The R&S SMBV100A vector signal generator can generate Galileo, GPS, and GLONASS signals for up to 24 satellites in real time. With the SMBV-K107 option, the simulator covers the BeiDou standard as well.
The R&S SMBV-K101 option allows developers in the automotive and wireless communications industries to test GNSS receivers for specific effects such as obscuration and multipath propagation. If the GNSS receiver of a navigation instrument or smartphone is located inside a vehicle, testing must also take into account the obscuring effect of the vehicle’s metal body. The R&S SMBV-K102 option can simulate this obscuration and, if required, the additional antenna pattern.
In addition to test scenarios for A-GPS, smartphone developers have the Assisted Galileo (R&S SMBV-K67) and Assisted GLONASS (R&S SMBV-K95) options at their disposal.
A new defense market report from Strategic Defence Intelligence has been released. “The Global Military GPS/GNSS Market 2013-2023 – SWOT Analysis: Market Profile“ provides readers with an exhaustive analysis of industry characteristics, determining the strengths, weaknesses, opportunities and threats faced by the Military GPS/GNSS market.
This SWOT analysis of military GPS/GNSS market is designed for industry executives and anyone looking to gain a better understanding of the market. It utilizes a wide range of primary and secondary sources, which are analyzed and presented in a consistent and easily accessible format. SDI strictly follows a standardized research methodology to ensure high levels of data quality and these characteristics guarantee a unique report, the company said.
The report provides these features to readers:
Quickly enhance your understanding of the global Military GPS/GNSS market.
Gain insight into the marketplace and a better understanding of internal and external factors which could impact the industry.
Obtain an overview of the global Military GPS/GNSS market, with examples being provided for each section.
Swedish WTS (Wonder Technology Solutions) and u-blox have announced that WTS has launched Trax, a personal tracking device for children and pets. Based on u-blox’ GNSS smart antenna and cellular module, the tiny tracker can be located anywhere, anytime via a free Android or iPhone mobile phone app.
In addition to real time tracking, Trax provides flexible geofence alerts, and can even monitor how fast your teenager is driving. It also works indoors thanks to a proprietary dead reckoning algorithm that delivers a position even when satellites are out of sight. Accurate down to 1.5 meters, the robust, water-resistant device also provides an “augmented reality” mode that helps users locate their trackers using a Smartphone’s built-in camera view.
To achieve the smallest possible size, Trax takes advantage of u-blox’ CAM-M8Q GNSS receiver module, which has a built-in antenna. CAM-M8Q (chip antenna module) provides both small size (9.6 x 14.0 x 1.95 mm) and multi-GNSS capability. It is based on a u-blox M8 chip and incorporates a chip antenna, SAW filter, LNA, TCXO and RTC crystal. The surface-mount module is also extremely low in height, making thin customer designs possible.
“Trax is the world’s smallest and most versatile personal tracking device available, packed with features designed to provide peace of mind to parents and pet owners almost anywhere in the world,” said Fredrik Danelius, managing director at WTS. “By combining the leading GNSS and cellular technologies from u‑blox, we have designed a tiny, reliable, low-cost device that protects our most valuable family members: children and pets.”
Trax comes with an integrated SIM-card and two years of free data and roaming in 33 countries. It is charged via USB and typically lasts between two and four days on a full battery. For wireless connectivity, the device contains u‑blox’ SARA-G3 GSM/GPRS module which is footprint compatible with u-blox’ 3G SARA-U2 module for easy 2G to 3G upgrade.
“Trax is an elegant and sophisticated example of our embedded GNSS and cellular modules combined to protect people’s loved ones”, said Pasi Alajoki, area sales manager at u-blox. “It is an important application of our mobile communications and global positioning technology where performance, size and power consumption play a critical role. We are proud WTS chose u-blox for Trax.”
This month I am writing to you from Munich, where I have just attended the Munich Satellite Navigation Conference. I have written up the full Summit proceedings for GPS World’s new European GNSS & Earth Obersvation Report (EAGER) newsletter. You can read that (much longer) column here and while you’re at it, sign up for the new quarterly newsletter. What follows is an excerpt of it, specially focused on professional GNSS OEM interests.
I used to spend quite a lot of time in Munich working on a multi-national, multi-role fighter aircraft program, so returning for this year’s Munich Satellite Navigation Summit stirred some good memories for me. Held in the opulent Residenz Muenchen March 25-27, the conference always has a special atmosphere that these historic 1385 surroundings convey to the attendees.
Munich is in the Southern German state of Bavaria, and Bavaria has taken a real interest in the promotion and success of Galileo; witness the extensive Bavarian booth at recent European and North American GNSS conferences. Germany has, of course, been one of the principle nations providing significant funding for Galileo from its inception.
So with this backdrop, the summit brings together people involved with GNSS from around the world to report on the current status of GNSS and to relate how their participation in satellite navigation has progressed. And, of course, Europe, Germany, Bavaria and the European GNSS industry, which is now recognized around the world, all take the opportunity to present their capabilities and successes.
The first day’s session contained constellation updates from GPS, Galileo, Beidou and the UN International Committee on GNSS (ICG) — GLONASS delegates were notably absent. There was much speculation that they declined to attend due to the Crimean situation, and one U.S. delegate even inferred that they were “uninvited.” For the constellation updates, see the longer article referenced above.
Munich Highlights
A collection of examples of Bavarian GNSS innovations followed in a very interesting session led off by an overview of Business Incubation Centers and their collaboration with government agencies and research centers. Small business start-ups are apparently encouraged to apply during four annual time-slots, and receive two years’ incubation support and cash incentives. This has lead to 81 new ventures and has apparently been the source of the 1,000 new jobs mentioned by the Minister of Economic Affairs. The annual European Satellite Navigation Competition and Galileo Masters competition have also generated a whole bunch of ideas and concepts (8,000), some of which have found support through this incubation process.
Airbus Defence gave a short overview of the testing work it accomplished in supporting the first Galileo fix and has prepared several vehicle test platforms, ready to take the next phase of Galileo testing to the streets in realistic, real-world environments.
DLR provided insights into a number of its activities, namely:
Iono mapping
Signal distortion
Multipath
Jammer mitigation – adaptive antenna and processing
GNSS repeaters – how they can become unintentional jammers
Spoofer and Multipath inbvestigations
Antenna designs
GNSS evolution – Maser and clock combination benefits
Army University of Munich discussed radio science experiments in the Solar System and experiments using Mars Express (above) in polar orbit around Mars and resulting measurements of the moon Phobos. Internal and external outreach efforts with numerous organizations were also mentioned.
IFEN provided more down-to-Earth information on the on-going activities at the GATE ground-based pseudolite range, which has enabled realistic outdoors testing of Galileo receivers, well in advance of signals from orbiting satellites. Recent testing has now been able to include the four operating Galileo SVs on orbit with GATE pseudolite signals. GATE will continue to evolve over the next few years to keep up as more Galileo orbital signals come on-line.
Fraunhofer presented information on its 40-channel GPS/Galileo/GLONASS chip-receiver (above) – claiming 1-meter accuracy, low-cost, robust reliable position solution, small form-factor and low-power. Following PRS test-bed development efforts, Fraunhofer has now received a contract to also deliver 20 pre-operational Galileo PRS receivers for use in initial pilot projects.
GNSS Interference
Vidal Ashkenazi, in his inimitable form, lead a panel discussion on interference, jamming (in particular Personal Privacy Devices, or PPD) and spoofing, and coaxed his panel members to provide a whole bunch of information on what’s being done, mitigation capabilities and potential enforcement. Unlike all the other sessions, Vidal’s panel members didn’t use presentations, but rather responded to wide-ranging questions on the subject from the session chair. For a complete view of this, as well as a subsequent session on “Legal Impacts of Personal Privacy Devices (PPDs),” see the EAGER newsletter column.
Precise Point Positioning (PPP)
The group discussing PPP options consisted of the the European GNSS Agency (GSA, charged with exploitation of Galileo services), several principle industry service providers of PPP, and the federal agency, which provides PPP-like services in Germany.
The GSA presented its ideas concerning the provision of high-accuracy PPP corrections over the Galileo E6 signal – the so-called Commercial Service (CS). The intent, however, would not be to disrupt the commercial marketplace. Nevertheless, GSA is proposing a public-funded service to be sold to users within a market that is already well served by commercial worldwide service providers who charge users for cm-level PPP service.
And while Trimble made a polite presentation on the many levels of capabilities of its TerraSat services, as did Veripos and to some extent Fugro, it was clear that the commercial providers are not eager to find competition in their market from a government entity. NovAtel also chimed in on this conflict as it will be involved in Veripos/TerraStar, following its acquisition by Hexagon. Fugro appeared to be interested in acquiring rights to distribute CS on behalf of GSA.
The German federal agency promoted open data, source and standards from the IGS network to which it contributes: IGS is supported by numerous national agencies around the world. Orbit and clock PPP service is available 24/7 from multiple sources. However, the service is offered on a best efforts basis without a service guarantee, and cannot achieve the accuracies or convergence times of commercial services.
I talked subsequently with Michael Ritter, CEO of NovAtel, to learn the background to the Veripos/TerraStar acquisition. It’s clear that providing PPP services means added value to NovAtel when they sell receivers with PPP capability, so they will quickly discontinue offering Omnistar subscriptions and will shortly launch NovAtel Correct, offering Veripos (marine) and TerraStar (land) PPP subscription services. NovAtel is making significant inroads in the agriculture segment, and they see PPP service as an essential element of this and other businesses. The acquisition was worth something on the order of $200 million, so there is a vested interest in making these services pay and discouraging GSA entry into this market. Veripos will continue supplying other GNSS OEM receiver manufacturers — notably Septentrio, who use TerraStar services, now also NovAtel, and potentially another major GNSS manufacturer.
Future of GNSS in User Segment
Chaired by Greg Turetzky of Intel, this session opened the third day of the Summit. The presenters offered their concepts for current and future GNSS equipment and systems.
Stanford University outlined its work with FAA on an alternate PNT system to be used as a back-up to GNSS. It used to be that GNSS systems were designed to overcome space-weather effects and faults in equipment design or manufacture — nowadays, there are “bad guys” out there and we need to “protect, toughen and augment” these systems. Antennas can be built that impart a specific signature to the signals they transmit, and this may aid in finding and prosecuting the bad guys, but the main focus of work is development of a hybrid system using Distance Measuring Equipment (DME) and a pseudolite.
Tests have demonstrated good performance, and these prototype efforts could lead to aviation requirements (MOPS) development by 2018 and deployment by 2020.
Septentrio has been involved in Galileo since it began and was the first company with Galileo receivers. Nowadays, they have receivers fielded in multiple commercial applications, including machine control, maritime, aviation, automation, and measurement, delivering accuracies from a meter down to a centimeter. They will add E6 to their AsteRx family of multiple-channel, multi-frequency, multi-constellation receivers, and have developed a number of hardware and software mitigation techniques to combat jamming, interference and multipath, and to integrate receivers with inertial units for aiding.
Furuno is interested in resilient PNT for marine applications, and has examined the use of eLoran as an alternative to GPS, but has moved towards a system of radar beacons that detect radar pulses from passing ships and transmit their positions, enabling position determination. In tests, accuracies of around 2 meters have been obtained with two beacons.
Quascom’s approach is to add firewalls inside receivers, which toughen the processing and prevent distortion of position information. Quascom believes this will be necessary until authentication can be added into the GNSS system itself, so that any data received is validated and is known to be good.
Chris Rizos from the University of New South Wales, Australia, drew attention to the “holes” that exist in GNSS, and reviewed a number of possible “Band-Aid” fixes, such as Wi-Fi especially for indoor location. However, his solution seems to be to establish terrestrial networks transmitting GNSS-like signals.
Eurocontrol indicated that aircraft currently use inertial and DME extensively as a back-up to GNSS navigation. By 2030, there will be multiple constellations, and dual-frequency use should become commonplace in aviation, so GNSS navigation should be much more robust. Aircraft approaches are required to be in conformance with Required Navigation Performance (RNP), so would it be possible to develop RNP procedures for DME and inertial to be used as back-up during approaches in the event GNSS is disrupted?
To conclude the session, Airbus provided a “starter course” overview on inertial systems – how they work, the range of different types available, what they can achieve, costs, strengths and weaknesses and integration with GNSS.
The summit continued with subsequent sessions on:
Space technologies and users
GNSS monitoring of Earth and disaster management
Copernicus – Earth Observation
GNSS Education
Unfortunately, my deadline didn’t allow me to attend these equally interesting presentations.
There is also a manufacturers’ exhibit area at the summit that just fits into a couple of corridors near the main hall – around 20 booths. I talked with several of the manufacturers, including Spirent who has launched its latest GSS9000 multi-frequency-constellation simulator, with a four-fold increase in system iteration rate over the previous model. Exhibitors appeared to be pleased to be at the summit and by the level of interest shown by the attendees.
So, as this year’s Munich Summit concludes, where does this leave us? We’ve learned some new things about several GNSS topics and heard some interesting new concepts. Europe appears to be now focused on users and applications, to ensure there is market growth and use of Galileo. What stands out for me is the contrast between how European governments go about GNSS and how North America and the commercial world does the same thing without as much direct influence. This is nothing new, of course, it’s just the European way…
Alps Electric has developed the UMSZ2 Series multi-GNSS module for automotive use, providing support for multiple satellite positioning systems with a single module. Samples will be made available starting in April.
The module can receive signals from multiple GNSS, allowing simultaneous reception of signals from multiple positioning systems with the single unit. It is a surface mount module with dimensions of 25.0 × 20.0 × 2.6 mm. Also equipped with an internal antenna status detection circuit, as required for GNSS signal reception, the module helps to reduce the customer’s workload in designing and installing such circuits.
Alps Electric harnessed RF circuit and software design technologies built up over the years to optimize the UMSZ2 Series’ circuitry and create a single-package multi GNSS module. The time taken to acquire a position fix after turning on the system was also shortened, realizing the industry’s fastest time to first fix.
Furthermore, the UMSZ2 Series can operate off a single 3.3V power supply despite simultaneously receiving signals from multiple GNSS. Eliminating the need for a multiple power supply contributes to greater freedom in system design.
A dead-reckoning function for updating position information inside tunnels or in other areas where a signal is unavailable will also be added as an option.
Spirent Communications, provider of testing solutions for positioning and navigations systems, has introduced the Spirent GSS9000 Multi-Frequency, Multi-GNSS RF Constellation Simulator. The GSS9000 offers a new benchmark in performance, capability and flexibility that includes the ability to simulate signals from all GNSS and regional navigation systems.
The GSS9000 offers new levels of performance, enabled by a four-fold increase in RF signal iteration rate (SIR) over Spirent’s current GSS8000 product. The GSS9000 SIR is 1000Hz (1ms), enabling higher dynamic simulations with even more accuracy and fidelity, Spirent said. It also includes support for restricted and classified signals from the GPS and Galileo systems as well as advanced capabilities for ultra-high dynamics. The GSS9000 can evaluate resilience of navigation systems to interference and spoofing attacks.
GSS9000 has the flexibility to reconfigure constellations, channels and frequencies, between test runs or test cases. In addition, the GSS9000 has been designed to be backward compatible, enabling the use of existing test cases and remote control/motion from existing Spirent simulators. Hardware changes can now be done in the field, supported by the new on-board calibrator module.
“The GSS9000 raises the performance bar and addresses the future challenges of improving accuracy and resilience for end users of GNSS technology,” said Martin Foulger, managing director of Spirent’s Positioning division. “The GSS9000 solution is a result of almost thirty years of unrivalled expertise, innovation and leadership.”
The GSS9000 is extensible and can support the widest range of carriers, ranging codes and data streams for the GPS, GLONASS, Galileo and BeiDou GNSS systems as well as regional/augmentation systems. Multi-antenna/multi-vehicle simulation, for differential-GNSS and attitude determination, and interference/jamming and spoofing testing are also supported.
Galileo Growth, Constellation Updates, and Jamming
I used to spend quite a lot of time in Munich working on a multi-national, multi-role fighter aircraft program, so returning for this year’s Munich Satellite Navigation Summit stirred some good memories for me.
Held in the opulent Residenz Muenchen March 25-27, the conference always has a special atmosphere that these historic 1385 surroundings convey to the attendees. The former royal palace of Bavarian monarchs, the whole complex has ten courtyards and 130 rooms. The summit was held in the Max-Joseph Hall, which took a little bit of work to find at first, wandering around the huge complex. One wing of the building hosts a theater, and the mainhall is the primary concert venue for the Bavarian Radio Symphony Orchestra. Overall, this is a delightful setting.
Munich is in the Southern German state of Bavaria, and Bavaria has taken a real interest in the promotion and success of Galileo; witness the extensive Bavarian booth at recent European and North American GNSS conferences. Germany has, of course, been one of the principle nations providing significant funding for Galileo from its inception.
Ilse Aigner
So with this backdrop, the summit brings together people involved with GNSS from around the world to report on the current status of GNSS and to relate how their participation in satellite navigation has progressed. And, of course, Europe, Germany, Bavaria and the European GNSS industry, which is now recognized around the world, all take the opportunity to present their capabilities and successes.
The plenary session on the first evening covered GNSS, Earth Observation (EO) and Telecommunications — with the panel headed by Ilse Aigner, Bavarian State Minister of Economic Affairs and Media, Energy and Technology — an extensive mandate, even for a state-certified engineer who used to work for Eurocopter.
Dr. Merith Niehuss, speaking at the opening of the summit. (copyright: Munich Satellite Navigation Summit).
The host of the summit is actually the University of the German Army in Munich, and we received a warm welcome from two leading professors: Dr. Bernd Eissfeller and Dr. Merith Niehuss, the president. The theme of the summit was to move from implementation to utilization, and in typical European form, all parties were looking to shower potential users with funded solutions to problems of which users are not yet aware — so users clearly need government-provided education, pilot projects and funding. Not exactly a North American concept, where we tend to encourage users to buy our innovative stuff by demonstrating how it can save them money or earn them more revenue.
The European Commission, ESA, DLR, European GNSS Agency (GSA), Airbus, OHB, and Telespazio were also represented. The minister did indeed associate with and praise the local area, claimed 1,000 jobs created related to Galileo through an incubation center at Oberpfaffenhofen, and declared Bavarian support for satellite navigation.
Other important things mentioned by the panel at the plenary included an €11B budget for Galileo/EGNOS and Copernicus (EO project) under the Horizon 2020 program, and an intent to declare Early Service for Galileo before the end of this year with two or three dual Galileo satellite launches — the first two FOC (production) SVs should go to the European launch center in Kourou in April in preparation for launch around June. I heard in a corridor that launches may be planned for June, October and December, but an EU spokesman later said that there would only be two launches this year. OHB now has the contract to build 22 FOC Galileo SVs, each with a design life of 14 years, and they are bullish on their ability to deliver on time and budget.
The program continued the following day with constellation updates from GPS, Galileo, Beidou and the UN International Committee on GNSS (ICG) — GLONASS delegates were notably absent. There was much speculation that they declined to attend due to the Crimean situation, and one U.S. delegate even inferred that they were “uninvited.”
Constellation Updates
GPS: It’s estimated that there are ~2B GPS receivers in use, and there may be ~10B by 2020. A return on investment (ROI) analysis is currently underway, but a rough guess is that costs are in the tens of billions, while annual returns are of the order of $60-100B/year. Another IIF satellite (SV) launched last month, bringing the total to five SVs transmitting L1, L2C and L5, with seven more to come, and multiple launches are expected this year. There are 30 operational SVs on orbit, signal performance significantly exceeds the specs, and consistent, dependable performance has been provided for more than 20 years.
Galileo: First fix was achieved March 12, 2013, with four SVs, two (maybe three?) launches of two SVs each planned for 2014, and early operational capability to be declared by end of this year. €7B in funding is provisioned for 2014-2020, with 16-24 operational ground stations, Commercial Service (CS) planned by 2016 (more on this later), and a long-term evolution plan being worked up during this year.
BeiDou: Fourteen SVs are on orbit — five GEO, four MEO and five Inclined Geosynchronous Orbit (IGOS) satellites, providing dual-frequency services. Thirty total SVs are planned, and the intent is to provide open, compatible, interoperable signals with other GNSS free of charge. There was not much other news to report, other than that China intends to invest significantly in BeiDou to keep improving services.
United Nations ICG: Nine nations and European Union = International Committee on GNSS (ICG), with 20 other associate and observer States. Activities include GNSS compatibility/interoperability, GNSS enhancements, information sharing, and reference frames, timing and applications — lots of upcoming meetings and activities.
Regional and Augmentation Updates
WAAS: Phase IV is underway with GEO replenishment begun, introduction of L5 to replace L2, and replacement of obsolete component parts. One hundred GIII receivers were ordered with L1/L2C and L5 capability for delivery by September this year — and have capacity to also add Galileo. GIII receivers have already been fielded in six locations as part of initial integration testing. The Safety computer will also be upgraded starting this year. 3,912 LP/LPV approaches have been approved, of which 3,379 LPVs serve 1,667 airports. GBAS CAT I is progressing with four U.S. airport installations. System design approval began in January this year, and United Airlines has begun equipping over 90 B737/B787 for GPS approach and landing. Alternative Positioning, Navigation and Timing (APNT) investigations are underway (as a backup to GPS) with a hybrid DME-pseudolite configuration currently favored. Stanford University subsequently presented this and other concepts.
EGNOS: A €1.58B budget has been approved, and EGNOS V3 evolution is underway, with L1/L5 and GEO (SES 5 and Astra 5B) replenishment, a requirement to expand East and West and to the North to provide full coverage to all EU States.
About 100 EGNOS LPV approaches are approved — this year, it’s hoped to add 150 more.
QZSS: The operational concept has been proven with the first IGOS SV (Michibiki), so Japan is moving forward quickly to add another three SVs (3xIGOS and 1xGEO) and ultimately would like to have a total of seven SVs in orbit providing QZSS services. L1/L1C/L2C/L5 signals are identical to GPS, and L1s/L5s are augmentation signals, while L6 is proposed to be similar to Galileo E6, providing centimeter-level PPP-type service. QZSS essentially is intended to provide higher elevation satellites to improve urban navigation in dense cities.
IRNSS: Coverage extends 1500 km beyond India. The target is <20-meter accuracy, and signals are in L5 and S band and can be used independently or in dual-frequency combinations. A second IRNSS-1B GEO satellite is scheduled to launch on April 4.
GAGAN: The Indian SBAS was commissioned and certified in February this year with a number of ground stations, redundant uplinks and two on-orbit GSAT 8 and 10 GEOs. Gagan is now qualified to provide RNP0.1 (navigation accuracy to 0.1 miles).
QZSS and Japan’s Space Policy
This session provided some detail on how changes in Japan’s Basic Space Law has lead to efforts to expand the use of space and derive further economic benefits that this provides.
Munich Highlights
A collection of examples of Bavarian GNSS innovations followed in a very interesting session led off by an overview of Business Incubation Centers and their collaboration with government agencies and research centers. Small business start-ups are apparently encouraged to apply during four annual time-slots, and receive two years’ incubation support and cash incentives. This has lead to 81 new ventures and has apparently been the source of the 1,000 new jobs mentioned by the Minister of Economic Affairs. The annual European Satellite Navigation Competition and Galileo Masters competition have also generated a whole bunch of ideas and concepts (8,000), some of which have found support through this incubation process.
Airbus Defence gave a short overview of the testing work it accomplished in supporting the first Galileo fix and has prepared several vehicle test platforms, ready to take the next phase of Galileo testing to the streets in realistic, real-world environments.
DLR provided insights into a number of its activities, namely:
Iono mapping
Signal distortion
Multipath
Jammer mitigation – adaptive antenna and processing
GNSS repeaters – how they can become unintentional jammers
Spoofer and Multipath inbvestigations
Antenna designs
GNSS evolution – Maser and clock combination benefits
Army University of Munich discussed radio science experiments in the Solar System and experiments using Mars Express (above) in polar orbit around Mars and resulting measurements of the moon Phobos. Internal and external outreach efforts with numerous organizations were also mentioned.
IFEN provided more down-to-Earth information on the on-going activities at the GATE ground-based pseudolite range, which has enabled realistic outdoors testing of Galileo receivers, well in advance of signals from orbiting satellites. Recent testing has now been able to include the four operating Galileo SVs on orbit with GATE pseudolite signals. GATE will continue to evolve over the next few years to keep up as more Galileo orbital signals come on-line.
Fraunhofer presented information on its 40-channel GPS/Galileo/GLONASS chip-receiver (above) – claiming 1-meter accuracy, low-cost, robust reliable position solution, small form-factor and low-power. Following PRS test-bed development efforts, Fraunhofer has now received a contract to also deliver 20 pre-operational Galileo PRS receivers for use in initial pilot projects.
GNSS Interference
Vidal Ashkenazi, in his inimitable form, lead a panel discussion on interference, jamming (in particular Personal Privacy Devices, or PPD) and spoofing, and coaxed his panel members to provide a whole bunch of information on what’s being done, mitigation capabilities and potential enforcement. Unlike all the other sessions, Vidal’s panel members didn’t use presentations, but rather responded to wide-ranging questions on the subject from the session chair.
David Turner, representing the U.S. State Department, indicated that the ICG will meet shortly in Geneva hosted by the International Telecommunication Union (ITU) to focus on interference, jamming and mitigation. The recourse that nations have for use of PPDs by their people is the law — jammers are illegal, sale and purchase of them is illegal — however, Internet sales are very difficult to police. So detection and mitigation are required to find and shut them down. Dave’s presentation on the GPS.gov website indicates that the ICG is working on an education program for states to inform about GNSS sensitivity to interference and the threat to critical infrastructure if they are allowed to operate. The ICG also has a task force on detection, reporting and systems development.
ISRO indicated that PPD jammers in India are restricted, but permitted for gatherings such as at churches where personal safety may be an issue. Ground-based detection is needed, as well as stronger legal protection that may well prohibit use of PPDs altogether.
Japan Aerospace Exploration Agency (JAXA) indicated that it is working on “signal proofing” for QZSS.
BeiDou said it is building a monitor network in China that will detect jamming.
There was a general discussion on whether receiver manufacturers should be mandated to make receivers that are resilient to jamming – many thought that there have already been significant advances in that direction by manufacturers. The normal approach would be to develop requirements with industry, agency and user inputs, publish them, and call up the requirements in equipment specifications. In the U.S., the Department of Homeland Security is seeking an approach to detection and location.
Legal Impacts of Personal Privacy Devices (PPDs)
While the audience may have had high hopes that the legal eagles could come up with some magic prevention and prosecution solution, the next session was more of a legal background briefing without any concrete conclusions (quite similar to other discussions I’ve had with some lawyers in the past, actually).
The first briefing was from the European Commission/European Union, who indicated that the EU doesn’t own the frequency rights to Galileo (Oh Oh…). They have to operate through a member state, which gets the rights through the International Telecommunication Union (ITU) and then licenses use to the EU — the bottom line being that EU enforcement of jamming protection laws maybe be difficult, as the legal framework only exists at the national level for each state. The EU is trying to get recognition under another class of ITU membership.
EU regulations were presented that state that GNSS re-transmitters can only be operated legally by governments or government contractors. Or can be used indoors for indoor navigation, but only for emergency services at fixed sites which are pre-approved. Pseudolites can only be operated indoors, and there should be no interference to other systems. Jammers are forbidden and cannot be placed on the market for sale.
Eurocontrol had a lot to say about the impact on aviation navigation infrastructure and receivers on aircraft. Existing ground nav aids have limitations, the worldwide equipment infrastructure is becoming quite old — aviation has generally moved away to GNSS and inertial based navigation and uses ground navaids as backup. There is a conflict between regulating GNSS heavily for aviation and how people want to use it in the commercial world. We may have to consider a trade-off between heavily restricted GNSS operations, and wide open commercial GNSS applications.
David Sobel, from Electronic Frontier Foundation in the U.S., presented the contrary case for individual privacy. His argument is that sale of tracking devices is unregulated and can readily be purchased, so people may presumably use them to track others, thereby infringing their privacy. So why shouldn’t people be able to “defend their privacy” by use of PPDs?
Say an employer insists that a vehicle you are driving have a tracking device so he knows where you are. Isn’t the driver also justified in trying to protect his privacy? Since the police in the U.S. can no longer place tracking equipment on suspect vehicles without a warrant, tracking appears to be down to private individuals or companies, who it would appear, have the legal ability to attach tracking devices under most circumstances. So the argument goes that if people have a legitimate concern about privacy, there should be acceptable provisions to allow them to disrupt tracking.
If there is a service such as road tolling, there is an incentive for people to avoid these costs. So systems should be robust enough to avoid disruption. Enforcement is a problem — should police chase people they suspect have jammers, or should they rather chase criminals or help and protect citizens? Mitigation systems need testing, so to test these systems there has to be jamming transmission — which needs to be controlled and regulated. Restricting the import of bad devices into a country might be desired, but the manufacturing countries don’t tend to want to restrict exports as exports help their economy. Again, the argument seems to be that of personal privacy over potential risks and damages to society.
No solutions, but a healthy discussion of views from a legal perspective.
Precise Point Positioning (PPP)
The group discussing PPP options consisted of the GSA (charged with exploitation of Galileo services), several principle industry service providers of PPP, and the federal agency, which provides PPP-like services in Germany.
The GSA presented its ideas concerning the provision of high-accuracy PPP corrections over the Galileo E6 signal – the so-called Commercial Service (CS). The intent, however, would not be to disrupt the commercial marketplace. Nevertheless, GSA is proposing a public-funded service to be sold to users within a market that is already well served by commercial worldwide service providers who charge users for cm-level PPP service.
And while Trimble made a polite presentation on the many levels of capabilities of its TerraSat services, as did Veripos and to some extent Fugro, it was clear that the commercial providers are not eager to find competition in their market from a government entity. NovAtel also chimed in on this conflict as it will be involved in Veripos/TerraStar, following its acquisition by Hexagon. Fugro appeared to be interested in acquiring rights to distribute CS on behalf of GSA.
The German Federal agency promoted open data, source and standards from the IGS network to which it contributes: IGS is supported by numerous national agencies around the world. Orbit and clock PPP service is available 24/7 from multiple sources. However, the service is offered on a best efforts basis without a service guarantee, and cannot achieve the accuracies or convergence times of commercial services.
I talked subsequently with Michael Ritter, CEO of NovAtel, to learn the background to the Veripos/TerraStar acquisition. It’s clear that providing PPP services means added value to NovAtel when they sell receivers with PPP capability, so they will quickly discontinue offering Omnistar subscriptions and will shortly launch NovAtel Correct, offering Veripos (marine) and TerraStar (land) PPP subscription services. NovAtel is making significant inroads in the agriculture segment, and they see PPP service as an essential element of this and other businesses. The acquisition was worth something on the order of $200 million, so there is a vested interest in making these services pay and discouraging GSA entry into this market. Veripos will continue supplying other GNSS OEM receiver manufacturers — notably Septentrio, who use TerraStar services, now also NovAtel, and potentially another major GNSS manufacturer.
Future of GNSS in User Segment
Chaired by Greg Turetzky of Intel, this session opened the third day of the Summit. The presenters offered their concepts for current and future GNSS equipment and systems.
Stanford University outlined its work with FAA on an alternate PNT system to be used as a back-up to GNSS. It used to be that GNSS systems were designed to overcome space-weather effects and faults in equipment design or manufacture — nowadays, there are “bad guys” out there and we need to “protect, toughen and augment” these systems. Antennas can be built that impart a specific signature to the signals they transmit, and this may aid in finding and prosecuting the bad guys, but the main focus of work is development of a hybrid system using Distance Measuring Equipment (DME) and a pseudolite.
Tests have demonstrated good performance, and these prototype efforts could lead to aviation requirements (MOPS) development by 2018 and deployment by 2020.
Septentrio has been involved in Galileo since it began and was the first company with Galileo receivers. Nowadays, they have receivers fielded in multiple commercial applications, including machine control, maritime, aviation, automation, and measurement, delivering accuracies from a meter down to a centimeter. They will add E6 to their AsteRx family of multiple-channel, multi-frequency, multi-constellation receivers, and have developed a number of hardware and software mitigation techniques to combat jamming, interference and multipath, and to integrate receivers with inertial units for aiding.
Furuno is interested in resilient PNT for marine applications, and has examined the use of eLoran as an alternative to GPS, but has moved towards a system of radar beacons that detect radar pulses from passing ships and transmit their positions, enabling position determination. In tests, accuracies of around 2 meters have been obtained with two beacons.
Quascom’s approach is to add firewalls inside receivers, which toughen the processing and prevent distortion of position information. Quascom believes this will be necessary until authentication can be added into the GNSS system itself, so that any data received is validated and is known to be good.
Chris Rizos from the University of New South Wales, Australia, drew attention to the “holes” that exist in GNSS, and reviewed a number of possible “Band-Aid” fixes, such as Wi-Fi especially for indoor location. However, his solution seems to be to establish terrestrial networks transmitting GNSS-like signals.
Eurocontrol indicated that aircraft currently use inertial and DME extensively as a back-up to GNSS navigation. By 2030, there will be multiple constellations, and dual-frequency use should become commonplace in aviation, so GNSS navigation should be much more robust. Aircraft approaches are required to be in conformance with Required Navigation Performance (RNP), so would it be possible to develop RNP procedures for DME and inertial to be used as back-up during approaches in the event GNSS is disrupted?
To conclude the session, Airbus provided a “starter course” overview on inertial systems – how they work, the range of different types available, what they can achieve, costs, strengths and weaknesses and integration with GNSS.
The summit continued with subsequent sessions on:
Space technologies and users
GNSS monitoring of Earth and disaster management
Copernicus – Earth Observation
GNSS Education
Unfortunately, my deadline didn’t allow me to attend these equally interesting presentations.
There is also a manufacturers’ exhibit area at the summit that just fits into a couple of corridors near the main hall – around 20 booths. I talked with several of the manufacturers, including Spirent who has launched its latest GSS9000 multi-frequency-constellation simulator, with a four-fold increase in system iteration rate over the previous model. Exhibitors appeared to be pleased to be at the summit and by the level of interest shown by the attendees.
So, as this year’s Munich Summit concludes, where does this leave us? We’ve learned some new things about several GNSS topics and heard some interesting new concepts. Europe appears to be now focused on users and applications, to ensure there is market growth and use of Galileo. What stands out for me is the contrast between how European governments go about GNSS and how North America and the commercial world does the same thing without as much direct influence. This is nothing new, of course, it’s just the European way…
The Munich Satellite Navigation Summit annually gathers people involved with GNSS from around the world to report on current status and progress of the multiple systems. It is a high-level briefing of significant global importance. Of course Europe, Germany, Bavaria, and the European GNSS industry, now recognized around the world, all take the opportunity to present their capabilities and successes.
This year’s Summit covered a lot of ground, and I’ve tried to do it justice in this column. For an overview, here are the main topics covered in what follows:
Opening Plenary
Constellation Updates
Regional and Augmentation Updates
Bavarian Highlights
GNSS Interference
Legal impacts of Personal Privacy Devices (PPDs)
Precise Point Positioning (PPP)
Future of GNSS in the User Segment
I used to spend quite a lot of time in Munich working on a multi-national, multi-role fighter aircraft program, so returning for this year’s Summit stirred some good memories for me.
Held in the opulent Residenz Muenchen, the conference derives a special atmosphere from these historic surroundings, some dating back to 1385. The former royal palace of Bavarian monarchs, the labyrinthine palace has ten courtyards and 130 rooms. Overall, this is a delightful setting.
Regional Flavor. Munich is in the southern German state of Bavaria, and Bavaria has taken a real interest in the promotion and success of Galileo; witness the expansive Bavarian booth at recent European and North American GNSS conferences, and the siting of a Galileo control center in Oberpfaffenhoffen, once a sleepy village in the Bavarian countryside 20 kilometers outside Munich, but now a significant high-tech research center with many aerospace facilities. Germany has of course been one of the lead nations funding Galileo from its inception.
Opening Plenary: A View from the Top
The host of the Summit is actually the University of the German Federal Army in Munich, and we received a warm welcome from two leading professors – Dr. Eissfeller and Dr. Niehuss, the president.
The theme of the Summit is to move from implementation to utilization, and in typical European form, all parties were looking to shower potential users with funded solutions to problems of which users are not yet aware — so users clearly need government-provided education, pilot projects, and funding. Not exactly a North American concept, where we tend to encourage users to buy our innovative stuff by demonstrating how it can save them money or earn them more revenue. But there’s a city called Rome over here . . .
The opening plenary session covered GNSS, Earth Observation (EO) and Telecommunications — an extensive mandate — with a panel headed by Ilse Aigner, Bavarian State Minister of Economic Affairs and Media, Energy and Technology, an equally extensive portfolio, even for a state-certified engineer who used to work for Eurocopter.
The European Commission, the European Space Agency (ESA), the German Aerospace Agency (DLR), the European GNSS Agency (GSA), and leading manufacturers Airbus, OHB (providers of the Galileo full-operational capability (FOC) satellites), and Telespazio were also represented. The Minister did indeed associate with and praise the local area, claimed 1,000 jobs created related to Galileo through an incubation center at Oberpfaffenhofen, and declared whole-hearted Bavarian support for satellite navigation.
Among important matters mentioned by the plenary panel:
an €11 billion budget for Galileo/EGNOS and Copernicus (an EO project) under the Horizon 2020 program;
an intent to declare Early Service for Galileo before the end of this year with two or three dual Galileo satellite launches.
Two Launches this Year. The first two FOC (production) SVs should go to the European launch center in Kourou in April in preparation for launch around June. I heard in a corridor that launches may be planned for June, October and December, but an EU spokesman later said that there would only be two launches this year. OHB now has the contract to build 22 FOC Galileo SVs, each with a design life of 14 years, and they are bullish on their ability to deliver on time and budget.
Constellation Updates
GPS. An estimated 2 billion GPS receivers are in use, and there may be ~10 billion by 2020. A return-on-investment (RoI) analysis is currently underway, but a rough guess is that costs are in the tens of $Billions, while annual returns are of the order of $60–100B/year. Another IIF satellite (SV) launched last month brought the total to 5 SVs transmitting L1, L2C, and L5 – with 7 more to come, and multiple launches are expected this year. There are 30 operational SVs on orbit. Signal performance significantly exceeds the specs, and consistent, dependable performance has been provided for more than 20 years.
Galileo. First fix achieved 12 March, 2013 with four SVs, two (maybe three?) launches of two SVs each planned for 2014 & early operational capability to be declared by end of this year. €7B funding provisioned for 2014-2020, 16-24 operational ground stations, Commercial Service (CS) planned by 2016 (more on this later), and a long-term evolution plan is being worked up during this year.
BeiDou. 14 SVs are on orbit: 5 geosynchronous orbit (GEO), 4 mid-Earth orbit (MEO) similar to GPS and other GNSS birds, and 5 inclined geosynchronous orbit (IGSO), together providing dual-frequency services. 30 total SVs are planned, and the intent is to provide open, compatible, interoperable signals with other GNSS, free of charge. There was not much other news to report, other than China intends to invest significantly in BeiDou to keep improving services.
GLONASS. Russian delegates were notably absent, and there was much speculation that they declined to attend due to the Crimean situation. One U.S. delegate even inferred that they were ‘un-invited.’
United Nations ICG. Nine nations and the European Union = International Committee on GNSS (ICG), with 20 other associate and observer states. Activities include GNSS compatibility/interoperability, GNSS enhancements, information sharing, and reference frames, timing & applications – lots of upcoming meetings and activities (see associated story).
Regional & Augmentation Updates
WAAS (the U.S. Wide Area Augmentation System). Phase IV is underway with GEO replenishment begun, introduction of L5 to replace L2, and replacement of obsolete component parts. 100 GIII receivers were ordered with L1/L2C and L5 capability for delivery by September this year– and have capacity to also add Galileo. GIII receivers have already been fielded in six locations as part of initial integration testing. The Safety computer will also be upgraded starting this year. 3,912 LP/LPV approaches have been approved, of which 3,379 LPVs serve 1,667 Airports.
GBAS CAT I is progressing with four US airport installations, system design approval began in January this year, and United Airlines has begun equipping more than 90 B737/B787 for GPS approach and landing. Alternative Positioning, Navigation and Timing (APNT) investigations are underway (as a backup to GPS) with a hybrid DME-pseudolite configuration currently favored. Stanford University subsequently presented this and other concepts.
EGNOS (the European Geostationary Navigation Overlay Service). €1.58B budget approved, EGNOS V3 evolution is underway – introduction of L1/L5 and GEO (SES 5 and Astra 5B) replenishment, a requirement to expand East and West and to the North to provide full coverage to all EU States.There are ~100 EGNOS LPV approaches approved, this year it is hoped to add 150 more.
QZSS (Japan’s Quasi-Zenith Satellite System). Operational concept has been proven with 1st IGSO SV (Michibiki), so Japan is moving forward quickly to add another 3 SVs (3xIGSO and 1xGEO) and ultimately would like to have a total of seven SVs in orbit providing QZSS services. L1/L1C/L2C/L5 signals are identical to GPS and L1s/L5s are augmentation signals, while L6 is proposed to be similar to Galileo E6, providing cm level PPP type service. QZSS essentially is intended to provide higher-elevation satellites to improve urban navigation in dense cities.
IRNSS (Indian Regional Navigation Satellite System). Coverage extends 1500 kilometers beyond India’s land area, target is <20m accuracy, signals are in L5 and S band and can be used independently or in dual frequency combinations. A 2nd IRNSS-1B GEO satellite is scheduled to launch on April 4th.
GAGAN – The Indian SBAS was commissioned and certified in February this year with a number of ground stations, redundant uplinks and two on-orbit GSAT 8 & 10 GEOs. Gagan is now qualified to provide RNP0.1 (navigation accuracy to 0.1 miles).
Bavarian Highlights
A collection of examples of Bavarian GNSS innovations followed in a very interesting session led off by an overview of Business Incubation Centers and their collaboration with government agencies and research centers. Small business start-ups are encouraged to apply during four annual time-slots, and receive two years’ incubation support and cash incentives. This has lead to 81 new ventures and has apparently been the source of the 1,000 new jobs mentioned by the Minister of Economic Affairs.
The annual European Satellite Navigation Competition and Galileo Masters competition have also generated a large number of ideas and concepts (8,000), some of which have found support through this incubation process.
Airbus Defence gave a short overview of the testing work they accomplished in supporting the first Galileo fix. The company fix has prepared several vehicle test platforms, ready to take the next phase of Galileo testing to the streets in realistic, real-world environments.
DLR provided insights into a number of their activities, namely: Iono mapping; signal distortion; multipath; jammer mitigation – adaptive antenna and processing; GNSS repeaters – how they can become unintentional jammers; spoofer and multipath investigations; antenna designs; GNSS evolution – maser and clock combination benefits.
IFEN provided information on the activities at the GATE ground-based pseudolite range, which has enabled realistic outdoors testing of Galileo receivers, well in advance of signals from orbiting satellites. Recent testing has now been able to include the four operating Galileo SVs on orbit with GATE pseudolite signals. GATE will continue to evolve over the next few years to keep up as more Galileo orbital signals come on-line.
Fraunhofer presented information on their 40-channel GPS/Galileo/GLONASS chip-receiver, claiming 1m accuracy, low-cost, robust reliable position solution, small form-factor and low-power. Following PRS test-bed development efforts, Fraunhofer has now received a contract to also deliver 20 pre-operational Galileo PRS receivers for use in initial pilot projects.
GNSS Interference
Vidal Ashkenazi, in his inimitable form, led a panel discussion on interference, jamming (in particular personal privacy devices (PPD)) and spoofing, and coaxed his panel members to provide a quantity of information on what’s being done, mitigation capabilities and potential enforcement. Unlike all the other sessions, panel members did not use presentations, instead responding to some wide-ranging questions on the subject from the session chair.
David Turner, representing the U.S. Department of State, indicated that the ICG will meet shortly in Geneva hosted by the International Telecommunication Union (ITU) to focus on interference, jamming and mitigation. The recourse that nations have for use of PPDs by their people is the law — jammers are illegal, sale and purchase of them is illegal — however internet sales are very difficult to police. So detection and mitigation are required to find and shut them down. Dave’s presentation on the GPS.gov website indicates that the ICG is working on an education program for States to inform about GNSS sensitivity to interference and the threat to critical infrastructure if they are allowed to operate. The ICG also has a task force on detection, reporting and systems development.
The Indian Space Research Organization (ISRO) indicated that PPD jammers in India are restricted but permitted for gatherings such as at churches where personal safety may be an issue. Ground-based detection is needed and stronger legal protection which may well prohibit use of PPDs altogether.
Japan Aerospace Exploration Agency (JAXA) indicated that they are working on ‘signal proofing’ for QZSS.
BeiDou said that they are building a monitor network in China which will detect jamming.
There was a general discussion on whether receiver manufacturers should be mandated to make receivers which are resilient to jamming. Many thought that there have already been significant advances in the direction by manufacturers. The normal approach would be to develop requirements with industry, agency and user inputs, publish them and call up the requirements in equipment specifications. In the United States, the Department of Homeland Security is seeking an approach to detection and location.
Legal impacts of Personal Privacy Devices (PPDs)
While the audience may have had high hopes that the ‘Legal Eagles’ could come up with some magic prevention and prosecution solution, the next session was more of a legal background briefing, without any concrete conclusions (quite similar to other discussions I’ve had with some lawyers in the past, actually).
The first briefing was from the European Commission/European Union who indicated that the EU doesn’t own the frequency rights to Galileo (uh-oh). They have to operate through a member state, which gets the rights through the International Telecommunication Union (ITU) and then licenses use to the EU – the bottom line being that EU enforcement of jamming protection laws maybe be difficult, as the legal framework only exists at the national level for each State. The EU is trying to get recognition under another class of ITU membership.
EU regulations were presented, stating that GNSS re-transmitters can only be operated legally by governments or government contractors. Or can be used indoors for indoor navigation, but only for emergency services at fixed sites which are pre-approved. Pseudolites can only be operated indoors,and there should be no interference to other systems. Jammers are forbidden and cannot be placed on the market for sale.
Eurocontrol had a lot to say about the impact on aviation navigation infrastructure and receivers on aircraft. Existing ground nav aids have limitations, the world-wide equipment infrastructure is becoming quite old, aviation has generally moved away to GNSS and inertial based navigation, and uses ground navaids as backup. There is a conflict between regulating GNSS heavily for aviation and how people want to use it in the commercial world. We may have to consider a trade-off between heavily restricted GNSS operations, and wide open commercial GNSS applications.
David Sobel from Electronic Frontier Foundation in the United States presented the contrary case for individual privacy. His argument is that sale of tracking devices is unregulated and can readily be purchased, so people may presumably use them to track others, thereby infringing their privacy. So why shouldn’t people be able to ‘defend their privacy’ by use of PPDs?
Say an employer insists that a vehicle you are driving have a tracking device so he knows where you are, isn’t the driver also justified in trying to protect his privacy? Since U.S. police can no longer place tracking equipment on suspect vehicles without a warrant, tracking appears to be down to private individuals or companies, who it would appear, have the legal ability to attach tracking devices under most circumstances. So the argument goes that if people have a legitimate concern about privacy, there should be acceptable provisions to allow them to disrupt tracking.
If there is a service such as road tolling, there is an incentive for people to avoid these costs. So systems should be robust enough to avoid disruption. Enforcement is a problem. Should police chase people they suspect have jammers, or should they rather chase criminals or help and protect citizens? Mitigation systems need testing, so to test these systems there has to be jamming transmission, which needs to be controlled and regulated. Restricting the import of bad devices into a country might be desired, but the manufacturing countries don’t tend to want to restrict exports, as exports help their economy. Again, the argument seems to be that of personal privacy over potential risks and damages to society.
No solutions, but a healthy discussion of views from a legal perspective.
Precise Point Positioning (PPP)
The group discussing PPP options consisted of the GSA (charged with exploitation of Galileo services), several principal industry service providers of PPP, and the Federal agency which provides PPP-like services in Germany.
The GSA presented its ideas concerning the provision of high-accuracy PPP corrections over the Galileo E6 signal – the so called Commercial Service (CS). The intent however would not be to disrupt the commercial market-place. Nevertheless, GSA is proposing a public-funded service to be sold to users within a market that is already well served by commercial worldwide service providers who charge users for cm-level PPP service.
While Trimble made a polite presentation on the many levels of capabilities of their TerraSat services, as did Veripos and to some extent Fugro, it was clear that the commercial providers are not eager to find competition in their market from a government entity. NovAtel also chimed in on this conflict as it will be involved in Veripos/TerraStar, following the acquisition of the latter by Hexagon, which also owns the former. Fugro appeared to be interested in acquiring rights to distribute CS on behalf of GSA.
The German Federal agency promoted open data, source and standards from the IGS network to which they contribute: IGS is supported by numerous national agencies around the world. Orbit and Clock PPP service is available 24/7 from multiple sources. However, the service is offered on a best-efforts basis without a service guarantee and cannot achieve the accuracies or convergence times of commercial services.
I talked subsequently with Michael Ritter, CEO of NovAtel to learn the background to the Veripos/TerraStar acquisition. It is clear that providing PPP services means added-value to NovAtel when it sells receivers with PPP capability, so it will quickly discontinue offering Omnistar subscriptions and will launch ‘NovAtel Correct’ shortly, offering Veripos (marine) and TerraStar (land) PPP subscription services. NovAtel is making significant inroads in the agriculture segment and sees PPP service as an essential element of this and other businesses. The acquisition was worth something on the order of $200 million, so there is a vested interest in making these services pay, and discouraging GSA entry into this market. Veripos will continue supplying other GNSS OEM receiver manufacturers — notably Septentrio — who use TerraStar services, now adding NovAtel, and potentially another major GNSS manufacturer.
Future of GNSS in User Segment
Chaired by Greg Turetzky of Intel, this session opened the third day of the Summit. The presenters offered their concepts for current and future GNSS equipment and systems.
Stanford University outlined its work with the U.S. Federal Aviation Administratin (FAA) on an alternate PNT system to be used as a back-up to GNSS. It used to be that GNSS systems were designed to overcome ‘space-weather’ effects and faults in equipment design or manufacture. Nowadays there are ‘bad-guys’ out there and we need to ‘protect, toughen and augment’ these systems. Antennas can be built which impart a specific signature to the signals they transmit, and this may aid in finding and prosecuting the bad guys, but the main focus of work is development of a hybrid system using Distance Measuring Equipment (DME) and a pseudolite.
Tests have demonstrated good performance and these prototype efforts could lead to aviation requirements (MOPS) development by 2018 and deployment by 2020.
Septentrio has been involved in Galileo since it began and was the first company with Galileo receivers. Nowadays it fields receivers in multiple commercial applications including machine control, maritime, aviation, automation, and measurement, delivering accuracies from a meter down to a centimeter. It will add E6 to the AsteRx family of multiple-channel, multi-frequency, multi-constellation receivers, has developed a number of hardware and software mitigation techniques to combat jamming, interference and multipath, and integrate receivers with inertial units for aiding.
Furuno is interested in resilient PNT for marine applications, and has examined the use of eLoran as an alternative to GPS, but has moved towards a system of radar beacons that detect radar pulses from passing ships and transmit their position, enabling position determination. In tests, accuracies of around 2 meters have been obtained with two beacons.
Quascom adds ‘firewalls’ inside receivers which ‘toughen’ the processing and prevent distortion of position information. It believes this will be necessary until authentication can be added into the GNSS system itself, so that any data received is validated and is known to be good.
Chris Rizos from the University of New South Wales, Australia drew attention to the ‘holes’ that exist in GNSS and reviewed a number of possible ‘band-aid’ fixes, such as WiFi especially for indoor location. However his solution seems to be to establish terrestrial networks transmitting GNSS-like signals.
Eurocontrol indicated that aircraft currently use inertial and DME extensively as a back-up to GNSS navigation. By 2030 there will be multiple constellations, and dual-frequency use should become commonplace in aviation, so GNSS navigation should be much more robust. Aircraft approaches are required to be in conformance with Required Navigation Performance (RNP), so would it be possible to develop RNP procedures for DME and Inertial to be used as back-up during approaches in the event GNSS is disrupted?
To conclude the session, Airbus provided a ‘starter-course’ overview on inertial systems – how they work, the range of different types available, what they can achieve, costs, strengths and weaknesses and integration with GNSS.
The Summit continued with subsequent sessions on: space technologies and users; GNSS monitoring of Earth and disaster management; Copernicus – Earth Observation; GNSS Education. Unfortunately neither the space available here nor my deadline allowed me to attend these equally interesting presentations.
A manufacturers’ exhibit area at the Summit fits into a couple of corridors near the main Hall, around 20 booths. I talked with several of the manufacturers, including Spirent who has launched its latest GSS9000 multi-frequency-constellation simulator, with a four-fold increase in system iteration rate over the previous model. Exhibitors appeared to be pleased to be at the Summit and the level of interest shown by the attendees.
As this year’s Munich Summit concludes, where does it leave us? We’ve learned some new things about several GNSS topics and heard some interesting new concepts. Europe appears to be now focused on users and applications, to ensure there is market growth and use of Galileo.
What stands out for me is the contrast between how European governments go about GNSS and how North America and the commercial world does the same thing without as much direct influence. This is nothing new of course, it is simply the European way.
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Tony Murfin is GPS World’s contributing editor for the Professional OEM e-newsletter.
The European GNSS scene received an early Easter present with the successful launch of two new-generation transponders for the European Geostationary Navigation Overlay Service (EGNOS) satellite-based augmentation system (SBAS). The two geostationary transponders, GEO-2, rose on board the SES ASTRA 5B satellite from the European Space Port in Kourou, French Guiana, on March 22 via an Ariane 5 lifter. The new transponders will provide higher accuracy positioning signals to those citizens and professionals using EGNOS enabled receivers.
Together with the previous transponder replenishment on the SES-5 satellite launched in July 2012, GEO-2 will ensure the continuity and quality of the EGNOS open service and safety-of-life services for the next 15 years. Once validated in orbit, the signals will be introduced in current EGNOS operations and will support the new EGNOS generation (EGNOS V3). EGNOS V3 will provide dual-frequency signals on L1 and L5 bands and augment both GPS and Galileo constellations as part of the Multi-Constellations Regional System (MRS) concept.
EGNOS is currently made up of transponders on board three geostationary satellites (Artemis, Inmarsat 3F2, Inmarsat 4F2), and an interconnected ground network of forty positioning stations and four control centres which cover most of the territory of the European Union. The ASTRA 5B payload for EGNOS will essentially extend transponder capacity and geographical reach over Eastern Europe and neighbouring potential markets.
Europe’s first venture into satellite navigation, EGNOS represents a major stepping-stone towards Galileo. EGNOS improves the accuracy of GPS by providing a positioning accuracy to within three metres together with system integrity messages. The system offers three services: an Open Service that is free of charge; a Safety-of-life Service (SoL) that was certified for civil aviation in 2011; and a Commercial Service – the EGNOS Data Access Service (EDAS) that disseminates EGNOS data in real time.
Since the beginning of 2014 the European GNSS Agency (GSA) has been responsible for the operation and service provision of EGNOS. “The successful launch is an important achievement in view of the enhanced performance that EGNOS will provide both today and in the future,” said Carlo des Dorides, GSA executive director.
EGNOS Extension
Future extension of EGNOS was discussed at the recent Munich Satellite Summit (see below and other articles in this issue of EAGER).
While GSA is now EGNOS exploitation manager, the European Commission is responsible for the overall programme, said Ignacio Alcantarilla Medina, deputy EGNOS project manger at the Commission. With medium-term finances for the service secured, through a budget of € 1,580 million for the period 2014 to 2021, the main aim for service extension was to ensure complete coverage of all EU territories.
“Coverage of Member States is the priority; that is what budget is for,” said Alcantarilla Medina. This essentially means reinforcing coverage in the east of Europe and extreme north and overall increase robustness.
Currently (March 2014) there are 100 EGNOS-enabled LPV procedures for the civil air space published in Europe. During 2014 a further 150 LPV procedures should be completed, he stated.
Once all EU territory is adequately served, then further extension might be possible. International projects in terms of demonstration were being undertaken under the European Commission’s FP7 and Horizon 2020 research programmes and funding for international extensions could come from third party or Commission sponsored development funding.
Interestingly, in the light of recent political events, funding for extension of EGNOS to the Ukraine has already been allocated in the European Commission’s budget by DG Development. Other countries could benefit from this type of funding or from other international development aid. An ambitious flight test campaign over Moldova, Poland, Romania, and Ukraine was carried out in the second quarter of 2013 under the auspices of the EGNOS Extension to Eastern Europe: Applications (EEGS2) project. Full demonstration of EGNOS performances and capabilities was performed flying Instrument Landing System (ILS) overlay procedures and by providing real guidance to the pilots during final approach. In total, 19 flight trials were performed between April and June 2013.
European Showcase at Munich Summit
Perhaps the good EGNOS news created the warm glow bathing the Munich Satellite Summit in late March. While input arrived from all parts of the world and all major satellite navigation programmes — except Russia and GLONASS — the majority of the discussions focused on the European programmes, Galileo/EGNOS and Copernicus/Earth Observation, and thus by extension on European technological accomplishment.
Matthias Petschke, Director of EU Satellite Navigation Programmes at the European Commission proclaimed: “Galileo is a reality. We are on track again!” But he stressed that infrastructure does not automatically generate services, and the focus must now be on service provision. On integration, Petschke emphasised that in most cases services meant applications, and few current applications relied on only one source of data. This meant it was not a question of “whether” for integration, but “what else” can be gained from integration of data.
The big challenge is to transform space infrastructure into commercial service platforms that provide clear benefits to users and society. The introduction of Galileo Early Services, possibly as early as Q4 2014, would herald this move to service platforms and that was when Europe needed to “get very, very busy.”
Galileo Boasts of Superiority. The plenary audience heard repeated statements from leading European figures on the ‘superiority’ of the Galileo system over current GPS satellites. The grinding of teeth from the various U.S. delegates was almost audible on some occasions but, in the spirit of world peace, they deigned to publicly challenge such statements.
Typical was Jean-Jacques Dordain, director-general of ESA, who proclaimed Galileo as a success with technologies much better than GPS. Although he did concede that with 22 satellites still to launch this “was not the end of the process – but a real good start.”
Evert Dudok of Airbus Defence and Space stated, “To develop from scratch a system significantly better than GPS is not easy, but we are creating the best system.” A number of delegates supported this, indicating Galileo’s better-quality code and phase measurement signals that were particularly important for higher-accuracy applications. The excellent, over-specification performance of the initial four in-orbit satellites was often quoted.
From a commercial point of view, Carlo des Dorides of the GSA claimed that effectively the European Union already had a 25 percent share of the sat nav market and that one-third of the existing global receiver base was already Galileo compatible. He saw a great future for the system.
“Galileo is unique compared to other GNSS due to its civil nature,” said des Dorides. And the user was at centre of the system’s evolution, with developments in Galileo moving from technology push to demand pull. The clear role of GSA was to ensure that both Galileo and EGNOS delivered the valuable services they are designed to deliver.
Galileo’s public regulated service (PRS) should be a key factor in growing market share in secure civilian applications with its enhanced ability to counter intentional and unintentional signal interference – another main topic of the Summit. In a dedicated session on combating interference, the introduction of a ‘PRS-lite’ authentification signal on the Galileo open service was mooted, which could be a very interesting development.
The absence of any Russian input to the Munich SatNav Summit — save for a small pile of the unexpectedly glossy GLONASS Herald publication outside the registration hall — brought the chill of geopolitics into the usually apolitical space arena.
Does Augmentation Have a Future?
Another interesting question raised at the Summit – given the near-future fact of four compatible GNSS constellations on station – was whether there will be a role for augmentation systems such as EGNOS and WAAS?
Deborah Lawrence of the FAA was clear that her organisation was working to take advantage of the multi-constellation future and that the role of SBAS might change, but that the FAA is already looking towards what the requirements for SBAS in 2040 might be.
European Commission spokespersons agreed with the need for multi-constellation, globally interoperable SBAS for the foreseeable future, not least because the currently installed receiver base in the aviation sector would likely have a 20-year replacement horizon.______________
Tim Reynolds is director of Inta Communication Ltd. and a long-term Brussels observer writing on many aspects of European government policy and implementation for a range of clients and publications. The material presented here was first prepared in a somewhat different form for the GSA. He is the contributing editor for GPS World’s new quarterly e-newsletter, EAGER: the European GNSS and Earth Observation Report. Subscribe free at env-gpsworld-integration.kinsta.cloud/subscribe.
With the first two full-operational-capability (FOC) Galileo satellites successfully through their thermal-vacuum tests, the program’s next hurdle is securing a firm launch date in June aboard a Europeanized Russian Soyuz rocket, operated from Europe’s spaceport on the northeast coast of South America.
It will not be a walk in the park. Competing with the two Galileo FOC satellites for the same June Soyuz launch are four commercial broadband communications spacecraft owned by O3b Networks of Britain’s Channel Islands, a start-up that promises, if all goes well, to launch as many as 100 satellites.
O3b and Galileo managers as of late March were rushing to complete final tests to be able to be first to ship their craft to the spaceport and thereby lay claim to priority rights aboard the June Soyuz. Both say they can be on a plane to the Guiana Space Center launch base in April. Should they arrive within days of each other, the already nightmarish dilemma confronting the Arianespace commercial launch consortium will only grow more complicated.
Here’s the matchup.
Powerful Backer. O3b, in addition to its plans to launch dozens of satellites if the business model proves out, is backed by SES of Luxembourg, the world’s second-largest satellite fleet operator and as such a big Arianespace customer.
SES has already shown itself disinclined to maintain its loyalty to the heavy-lift Ariane 5 rocket operated by Arianespace by booking three less-expensive launches, one already completed, aboard the new Falcon 9 rocket operated by SpaceX of the United States. Arianespace can ill-afford to alienate SES, whose 50-satellite fleet requires 3-4 launches per year just to maintain its existing capacity.
The four first O3b satellites in orbit all have a defect that could cause one or more of them to stop functioning at any time. Without at least four satellites — and preferably six — O3b does not have a business and its future is put into question.
It would be, to say the least, a public relations calamity for the company if its initial commercial operations, which began in March, were to be suspended in the wake of a satellite failure while waiting for a second batch of four spacecraft. This explains the extraordinary pressure that SES is placing on Arianespace on behalf of a June Soyuz launch for O3b.
Does it really matter, O3b backers say, if Galileo waits until the next Soyuz launch slot, tentatively set for August?
Emphatic Politician. It matters to the European Commission, which owns Galileo. Commission Vice President Antonio Tajani has all but pounded the table, insisting that the European Space Agency, hired to oversee Galileo’s technical development, ensure three Galileo launches on Soyuz rockets in 2014.
Four initial-operating-capability Galileo satellites are in orbit. Indications are that their performance exceeds specifications. Three Soyuz launches carrying two satellites at a time would bring the constellation to 10 spacecraft, enough to offer initial commercial services, according to the Commission.
Tajani has made clear how much he wants that feather in his cap as he prepares to leave the EC this year, probably headed for a political career in Italy. Make no mistake: as is the case with many wounded animals, Tajani’s status as a lame duck has made him all the more fierce in his insistence that Galileo meet its three-launch schedule in 2014.
Tajani has put very public pressure on the European Space Agency, which in turn is pressuring Arianespace, for Galileo launches.
Ariane’s Quandary. Arianespace is already facing an exceptionally crowded launch manifest in 2014 as it coordinates the schedules of three vehicles: the small Vega rocket in addition to the medium-lift Soyuz and the heavy-lift Ariane 5. Because both O3b and Galileo are late, neither has an obvious claim of priority status at Arianespace, which is clearly hoping that the problem will solve itself when either O3b or Galileo arrives at least several weeks ahead of the other.
At press time, the next Soyuz launch was scheduled for April 3, carrying a European Commission environment-monitoring satellite. Commission officials will attend the launch and no doubt use the occasion to press their case for Galileo.
There is no telling how this will turn out. Satellites have been known to face last-minute problems even after arrival at the spaceport. This happened to O3b in 2013, as the in-orbit defect did not surface until just before its scheduled Soyuz launch.
But if one were to hazard a guess, here is the most likely scenario: O3b arrives ready for launch several weeks ahead of Galileo and secures the June launch. Galileo moves to August and is promised a second launch in the autumn. O3b’s planned second launch in 2014 is moved to early 2015, as is the planned third launch of Galileo.
The effect of these schedule slips on the cost of the Galileo program, which is about a year late — cost overruns that Tajani has vowed will not be paid by the Commission — is a subject for another day.
Flight operators can now use EGNOS approach procedures at airports in the Czech Republic, Austria, Finland, and Tunisia, all part of a growing list of airports across Europe that have implemented localizer performance with vertical guidance (LPV) procedures. The European Satellite Services Provider (ESSP), a Toulouse-based company which has the contract for EGNOS system operation and service provision, made this and several other announcements recently.
In all, 17 EGNOS Working Agreements (EWA) with airports have been signed and 171 EGNOS-based approach procedures authorized for specific runways.
The European GNSS Agency (GSA) is launching the implementation of the first LPV procedures in seven countries in 2014, as an exercise to gain the necessary competencies at national level, leading to a further plan for EGNOS adoption in the Perfromance-Based Navigation (PBN) plans.
EGNOS provides a cost-effective alternative to ILS CAT I, offering similar performance, and increasing safety by allowing Instrument Flight Rules (IFR) approaches at difficult locations or under meteorological conditions where previously such approaches were not possible due to safety concerns. The use of EGNOS is free of charge.
Cost-effective synergies between the European Rail Traffic Management System (ERTMS) and satellite technologies such as Galileo can make rail transport more efficient and reliable, agreed European authorities in February at a Rail Forum Europe dinner in Brussels. But while the technology is now available, its implementation pace is still too slow due to the long term return on investment.
Francesco Rispoli, manager of satellite technologies at Ansaldo STS, an Italian provider of rail-traffic management, planning, train control and signalling systems, stressed that satellite technology can improve the penetration of ERTMS in the worldwide market as well as on European local and low-traffic lines. He predicted that further synergies will be developed on the SHIFT²RAIL initiative: “EGNOS and Galileo are key enabling technologies for a market-driven step change in the rail sector” he concluded. In that light, Ansaldo STS is developing an open platform to allow the ERTMS to fully exploit EGNOS and Galileo.
Olivier Onidi, director for Innovative and Sustainable Mobility at the EC’s Directorate General for Mobility and Transport (DG MOVE), highlighted the role of ERTMS in achieving an interoperable Single European Railway Area. “2014 is a key year in terms of innovation for the rail sector. Major progress is expected on ERTMS, Galileo, and SHIFT2RAIL”.
SHIFT²RAIL is a European technology initiative seeking to double the capacity of the European rail system, increase its reliability and service quality by 50 percent ,and cut lifecycle costs in half.
Carlo des Dorides, executive director of the European GNSS Agency, applauded the ERTMS Memorandum of Understanding envisaging the future use of EGNOS and Galileo to improve the competitiveness of train control systems. “There are signs that GNSS will be adopted globally as in the aviation sector. In this scenario, Europe now has the opportunity to exploit the synergy between ERTMS and GNSS.”