Author: GPS World Staff

  • FAA evaluates drone detection dystems at DFW

    This week, the Federal Aviation Administration (FAA) and its partners are conducting detection research on unmanned aircraft (UAS) at Dallas/Fort Worth International (DFW) Airport.

    The DFW evaluation is the latest in a series of detection system evaluations that began in February 2016. Previous evaluations took place at Atlantic City International Airport; John F. Kennedy International Airport; Eglin Air Force Base; Helsinki, Finland Airport; and Denver International Airport.

    Drones that enter the airspace around airports can pose serious safety threats. The FAA is coordinating with government and industry partners to evaluate technologies that could be used to detect drones in and around airports. This effort complies with congressional language directing the FAA to evaluate UAS detection systems at airports and other critical infrastructure sites.

    At DFW, the Texas A&M University-Corpus Christi UAS test site is performing the flight operations using multiple drones. Gryphon Sensors is the participating industry partner. The company’s drone detection technologies include radar, radio frequency and electro-optical systems.

    The FAA’s federal partners in the overall drone detection evaluation effort include the Department of Homeland Security; the Department of Defense; the Federal Bureau of Investigation; the Federal Communications Commission; Customs and Border Protection; the Department of the Interior; the Department of Energy; NASA; the Department of Justice; the Bureau of Prisons; the U.S. Secret Service; a and the U.S. Capitol Police; and the Department of Transportation. The work is part of the FAA’s Pathfinder Program for UAS detection at airports.

    The FAA intends to use the information gathered during this assessment and other previous evaluations to develop minimum performance standards for any UAS detection technology that may be deployed in or around U.S. airports. These standards are expected to facilitate a consistent and safe approach to UAS detection at U.S. airports.

  • ISRO inaugurates advanced GNSS research lab

    The Indian Space Research Organisation (ISRO) has launched the Advanced GNSS Research Laboratory (AGRL) in the Department of Electronics and Communication Engineering at the Osmania University College of Engineering in Hyderabad, reports The Hindu.

    ISRO Chairman A. S. Kiran Kumar inaugurated the facility on April 27. He discussed various technical aspects related to NavIC Satellite Navigation System of India (formerly the INSS).

    He also advised students and faculty to carry out research work on differential corrections, development of various modules using IRNSS, atmospheric effects, work related to mutli-constellation, kinematic applications, fisheries applications and innovative applications for the public.

    The laboratory was established to enable research projects for Ph.D., M.E. and B.E. students. It was developed under the Memorandum of Understanding (MoU) between the University College of Engineering with the Space Applications Centre (SAC), ISRO, Ahmedabad.

  • China Eagle builds production base for industrial drones

    China Eagle builds production base for industrial drones

    China Eagle’s Sharp Sword is in prototype testing.
    China Eagle’s Sharp Sword is in prototype testing.

    China Eagle is building the country’s largest production base for industrial drones.

    A Beijing-based UAV developer, China Eagle is maker of the Divine Eagle and the Sharp Sword stealth drones. The firm also works with the state oceanic administration to produce drones for shore patrols.

    The production base in Jingjiang’s economic and technological development zone in east China’s Jiangsu province is expected to produce its first industrial UAV this month. The drones will be designed for mapping, aerial inspection and unmanned cargo transport.

    With an investment of 510 million yuan ($74 million), China Eagle’s new production base is designed with an annual production capacity of 5,000 units. Its total output value is estimated at 3 billion yuan a year. Analysts say the general aviation sector is unable to meet the needs of industrial customers in China, where demand is high.

  • Laser Technology offers TruPoint 300 total station

    Laser Technology offers TruPoint 300 total station

    The TruPoint 300 total station by Laser Technology.
    The TruPoint 300 total station by Laser Technology.

    Laser Technology Inc. (LTI) has released its TruPoint 300 for field data collection and mapping, as well as producing +/–1 millimeter range accuracy. It is a fully integrated laser with vertical and horizontal angle encoders capable of producing 3D, survey-grade measurements.

    The TruPoint 300 is LTI’s first phase-technology product with a laser diode that emits light pulses with a distinct wavelength and pulse repetition frequency that obtains millimeter accuracy.

    The fully integrated MapStar Angle Technology make the Trupoint 300 suitable for GIS, incident mapping, crush analysis, surveying, electric utilities, architecture and construction.

    It will measure the distance between two remote points and has onboard solutions for volume, height, and 2D and 3D area, the company said. Professionals can navigate through measured data, routines, and menus with a full-color touchscreen.

    In addition, the laser features an integrated red-dot visual indicator and crosshair with four-power zoom camera, which makes taking measurements easier, especially indoors, LTI said. The unit will also capture a photo of every shot taken that includes raw measurement values and onboard calculations.

    Both photos and data can be stored in a CAD-friendly format for professional documentation. With Bluetooth and WLAN, professionals can communicate with apps and transfer X-, Y-, Z-point data files with images.

    Several measurement and mapping apps designed by LTI are expected to be released in the coming months. Besides professional-grade lasers for mapping, LTI also provides a line of recreational rangefinders by Bushnell for golfing and hunting.

  • M3, Averna join to test auto infotainment

    M3, Averna join to test auto infotainment

    Averna AST-1000.
    Averna AST-1000.

    Averna has entered a strategic partnership with M3 Systems to distribute M3’s StellaNGC GNSS Simulator on National Instruments’ VST platforms for the infotainment segment of the automotive market.

    M3 Systems’ GNSS simulator, based on National Instruments’ Vector Signal Transceiver (NI VST), will now be available as part of Averna’s AST-1000 platform, extending its capability to navigation and GNSS testing.

    Launched in July 2016, the AST-1000 is an RF solution designed for radio, navigation, video and connectivity testing. Also based on the NI VST, the software-defined AST-1000 supports all common infotainment RF signals, including AM/FM, DAB, RDS, HD Radio and Sirius/XMas, as well as GNSS navigation.

    The combination provides a comprehensive solution and enables unprecedented applications for the testing of infotainment systems.

    M3 Systems’ GNSS simulator is a good fit to extend the capability of the AST-1000 for navigation testing because both instruments are based on the NI VST, the companies said.

    Averna is aiming for an all-in-one platform for the complete validation of infotainment systems, including radio, navigation, audio/video and connectivity testing.

    The Averna AST-1000 is available to customers worldwide.

  • System of Systems: Brexit may oust UK from Galileo work

    Brexit May Oust U.K. from Galileo Work

    Participation of the United Kingdom space industry in Galileo may be in doubt as negotiations get underway on details of the U.K. withdrawal from the European Union (EU).

    European Commission officials signaled that they want to rely solely on producers within the European Union for the block’s major programs, citing security concerns such as the possible acquisition of a U.K. contractor by a company from a non-EU country such as China.

    In particular, officials are concerned about protecting the heavily encrypted, jam-resistant Public Regulated Service capability designed for government use that is reserved for EU member states and where U.K. industry has had a significant role.

    Surrey Satellite Technology Ltd., based in Guildford, England, but a subsidiary of France-based Airbus, built 22 navigation payloads for Europe’s Galileo satellite fleet.

    Other companies with U.K. interests that could be affected include Qinetiq, CGI, Airbus and Scisys.


    Galileo SAR Service Launched

    Galileo’s Search And Rescue (SAR) service became officially operational with a public launch on April 6, as part of the COSPAS-SARSAT network for detecting and locating emergency beacons activated by aircraft, ships and hikers. According to the European Commission, Galileo SAR will help reduce the detection delay of a distress signal from up to several hours to 10 minutes.

    At sea, this makes SAR rescue operations easier thanks to a narrowed search box, since the vessel in distress has less time to drift. On land, acquisition of a precise position enables rescue teams to more quickly reach the operation zone and assist the victims. In the air, Galileo contributes to fulfilling International Civil Aviation Organization (ICAO) requirements for implementing the next-generation emergency management system Global Aeronautical Distress and Safety System (GADSS).

    SAR transponders on Galileo satellites can pick up signals emitted from 406-MHz distress beacons anywhere in the service coverage area and transmit this information to the dedicated ground stations, the Medium-Earth Orbit Local User Terminals (MEOLUTs). The SAR/Galileo infrastructure is interoperable with GPS and GLONASS SAR transponders.
    Once the beacon is located by the MEOLUTs, the location data is sent to the COSPAS-SARSAT mission control center, which distributes it to the relevant rescue centers. These then coordinate the required rescue efforts.

    Galileo provides a ground segment coverage of 40 million square kilometers over Europe as a contribution to MEOSAR global coverage. Galileo SAR service is one of the three services launched in December 2016 with the Initial Services. The SAR service represented 1 percent of total Galileo program costs, but should result in thousands of lives being saved, said the European Commission.


    Pile of Studies Produced Not a Lot

    Gen. Shelton
    Headshot: Gen. Shelton

    Testifying before a joint hearing of the House Homeland Security Committee and House Armed Services strategic forces subcommittee on March 29, Retired Gen. William Shelton, the former head of Air Force Space Command, warned that the U.S. needs to take action to protect GPS very soon.

    He cited demonstrated ability by the Chinese government in 2007 to destroy a satellite in orbit, and improved signal jamming and cyber attack capabilities against ground control systems. The U.S. is unprepared to meet those threats, he said.

    “Here we are 10 years later and we don’t really have a lot to show but a pile of studies,” Shelton said. “We’ve been part of this ‘one more study’ kind of attitude. ‘Well, that may not be the perfect answer, so let’s just do one more study’ and meanwhile time marches on. Satellites have fixed lifetimes, and you need to plan for the death of the satellite. A decision not to move forward is a de facto decision to maintain the status quo with no protection.”

    Shelton stated that space research and development is at a 30-year low, with 15–40 percent of R&D funds taken by management services and technical assistance rather than actual research and development.

    “The executive branch and the legislative branch could get together and agree on a strategy and a way forward and then execute … I don’t see any other way. There has to be some broad agreement here in the whole of government as we move forward.”


    June Launch in japan for QZSS Michibiki 2

    QZSS’s second satellite is scheduled for launch in June. Once completed, the Quasi-Zenith Satellite System will be a satellite augmentation system for GPS over Japan and other parts of the Pacific region.

    Michibiki 2 will be launched by the Japan Aerospace Exploration Agency (JAXA), with a launch window planned for June 1–30. The system’s first Michibiki satellite was launched in September 2010.


    OCX Back on Track

    OCX, the next-generation ground control system for GPS, is back on track following a 2016 government contract breach that prompted the Air Force to work with Raytheon to revise OCX’s budget and schedule, according to the company.

    Raytheon implemented a series of corrective actions through 2015 and 2016 to get the delayed program on a firm timeframe for completion. Coding on OCX was about 80 percent complete in late March, according to the company.

    Raytheon completed a re-baselining on OCX in March, setting up a new timeline for completion. Current delivery for the full system is planned for December 2020.

    DevOps. The OCX team reduced development cycle times to create more efficient software development by using a commercial best practice called DevOps, which adds more automation into coding and testing, and breaks coding down into units rather than focusing on the need to finish the complete system all at once.

    A subset of OCX, the Launch and Checkout System for GPS satellites is undergoing testing at Schriever Air Force Base in Colorado. Raytheon expects to complete testing and deliver the system by late September or early October.


    EGNOS Refreshes

    The geosynchrous Earth-orbit (GEO) satellites broadcasting EGNOS messages changed in March. PRN 123 was introduced in the operational platform, and PRN 136 was moved from the operational platform to the test platform.

    Regional aviation in the dense European air traffic system is a key market segment for EGNOS, according to Gian Gherardo Calini, the European GNSS Agency’s head of market development. More than 440 EGNOS-based approaches are available at nearly 220 airports across Europe. These figures are expected to dramatically increase in the coming years.

    A proposal from the European Aviation Safety Agency recommends that air ANSPs and aerodrome operators implement Performance Based Navigation (PBN) approach procedures with vertical guidance (APV), such as EGNOS LPVs, at all non-precision instrument runway ends by 2020.


    Second GPS III Launch Contracted

    The U.S. Air Force has awarded a second GPS III satellite launch contract to SpaceX.

    According to the $96.5 million agreement, the company will provide GPS III launch vehicle production, mission integration, launch operations, spaceflight worthiness and mission-unique activities. Work is expected to be complete by April 30, 2019.

    An earlier SpaceX launch contract, worth $82.7 million, calls for orbiting a GPS satellite aboard a Falcon 9 rocket in May 2018.

  • Research Online: GPS UTC anomaly, spatial reference system access

    Research Online: GPS UTC anomaly, spatial reference system access

    Click to enlarge.
    Click to enlarge.
    Click to enlarge.
    Click to enlarge.

    Impact of January 2016 GPS UTC Anomaly

    By Charles Curry / Presented at ION ITM, January 2017

    On Jan. 26, 2016 alarms occurred on GPS timing receivers around the globe. This article tells the story as experienced by the Chronos support team over a four-day period, dealing with nearly 5,000 alarm events from many different GPS timing receivers worldwide. It examines whether the alarms were service-affecting or if the equipment switched to a resilient fallback status. This event was not without precedent. The last time such an event happened to the GPS transmission was Jan. 1, 2004, and coincidentally SVN23 was also to blame then. A major network event happened to GLONASS on April 1, 2014. These qualify as “Black Swan Events” first proposed by Nassim Nicholas Taleb in his 2001 book, Fooled by Randomness. This was a unique event with unique impact across the globe. Chronos supports many thousands of GPS-based timing receivers for more than 100 clients in more than 50 countries. This article also reviews more recent work to understand what caused the event and how it manifested itself.

    National Spatial Reference System Access in 2022

    By Daniel Roman, NOAA / Presented at ION ITM, Jan 2017

    In 2022, the National Geodetic Survey will implement a new datum to replace both the North American Datum of 1983 (NAD 83) and the North American Vertical Datum of 1988 (NAVD 88). This datum will provide the primary access to the National Spatial Reference System (NSRS) through GNSS and a geopotential model. Foundation CORS sites will provide a backbone network to ensure that the U.S. contributions to the ITRF solutions remain robust. In turn, these sites will also provide the connection to the densified network of CORS stations to provide local access. RTN and RTK surveys will provide an additional layer of access for improved local resolution. Velocities will be taken into account to provide tie back to survey points. Passive control (benchmarks) will become secondary access to the NSRS with conversion models being provided to ensure backward compatibility to NAD 83 and NAVD 88.

  • Launchpad: Reference clock, receivers, drones

    Launchpad: Reference clock, receivers, drones

    OEM

    Rakon RHT1490 series.
    Rakon RHT1490 series TCXO.

    High-Frequency TCXOs

    Ultra stable for low jitter and phase noise applications

    The RHT1490 series of high-frequency and low-jitter ultra-stable TCXOs are available in frequencies from 50 MHz to 204.8 MHz. It delivers telecommunications-grade stability with a low real mean squared (rms) phase jitter of <200 fs (12 kHz–20 MHz). The platform’s frequency output enables lower system jitter, allowing communication system architects to optimize noise budget and performance. It can serve as a reference clock for SyncE and packet clock requirements (ITU-T G.826x and G.827x). It works with both discrete and integrated IEEE 1588 solutions, providing medium-term stability for low loop bandwidth applications. Its ultra-low noise floor performance, combined with system phase locked loop filtering, helps achieve very low system clock rms jitter numbers required by reference clocks of physical layer devices for high -speed interfaces (40 G and 100 G applications).

    Rakon, www.rakon.com

    Reference clock

    50-channel 8835 GPS reference clock.
    Smiths Interconnect’s 50-channel 8835 GPS reference clock.

    Compact and configurable

    The 50-channel 8835 GPS reference clock serves satellite communications, defense and wireless applications. It has extreme power and interoperability options while maintaining GPS accuracy and reliability. Tracking GPS, the clock exhibits a frequency accuracy of <1 x 10-12 and a 1 PPS accuracy with <50 nanoseconds real mean squared. The proprietary oscillator steering discipline algorithm can enhance the rms accuracy of either the double-oven crystal oscillator or optional enhanced rubidium oscillator for greater depths of accuracy. It operates from –30° C to +60° C with a terminal node controller GPS receiver port.

    Smiths Interconnect, www.trak.com

    Survey

    Windows tablet

    Algiz 8X ultra-rugged tablet computer.
    Handheld Group’s Algiz 8X ultra-rugged tablet computer.

    Rigorously tested for tough environments

    The Algiz 8X ultra-rugged tablet computer is built for field workers who require a powerful, portable computer for mobile tasks. It offers communication features such as LTE and dual-band WLAN, along with an 8-inch projective capacitive touchscreen for outdoor use. Enabling glove mode or rain mode allows for operation in changing weather. The chemically strengthened glass survives an impact test in which a 64-gram steel ball is dropped on the screen 10 times from a height of 1.2 meters. The Algiz 8X has optional active capacitive stylus. Built-in features include Windows 10 Enterprise LTSB; u-blox GPS and GLONASS; WLAN a/b/g/n/ac; BT 4.2 LE; a rear-facing 8-MP camera with autofocus and LED flash; and 4G/LTE.

    Handheld Group, www.handheldgroup.com

    2D excavating system

    Topcon X-52 entry-level machine control system.
    Topcon X-52 entry-level machine control system.

    Cost-effective grade control

    The X-52 entry-level machine control system for excavation features the new intuitive MC-X1 controller, compatible with all brands and models of excavators. Its reliable and rugged TS-i3 tilt sensors detect the precise positioning of the boom, stick and bucket at all times. Later this year, the X-52 will be upgradeable to a full 3D system with GNSS. The X-52 not only allows operators to work faster and with better accuracy, but also promotes a safer work site by keeping grade checkers out of the trenches. The system is designed to pair with the GX-55 touchscreen control box to offer sunlight-readable indicate grade reference in any climate.

    Topcon Positioning Group, www.topcon.com

    GNSS RTK receiver

    Tersus GNSS' Precis-TX204 receiver.
    Tersus GNSS’ Precis-TX204 receiver.

    Integrated display and keypad for configuration without controller

    The Precis-TX204 receiver is a light-weight, rugged, all-in-one GNSS receiver with a built-in centimeter-accuracy RTK engine, onboard storage and versatile connectivity. The built-in battery can support up to 10 hours of continuous field work. Up to 16-GB SD card support makes field work easier, and the rugged enclosure enables the receiver to work in harsh environment. The receiver is designed for infrastructure applications such as providing differential data or logging observations; centimeter-level position and velocity information; precise tracking for internet of things; precise navigation for UAV and robotics. It supports GPS L1 and L2, and BDS B1 and B2.

    Tersus GNSS, www.tersus-gnss.com

    Transportation

    Aviation Receiver

    Esterline's CMA-6024 aviation GPS/SBAS/GBAS sensor.
    Esterline’s CMA-6024 aviation GPS/SBAS/GBAS sensor.

    High-performance GPS/SBAS/GBAS for all aircraft

    The CMA-6024 aviation GPS/SBAS/GBAS sensor, featuring an embedded VHF data broadcast (VDB) receiver, is a complete, self-contained, fully certified, precision approach and navigation solution certified to Design Assurance Level A (DAL-A). Designed as an easy-to-integrate solution for all aircraft, the plug-and-play standalone unit requires no specialized installation or integration support. The new CMA-6024 provides a navigation solution that is fully compliant with automatic dependent surveillance-broadcast (ADS-B) and Required Navigation Performance (RNP). The CMA-6024 includes SBAS Localizer Performance/Localizer Performance with Vertical Guidance (LP/LPV) and GBAS GNSS Landing System (GLS) GAST-C/D precision approach guidance for all aircraft. Built on the success of the CMA-5024, the CMA-6024 is the next step forward, adding a complete GBAS/GLS solution. All CMA-5024 receivers can be upgraded to a CMA-6024.

    Esterline CMC Electronics, www.esterline.com

    Electronic logging

    GPS Insight's Electronic Logging Device.
    GPS Insight’s Electronic Logging Device.

    Alternative to paper logs streamlines fleet management

    The GPS Insight Hours of Service solution has a feature set designed to streamline fleet management and ensure Federal Motor Carrier Safety Administration (FMCSA) compliance. Hours of Service bundles an Android tablet hardwired to a GPS tracking device. The ruggedized Electronic Logging Device (ELD) tablet features an intuitive user interface to ensure ease of use for all drivers. The management portal is web-based, secure and accessible via PC, tablet and smartphone. Features include messaging between drivers and dispatch; audible and visual directions using designated truck-specific routes; and e-logs combined with GPS monitoring, alerting and reporting. The GPS Insight Hours of Service Solution offers a simple alternative to paper logs and provides many benefits beyond compliance.

    GPS Insight, www.gpsinsight.com

    UAV

    Professional drone

    DJI's Matrice 200 drone.
    DJI’s Matrice 200 drone.

    Rugged platform designed for aerial inspection, data collection

    The Matrice 200 drone series (M200) is built for professional users to perform aerial inspections and collect data. The folding body is easy to carry and set up, with a weather- and water-resistant body for field operations. It offers DJI’s first upward-facing gimbal mount, for inspecting the undersides of bridges, towers and other structure. It is compatible with DJI’s X4S and X5S cameras, the high-powered Z30 zoom camera and the XT camera for thermal imaging. A forward-facing first-person-view camera allows a pilot and camera operator to monitor separate images on dual controllers. Obstacle avoidance sensors face forward and up and down, and it has an ADS-B receiver for advisory traffic information from nearby manned aircraft.

    DJI, www.dji.com

    UAV data analysis tool

    PCI Geomatics' STAX UAV image alignment and analysis tool.
    PCI Geomatics’ STAX UAV image alignment and analysis tool.

    Designed to ease image alignment

    The STAX UAV image alignment and analysis tool provides automated tools for aligning and analyzing UAV imagery without a full photogrammetric software suite. STAX was built to address the challenges of collecting and aligning multiple UAV surveys of the same location over time. By automating the alignment process, UAV operators can reduce or eliminate the use of ground control points that are traditionally installed and measured in survey sites. Relative corrections can be applied by using one of the surveys in a stack as a reference. Alternately, a highly accurate reference image of similar resolution over the area of interest can be used to automate the image alignment process. Once multi-pass UAV surveys have been aligned, customers can accurately make comparisons between surveys to measure changes over time or perform feature extraction. STAX provides tools to calculate vegetation indices as well as visualization and basic cartographic capability. Stacked data sets
    can be exported for deeper analysis.

    PCI Geomatics, www.pcigeomatics.com

    SATCOM terminal

    Gilat's BlackRay 72Ka.
    Gilat’s BlackRay 72Ka.

    Enables long-endurance missions for very small UAVs

    The miniature, lightweight BlackRay 72Ka terminal enables long-endurance missions for very small UAVs. The ultra-compact airborne SATCOM terminal for unmanned aircraft systems delivers exceptional throughput for its size. Tactical, long-endurance unmanned aircraft systems (UAS) are commonly used to gather and send intelligence, surveillance and reconnaissance information to ground stations in real time. Reliable, high-performance satellite communications are crucial for ensuring uninterrupted broadband connectivity in beyond line-of-sight missions. Weighing less than 5 Kg, the BlackRay 72Ka combines high performance and throughput with minimal footprint.

    Gilat Satellite Networks, www.gilat.com

    Hydrogen drone

    MMC's HyDrone 1800.
    MMC’s HyDrone 1800.

    Long endurance aircraft equipped for military applications

    The carbon-fiber HyDrone 1800 is designed for use in tough conditions. The drone is wind-resistant, rain-resistant, cold-resistant and lightweight. Its hydrogen fuel-cell technology provides a flight endurance of 4 hours — 50+ hours when combined with MMC tethered technology. The HyDrone 1800 achieves extended flight time while maintaining altitude limits of 4,500 meters with a payload capacity of up to 5 kg. Constructed for safety and durability, an auxiliary lithium battery starts the fuel cell and provides a backup power source. Hydrogen drones can be flown in extreme temperatures from –10° C to 40° C. Payloads include a thermal imaging camera, low light camera, laser equipment or zoom camera, making the system suitable for many military applications such as intelligence gathering, border patrol, aerial fire support, laser designation or battle management services to tactical military operators. MMC also offers packaged solutions in target acquisition and reconnaissance technology (ISTAR).

    MMC, www.mmcuav.com

  • NAVMAR and UAVT plan to demonstrate turboprop engine for drones

    Navmar Applied Sciences Corp. (NASC) and UAV Turbines Inc. (UAVT) have announced plans for a joint flight demonstration of NASC’s TigerShark aircraft with a UAVT micro-turboprop propulsion system.

    First flights are scheduled before the end of the year. This will mark the first time that a Group 3 UAV (medium endurance and size) is powered by a micro-turboprop engine with a new recuperator design that significantly increases engine efficiency, the companies said.

    CAD Representation of the UAVT UTP50R Turbobrop Propulsion system to be demonstrated in flight in the NASC TigerShark XP. (Credit: UAV Turbines, Inc.)
    CAD Representation of the UAVT UTP50R Turbobrop Propulsion system to be demonstrated in flight in the NASC TigerShark XP. (Credit: UAV Turbines Inc.)

    “We are delighted to partner with one of the leading UAV aircraft system developers and be able to access their expertise on these first flights of our proprietary micro-turboprop propulsion technology,” said UAVT President Kirk Warshaw. “The opportunity to work with NASC’s TigerShark speeds development significantly, and we look forward to the time when the technology itself becomes the standard propulsion system for Group 3 and 4 UAVs.”

    “Where many major companies have tried and failed, we were pleasantly surprised at the significant engineering milestones achieved by the UAVT team, technical coordination between our teams and the ability to monitor UAVT’s prototypes in operation during the past year were instrumental in giving us confidence to participate in the flight demonstration program using the TigerShark aircraft,” said NASC president Tom Fenerty. “This first step is a big one, but as micro-turbine technology becomes the standard for UAVs, the missions will change and the support provided to our warfighters will be greatly enhanced.”

    “The benefits of turbines were clear to the air transport industry when turbojets first came into service in 1958, and they quickly dominated the industry,” Warshaw said. “The same advantages of high reliability, long life, smooth quiet operation, and the use of safe heavy JP fuel have long made turbine propulsion desirable for UAVs, although no one until now has produced a viable system. Development of turboprops for UAVs presented extreme challenges due to the high temperatures and physical forces involved in obtaining sufficient power from very small systems. UAVT has spent seventeen years and tens of millions of dollars to overcome these challenges and achieve reliable solutions.”

    Both Navmar Applied Sciences Corporation and UAV Turbines Inc. are privately held. This joint project is funded by NASC and UAVT outside of any government program or agency affiliation.

  • Innovation: Orbit determination of LEO satellites with real-time corrections

    Innovation: Orbit determination of LEO satellites with real-time corrections

    Precision on Board

    INNOVATION INSIGHTS with Richard Langley
    INNOVATION INSIGHTS with Richard Langley

    SATELLITES. I have been fascinated by them ever since I was a child. My interest in satellites and space in general led me on my career path, which began with an undergraduate degree in physics at the University of Waterloo. Although it was an applied physics program and I did work terms at Atomic Energy of Canada, I was more interested in astronomy than nuclear physics and took all the astronomy courses I could. That, in turn, led me to pursue a Ph.D. in experimental space science doing research in the application of very long baseline (radio) interferometry (VLBI) to geodesy. As a postdoctoral fellow at MIT, I worked on ranging data from the U.S. and Soviet laser reflectors placed on the surface of Earth’s natural satellite — the moon.

    I continued my interest in VLBI and lunar laser ranging for a while after I arrived at the University of New Brunswick in 1981 but I quickly got involved with satellite Doppler positioning and that was when I heard my first satellite signals through the speaker of a Canadian Marconi CMA-722B Doppler receiver. At that time, Doppler positioning was being quickly supplanted by GPS and so my interest naturally migrated to the new system. GPS and the other global navigation satellite systems have been a consuming interest ever since.

    That interest includes helping to develop techniques for precision positioning and navigation — ones that minimize as much as possible the effect of various sources of error that plague GPS measurements. One such technique is precise point positioning or PPP, which uses primarily precise carrier-phase measurements along with an accurate model of those measurements to obtain position accuracies down to the centimeter level.

    Although often carried out with recorded data, PPP with real-time GPS orbit and clock correction streams has become an established technique for land, air and sea applications. However, the use of real-time corrections for precise positioning of satellites has not been attempted yet although a number of low-Earth-orbit (LEO) satellite missions could benefit from such a capability. Future satellites with altimeter and radio-occultation payloads may require real-time precise-orbit determination to enable onboard processing of science data for forecasting or now-casting of meteorology data, open-loop instrument operation of radar payloads, or quick-look onboard science data generation. Precise real-time orbit information could also be used for maintaining the formations of closely-spaced satellite constellations.

    In this month’s column, our authors discuss the results of realistic simulations they have carried out to precisely position a LEO satellite using a source of real-time GPS corrections actually transmitted by a network of geostationary satellites. Even accounting for data outages, 3D positioning accuracies better than a decimeter have been obtained. Precision on board? Not right now but likely coming real soon.


    Precise point positioning (PPP) with real-time orbit and clock correction streams has become an established technique over the past decade. Several free as well as commercial sources of precise correction streams are available through the internet or via a satellite link to geostationary satellites.

    Many applications exist for land, air and sea applications, but use of real-time corrections for precise positioning has not extended into orbit yet, although a number of low Earth orbit (LEO) satellite missions have a demand for precise orbit determination (POD). Mission requirements often allow for a relatively high latency for the availability of the precise orbit products, thus ground-based, near-real-time processing is sufficient. However, future satellites with altimeter and radio-occultation payloads may require real-time POD to enable onboard processing of science data for short-term forecasting or now-casting of meteorology data, open-loop instrument operations of radar payloads, or quick-look onboard science data generation. Also, precise real-time orbit information may be used for constellation maintenance of satellite formations. Despite early technology readiness demonstrations by the Jet Propulsion Laboratory carried out one decade ago to transmit real-time corrections via geostationary relay satellites to LEO spacecraft, this technique has so far not been implemented and used in a space mission.

    POD accuracy of a few decimeters or less with real-time corrections has been demonstrated repeatedly by various groups. For these studies, it was assumed that the required real-time precise orbit and clock products are continuously available on board the LEO satellite. Even though a network of several distributed geostationary Earth orbit (GEO) relay satellites may achieve seamless coverage in the equatorial region, gaps at high latitude close to the North and South Poles may occur. The extent of these gaps depends on the gain pattern of the transmitting antenna of the GEO relay satellite. Likewise, the availability of corrections depends on the LEO orbit characteristics, the gain pattern and mounting of the receiving antenna and the attitude profile of the LEO satellite. Most Earth observation and altimeter missions are launched into polar orbits to achieve global coverage. Up-to-date real-time corrections may therefore not be available for POD processing over the polar regions, which are typically also affected by reduced GNSS satellite visibility. As a result, the positioning performance will be degraded during this part of the orbit.

    To study the effects of interrupted availability of precise correction data, we simulated real-time POD using real flight data of the Swarm-C satellite, a representative LEO satellite orbiting Earth at an altitude of about 440 kilometers in a polar orbit with approximately 87° inclination. The satellite was launched into orbit in Nov. 2013 and is part of a three-satellite constellation of identical spacecraft with the mission objective to study Earth’s magnetic field and the electric field in the atmosphere (see FIGURE 1). The orbital period is 93 minutes. The satellite is equipped with a dual-frequency GPS receiver and two zenith-pointing POD antennas. The receiver provides dual-frequency GPS observations of up to eight satellites simultaneously. For the analysis, we selected a test data period of Feb. 1–15, 2016.

    FIGURE 1. Close-up view of the Swarm-C satellite with Swarm-A and -B in the background (artist’s impression). The satellites’ booms point in the anti-flight direction. Two GPS antennas are located on the top side of each satellite’s structure (Credit: ESA-AOES-Medialab).
    FIGURE 1. Close-up view of the Swarm-C satellite with Swarm-A and -B in the background (artist’s impression). The satellites’ booms point in the anti-flight direction. Two GPS antennas are located on the top side of each satellite’s structure (Credit: ESA-AOES-Medialab).

    We processed the GPS observations using a high-performance navigation filter together with precise real-time orbit and clock corrections provided by Fugro, a Dutch multi-national company that provides a multi-GNSS real-time PPP service tailored for maritime applications. The complete processing emulates real-time onboard POD and only uses information available up to the current epoch being processed. This information includes GNSS observations and ephemerides as well as satellite attitude information and predicted Earth orientation parameters.

    We assessed POD accuracy by comparing the results of the real-time POD filter to a reference orbit, which was generated with a least-squares reduced-dynamics POD and precise post-processed GPS orbit and clock products. Correction data gaps over the polar regions were realistically simulated. During such gaps, an onboard POD filter cannot use the most recent corrections and may have to use outdated orbit and clock correction information for several minutes. We investigated the impact of outages of different durations on the positioning accuracy.

    REAL-TIME ORBIT AND CLOCK PRODUCT

    Fugro’s G4 reference station network consists of 45 geodetic receivers distributed worldwide, which deliver real-time multi-constellation GNSS observations and ephemerides to the processing centers located in Norway and Germany. Precise orbit and clocks are then computed in real time for all constellations and broadcast to the users via seven L-band geostationary satellites. GNSS orbits are computed using a batch process with hourly updates, and clocks are estimated at a 1-Hz rate in real time. G4 supports GPS, GLONASS and BeiDou. Galileo corrections will be made available to customers as soon as Galileo enters initial operational capability. The broadcast coverage ensures that the majority of users can receive corrections simultaneously through two independent satellite beams, thus ensuring redundancy and increased availability for critical operations at sea (see FIGURE 2).

    FIGURE 2. Fugro’s G4 global GNSS station network for real-time orbit and clock generation. Colored dots at the equator show the positions of the geostationary relay satellites. Colored circles indicate the GEO access areas.
    FIGURE 2. Fugro’s G4 global GNSS station network for real-time orbit and clock generation. Colored dots at the equator show the positions of the geostationary relay satellites. Colored circles indicate the GEO access areas.

    Additionally, uncalibrated phase delays (UPDs) for GPS are also estimated and broadcast in real time, which allows integer carrier-phase ambiguity resolution for PPP users requiring higher levels of accuracy. Typical real-time GPS orbit accuracy is 3–4 centimeters root-mean-square (rms) when compared with International GNSS Service final products. GPS clock accuracy is generally better than 0.1 nanoseconds (standard deviation). The accuracy of these products guarantees that end-user position accuracy is a few centimeters in real time. One of the objectives of our study is to determine whether the same level of accuracy can be achieved for real-time LEO POD.

    ONBOARD NAVIGATION FOR LEO POD

    The precise real-time orbit- and clock-products are used in a Kalman-filter-based real-time navigation algorithm, which has been developed for use in onboard navigation systems for LEO satellites. The algorithm is capable of processing single- or dual-frequency measurements and can be used with pseudoranges only or with both pseudorange and carrier-phase measurements. In the configuration used for this study, the filter processes dual-frequency pseudorange and carrier-phase GPS observations. The state vector comprises 12 + n states: satellite position and velocity vectors, receiver time offset, scaling coefficients for atmospheric drag and solar radiation pressure, empirical accelerations in radial-, along- and cross-track directions, and n carrier-phase ambiguities, one for each satellite tracked. The prediction model of the satellite’s trajectory considers accelerations due to Earth’s gravity field, luni-solar perturbations, drag, solar-radiation pressure, thrust and empirical accelerations.

    Although the data is processed post facto in this study, the algorithm emulates a true real-time process by only using past and current observations in the data cleaning and quality control. Furthermore, the limited resources of a satellite onboard processor are taken into account by using only a reduced gravity field model of 70 × 70 terms and fixed Earth-orientation parameters. When processing dual-frequency pseudorange and carrier-phase measurements, typical 3D rms positioning errors are about 50 centimeters with GPS broadcast ephemerides and approximately 10 centimeters with precise orbit and clock products. The algorithm has flight heritage through the use in the Phoenix eXtended Navigation System (XNS) on board the PROBA2 PRoject for OnBoard Autonomy satellite.

    The results of the real-time navigation algorithm were compared against reference orbit solutions generated with a precise reduced-dynamics POD, which is based on a least-squares fit using the final orbit products of the Center for Orbit Determination in Europe (CODE). Independent validation through satellite-laser-ranging measurements suggests an accuracy of the reference solution of a few centimeters.

    POD WITH CORRECTIONS

    For the precise real-time POD analysis, the navigation filter uses orbit and clock corrections together with GPS broadcast data. To assess the best possible real-time POD performance, the GPS observations from Swarm-C are processed with continuously available corrections. To take into account the latency in the clock correction generation process, the corrections are processed in the filter with an assumed delay of 10 seconds. The results for the 3D orbit errors are shown in FIGURE 3.

    FIGURE 3. 3D orbit errors of the real-time navigation filter with continuous precise orbit and clock corrections based on Fugro’s products. The errors are plotted over argument of latitude u, where the northern-most point on the orbit corresponds to u = +90° and the southern-most point is u = −90°. 3D rms orbit errors are 6.8 centimeters.
    FIGURE 3. 3D orbit errors of the real-time navigation filter with continuous precise orbit and clock corrections based on Fugro’s products. The errors are plotted over argument of latitude u, where the northern-most point on the orbit corresponds to u = +90° and the southern-most point is u = −90°. 3D rms orbit errors are 6.8 centimeters.

    The position errors of the two weeks of data are plotted vs. argument of latitude u, which is the sum of a satellite’s true anomaly and argument of perigee. As a result, the equator crossings of the satellite correspond to u = 0° and u = 180°. As the satellite proceeds along its orbit, it moves from left to right through the plot. The northern-most point on the orbit is reached at u = +90°, the southern-most point is u = −90°. The results show that a 3D rms LEO orbit accuracy of 6.8 centimeters can be achieved with the Fugro real-time orbits and clocks.

    In addition, orbit and clock corrections are also generated based on the precise final orbits and clocks from CODE, which are used for the generation of the reference orbit solution. These corrections are also processed in the real-time navigation filter with the same settings as Fugro’s product. Comparison to the reference solution yields 3D rms orbit errors of 6.0 centimeters. This result demonstrates that the use of the real-time orbits and clocks only leads to a small degradation in the orbit accuracy compared to the use of post-processed GPS products.

    EFFECTS OF CORRECTION DATA GAPS

    The analysis in the previous section has shown that the use of real-time corrections enables high orbit accuracy when the corrections are continuously available. However, in an on-orbit scenario, the demodulator, which keeps track of GEO satellites and delivers corrections to the navigation filter, may not be able to track them continuously for various reasons. Even though dedicated GEO satellite networks for space-borne applications, like NASA’s Tracking and Data Relay Satellite System (TDRSS) or the European Data Relay Satellite (EDRS) system, potentially offer a seamless service volume for LEO users anywhere on the globe, this may not be feasible with a GEO network originally intended for ground-based users. These satellites typically have a more focused beam, which potentially hinders reliable data transmission in polar regions. This situation is depicted in FIGURE 4, which shows the approximate access areas of the GEO satellite network used to transmit Fugro’s corrections. It also depicts the ground track of two orbital revolutions of the Swarm-C satellite, which leaves the access areas at latitudes beyond approximately 80° N/S.

    FIGURE 4. Coverage area of the GEO satellite network for orbit- and clock-correction dissemination (colored circles) and Swarm-C satellite ground track (black). Dotted lines indicate the assumed coverage area limits at 66° N/S and 75° N/S.
    FIGURE 4. Coverage area of the GEO satellite network for orbit- and clock-correction dissemination (colored circles) and Swarm-C satellite ground track (black). Dotted lines indicate the assumed coverage area limits at 66° N/S and 75° N/S.

    Even if the beamwidth of a GEO satellite’s antenna allows for a continuous link at high latitudes, the receiving satellite demodulator on board the LEO spacecraft will have to switch signal reception to another GEO satellite when the tracked satellite drops out of the field of view. These switches typically happen in polar regions. The acquisition of the new GEO signal is not a trivial task, as it is done under unfavorable conditions at the edge of the service area and requires, for example, correct prediction of the expected Doppler shift due to relative motion the GEO and LEO satellites. Thus, interruptions in the correction data streams are likely to occur and the extent of these interruptions depends on how the switching mechanism is implemented in the demodulator and how fast the acquisition of the new GEO satellite’s signal takes place.

    It is worth mentioning in this context that GEO signal reception depends not only on the transmitting antenna gain pattern, but also on the gain pattern of the receiving antenna on the LEO satellite, the antenna placement on the satellite structure as well as its attitude profile. Experience has shown that satellite design constraints may prevent the antenna from being placed in the most favorable position. Operational constraints can force the satellite not to be oriented in the preferred way for GNSS and GEO signal reception. Instead, priority must often be given to the optimal orientation of body-fixed solar panels for maximum power generation or the pointing of payload sensors, such as optical instruments, to certain target directions.

    To study the impact of correction data outage on the LEO POD, we defined reduced-coverage areas. The first scenario limits the reception of correction data beyond latitudes of 66° N/S. In the case of Swarm-C at approximately 440-kilometers altitude, the outage intervals over the North and South Poles extend to 13 minutes at maximum. In the second case, the corrections are received up to 75° N/S, which corresponds to a maximum outage of 8 minutes, twice per orbit. The smaller coverage area serves as a worst-case scenario, whereas the larger service area is more representative of the expected on-orbit performance.

    Prediction of Orbit- and Clock-Corrections. When up-to-date corrections are no longer available due to an outage in the GEO satellite link, the last received set of corrections must be extrapolated. Up to a certain prediction interval, this method still provides more precise orbit and clock information than the broadcast ephemerides and thus yields better positioning results. The prediction of orbit and clock information is therefore crucial to bridge correction outages and still maintain a precise positioning solution. The following analysis assesses the errors introduced by only extrapolating the orbit and clock corrections. In addition to these errors, the modeling of the observations is also affected by the absolute errors in the real-time orbit and clock product.

    The satellite clock offsets are estimated based on predicted orbits. Therefore, the radial, along-track and cross-track components of the orbit corrections can be computed so that prediction errors over a predefined time interval are minimized. Taking advantage of this, the prediction errors are typically less than 1 centimeter even for extrapolation times of 12 minutes and therefore have negligible effect on the POD.

    In the case of the satellite clock offset, corrections are only available up to the present epoch. Thus, the extrapolation is done based on a fit through the past hour of data.

    The results for the rms clock extrapolation errors over interpolation intervals of 0–15 minutes are displayed in FIGURE 5.

    FIGURE 5. Clock extrapolation errors (rms) for different GPS block types for a linear clock extrapolation polynomial fitted through one hour of data. The results reflect the GPS constellation on Feb. 1, 2016. The largest errors are obtained for the two Block-IIF satellites SVN 38 (PRN 08) and SVN 65 (PRN 24) operated on cesium clocks (light-blue diamonds) and the rubidium clock of Block IIR-A satellite SVN 45 (PRN 21) (red diamonds).
    FIGURE 5. Clock extrapolation errors (rms) for different GPS block types for a linear clock extrapolation polynomial fitted through one hour of data. The results reflect the GPS constellation on Feb. 1, 2016. The largest errors are obtained for the two Block-IIF satellites SVN 38 (PRN 08) and SVN 65 (PRN 24) operated on cesium clocks (light-blue diamonds) and the rubidium clock of Block IIR-A satellite SVN 45 (PRN 21) (red diamonds).

    The errors have been computed for clock data of Feb. 1, 2016, for each GPS satellite independently and are color-coded depending on the satellite type. It becomes obvious that the newest generation of Block IIF satellites with their rubidium atomic clocks yield the smallest extrapolation errors. After 15 minutes, the most stable clock has an rms error of approximately 0.10 nanoseconds and the least stable Block IIF rubidium clock does not exceed extrapolation errors of 0.15 nanoseconds. It is interesting to note that two Block IIF satellites are operated on cesium atomic clocks, which are significantly less stable than the rubidium ones. Their maximum rms clock extrapolation error (plotted in light blue) amounts to approximately 0.45 nanoseconds and 0.60 nanoseconds at the longest time interval of 15 minutes. The satellites of the GPS Block IIR (both the earlier IIR-As and the later IIR-Bs, which have a different transmitting antenna panel) and the IIR-M generations are equipped with less stable atomic clocks, which exhibit extrapolation errors of 0.15–0.25 nanoseconds. The Block IIR-A satellite SVN 45 plotted in red exhibits a clearly reduced stability, possibly an indication of degraded performance of its operational rubidium clock. The clock extrapolation error amounts to 0.40 nanoseconds at 15 minutes.

    POD with Real-Time Correction Data Gaps. For the simulation of GEO-link outages in the real-time POD, the navigation filter starts extrapolating the orbit and clock corrections when the LEO satellite exceeds the latitude threshold. The 3D rms orbit errors are shown in FIGURE 6.

    FIGURE 6. 3D orbit errors of real-time navigation filter results plotted over argument of latitude u, where the northern-most and southern-most point on the orbit correspond to u = +90° and u = −90°, respectively. Corrections are available between 66° S and 66° N (Figure 6a) and 75° S and 75° N (Figure 6b). The orange color indicates outage periods of the GEO-link when extrapolated corrections are used. 3D rms errors are 8.5 centimeters (Figure 6a) and 7.5 centimeters (Figure 6b).
    FIGURE 6. 3D orbit errors of real-time navigation filter results plotted over argument of latitude u, where the northern-most and southern-most point on the orbit correspond to u = +90° and u = −90°, respectively. Corrections are available between 66° S and 66° N (Figure 6a) and 75° S and 75° N (Figure 6b). The orange color indicates outage periods of the GEO-link when extrapolated corrections are used. 3D rms errors are 8.5 centimeters (Figure 6a) and 7.5 centimeters (Figure 6b).
    FIGURE 6. 3D orbit errors of real-time navigation filter results plotted over argument of latitude u, where the northern-most and southern-most point on the orbit correspond to u = +90° and u = −90°, respectively. Corrections are available between 66° S and 66° N (Figure 6a) and 75° S and 75° N (Figure 6b). The orange color indicates outage periods of the GEO-link when extrapolated corrections are used. 3D rms errors are 8.5 centimeters (Figure 6a) and 7.5 centimeters (Figure 6b).
    FIGURE 6. 3D orbit errors of real-time navigation filter results plotted over argument of latitude u, where the northern-most and southern-most point on the orbit correspond to u = +90° and u = −90°, respectively. Corrections are available between 66° S and 66° N (Figure 6a) and 75° S and 75° N (Figure 6b). The orange color indicates outage periods of the GEO-link when extrapolated corrections are used. 3D rms errors are 8.5 centimeters (Figure 6a) and 7.5 centimeters (Figure 6b).

    The top plot depicts the conservative threshold of 66° N/S and the bottom plot refers to the threshold of 75° N/S. The orange color marks the time periods during which the corrections are extrapolated. It becomes obvious that the position solution degrades for increasing extrapolation intervals. In the case of the conservative latitude threshold, the maximum 3D position error is 38 centimeters and the rms error is 8.5 centimeters. For the latitude threshold of 75° N/S, the maximum error reduces to 33 centimeters and the rms to 7.5 centimeters. The plot also shows that the largest orbit errors typically do not appear at the end of the extrapolation interval, but shortly afterwards. The reason for this effect is that the systematic extrapolation errors in the clock corrections cause the filter state to diverge. When up-to-date corrections become available again, the filter requires a certain time to recover and converge back.

    The degradation of the orbit accuracy is not only affected by the errors due to the clock extrapolation alone; the reduced GPS satellite visibility and unfavorable geometry over the North and South Poles also has an impact on the orbit determination performance. The resulting higher dilution of precision or DOP further amplifies the errors in the modeling of the GPS clock offset. Also, with only eight tracking channels available, the onboard receiver cannot track all visible satellites, leading to reduced measurement redundancy. Additional degradation of orbit accuracy is also caused when observations of GPS satellites are rejected in the data screening process due to the errors introduced by the extrapolation of corrections. Nevertheless, even for the conservative latitude thresholds for orbit and clock corrections, a 3D rms POD accuracy of less than 10 centimeters can be achieved with sufficient margin. This is an important result, since sub-decimeter POD accuracy is a key mission requirement for many space missions, such as radio occultation satellites.

    To assess the effects of the absolute orbit and clock errors in the real-time orbit and clock product on the POD, we repeated the same processing procedure with corrections generated based on the CODE final products. In this case, the POD with the conservative latitude threshold of 66° N/S yields 7.2 centimeter 3D rms orbit errors, and the threshold of 75° N/S leads to 3D rms errors of 6.5 centimeters. These results confirm that the use of the real-time product leads to only a small degradation of the POD performance. The results for the orbit determination with continuous and limited availability of corrections are summarized in TABLE 1. In addition, a real-time POD with uncorrected broadcast ephemerides (BCEs) yields an accuracy of 36.4 centimeters.

    Table 1. Overview of 3D rms orbit errors (in centimeters) for real-time POD based on different orbit and clock products and different latitude limits for the availability of precise corrections. The age of data (AoD) indicates the extrapolation interval of the corrections.
    Table 1. Overview of 3D rms orbit errors (in centimeters) for real-time POD based on different orbit and clock products and different latitude limits for the availability of precise corrections. The age of data (AoD) indicates the extrapolation interval of the corrections.

    SUMMARY AND CONCLUSIONS

    Onboard orbit determination simulations for the Swarm-C satellite with real-world flight data and precise real-time orbit and clock products from Fugro have achieved sub-decimeter 3D rms orbit errors. When the GPS orbit and clock corrections are continuously available, 6.8 centimeters 3D rms can be achieved. With conservative assumptions for correction data gaps at latitudes beyond 66° N/S, the 3D rms errors are still just 8.5 centimeters. This result fulfills the accuracy requirements of, for example, radio occultation missions with sufficient margin. This is an important result, as it allows us to shift the POD process from the ground into the spacecraft for future missions and thus provide a precise orbit solution without delay, with possible implications for onboard processing of science data, now-casting of meteorology data, or open-loop instrument operation of radar payloads.

    Even though a small degradation of the POD accuracy is noticeable in the case of correction data gaps, the dissemination of precise orbit and clock corrections for LEO users is a competitive approach to a global centimeter-level augmentation service using high-rate data channels in the navigation signal itself. This service is presently only offered by the Quasi-Zenith Satellite System (QZSS) on the Michibiki L-band Experiment (LEX) signal and is limited to regional users.

    The extrapolation error of the GPS satellite clock corrections has been identified as the main contributor to the error budget. The introduction of additional precise atomic clocks into the GPS constellation in the course of the GPS Block III deployment or the use of the Galileo satellites with their ultra-stable passive hydrogen masers in a multi-GNSS POD promise further improvements. Also, the use of Fugro’s uncalibrated phase delays to fix integer ambiguities in the POD would also lead to improved orbit results.

    Having demonstrated the overall fitness of the concept, the development of an onboard real-time POD demonstrator will be the next step. This hardware unit requires a space-enabled dual-frequency GNSS receiver with a geodetic choke-ring antenna, an onboard processing unit for the navigation filter, and a demodulator unit with a suitable antenna, to receive and demodulate the corrections and provide them for the use in the POD.

    ACKNOWLEDGMENTS

    This article is based on the paper “Precise Onboard Orbit Determination for LEO Satellites with Real-Time Orbit and Clock Corrections” presented at ION GNSS+ 2016, the 29th International Technical Meeting of the Satellite Division of The Institute of Navigation, held Sept. 12–16, 2016, in Portland, Oregon.

    The European Space Agency is acknowledged for the provision of Swarm-C GPS measurements. The Center for Orbit Determination in Europe is acknowledged for providing their precise GPS orbit and 5-second high-rate clock products for the POD reference solution.


    ANDRÉ HAUSCHILD is a member of the scientific staff of the GNSS Technology and Navigation Group at DLR’s German Space Operations Center (GSOC), Oberpfaffenhofen, near Munich.

    JAVIER TEGEDOR works as a GNSS scientist for Fugro Satellite Positioning AS in Oslo, Norway, focusing on the enhancement of Fugro’s high-accuracy positioning services and solutions.

    OLIVER MONTENBRUCK is head of the GNSS Technology and Navigation Group at DLR/GSOC.

    HANS VISSER works for Fugro-Intersite BV in the Netherlands monitoring the Fugro network.

    MARKUS MARKGRAF is a senior research engineer in the GNSS Technology and Navigation Group at DLR/GSOC.

     

    FURTHER READING

    • Authors’ Conference Paper

    “Precise Onboard Orbit Determination for LEO Satellites with Real-Time Orbit and Clock Corrections” by A. Hauschild, J. Tegedor, O. Montenbruck, H. Visser and M. Markgraf in Proceedings of ION GNSS+ 2016, the 29th International Technical Meeting of the Satellite Division of The Institute of Navigation, Portland, Oregon, Sept. 12–16, 2016, pp. 3715–3723.

    • Satellite Orbit Determination

    A New Chapter in Precise Orbit Determination” by T.P. Yunck in GPS World, Vol. 3, No. 9, October 1992, pp. 56–61.

    • Earlier Work in On-Orbit High-Accuracy Positioning

    “Real-time Clock Estimation for Precise Orbit Determination of LEO-Satellites” by A. Hauschild and O. Montenbruck in Proceedings of ION GNSS 2008, the 21st International Technical Meeting of the Satellite Division of The Institute of Navigation, Savannah, Georgia, Sept. 16–19, 2008, pp. 581–589.

    “Autonomous and Precise Navigation of the PROBA-2 Spacecraft” by O. Montenbruck, M. Markgraf, J. Naudet, S. Santandrea, K. Gantois and P. Vuilleumier in Proceedings of AIAA/AAS Astrodynamics Specialist Conference and Exhibit, Honolulu, Hawaii, Aug. 18–21, 2008, paper AIAA 2008-7086, doi: 10.2514/6.2008-7086.

    “Extremely Accurate On-Orbit Position Accuracy Using NASA’s Tracking and Data Relay Satellite System (TDRSS)” by M. Toral, F. Stocklin, Y. Bar-Server, L. Young, and J. Rush in Proceedings of the 24th AIAA International Communications Satellite Systems Conference, San Diego, California, June 11–14, 2006, doi: 10.2514/6.2006-5312.

    “Toward Decimeter-Level Real-Time Orbit Determination: A Demonstration Using the SAC-C and CHAMP Spacecraft” by A. Reichert, T. Meehan and T. Munson in Proceedings of ION GPS 2002, the 15th International Technical Meeting of the Satellite Division of The Institute of Navigation, Portland, Oregon, Sept. 24–27, 2002, pp. 1996–2003.

    • Real-Time Precise Orbit Determination

    “Integer Ambiguity Resolution on Undifferenced GPS Phase Measurements and Its Application to PPP and Satellite Precise Orbit Determination” by D. Laurichesse, F. Mercier, J.-P. Berthias, P. Broca and L. Cerri in Navigation, Journal of The Institute of Navigation, Vol. 56, No.2, Summer 2009, pp. 135–149.

    • Swarm Constellation GPS Receiver

    “Precise Science Orbits for the Swarm Satellite Constellation” by J. van den IJssel, J. Encarnação, E. Doornbos and P. Visser in Advances in Space Research, Vol. 56, No. 6, September 2015, pp. 1042–1055, doi: 10.1016/j.asr.2015.06.002.

    • High-Performance Navigation Filter

    “Precision Real-time Navigation of LEO Satellites Using Global Positioning System Measurements” by O. Montenbruck and P. Ramos-Bosch in GPS Solutions, Vol. 12, No. 3, 2008, pp. 187–198, doi: 10.1007/s10291-007-0080-x.

    • Kalman-Filter-Based Real-Time Navigation Algorithm

    “(Near-)real-time Orbit Determination for GNSS Radio Occultation Processing” by O. Montenbruck, A. Hauschild, Y. Andres, A. von Engeln and C. Marquardt in GPS Solutions, Vol. 17, No. 2, April 2013, pp. 199–209, doi: 10.1007/s10291-012-0271-y.

    • Fugro Precise Real-Time Orbit and Clock Corrections

    “The New G4 Service: Multi-Constellation Precise Point Positioning Including GPS, GLONASS, Galileo and BeiDou” by J. Tegedor, D. Lapucha, O. Ørpen, E. Vigen, T. Melgård and R. Strandli in Proceedings of ION GNSS+ 2015, the 28th International Technical Meeting of the Satellite Division of The Institute of Navigation, Tampa, Florida, Sept. 14–18, 2015, pp. 1089–1095.

  • U.S. Air Force says goodbye to 25-year-old GPS satellite

    U.S. Air Force says goodbye to 25-year-old GPS satellite

    At 25 years old, GPS Satellite Vehicle No. 27 completed its time in orbit on April 18. With the satellite’s final duty completed, the 2nd Space Operations Squadron (2 SOPS) said goodbye via final command and disposal from Schriever Air Force Base in Colorado.

    SVN 27 was launched in 1992, meaning it performed more than triple its design life of 7.5 years.

    “The most interesting thing about this process for me was the ability to do some experimentation and advance training prior to the disposal,” said 1st Lt. Cameron Smith, 2 SOPS bus subsystem analyst. “Experimentation started in mid-March, which consisted of advance training opportunities and vehicle component validation. This was very exciting and new to a lot of people in 2 SOPS.”

    Smith explained underperforming satellites, such as SVN 27, are removed from the GPS constellation to make room for satellites with increased capability.

    Since GPS satellites do not carry the amount of fuel required for de-orbit maneuvers, they are instead pushed to a higher orbit, roughly 1,000 kilometers above the operational GPS orbit.

    During the final contact with the vehicle, the satellite is commanded into the safest, lowest energy state possible. This means all fuel has been depleted from the fuel tanks, the batteries are unable to hold a charge, and the vehicle is in a spin-stabilized configuration.

    Bus component degradations and navigational issues, among other reasons, usually kill a satellite. Fortunately for SVN 27, there were no major flaws throughout its life span.

    “SVN 27 was disposed of because its navigation payload could no longer perform up to the GPS standards,” said 1st Lt. Shannon Sewell, 2 SOPS subsystem analysis chief. “In 1993, a year after it launched, it had a suspect component we never tested out until we disposed of it. The decoder wasn’t fully powered. Since it was a backup, we made a decision to leave it in the same configuration. However, this did not cause any major effects during its life span.”

    In the last two years, the unit conducted six disposal operations. For Sewell, even though she has witnessed final commands given during past disposal operations, this marked the first time she sent the kill command.

    “It’s a rite of passage to send out the last command to vehicles,” said Sewell. “This was my sixth and final disposal in the shop before I move on, but the first kill command I sent. It was a great way to end my tenure here and was a unique opportunity.”

    So far, there have been 28 disposal operations in 2 SOPS history, which support the Air Force’s GPS modernization efforts.

  • Topcon’s new GNSS receiver boards have expanded constellation tracking

    Topcon’s new GNSS receiver boards have expanded constellation tracking

    Topcon Positioning Group has launched two new full constellation GNSS receivers for the original equipment manufacturer (OEM) market. The new B111 and B125 boards are designed for use with a broad range of positioning applications.

    Topcon_B125_Receiver-WThe boards utilize the GPS, GLONASS, BeiDou and Galileo constellations with the B111 tracking signals in the L1 and L2 frequency band, while the B125 adds signals in the L5 band. Both boards are designed to provide scalable positioning from sub-meter DGPS positioning to sub-centimeter RTK positioning.

    “The new boards both include 226-channel Vanguard Technology with Universal Tracking Channels, for reliable ‘all-in-view’ and ‘future-proof’ tracking,” said Jason Hallett, vice president of Topcon global product management. “The addition of BeiDou and Galileo constellation tracking along with GPS, GLONASS, SBAS and QZSS functionality ensures the boards provide the best performance available.

    “The dual-frequency B111 board has very low-power consumption and flexible communication interfaces, making it easy for OEMs to integrate the compact board into any precise positioning application, reducing their time to market,” Hallett said. “The B111 is also form, fit and function compatible with its predecessor, the B110, allowing a plug-and-play upgrade option to track BeiDou and Galileo.”

    The board also includes an SD-card interface designed to provide quick and easy support for datalogging in addition to Quartz Lock Loop technology for superior GNSS tracking in high-vibration environments.

    “The B125 board offers Ethernet connectivity for options for advanced OEM integration,” Hallett said.