GPS World

Tag: Stuart Riley

  • Editorial Advisory Board PNT Q&A: GNSS diminishing returns?

    As the number of GNSS constellations and satellites in orbit continues to grow,
    will we reach the point of diminishing returns?

    Ellen Hall
    Ellen Hall

    “More satellites equal more data, and redundant constellation systems — through GNSS interoperability — can give us more robust PNT, as restated in the January Memorandum on Space Policy Directive 7. That said, there are always diminishing returns. Treaties place liability on the launching country if something goes wrong, but with tens of thousands of small satellites expected to be launched over the next decade, it will be getting increasingly crowded. Concerns are growing about the necessity of increased maneuvers to keep these satellites from a chain reaction of collisions, which ultimately could cause debris to fall to inhabited areas of Earth.”
    — Ellen Hall / Spirent Federal Systems

    Jean-Marie Sleewaegen
    Jean-Marie Sleewaegen

    “With already more than 130 GNSS satellites in orbit, the benefit of new satellites decreases while the risk of satellites interfering with each other increases. However, this is only considering GNSS as we know it, in the MEO orbit (altitude about 22,000 km). The future of GNSS may well be closer to Earth, in the LEO orbit (<1,000 km), with well-known benefits in terms of convergence time and resilience to jamming. Sooner than later, we can expect constellations of hundreds or thousands of LEO satellites carrying a GNSS-like payload supporting PNT services. No worries, there is still growth potential!”
    — Jean-Marie Sleewaegen / Septentrio

    Headshot: Stuart Riley
    Stuart Riley

    “With the current four GNSS constellations and a typical survey elevation mask of 10˚in North America, we average around 30 visible satellites. Far more are visible in Asia with the addition of the regional systems. In an area with a clear view of the sky, this provides more than enough satellites for precision centimeter positioning. However, most professional GNSS users do not have the luxury of operating exclusively in open areas with ideal conditions. Accessing many satellites across multiple constellations increases the probability of receiving sufficient satellites that produce high-quality measurements in obstructed areas. As the constellations expand, we observe improvement in precision position availability in these locations. The large number of satellites, coupled with independence across the four systems, improves system integrity and continuity while also helping to reduce the converge time in PPP solutions.”
    — Stuart Riley / Trimble

    Bernard Gruber
    Bernard Gruber

    “In a utopian vision of navigation, data gluttons and like-users of GNSS would say that there will never be enough! If capabilities remained static, then yes, I believe we would reach the point of diminishing returns. I would offer that innovation and competition will continue to drive capability improvements via power, signal quality, coverage, integrity and clock/timing accuracy. These innovations, coupled with user equipment flexibility utilizing signals from space, will drive an ever-maturing market balance and increasing return.”
    — Bernard Gruber / Northrop Grumman

  • Editorial Advisory Board PNT Q&A: GPS in popular culture

    Editorial Advisory Board PNT Q&A: GPS in popular culture

    Photo: KenWiedemann/iStock/Getty Images Plus/Getty Images
    Photo: KenWiedemann/iStock/Getty Images Plus/Getty Images

    What is your pet peeve about how GPS/GNSS is portrayed or discussed in the media and popular culture?

    Headshot: Terry Moore
    Terry Moore, professor emeritus, University of Nottingham

    “What really annoys me is the misinformed assumption that SatNav and GNSS are one and the same. There is now a proliferation of ‘Do Not Follow SatNav’ signs [in the United Kingdom], and so many anecdotal stories about accidents caused by drivers blindly following SatNavs in their vehicles. These are almost always due to the deficiencies of the mapping and the route guidance components of the SatNav systems and not due to any problem with GNSS whatsoever. Nevertheless, it is GNSS that takes the blame.”

    Terry Moore
    University of Nottingham

    Headshot: Julian Thomas
    Julian Thomas
    Managing Director

    “In films, you often see what looks like the tracking of a person inside a building using GPS. Yet, this cannot be done currently with satellites and the kind of technology that can track people or objects indoors is highly specialized and localized to that environment.”

    Julian Thomas
    Racelogic Ltd.

     

     

    Headshot: Stuart Riley
    Stuart Riley, vice president of GNSS technology, Trimble

    “My pet peeve is the oversimplification of consumer navigation issues. I ran a few searches for ‘GPS fails’ and almost immediately saw images of cars in water and stuck in narrow streets. All too often, this is attributed to a GPS issue or failure. From a consumer perspective, the overall system from maps to satellites is considered GPS. The reality is that GPS (the satellites and control segment) is extremely reliable. Historically, satellite issues have been minimal. The most likely navigation errors are routing errors and old or erroneous maps, coupled with users blindly following the directions, and, to a lesser extent, receiver design issues (e.g., lack of ICD compliance) and harsh conditions (deep urban canyons).”

    Stuart Riley
    Trimble

    Mitch Narins
    Mitch Narins

    “For many, GPS/GNSS remains the miracle cure for all that ails you — for position/surveillance (e.g., ADS-B), for navigation (RNAV and RNP), and for the largest user base, time and frequency. Even while acknowledging the risks, many still treat GPS/GNSS interference as the 500-year flood that will ‘never’ happen in their lifetimes and, if it does, can be excused away as force majeure. It seems that in most of the articles I read it is always a sunny day and GPS/GNSS works perfectly. The need to incorporate resiliency is never emphasized. Nobody would buy a car without a spare tire. Isn’t it time for GPS/GNSS users to recognize the need and insist that an appropriate PNT ‘spare’ be included in the deal?”

    Mitch Narins
    Consultant

    Headshot: F. Michael Swiek
    Headshot: F. Michael Swiek

    “We can chuckle while watching spies, super sleuths, and adventurers receive GPS positions in incredibly challenged environments — even in caves. My main beef is that nowhere is any mention made of who operates GPS. Instead, GPS is treated as an assumed given, embedded in a smart device, constantly and reliably available on demand anywhere and under all conditions. It is about time recognition and credit is given to those who actually make the miracle of GPS happen.”

    Michael Swiek
    GPS Alliance

  • GPS: Obscurity to ubiquity

    GPS: Obscurity to ubiquity

    Headshot: Stuart Riley
    Stuart Riley, vice president of GNSS technology, Trimble

    Over the past 30 years, GPS World has been at the forefront of the transition of GPS from obscure technology to ubiquitous utility. The magazine was first published before the satellite constellation achieved Initial Operational Capability (IOC). In fact, it preceded Operation Desert Storm, which created unprecedented publicity and demand for GPS equipment; and has documented a period of unprecedented increase in the rate of change in the technical disciplines.

    Thirty years after the Wright brothers’ initial flight, commercial air travel remained expensive, uncomfortable, and available to relatively few people. Compare that to GPS and GNSS — in 30 years the technology has moved from 50-pound receivers powered by car batteries to residing in the pockets and on the wrists of billions of people.

    In 1978, the year the first GPS Block-I satellite was launched, Trimble was founded. Trimble’s first product was a Loran receiver in 1980, followed by the world’s first commercial GPS product in 1984. The year the magazine was launched, Trimble became the first publicly traded GPS company in 1990. Positioning technology is in Trimble’s DNA and the foundation for helping transform industries such as construction, agriculture, transportation, geospatial and more.

    Two factors drove GPS from obsurity to ubiquity: Rapid technological advances (electronics, software, communications, and increasing numbers of satellites) combined with innovations using positioning to benefit large numbers of users across disparate applications. Think of it as “Moore’s Law meets market demand.”

    A Malaysian tribe and the Trimble 4000SLD, the first kinematic “backpack” GPS receiver. Weighing 44 lbs. without batteries, the receiver was introduced in 1988. (Photo: Trimble)
    A Malaysian tribe and the Trimble 4000SLD, the first kinematic “backpack” GPS receiver. Weighing 44 lbs. without batteries, the receiver was introduced in 1988. (Photo: Trimble)

    The key to GNSS’s growth is its adaptability. By serving a broad range of industries, GNSS manufacturers addressed widely differing needs for precision, form factors, interfacing, and availability of positions. The markets drove the development of more-capable and cost-efficient solutions and injected varying requirements for performance and functionality.

    Recent advances illustrate the ability of GNSS technology to react to market needs. Satellite-delivered PPP corrections enable users to achieve real-time centimeter accuracy with fast convergence time almost anywhere on Earth. Low-cost, high-performance inertial sensors boost performance in challenging environments. Software-defined high-precision GNSS receivers, coupled with augmented reality on consumer devices (phones and tablets), open the door to innovation in as-yet-undiscovered directions.

    GNSS is playing a key role in a broad range of applications. For example, compact, high-precision receivers are transforming work by delivering higher levels of productivity, reliability, safety and flexibility in industries including automobile and trucking, precision farming, and earthworks and construction. Future applications are expected to increasingly integrate GNSS with other sensors to drive productivity and safety for autonomous applications.

    It took less than 30 years to move from static post-processed positioning to holding centimeter precision in your hand. For those of us who experienced the early days, GNSS has changed the world in ways we never imagined. The next three decades will see GNSS embedded into applications unimaginable today.

    And to GPS World: Congratulations and thank you for 30 great years of pioneering the education, awareness, and promotion of the GNSS industry.

  • GPS World welcomes new EAB members

    GPS World welcomes new EAB members

    GPS World magazine is excited to announce two additions to our Editorial Advisory Board.

    Mitch Narins
    Mitch Narins

    Mitch Narins is the principal consultant and owner of Strategic Synergies LLC, a technical and management consulting firm that he formed after retiring following over four decades of U.S. government service. He worked at the Federal Communications Commission as an acquisition engineer for the Field Operation Bureau; supported the U.S. Navy and U.S. Marine Corps as branch chief for Data Terminal Systems and Electronic Warfare Systems; and served more than 26 years at the Federal Aviation Administration as a program manager, systems engineer, and finally as the chief systems engineer for navigation.

    At the FAA, he was integrated into all aspects of aviation sector position, navigation and time systems engineering, standards development, and enterprise architecture efforts in support of the National Airspace System and the Next Generation Air Transportation System (NextGen).

    Narins is a recognized position, navigation, and timing (PNT) expert, who has published numerous articles and delivered many papers at conferences and seminars worldwide. He is a Certified Information Systems Security Professional (CISSP), a Fellow of the Royal Institute of Navigation, an active member of the Institute of Navigation (ION), and a member of RTCA, RTCM, and SAE Standards Committees. He is a recipient of ION’s Norman P. Hays Award and the International Loran Association’s President’s Award and Medal of Merit.

    Stuart Riley
    Stuart Riley

    Stuart Riley is vice president of GNSS technology responsible for GNSS signal processing and products for several Trimble business areas. In this role, he is responsible for the core GNSS technology from signal reception through to the measurement engine that is used in all Trimble GNSS precision products. He oversees GNSS product development for Trimble’s GNSS Real-time Networks, Geospatial, Heavy Civil Construction and InTech OEM Divisions.

    Beginning his career at Trimble in 1995, Stuart has worked on GNSS receiver development in various engineering roles, in addition to holding several management roles. He holds several patents filed and pending in the field of GNSS and is often a guest speaker at international conferences.

    His research interests include improving GNSS performance in harsh environments, and taking measurements from additional sensors along with optimizing the GNSS receiver architecture, especially for the newer GNSS signals BeiDou, Galileo, IRNSS, QZSS and next-generation GPS and GLONASS signals.

    Riley has an electronic engineering Ph.D. in the field of GNSS from the University of Leeds in England. After he graduated, he was a research fellow at the university on a European Space Agency-funded project to develop a prototype GNSS receiver for space applications.