support G2G signals evolution requirements.

    The primary objective of the G2G RFCS initiative is to design, develop, manufacture and test an enhanced radio-frequency constellation simulator dedicated to Galileo engineering and experiments. This simulation technology will enable scientists and industries to verify, demonstrate and validate the future G2G configuration.

    To meet these requirements, Orolia will provide the core GNSS simulation engine based on its Skydel software technology, within a custom hardware configuration, to simulate all Galileo signals including Open Service (OS) and Public Regulated Service (PRS). Orolia’s GNSS simulators offer the high-end performance level and flexibility required to configure this new testing infrastructure in a software-defined solution.

    “With this project, Orolia demonstrates the Skydel platform’s exceptional flexibility to meet critical application requirements and serve as the core engine to design the next generation of GNSS signals,” said Orolia CEO Jean-Yves Courtois. “We are very proud to work with ESA, GMV and Tecnobit to help develop the next generation European Galileo constellation.”

    Image: ESA
    Image: ESA
  • Second-generation Galileo contract awarded to Thales

    Second-generation Galileo contract awarded to Thales

    Illustration: Thales Alenia Space
    Illustration: Thales Alenia Space

    Project will boost the positioning performance and real-time operability of the Galileo system.

    The European Space Agency (ESA) has selected Thales Alenia Space to support the implementation and experimentation of the navigation algorithms that will be used in the Galileo Second Generation program. Under the contract, Thales will develop the Advanced Orbit Determination and Time Synchronisation (ODTS) Algorithms Test Platform (A-OATP).

    Thales Alenia Space, a joint venture between Thales (67%) and Leonardo (33%), is the prime contractor for Galileo First Generation’s Ground Mission Segment,.

    ESA granted the contract on behalf of the European Commission in the Horizon 2020 Satellite Navigation Program (HSNAV).

    In a previous contract, Thales Alenia Space was chosen to provide six satellites and initiate the B2 phase of development and implementation of its ground segment for the Galileo Second Generation constellation.

    Using its long-standing legacy regarding navigation algorithms in addition to an innovative approach, Thales Alenia Space will develop and test a new Advanced ODTS solution. The new orbitography algorithms will allow a significant improvement in positioning performance and real-time operability of the Galileo system. It will exploit the accuracy of the GNSS orbit and clock estimation, with a solution optimized for the real-time generation of Galileo navigation messages, and take full advantage of the evolution of satellites and ground stations considered in the Galileo Second Generation.

    With this new contract, Thales Alenia Space applies on a deep experience concerning orbitography algorithms as well as knowledge of the Galileo system to strengthen its position as a major actor for the development of the new generation of this satellite system, the company stated in a press release.

  • ESA chooses GMV as 1 of 3 contractors for new phase of Galileo ground station

    ESA chooses GMV as 1 of 3 contractors for new phase of Galileo ground station

    The Galileo Second Generation will phase in of new services, improve existing services and increase security

    The technology multinational GMV is playing a key role in the Galileo Second Generation (G2G) ground segment.

    G2G’s main objectives are to phase in new services, improve existing services, and boost system robustness and security while cutting both operating and maintenance costs, to cement Galileo’s position as one the future’s top GNSS.

    Three phases. G2G is divided into several phases. In the first, led by the European Space Agency (ESA), mission requirements were defined at system level. This was followed by a preparation phase, then an implementation phase.

    As well as priming several mission-requirement projects, GMV, since 2018, has been heading one of the consortia working on G2G’s complete ground segment during the preparation phase.

    Within the preparation phase — shortly before the start of the COVID lockdown — ESA announced the successful end of the first phase before launching a bid invitation for the second phase as the prelude to G2G implementation.

    Although publication of the bid invitation for this phase was eventually pushed back until mid-June, GMV never broke off its G2G activities. In recent months GMV has brought new recruitments and partners into the project team while also working on new ideas and kicking off some project activities.

    Team members have attended various skills-training courses, some of them gaining certification under SAFe 5 Agilist. During these months, GMV has also been working under new pandemic circumstances with teleworking, virtual meetings and new toolboxes.

    First Generation. Galileo First Generation (G1G), running since December 2016, consists of space infrastructure (26 satellites to date) and ground infrastructure. Galileo is now providing 20-cm-precision positioning, navigation and timing services for over 400 million users around the world.

    The worldwide Galileo ground segment includes two control centers (Italy and Germany) as well as various tracking, uplink and sensor stations and monitoring and test centers. (Image: ESA)
    The worldwide Galileo ground segment includes two control centers (Italy and Germany) as well as various tracking, uplink and sensor stations and monitoring and test centers. (Image: ESA)
  • Galileo next-gen satellites to be more powerful, reconfigurable

    Galileo next-gen satellites to be more powerful, reconfigurable

    ESA shifts from Galileo transition plan to full second-generation plan.

    News from the European Space Agency

    With 26 satellites now in orbit and more than 1.5 billion smartphones and devices worldwide receiving highly accurate navigation signals, Europe’s Galileo navigation system will soon become even better, ensuring quality services over the next decades.

    Following the European Commission’s decision to accelerate development of Galileo Next Generation, ESA has asked European satellite manufacturers to submit bids for the first batch of the Galileo Second Generation (G2) satellites. The new spacecraft are expected to be launched in about four years.

    Paul Verhoef, director of the Galileo Programme addresses the audience at ESA's annual Navigation Days, held Jan. 26. (Photo: ESA)
    Paul Verhoef, director of the Galileo Programme. (Photo: ESA)

    The next-generation satellites will provide all the services and capabilities of the current first generation with a substantial improvements and new services and capabilities.

    “We want an ultra-flexible and mostly digital design,” said Paul Verhoef, ESA director of Navigation.

    “Developing the second generation is challenging for both industry and for ESA. In 2024, we need to launch the first satellites for this new state-of-the-art constellation.”

    Invitation to Tender

    Following almost 24 months of a competitive dialogue procedure with the three large system integrators involved, ESA issued a “Best and Final Offer” invitation to tender on Aug. 11 to Airbus, OHB System AG and Thales Alenia Space.

    ESA is implementing a dual-sourcing approach, and two parallel contracts are expected to be signed by the end of 2020 among the current three bidders. Under the plan, each of the two selectees will build two satellites for development purposes, with options for up to 12 satellites in total.

    The first satellites of the new constellation are expected to be launched before the end of 2024, together with updated ground systems to support the new satellites.

    Reconfigurable in Orbit

    In addition to being more powerful, the second-generation Galileo satellites will be more flexible, able to be reconfigured in orbit in order to satisfy the expected evolution in end-user needs.

    A number of challenges exist for the bidders. The goal of a digital and fully flexible design represents the cutting edge of industrial capability.

    Navigation Antenna Progress

    A Galileo satellite undergoes its fit-check validation at the Spaceport. Flight VA240. (Photo: ESA/Arianespace)
    A Galileo satellite undergoes its fit-check validation at the Kourou Spaceport in French Guiana. (Photo: ESA/Arianespace)

    Furthermore, the required navigation antennas will have a very advanced design; much research and development by ESA has been done, yet more remains for industry.

    ESA has already built such an antenna as a proof of concept at the Agency’s ESTEC technology center in the Netherlands to ensure feasibility, and the know-how has been shared with the three bidders.

    “Each bidder must determine how they can best manufacture the navigation antenna, and we’ll have to see how each proposes to do it. Also, requiring a fully flexible payload is quite a challenge. No such navigation spacecraft of that type have flown yet,” Verhoef said.

    Ambitious Plan

    The European Commission has decided that what was previously going to be called the “transition batch” of new satellites will now become, in fact, the Galileo Second Generation satellites. The European Commission and EU Member States have already made clear that they want to be very ambitious and further increase the technical capabilities of the Galileo system.

    The name change reflects of how the current batch is actually shaping up.

    The transition satellites were initially foreseen as interim upgrades, to cater for the potential risk of late delivery of the later, completely new and very advanced G2 satellites.

    Estimated Lifetime Increased

    Based on constant measurements of the performance of the current satellites in orbit, their predicted lifetime has increased. So, together with a slight spreading out of the launches of the Batch 3 satellites — currently under construction by OHB and in testing at ESTEC —this will ensure service continuity before the new, advanced capabilities of Galileo become operational.

    The second-generation satellites will gradually take over from the current first-generation satellites in the provision of Galileo services. At a future date, they will all constitute a complete constellation plus the necessary in-orbit spares.

    ESA serves as the design, development and procurement agent for Galileo satellites on behalf of the European Commission, which funds the system overall.