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Tag: Directions 2016

  • Directions 2016: Galileo — strategic tool for European autonomy

    Directions 2016: Galileo — strategic tool for European autonomy

    Jeremie Godet, Galileo Implementation Head of Sector, European Commission (left); Fiammetta Diani, deputy head of Market Development, European GNSS Agency.
    Jeremie Godet, Galileo Implementation Head of Sector, European Commission (left); Fiammetta Diani, deputy head of Market Development, European GNSS Agency.

    By Jérémie Godet and Fiammetta Diani

    The Galileo programme is currently in its deployment phase, which is due for completion in 2020. Following declaration of initial services in 2016, an exploitation phase will start and aim at delivering a fully operational system by the end of 2020. The deployment and the exploitation are entirely financed through the budget of the European Union, while two non-EU members, Norway and Switzerland, contribute through international agreements.

    The aim of the Galileo programme is to establish and operate the first global satellite navigation system under the control of the European Union, thus contributing, amongst other things, to the strategic autonomy of the Union. This is the first time that the EU has developed, owned and been responsible for such a large-scale infrastructure.

    While independence is the main political objective, ensuring compatibility and interoperability with other existing and future systems is also critical. Indeed, frequency compatibility has been achieved with GPS, IRNSS, QZSS and COMPASS with a range of coordinations achieved in the last two years under the framework of the International Telecommunication Union (ITU). A wider international agreement was previously reached in 2004 between the U.S and the EU, achieving the compatibility and interoperability of their respective systems and resulting in a common modulation for both systems’ state-of-the-art open signals. A positive outcome of this for all GNSS users is that similar signals have been adopted by other global or regional systems, in particular the MBOC modulation jointly defined by the U.S. and the EU (Galileo, GPS, COMPASS, QZSS), the ALTBOC modulation adopted by COMPASS and a common signal in E6 adopted by QZSS.

    The Galileo programme will provide unique services, functionalities and performance levels that have never, or not yet, been provided by other satellites navigation providers.

    What Will Users Get, and When?

    These services, defined in consultation with user communities and EU Member States, will be offered by the system:

    • An Open Service (OS): With positioning accurate to around 1 meter using up to three different frequencies (E5a, E5b and L1), free of charge to the user and providing positioning and synchronization information intended mainly for high-volume satellite navigation applications;
    • A Public Regulated Service (PRS): Restricted to government-authorized users, for sensitive applications which require a high level of service continuity. It will use strong encrypted signals. This service is intended for security-related use for the EU Member States, the European Council, the European Commission, the European External Action Service and duly authorized Union agencies. It may be accessed by non-EU states and international organizations subject to bilateral agreements.
    • A contribution to the Search and Rescue Service (SAR) of the COSPAS-SARSAT system: Galileo’s worldwide search-and-rescue service will help to forward distress signals to a rescue coordination center by detecting emergency signals from beacons and relaying messages to them in near real time.
    • A contribution to integrity monitoring services by means of Galileo OS signals, in cooperation with other satellite navigation systems, aimed at users of safety-of-life applications in compliance with international standards;
    • A Commercial Service (CS): Encrypted for authentication purposes and offering very high accuracy to the sub-decimeter level, it will target applications for professional or commercial use owing to improved performance and data with greater added value than that obtained through the open service.

    As of 2016, Galileo will progressively offer initial services for the open service, search-and-rescue service and the public regulated service. Those initial services will be gradually improved, and the other two services will be gradually implemented, with the aim of reaching full operational capability by end 2020.

    The performance improvements of the services expected between 2016 and 2020 are linked to completion of the constellation deployment. In 2018, this will reach 24 satellites, the number required to achieve Galileo’s positioning performance targets, and the completed constellation with up to 30 satellites will be in place by the end of 2020 to provide the necessary spares to ensure performance commitments.

    On top of this, a number of additional capabilities are planned to be added to the core services, including:

    • An improvement of the OS nav message with full backward compatibility to enhance both the time-to-first-fix and the ability to perform signal acquisition and tracking for users in lower visibility conditions (INAV improvement);
    • An authentication of the OS navigation message allowing users to verify that a certain number of broadcast parameters are the actual Galileo data — aimed at applications requiring trusted position and timing information for commercial purposes;
    • An improvement of the PRS;
    • A new functionality within SAR that provides, via the navigation message, a Return Link Message to distress beacons acknowledging that a rescue center has received their distress signal.
    • Constellation Status

    The current Galileo constellation is composed of two different families of satellites: the In-Orbit-Validation (IOV) satellites procured before 2010 and the Full-Operational-Capability (FOC) satellites procured after 2010. Since the last Galileo launch on Sept. 10, there are four IOV satellites and six FOC satellites in orbit. The FOC satellites have improved capabilities regarding signal transmission compared to the IOV satellites, despite a similar mass and size. The FOC satellites carry a SAR payload; two IOV satellites have this capability. While this initial deployment faced a number of difficulties, these are now well behind us.
    Sixteen more FOC satellites are being built. The next launch of two FOC satellites is scheduled for Dec. 17, and four more launches (three Ariane 5 and one Soyuz) are foreseen from 2016 to mid-2018. This implies four to six satellites launched per year, and this is judged perfectly realistic as demonstrated already in 2015.

    An additional series of satellites will be procured in 2016 for deployment starting in late 2019/early 2020.

    Preparing to Use and Benefit

    The ultimate objective of the Galileo program is for its signals to be translated into valuable and reliable services for users across the globe. Europe aims to generate the return on investments in terms of public benefits for citizens and businesses, and for this reason the users are at center of the program.

    This is the focus of the European GNSS Agency (GSA), which is in constant dialog with user communities via a wide range of activities.

    For example, cooperation with chipset and receiver manufacturers aims to ensure that all products are Galileo-ready. This process involved a successful testing campaign done in cooperation with ESA and the EC’s Joint Research Centre (JRC). Equally important is to work closely with large user communities, such as road, maritime and rail, to support them in updating their systems so that they are ready to use Galileo. This is accomplished by dedicated market and technical support, via cost-benefit analyses, testing campaigns, initiation of standards and certification processes, user satisfaction surveys and more. These actions are part of tailored adoption roadmaps built with each user community. Periodic user fora are also organised to get feedback on current services and collect ideas for the evolution of the European GNSS systems.

    EU R&D programmes, such as Horizon 2020 for the development of Galileo applications as well as the recently launched Fundamental Elements program that focuses on funding European GNSS chipset and receiver technologies, are essential tools for preparing users and supporting EU competitiveness in the downstream sector.

    The GSA leverages these EU R&D programmes as a tool for adoption with large user communities and receiver manufacturers fully involved. The projects are managed by experienced staff specialised in different markets and application areas. In the case of PRS, the core user equipment technology is being designed and tested. This work is already paying off; today, a growing number of receivers available on the global market are Galileo-enabled, while almost 70 percent of the models have EGNOS.

    Among others, Europe’s ST Microelectronics in the automotive sector, and the U.S.’s Broadcom and the Taiwanese Mediatek in smartphones, have already announced their Galileo-ready chipsets. Many other chipset manufacturers are ready and tested for Galileo. It is expected that, with recent successful launches and the deployment schedule, most of them will bring their Galileo products to market in 2016.

    Galileo on the Horizon

    Despite its particularly challenging complexity, involving extensive technical and security requirements, Galileo deployment is now progressing well and services will be provided starting in 2016, to reach their full operational capability in 2020. One early benefit of interoperability with GPS is that even before the Galileo constellation is completed, the number of L5/E5a signals in space will allow meaningful use of that frequency for the first time. Galileo will deliver real advances in precision, availability, coverage and additional features unprecedented in any other satellite navigation systems to date: while GPS is today’s de facto standard, Galileo is aiming to be the world’s second GNSS reference system by 2020.

    Governance Set-up

    The European Commission (EC) has overall programme supervision and budget responsibilities. The EC delegates system design and infrastructure procurement to the European Space Agency (ESA) and service preparation, delivery and operations to the European GNSS Agency (GSA). ESA is one of founders of the Galileo system and has been responsible for the development phase, co-financed by the Member States of ESA and the EU. ESA is the procurement agent of core infrastructure and in charge of the overall system integration since 2007.

    The GSA’s role will grow considerably in the exploitation phase as it becomes the day-to-day interface with ESA in several areas, including infrastructure roll-out and maintenance. The GSA will procure main operations of the system from 2017 and will operate key services facilities such as the Galileo Security Monitoring Centre in France and the UK, the European GNSS Service Centre in Spain, and the Galileo Reference Centre in the Netherlands. The GSA also supports the enabling of receivers and chipsets for Galileo use and the development of applications in downstream segments, in close cooperation with the major user communities.

     

  • Directions 2016: A new stage for the development of BeiDou

    Directions 2016: A new stage for the development of BeiDou

    Shuren Guo, deputy director of China Satellite Navigation Project Center.
    Shuren Guo, deputy director of China Satellite Navigation Project Center.

    By Shuren Guo

    In line with its three-step development plan, the BeiDou Navigation Satellite System (BDS) will constitute a complete space constellation by around 2020, when it will be comprised of five geosynchronous orbit (GEO) satellites and 30 non-GEO satellites, providing services for global users. The year 2015 is of particular significance for the BDS establishment, which has witnessed stable operation of regional services and formal deployment of new-generation satellites. These satellites possess higher performance and better compatibility and interoperability with other navigation satellite systems.

    In March 2015, the first new-generation BDS satellite, or 17th BDS satellite overall, was launched at the Xichang Satellite Launch Center, and kicked off the deployment of the BDS global constellation. Launched and directly inserted into an inclined geo-synchronous orbit (IGSO) by a Long March launch vehicle with a newly designed upper stage, the satellite is equipped with a new bus system, as well as a payload system carrying inter-satellite links and new navigation signals.

    In July 2015, two mid-Earth orbit (MEO) BDS satellites, the 18th and 19th overall, were launched into their scheduled orbits precisely with one single launch vehicle. More new types of payloads are on board, and the satellite performance is dramatically improved. After the in-orbit-delivery, these two satellites are able to interconnect with other existing BDS satellites, and jointly carry out the experiment and verification of the global network deployment process.

    In September 2015, another BDS satellite was successfully launched into IGSO, and became the 20th of the BDS space constellation. Different from pervious launches, this satellite reached its designed orbit by using its built-in autonomous orbit maneuver mechanism. For the first time, the satellite also carries a Chinese-made hydrogen atomic clock, which provides enhanced time and frequency reference capacities.

    Currently, these last four launched satellites are in normal working mode. The ongoing in-orbit tests show that these satellites satisfy the desired requirements. At present, tests and validations for the new navigation signal system, inter-satellite links, and the new atomic clock are being conducted. Once the tests and validations are completed, these satellites will be included in the network, and start to provide services for global users.

    In 2016, BDS will keep improving its service performance. Three BDS satellites will be launched to boost up the deployment of global constellation. The construction of the BDS augmentation systems will be accelerated. Meanwhile, international cooperation activities will be further promoted, and the application development process will be attached with much importance, to broaden the fields and domains of BDS/GNSS applications.

    “To serve the world and benefit Mankind” is not only the purpose of BDS, but also its commitment to the world. On the basis of maintaining stable services, BDS will make all efforts to enhance the performance, to speed up the deployment of global constellation, and to provide better services for global users.

     

    Shuren Guo is the deputy director of China Satellite Navigation Project Center. He received his bachelor’s degree in electromagnetic theory and microwave engineering from Xi’an Jiaotong University, and his master’s in electronics and communication engineering from Beihang University. As a researcher, he has long been engaged in the design, research and development of the BeiDou Navigation Satellite System.

  • Directions 2016: GPS — dedicated to excellence

    Directions 2016: GPS — dedicated to excellence

    Col. Steve Whitney, director, Space and Missile Systems Center’s Global Positioning Systems Directorate.
    Col. Steve Whitney, director, Space and Missile Systems Center’s Global Positioning Systems Directorate.

    By Col. Steve Whitney

    The year 2015 was an exciting one to assume leadership of the Global Positioning Systems Directorate. I’ve witnessed the men and women of our team accomplish some amazing things, across all of our efforts to modernize the constellation, and would like to take a moment to share our progress over the past year and set the vision for 2016 as we remain dedicated to excellence.

    The past year has been another outstanding one in terms of delivering capability on-orbit. We’ve continued the pace from last year, placing another three new satellites into space, most recently including the launch of our 11th GPS IIF satellite, built by Boeing. This launch marks the 18th satellite to broadcast the Military Code (M-code) and second civil signals (L2C). Each time the dedicated professionals from government and industry, representing many, many organizations, have come together to show the world the gold standard.

    GPS III. In the development of our next generation of satellites, the GPS team continues to make progress. In September, we completed flight qualification of the navigation payload and its software — many of you recall that this area has been a challenge for us over the years, and I wanted to share this success. Additionally, the first GPS III satellite entered into thermal vacuum testing at prime contractor Lockheed Martin’s facility in Waterton, Colorado, in October.

    Thermal vacuum testing, or TVAC, is one of the last major events in the assembly and integration flow of the satellite and will prove out the hard work of the team. This first GPS III satellite is scheduled to be available for launch by the end of 2016. Lastly, we aren’t losing focus on the rest of the development units, as the second GPS III space vehicle is over 95 percent delivered and integrated at the GPS III processing facility.

    OCX. Over in the development of the ground segment, it’s no secret we’ve had very significant cost and schedule challenges in the development of the GPS next-generation system, OCX. Right now, we are engaging with both our industry partner, Raytheon, and the Department of Defense leadership to plot a way forward to deliver these much-needed capabilities. This effort is intended to improve both Positioning, Navigation, and Timing (PNT) capabilities and cyber-security posture in increasingly contested, congested and competitive space and cyber domains.

    User Equipment. The third area of our modernization efforts is our work on user equipment. Our military user equipment division continued to make acquisition history by pursuing a commercially driven strategy with all three contractors: L-3 Interstate Electronics Corporation, Rockwell Collins and Raytheon Space and Airborne Systems. They started the year by taking prototype cards to field exercises such as RED FLAG and are currently in full developmental testing of the functioning receiver cards. 2015 was an exciting year, and I’m proud to say 2016 will be no different.

    As we enter 2016, I’d like to reemphasize a challenge my predecessor Brig. Gen. Bill Cooley laid out in his 2015 Directions article, “What It Takes to Make a Gold Standard.” A challenge that GPS manufacturers worldwide innovate and build products that utilize modernized civil signals and the improved PNT capabilities brought by the Civil Navigation message. After all, in February 2016 we will launch the 19th satellite to broadcast M-code and L2C signals as well as the 12th satellite to broadcast the third civil signal, L5. With 19 satellites providing global coverage of L2C, it’s now up to industry to take advantage of these capabilities and pave the way towards modernized civil navigation.

    New Capabilities. For the first time in history, civil users will have access to what has been available to military users since the inception of GPS, full use of dual-signal frequency accuracy. This, combined with other advances, translates into increased PNT accuracy and resiliency for users worldwide. It’s time for the civil community to develop receivers that take advantage of these capabilities and usher in an era of more robust civil navigation.

    The February 2016 launch also marks the end of an era. It is the 12th and final GPS IIF satellite to launch, presenting a finale to one of the most aggressive launch campaigns in recent history: seven GPS IIF satellites in 21 months! This satellite is the last GPS satellite considered “second generation,” a generation that began operations in 1989.

    In total, Generation II GPS launches will have spanned over 28 years comprised of 61 space vehicles amongst five different blocks: II, IIA, IIR, IIR-M and IIF. Over these years, characteristics such as User Range Error (URE) have continuously improved, hallmarking the success of the GPS developers and operators past and present. In fact, from 2001 to 2014, URE was nearly cut in half, going from an annual average of 1.6 meters to just 0.7 meters for the civil user. These improvements will continue as we launch the next-generation GPS III satellites.

    In preparation for continued success into the future, 2016 will also be the year the GPS Directorate begins acquisition of GPS III space vehicles 11+. On July 3, 2015, the Office of the Secretary of Defense for Acquisition, Technology and Logistics approved the acquisition strategy for the GPS III space vehicles 11+ Production Readiness Feasibility Assessment to verify if capable GPS III production designs exist beyond the current GPS III contractor. The results of the GPS III Production Readiness Feasibility Assessment will shape and inform a GPS III space vehicles 11+ follow-on production acquisition strategy in the FY17 timeframe.

    Service. Also in 2016, the GPS Directorate will reaffirm our commitment to excellence and providing unparalleled service and capability. Challenges remain ahead, but the GPS Directorate is dedicated to delivering a ground system necessary for command and control of both today and tomorrow’s GPS enterprise. This includes the GPS Directorate’s pursuit of aggressive and innovative strategies to meet interim and future needs such as increasing the resiliency of the current ground system and investigating means for launching GPS III satellites as soon as possible so they are ready for operation at full capability with the completion of a modernized ground segment.

    Just this past year, we successfully accomplished several “hardening” efforts of the current ground system, adding to its robustness against the threats of today and tomorrow. Another endeavor we are working on is providing options to higher headquarters for the early use of M-code.

    The modernized GPS user equipment (MGUE) program will continue to pursue an innovative and aggressive acquisition strategy in 2016. Next year will kick off integrating receiver cards into service nominated lead platforms, which include the Defense Advanced GPS Receiver Distributed Device or D3, Joint Light Tactical Vehicle, Arleigh Burke-class Destroyer’s navigation system, and the B-2 Spirit. These efforts culminate with operational testing and eventually allow services to procure receiver cards directly. Over the next 12 months, the GPS Directorate also plans to begin work on a modernized GPS handheld, ensuring airmen, marines, soldiers and sailors have access to portable, accurate, and resilient position, navigation and timing powered by M-code. As MGUE is integrated into a myriad of DoD systems over the coming years, our users will continue to have the assured PNT needed to win today and tomorrow’s fight.

    Team. Finally, you can count on the professionals of GPS Directorate’s team to continue to exhibit acquisition excellence. It’s been six months since I assumed leadership of the GPS Directorate, and I am amazed every day with the passion and accomplishments of our people — which includes military, civilian, support contractors, federally funded research and development center partners and our industry partners. I feel privileged to work with each and every one of them on daily basis and look forward to what 2016 has in store for us all.

    A final thanks to you, the GPS user. With over 4 billion users and an ever growing-economic impact, you motivate us to continue to improve and assure this vital mission.