Category: Applications

  • Rockwell Collins’ Avionics Enable Successful European Union Flight Demonstrations

    Rockwell Collins’ flight management system (FMS) and GNSS receiver successfully enabled the first demonstrations of advanced arrival and departure flight operations for the European Union’s airspace-enhancing project FilGAPP (“Filling the Gap” in GNSS Advanced Procedures and Operations).

    The goal of FilGAPP is to create new, more efficient methods of navigating airspace using satellite-based navigation and advanced FMS functions.

    “FilGAPP highlights the opportunity that exists for air carriers and corporate operators to increase operating capacity and to save time and fuel through more efficient terminal procedures at European airports,” said Claude Alber, vice president and managing director, Europe, the Middle East and Africa (EuMEA) for Rockwell Collins.

    The most recent demonstration, performed in Germany in collaboration with key FilGAPP operational partners, took place on a Hawker 750 aircraft equipped with Rockwell Collins’ FMS and GNSS receiver. It was the first time that a high precision and high integrity missed approach/departure was performed in Europe.

    The flights also validated technical and operational independence from the closely spaced air traffic control systems of two nearby airports, which enabled increased operational capacity for each airport.

    Similar advanced departure/arrival demonstrations as part of project FilGAPP were performed earlier in the year with Air Nostrum (Iberia Regional) in Spain on Bombardier CRJ-1000 aircraft equipped with Rockwell Collins systems. The trials took advantage of the radius-to-fix functionality connected to European Geostationary Navigation Overlay Service (EGNOS)-enabled localizer performance with vertical guidance (LPV) approaches.

    FilGAPP is a project of the European Commission’s 7th Framework Program managed by the European GNSS Agency (GSA) and coordinated by the Spanish transport consultancy, INECO, with industry and national air navigation service provider partners, including Rockwell Collins.

  • Chemring Develops Miniaturized GPS/Galileo Anti-Jamming Technology

    2014-gincan

    Chemring Technology Solutions has developed miniaturized GPS anti-jamming technology it has dubbed GINCANGINCAN is designed to combat illegal GPS jammers and is based on the adaptive antenna concept used by military systems. GINCAN has a chip footprint of six millimeters squared.

    GINCAN’s reduced size and weight will significantly cut power usage and cost, the company said, making it ideal for combatting the widespread problem of low-powered GPS jamming. GINCAN can be integrated into a range of applications, including in-vehicle satellite navigation systems and cellular technology, and can be used for the protection of the critical infrastructures which rely on GPS to provide positioning and timing.

    GPS jammers have already been developed to interfere with the European Union’s Galileo system, which will provide European satellite navigation independently from the Russian, USA and Chinese systems by 2019. Chemring Technology Solutions, based in Romsey, England, has anticipated this problem and its GPS anti-jamming technology will also support systems using Galileo.

    Once the preserve of the military, there is now an increasing demand for GPS protection in the civilian market as illegal GPS jamming equipment becomes widely available on the Internet. The £1.5 million government-funded Sentinel project, designed to measure GPS jamming on UK roads, recorded more than 60 individual jamming incidents across six months at a single location. Such attacks could seriously impact industries, including maritime, aerospace, the emergency services and even stock market trading.

    “Many years of developing GPS protection technology for the military has enabled our research and development team to miniaturize anti-jamming technology,” said Martin Ward, product manager, Chemring Technology Solutions. “GINCAN can now be easily integrated in to a range of applications to provide effective protection against jamming devices.

    “As we become increasingly reliant on GPS technology, and low-cost jammers are proliferating, so a potential time bomb is being created. Chemring Technology Solutions is now able to offer the answer to this problem with jammer protection at a reduced size, weight, power and cost footprint.”

    GINCAN is an export controlled product and subject to UK export restrictions.

  • Altus Introduces RTK Receiver for Esri Community

    At the 2014 Esri User Conference, Altus Positioning Systems is unveiling a new GNSS RTK receiver designed and developed specifically for the Esri user community.

    According to Altus CEO Neil Vancans, the new Altus APS-NR2 provides a new combination of performance and features that make it ideal for Esri users:

    • Light weight – At 1.5 lbs., the APS-NR2 weighs the same as a dozen glazed doughnuts.
    • Dual-cellular antennae – With automatic switchover, users will minimize downtime due to signal loss.
    • Unlimited flexibility – It works on virtually all RTK networks.
    • Built-in Wi-Fi – Users can configure and monitor the unit and stream data directly to their own tablets.
    • Supercharged – It runs all day on hot-swappable batteries and recharges from any USB port.
    • Esri Compatible – It communicates seamlessly with Esri cloud-based platforms.
    • Open architecture – Users can choose their own data collector software or interface directly with Esri ArcGIS Online.

    “It all adds up to the world’s most versatile RTK rover that provides more productivity and less downtime in the field,” said Vancans. “The APS-NR2 raises the bar and sets a new standard for the state-of-the-art in high-precision surveying and geolocation, leveraging the power and convenience of mobile tablet platforms.”

    The APS-NR2 will be commercially available by September, according to Vancans.

    In addition to the APS-NR2, Altus will show the APS GeoPod, a compact GNSS module that adds high-precision RTK positioning to any USB-compatible tablet PC. “This unique product gives users the convenience of adding RTK precision to any on-board application on their own mobile devices,” said Vancans.

    Altus is showcasing the APS-NR2 and APS GeoPod, along with the full range of Altus products, in Booth 1218 at the 2014 Esri Users Conference, July 14-18, in the San Diego Convention Center.

  • Esri Introduces ArcGIS Explorer for Apple Mac

    Esri has released Explorer for ArcGIS on the Mac, a native OS X application to discover, view, and share maps. The ready-to-use app joins Esri’s family of mapping apps, including Collector for ArcGIS, Dashboard for ArcGIS, and Explorer for ArcGIS on iOS. It can be downloaded from the Mac App Store and Esri ArcGIS Marketplace.

    Explorer for ArcGIS running on OSX
    Explorer for ArcGIS running on OSX

    According to the announcement, with Explorer for ArcGIS, users can access maps, search for and visualize data, and brief stakeholders. In the new Mac version, users also have the ability to open and view multiple maps at once, dock and undock pop-up windows, and go full screen — taking advantage of Apple’s Retina technology on MacBook and Thunderbolt displays.

    Esri reports that Explorer for ArcGIS is one of many ready-to-use apps to access maps authored by users or others within their organizations, and share them from Macs or iOS devices. The app is designed for anyone who needs to explore data in a geographic context and use maps to make more informed decisions. With an elegant and intuitive interface, it requires no GIS experience to operate.

    Anyone using a Mac desktop or iOS device can download and try the sample maps included in the app. ArcGIS Online subscribers, trial users, and those with a Portal for ArcGIS account can simply download the app, sign in, and begin exploring their maps and data. An Android version of the Explorer for ArcGIS app will be available in a later release.

  • Year of the Generals

    Several pleasant surprises popped up at this year’s Institute of Navigation’s Joint Navigation Conference (ION JNC) in Orlando, Florida, and the best by far centered on the presenters and the attendees. In a change from recent years due to budget restrictions, better known as sequescastration, this year two senior Air Force generals attended and actively participated in several events.

    General (S) John Hyten – Vice Commander AFSPC - Courtesy of the USAF
    General (S) John Hyten – Vice Commander AFSPC – Courtesy of the USAF

    General (S) John E. Hyten (USAF), currently the Vice and soon to be the Commander of USAF Space Command (AFSPC), participated in two days of ION JNC and was featured as the keynote speaker on the second day of the plenary session. As a senior steward of the Global Positioning System, indeed for all USAF Space Systems, General Hyten has a special place in his heart for GPS, having served as the Commander, 50th Space Wing, Schriever AFB in Colorado, the home of GPS.

     The 2nd Space Operations Squadron is a component of the 50th Operations Group, 50th Space Wing, Schriever AFB, CO. The squadron was activated Jan. 30, 1992.
    The 2nd Space Operations Squadron is a component of the
    50th Operations Group, 50th Space Wing, Schriever AFB, CO.
    The squadron was activated Jan. 30, 1992.

    Conference attendees were pleasantly surprised with the access they had to General Hyten as he toured exhibits and joined fellow attendees for lunch, presentations, and discussions in the hallways. General Hyten made it clear that he was there to interact with ION JNC attendees and welcomed everyone to engage him in conversation. A rare invitation from a very busy general officer with huge responsibilities — and an invitation that many attendees clearly took to heart, as General Hyten was continually engaged in discussions during his two-day stay.

    In his plenary presentation, General Hyten addressed GPS and the general lack of knowledge in the public today concerning the origins of the system. Hint — the answer is the United States Air Force. More on that later.

    Major General (USAF) Robert Wheeler
    Major General (USAF) Robert Wheeler

    Major General Robert Wheeler (call sign Wheels) also attended ION JNC this year to speak during the classified day on June 19 and to participate as an ad hoc member of the always-popular War Fighter Crosstalk Panel. General Wheeler  currently serves on the staff of the Secretary of Defense (SECDEF) as  Deputy Chief Information Officer for Command, Control, Communications and Computers (C4) and Information Infrastructure Capabilities (DCIO for C4IIC). General Wheeler is a command pilot with more than 5,000 hours in multiple aircraft, including the B-2 bomber in which he saw combat time over theater.

    It was obvious from his initial comments in the classified sessions that General Wheeler is a warrior and staunch supporter of GPS and all things PNT-related. As much as I would like to relate some of his more pithy remarks, they were made in a classified environment, so sharing them is impossible in this venue. However, suffice it to say the General’s comments were well received by the war fighters who attended as well as the classified session attendees, which included many of our closest international allies.

    The comment was made several times in my hearing that “We sure hope General Hyten and General Wheeler are invited back again next year.”

    If all goes according to plan, General Hyten will be a four star and a MAJCOM Commander in just a few weeks. If he thought he was busy before . . .

    Now let’s utilize that sage observation as a segue to General Hyten’s Plenary remarks at this years ION JNC. Having known John Hyten for over 20 years it has always been my experience that he does things just a bit differently – he hears a slightly different drumbeat and this year’s plenary speech was certainly no exception. Right from the start this speech was a bit different. General Hyten warned his audience he was going to praise them for their hard work and then gently admonish them but in a good way. With that opening statement he certainly had everyone’s attention. General Hyten asked for a show of hands from those attendees who knew that GPS originated with the USAF, the 50th Space Wing at Schriever AFB and particularly the 2SOPS (2nd Space Operations Squadron).

    2SOPS operators on the GPS Operations Floor at Schriever AFB, CO
    2SOPS operators on the GPS Operations Floor at Schriever AFB, CO

    In the GPS/PNT-savvy audience Gen Hyten was addressing, literally every hand went up, and that was evidently what he hoped to see. The response was not a surprise to anyone, however the general went on to make the point that if he went out into the general population in the Renaissance Hotel at SeaWorld he would be lucky to find one in ten who even knew what GPS stood for, and that it came from space, and almost none would know that it was, is, and will for the foreseeable future always be provided free of charge to global users courtesy of the USAF.

    GPS has been provided by the USAF free of charge for global users ever since President Ronald Reagan declared it so via a Presidential Decision Directive issued in 1988 shortly after the Soviet military shot down a Korean Air airliner (Flight 007) that had strayed off course and into Soviet Airspace due to a navigation error.

    Ironically, General Hyten made the point that if the U.S. Government charged for use of the GPS signals, even at a nickel (5 cents) per user per device per year, it would pay for itself, and everyone would know that the USAF provided the service on behalf of the U.S. Government.

    However, since it is free, ubiquitous, and considered almost a utility today, everyone around the world just assumes it will always be there and they don’t think about how or why the signals are provided. GPS is just always there.

    GPS Orbitology 101- Courtesy of the USAF
    GPS Orbitology 101- Courtesy of the USAF

     

    General Hyten went on to make several cogent points concerning current and future use of GPS and other PNT assets. At the same time he warned us that there are those in the Pentagon  [Obviously shortsighted, my comment, not the general’s.— DJ]  who erroneously question why we still need GPS today. They myopically see it as an antiquated, compromised system. When in fact GPS and multi-GNSS PNT systems are on the cutting edge of technology.

    The general made the comparison with WWII bombers that were being shot down at an alarming rate until the War Department (circa 1943) started the practice ofusing fighter escorts to help them fight through and return home safely. The analogy applies to GPS, which even today is being purposefully and at times maliciously attacked by spoofers and jammers.

    Augmentations

    Fortunately there are numerous actions that can and are being taken to secure GPS as a critical global service — fighter escorts if you will — that will not only help GPS maintain its preeminent Gold Standard position in the world of global PNT, but allow the system to grow and mature, even flourish, with additional high tech capabilities such as CNAV and MNAV (new civilian and military navigation messages).

    Indeed the general stated that we have just begun to explore all the transformational capabilities being added to our GPS/PNT and multi-GNSS arsenal with the addition of L1-L2 M-Code (military code) and L2-L5 CNAV signals.

    Of additional interest are space-based augmentations (SBAS) such as WAAS (Wide Area Augmentation System) and EGNOS (European Geostationary Navigation Overlay Service) as well as independent regional terrestrial augmentations and backups such as E- and D-LORAN (long range navigation), which today have demonstrated a time stability of 1×10(-12) and a position accuracy of 5-10 meters,  an order of magnitude better than LORAN C’s 50-1,000 meters.

    General Hyten went on to warn the commercial PNT vendors and government program managers in the 400+ audience that they must cease placing commercial GPS receivers in critical government systems that support the war fighters, government users, and our critical national infrastructure. Indeed he said this is why we have SAASM (Selective Availability Anti-Spoofing Module) and M-Code: to help secure these critical systems against interference, jamming and spoofing, intentional or otherwise. He also pleaded with industry manufacturers and vendors of PNT devices to please build their devices in strict adherence to the U.S. government;s ICD process. While the general declined to mention specific cases or companies, most in the room were aware of the ramifications of ICD non-compliance, from usefulness, mission and financial perspectives.

    The general cited several known cases where, due to noncompliance, several systems just never did work well or consistently in a war zone. He said he knew of cases where “…the PNT systems worked fine in Yuma, Arizona but failed to work in Afghanistan. Please do not put commercial systems in critical military equipment.”

    Pseudolites

    Pseudolites are another area where the general has concerns. This is of course a hotly debated spectrum issue. Whereas we in the United States have been fighting highly-publicized spectrum battles, attempting to preserve the sanctity of the GPS spectrum globally, the Europeans are on the verge of approving pseudolite implementations all over the European continent that could seriously degrade GPS/PNT/Galileo signal reception and make PNT systems unusable or at least undependable in some critical areas, especially around the approaches to airports. Although on the surface pseudolites may seem like a good solution, I always remember what Dr. Bradford Parkinson is fond of saying: “An improperly implemented pseudolite is just another name for a potential GPS or PNT jammer.”

    The Unofficial Test

    After General Hyten’s comments, I decided to put his theory to the test. Just how many people know GPS is provided free to the world courtesy of the United States Air Force?

    As someone who has been working GPS issues since 1975, I find it hard to believe that the American public is so uninformed about a system that is so critical to their everyday existence, because as most of you know, GPS is pervasive in almost all of our critical and not-so-critical national infrastructure. Indeed stealth GPS chips and receivers are embedded in so many devices today that it would be easier to name the devices that don’t use GPS. So I took the General at his word and set out to conduct my own mini-survey.

    However, before I even had a chance to think much about what I would ask, I stepped into an elevator at the Sea World Renaissance Hotel where the ION JNC was taking place and found myself face to face with an elevator full of attendees from a major medical convention in the same hotel. They saw the ION JNC patch on my black golf shirt and asked me about it.

    I told them and then asked what they knew about GPS. As in, did they know where the GPS signals came from and who provided them? Lots of answers were given and none of them remotely correct.

    Frankly I was appalled, and before they exited the elevator I made sure they knew that GPS signals came from space and were provided totally free by the USAF. Mission accomplished. But not so fast; unfortunately the rest of my day and ad hoc surveys went about the same way. Some actually knew that GPS signals were free, some knew or thought they were provided by the government but had not a clue what agency or service.

    Most thought they were radio signals from ground transmitters and were provided by the GPS equipment manufacturers. After asking more than 100 people where GPS signals originated and who provided them, I received exactly two correct answers, from wives whose husbands had recently served in the military in theater.

    In my informal survey, 2% (two percent) of the respondents knew the right answers — and they had a military background. None of the true civilians had a clue. It was appalling and discouraging! Apparently General Hyten has done his homework and his point is well taken.

    We need to get the word out that GPS is totally free, provided to the world by the United States Air Force. A simple but important message. Simple yes, and certainly discouraging at this specific venue, as this is a major part of the mission of ION and JNC — educating the world about the capabilities of GPS. Now I guess we need to emphasize the basics, just as GPS acquisition has reverted to a “back to a basics” approach. I agree with General Hyten that we (all those of us who care about GPS and all that it enables) need to do the same: get out the basic message every chance we get. Join me, won’t you, in getting that simple message across?
    The next ION symposium, ION GNSS+ 2014 will take place September 8-12, 2014 at the Tampa Convention Center in Tampa, Florida. I hope to see you there.

    Thanks

    In closing I tip my hat to Lisa Beaty, the Executive Director of ION, and her entire team especially the new Military Division headed by my good friend and Institute for Defense Analyses (IDA) colleague Jim Doherty. Jim arranged  the classified Cross Talk Military Panel this year, which was the hit of the show, as it has been under Jim’s leadership for the past several years. Jim stepped down this year as the Military Division Chair during the ION JNC symposium, and he will be sorely missed, although I suspect he will still be involved in some fashion.

    The bottom line is that the ION symposia just keep getting better every year. The venues and the host hotels are first class, the food is excellent, and most of all the speakers and papers presented are scrubbed to the point that you really only get the cream of the crop. Unfortunately, you can’t say that about every GPS/PNT symposium today.

    This year the exhibitors were in a large area that allowed everyone more room, and it made for a much more relaxed atmosphere in the exhibit area. I found that I spent a great deal more time with the exhibitors this year than in years past, and what I discovered there will be the subject of several future columns.

    Until next time, happy navigating and remember, GPS comes to you courtesy of the United States Air Force.

    Aim High!

    What’s Don Reading?

    Beyond Horizons – A Half Century of Air Force Space Leadership

    David N. Spires, PhD – Professor Emeritus University of Colorado, Boulder, CO.

    Reading good history volumes is one of my favorite pass times and when it comes to an early history of Air Force Space there is none better than Beyond Horizons.

    Dr. Spires does an excellent job of setting the stage and explaining exactly how Air Force Space Command came into existence and why it was so sorely needed. The current volume covers the US Air Force and Air Force Space from its very beginnings at the end of WWII; think Dr. Theodore von Karman (Toward New Horizons) and General of the Army (Five-star) H.H. Arnold.

    General Arnold actually flew a Wright Flyer back in 1911 and would have retired as a 5-star Army General but on May 7, 1949, Public Law 58-81 changed the designation of Arnold’s final rank and grade to that of General of the Air Force, and he remains the only person to have held the rank. He is also the only person to hold five-star rank in two U.S. military services. General Arnold was instrumental in funding and authorizing research conducted by von Karman, and von Karman was instrumental in research that eventually led to an Air Force and an Air Force Space Command. It is all here in this fascinating book which is edited by longtime friends and colleagues George W. Bradley III (PhD) and Rick W. Sturdevant (PhD), who serve today as the Chief and Deputy Historians respectively at Air Force Space Command.

    I highly recommend this wonderful historical masterpiece, which is now in its third printing, and I predict will see many more versions and updates. In fact you can read it online at: http://www.afhso.af.mil/shared/media/document/AFD-110125-038.pdf

    The only pastime better than reading, this book is talking about it with the author personally, who was also a career Air Force Officer, which I have had the pleasure of doing briefly, on several occasions, and the conversations were fascinating. David is just full of interesting facts and stories concerning Air Force Space. I am convinced that if he were to commit them all to paper, there would be several volumes. I hope you enjoy this fascinating Air Force Space history.

     

  • Boeing, Northrop Grumman Enter GPS III Bid

    Northrop Grumman and Boeing have responded to a U.S. Air Force call for contractors interested in building a follow-on set of GPS III satellites, according to a report in Space News.

    Lockheed Martin is under contract to deliver the first eight GPS III satellites, but the award for up to 22 further IIIs remains open. Difficulties with the payload for the first batch of satellites mean that although the Lockheed has three space vehicles ready, it has no signal payload to put aboard them. Subcontractor Exelis is at work on that. Delivery delays have prompted the Air Force to look about for alternatives.

    Lockheed Martin itself began investigating options for its supply line last year.

    Air Force “Sources Sought” Call

    The U.S. Air Force issued an official “Sources sought” notice in June on a production-ready GPS space vehicle, equipped with an alternate payload, for consideration alongside the Lockheed Martin-built GPS III vehicle. The first phase of the contract would include two firm-fixed price contracts worth $100–$200 million to demonstrate a competitor to GPS III.

    Key requirements are that the satellite must offer a payload alternative to that built by Exelis; the satellite must be ready to launch by 2023; and the production line must turn out two to three new satellites per year.

    The second phase features a competition between Lockheed Martin and one or more other companies for as many as 22 satellites. A final contract award would be made in 2017 or 2018.

    Current GPS III contractor Lockheed Martin reportedly sent an engineering team to help Exelis expedite a resolution of payload holdups, while simultaneously investigating a switch to other suppliers, beginning with the ninth satellite in the GPS 3 series. Lockheed Martin says five companies responded to its solicitation last year.

    Air Force Gives Free Hand. Gen. Ellen Pawlikowski, head of the Air Force Space and Missile Systems Center (SMC), told the national Space Symposium in Colorado in June, “Obviously we want a GPS III that does what its supposed to do, delivered on time, and it’s up to Lockheed to manage its subcontractors. My view is if Lockheed is not happy with their subcontractors nav payload, and they believe that they can get a lower risk approach to delivering a nav payload by seeking a secondary source for that, then that’s clearly a decision for them to make.

    “They [Lockheed ] know we are disappointed at the delays that we have seen, the technical issues that their subcontractor has had, and probably they are considering whether an alternative source could provide them a better opportunity.“

    Lockheed Martin spokesman Chip Eschenfelder issued a statement: “Exelis has made good progress on the first GPS III space vehicle, SV01 navigation payload. All GPS III SV01 navigation payload components have successfully completed unit acceptance and environmental testing, with the exception of one component, the mission data unit.

    “To date, significant MDU hardware testing indicates signal cross talk issues are resolved. The SV01 navigation payload forecast delivery to Lockheed Martin is fall 2014.”

    Boeing built the platform and major payload components for the GPS IIF satellites and is one of three companies that received contracts in January 2013 to study how to improve the accuracy, coverage, and efficiency of GPS using smaller satellites.

    Northrop Grumman Aerospace of Redondo Beach, California, has already delivered deployable antenna sets to Lockheed Martin for the first six GPS III satellites. The division has delivered more than 1,000 antennas for previous generations of GPS spacecraft, Northrop Grumman said.

  • RPScan: Rapid Laser Interior Facility Plans

    Two weeks ago, GEOHuntsville held a mini conference for emergency responders hosted by Chris Johnson of A Visual Edge, Inc., Joe Francica of Directions Magazine, and AEgis Technologies.  The conference covered work being done under “The Blueprint for Safety” (BfS), a pilot effort of GEO Huntsville to support local public safety agencies with geospatial technology in the event of area emergencies.

    The goal of the pilot is to integrate existing and emerging geospatial technologies to improve multi-jurisdictional rapid response. One part of the system being used is a new on-demand, online, self-service toolset created by the National Geospatial-Intelligence Agency’s (NGA) Integrated Working Group – Readiness, Response, and Recovery (IWG-R3).  The pilot will also employ crowdsourcing, gamification, and RFID management while assembling all information in an Event Page to enhance information gathering and sharing during critical events.

    BfS

    RPScan

    One emerging technology that I found especially interesting at the conference was from Robotic Paradigm Systems, LLC of Huntsville, Alabama. It is in the business of creating rapid facility layouts using a laser scanning system. I get excited when I see technology that addresses a need using an elegant approach that is simple, effective, and low cost while also having a “light footprint.” RPScan seems to be such a technology.

    As you know, many laser scanning systems do a superb job building interior and exterior 3D models. Some systems produce such high-resolution 3D models that they look almost photorealistic, showing every minute detail. Those systems, by necessity, are also somewhat cumbersome and intrusive for the customer. The resultant models are also large and can be difficult to manage.

    Robotic Paradigm Systems took a more pragmaticm user-oriented approach. The team there realized that many users, especially emergency responders, don’t need extremely detailed 3D models that are only available for a few facilities.  What they need are “good enough” 2D models of as many facilities as possible, as soon as possible.

    RPScan Operation

    That has been the driving force behind RPScan.  RPScan is a very light, wearable backpack with an elevated sensor that “sees” above most furniture and even people in a room. Many current 3D scanning systems require stationary equipment firmly mounted on a stand in the center of a room. By comparison, RPScan captures data as the operator simply walks through the rooms in a building.  The continuous data capture is displayed on a wrist-mounted display, so verification of complete data capture is available to the operator real time. RPScan quickly maps indoor spaces, providing data that is then used to create accurate dimensional floor plans.

    rpscan capture
    Here the operator walks briskly through a church capturing 2D floor plan data.
    rpscan wrist
    The wrist-mounted screen shows the captured data as collected, thus providing continuous quality control.

    RPScan is a lightweight and mobile system that can rapidly create accurate dimensional layouts of large complex facilities. It captures spatial data of occupied buildings at an approximate rate of 75,000 square feet per hour, with roughly two hours more needed to convert the raw data to CAD floor plans depending on conditions and desired CAD details. The hardware ergonomic design is also very comfortable and unobtrusive. Watch this RPScan video of a capture session to see it in operation.

    Traditional 3D scanning systems typically use stationary hardware suites that are set up in a room. Frequently the operator has to work during off hours or ask occupants to leave the room during scanning. This stationary method of scanning is relatively easy since all measurements are captured from a fixed point and reference angle. By comparison, a mobile system, like RPScan, is more complicated because the location, position and attitude, are continuously changing during the capture process. To operate under these conditions, the system has to capture data while also accurately tracking and compensating for the equipment/operator movement. This is a proprietary feature of RPScan and the key to its efficient data-capture capability.

    Since RPScan is capturing a horizontal “slice” of data, adjusting the height of the scanner provides several advantages. Fixing the scanner height above the heads of occupants, data capture can be done without the need to evacuate rooms. Building occupants can go about their business with minimal interruption. This is especially important in facilities like hospitals that cannot easily stop operations or move occupants. The operator can quickly and unobtrusively move from room to room with only minimal disruption. Conversely, lowering the scanner height permits the capture of cubical walls or fixed furnishings such as benches and pews. Furniture can remain in rooms because it’s not necessary to view all walls in their entirety. During post-processing, continuous walls are obvious in the laser images so conversion to architecture CAD models is fairly easy.

    rpscan displayReal-Time Display

    A unique feature of RPScan is that the 2D layout is continuously displayed on a touchscreen attached to the operator’s arm.  As the operator walks through the interior space, continuous data capture is displayed as the layout image is being assembled. This real-time rendered display is more than just a convenience. It is the key to complete data capture and quality control. During the scanning process, it’s important to see areas that haven’t been scanned or areas that may need to be scanned more thoroughly. Since scanning efforts typically involve onsite data collection followed by off-site post processing, seeing results immediately builds confidence that the visit to the facility has been thoroughly and properly detailed.  This minimizes the possibility of a return trip to recapture an area that may have been missed or poorly scanned.

    Another valuable feature of RPScan is that it can simultaneously record linked audio and video during the entire capture process.  This linking of audio, video, and location is a powerful capability and could be used to enhance first responder pre-plans by permitting virtual walkthroughs.

    Uses of 2D Data

    The high cost of 3D scanning systems and software can become a barrier for use in many applications. Some users cannot justify the complexity and cost of high-end 3D data capture and modeling when a 2D model would suffice. Some examples where 2D data has proved effective include:

    • Interior design
    • Firefighter pre-plans
    • Architectural firms (initial survey and proposal)
    • Building remodel/renovation
    • Real estate sales
    • Homeland security (interior mapping, tactical response, rescue, recovery)
    • In-store people tracking for marketing
    • In-store marketing material placement
    • Archeology
    • Facility management 

    Future Applications

    There have been significant advancements in GPS, IMUs, RFIDs, and other micro-technologies embedded in mobile devices, but much of this new capability also needs a “base map” to register the tracked locations. Thanks to overhead and ground-level imagery assembled by national agencies, Google, and Microsoft, we have very rich data sets of our exterior world. However, to fully exploit indoor tracking technology, we will need equally robust building interior maps. Until we have BIM models of all buildings, I believe that 2D mapping will fill that void faster than other options. Robotic Paradigm Systems, with its RPScan system, seems well positioned to lead the indoor mapping effort.

    For more information contact:

    Tim Coddington
    [email protected]
    (256) 694-3940

    Lynn Coddington Gilbert
    [email protected]
    (678) 428-0935

    P.S. I’m always looking for new technology to share with my readers, but my view is limited. If you know of new technology that others might find interesting, please drop a note in the comments section so I can investigate and possibly provide some visibility for the technology.

  • FAA Issues First Commercial UAS Authorization over Land

    FAA Issues First Commercial UAS Authorization over Land

    Like it or not, as a person who works with geospatial data, UAS (unmanned aerial systems such as drones and UAVs) are in your future. The upside of said technology for “quick and dirty” mapping is undeniable.

    GNSS plays a key role with UAS, just like it plays a key role in classical photogrammetry. In fact, UAS may even push GNSS technology into areas where it hasn’t gone. For example, L1 RTK. I wrote about L1 RTK technology several years ago, and while several products attempted to exploit it, L1 RTK never was adopted in any significant numbers, primarily due to the short baseline, clear sky, and longer initialization requirements. However, UAS may change that because, by their nature, they work with short baselines, clear sky environments and require some setup time, at least enough for L1 RTK initialization.

    However, before we get ahead of ourselves, the regulatory machine (the Federal Aviation Administration) must publish regulations that provide guidelines on the use of UAS for commercial operations. In June, amidst its recent enforcement actions, the FAA issued its first commercial authorization for mapping UAS over land in the U.S. The FAA issued a Certificate of Waiver or Authorization (CoA) to BP to conduct aerial surveys in Prudhoe Bay, Alaska. According to the FAA, the first flights took place on June 8 and used a AeroEnvironment 13.5 lb. Puma AE fixed-wing UAS with a nine-foot wingspan.

    AeroEnvironment Puma AE UAS. 9.2' Wingspan. 13.5 lbs.
    AeroEnvironment Puma AE UAS. 9.2′ Wingspan. 13.5 lbs.

    According to a Wall Street Journal article, AeroEnvironment spokesman Steve Gitlin said it took about a year and considerable financial investment to win FAA approval for the BP project. Curt Smith, a director in BP’s technology office, said that manned aircraft are sometimes less expensive per flight than the AeroVironment devices, but that the drones will gather far more data, enabling BP to operate “more effectively, more safely, and at a lower cost.”

    The FAA announced that last summer that it issued restricted category type certificates to the Puma and Insitu’s Scan Eagle, another small UAS. The certificates were limited to aerial surveillance only over Arctic waters. The FAA recently modified the data sheet of the Puma’s restricted category type certificate to allow operations over land after AeroVironment showed that the Puma could perform such flights safely.

    Texas A&M University Becomes Fourth Operational UAS Test Site

    In further UAS news, the FAA announced on June 20 that Texas A&M University – Corpus Christi became the fourth of six UAS test sites to become operational. The FAA issued a CoA for the university to use an 85 lb AAAI RS-16 UAS with a ~13-foot wingspan. The other five UAS test sites are Griffiss (NY) International Airport, North Dakota Department of Commerce, State of Nevada, University of Alaska, and Virginia Polytechnic Institute and State University.

    American Aerospace RS-16 UAS. 12'11" Wingspan. 85 lbs.
    American Aerospace RS-16 UAS. 12’11” Wingspan. 85 lbs.

    The FAA UAS Legal Stuff

    Despite its setback when an NTSB administrative law judge ruled against the FAA in March 2013, the FAA sternly maintains its position that commercial operations of UAS in the U.S. are strictly prohibited without a CoA. In fact, just this week (June 23), the FAA issued a press release about a Federal Register Notice the FAA published of its interpretation of UAS rules for model aircraft in the FAA Modernization and Reform Act of 2012. In the Act, the Sec. 336 Special Rule for Model Aircraft reads:

    SEC. 336. SPECIAL RULE FOR MODEL AIRCRAFT

    (a) IN GENERAL.—Notwithstanding any other provision of law relating to the incorporation of unmanned aircraft systems into Federal Aviation Administration plans and policies, including this subtitle, the Administrator of the Federal Aviation Administration may not promulgate any rule or regulation regarding a model aircraft, or an aircraft being developed as a model aircraft, if—

    (1) the aircraft is flown strictly for hobby or recreational use;

    (2) the aircraft is operated in accordance with a community-based set of safety guidelines and within the programming of a nationwide community-based organization;

    (3) the aircraft is limited to not more than 55 pounds unless otherwise certified through a design,  construction, inspection, flight test, and operational safety program administered by a community-based organization;

    (4) the aircraft is operated in a manner that does not interfere with and gives way to any manned aircraft; and

    (5) when flown within 5 miles of an airport, the operator of the aircraft provides the airport operator and the airport air traffic control tower (when an air traffic facility is located at the airport) with prior notice of the operation (model aircraft operators flying from a permanent location within 5 miles of an airport should establish a mutually-agreed upon operating procedure with the airport operator and the airport air traffic control tower (when an air traffic facility is located at the airport)).

    (b) STATUTORY CONSTRUCTION.—Nothing in this section shall be construed to limit the authority of the Administrator to pursue enforcement action against persons operating model aircraft who endanger the safety of the national airspace system.

    (c) MODEL AIRCRAFT DEFINED.—In this section, the term ‘‘model aircraft’’ means an unmanned aircraft that is—

    (1)    capable of sustained flight in the atmosphere;

    (2)    flown within visual line of sight of the person operating

    (3)    the aircraft; and

    (4)    flown for hobby or recreational purposes.

    You can read more (lots more) about the FAA’s interpretation of the Act here. You can submit a comment on the FAA’s interpretation of the Act here. The comment period ends July 25.

    More FAA UAS Legal Stuff

    On June 25, the FAA issued a press release announcing that seven aerial photo and video production companies requested regulatory exemptions from the FAA to operate UAS before the FAA UAS rule-making is finalized. According to the FAA, “the Motion Picture Association of America facilitated the exemption requests on behalf of their membership. The firms that filed the petitions are all independent aerial cinematography professionals who collectively developed the exemption requests as a requirement to satisfy the safety and public interest concerns of the FAA, MPAA, and the public at large.”

    From the FAA press release, “The FAA published a brief summary of the petition from Astraeus Aerial in the Federal Register. The agency opted to ask for comments only on the Astraeus petition because that company’s request came in first, and the petitions from the other six companies ask for identical exemptions.”

    Interestingly enough, the FAA is soliciting public comment before it makes a ruling on the MPAA request, clearly highlighting the tremendous pressure the FAA is under to integrate commercial use of UAS in the U.S.

    More Commercial Use of UAS Despite what the FAA Says

    Back in February, I wrote an article entitled FAA Says Commercial Drone Operations Are Illegal… Public Says So What? discussing the expanding use of UAS in the commercial sector before the FAA rule-making on UAS was completed. To compound the FAA’s challenge, in March an NTSB Administrative Law Judge ruled against the FAA in an enforcement action the FAA attempted to impose on Rafael Pirker: a fine of $10,000 for commercial use of UAS and other violations.

    The NTSB ruling against the FAA fueled the commercial UAS fire and certainly gave commercial UAS operators, operating illegally according to the FAA, more confidence that the FAA may not pursue them. That might be the case in an incident publicized last week in Seattle, Washington, where a woman called police after she saw a UAS buzzing around outside of her apartment building, believing it was spying on her 26th-floor apartment. The Portland, Oregon-based UAS operator, Skyris Imaging, was interviewed by Portland’s KATU news.

    “It was not our intent to view anything other than the views from a 20-story office building that will be built across the street,” said Skyris’s Joe Vaughn. Vaughn told KATU that a Seattle-based developer hired Vaughn’s company to use one of his drones equipped with cameras to take photos of the view for a new 20-story building.

    Vaughn told KATU that his company has a fleet of six drones he says he responsibly flies. He told KATU that his company has strict guidelines to never fly for a third party, over crowds, above 400 feet, or beyond visual range. Click below to view the KATU interview.

    Live Webinar at the Esri International User Conference

    In a GPS World first, we’ll be producing a live webinar from the Esri International User Conference on Thursday, July 17, @ 10 a.m. Pacific Time in the exhibit hall at the San Diego Convention Center. Of course, the webinar will be focused on one of the hottest topics: high-precision mobile GIS. It will cover high-precision GNSS on mobile devices, from iPads to Android tablets to smartphones.

    Tune in or join us live from the exhibit hall floor! Register here.

    Thanks, and see you next month.

    Follow me on Twitter at https://twitter.com/GPSGIS_Eric

  • Innovation: Not Just a Fairy Tale

    Innovation: Not Just a Fairy Tale

    A Hansel and Gretel Approach to Cooperative Vehicle Positioning

    By Scott Stephenson, Xiaolin Meng, Terry Moore, Anthony Baxendale, and Tim Edwards

    MEET GEORGE JETSON.Those of us of a certain age will remember the animated TV sitcom The Jetsons, which featured George Jetson, “his boy Elroy, daughter Judy, and Jane, his wife.” It portrayed life in 2062, 100 years after the series debuted in 1962.  George and his family used many futuristic gadgets including robot maids, talking alarm clocks, flat-screen TVs, and flying automated cars. Many of those devices are already available, well ahead of schedule. But flying cars are not quite with us yet. However, asphalt-hugging automated vehicles are already here, albeit still in limited numbers. Google created a buzz recently with tests of its self-driving car. Google’s cars were developed as an outcome of the Defense Advanced Research Projects Agency’s 2005 Grand Challenge in which teams created autonomous vehicles and raced them through a challenging road course.

    Self-driving cars use a host of sensors to determine their position with respect to their surroundings and to navigate a chosen route legally and safely. Although wide-spread ownership of self-driving cars might still be a ways off, drivers of conventional vehicles will soon benefit from the research being conducted to provide them with positional awareness of other vehicles in their vicinity. This work may be characterized as part of the larger effort in developing intelligent transportation systems or ITS.

    What is ITS? In the words of ITS Canada, it’s “the application of advanced and emerging technologies (computers, sensors, control, communications, and electronic devices) in transportation to save lives, time, money, energy and the environment.” This definition applies to all modes of transportation, including ground transportation such as private automobiles, commercial vehicles, and public transit, as well as rail, marine, and air modalities. The term ITS includes consideration not only of the vehicle, but also the infrastructure, and the driver or user, interacting together dynamically.

    Just looking at ground transportation, there are many ITS developments underway, some of which are already implemented to some degree including systems for vehicle navigation, traffic-signal-control, automatic license-plate recognition, parking guidance, and road lighting to name but a few.

    An important aspect of ITS is cooperative vehicle communication, which includes transmission of data vehicle–to–vehicle or vehicle–to–infrastructure (and vice versa — known by the abbreviation V2X. Data from vehicles can be acquired and transmitted to other vehicles or to a server for central fusion and processing. These data can include accurate real-time vehicle coordinates, which can be used to improve driver situational awareness and to monitor traffic flow for example.  This use of V2X is known as cooperative vehicle positioning.

    Several technologies are being developed for accurate cooperative vehicle positioning including lidar, radar, image-based cameras, ultra-wideband, and signals of opportunity. But GNSS also has a role to play. In this month’s column, team of British researchers turn to a children’s fairy tale for inspiration in their development of a cooperative vehicle positioning approach using carrier-phase observations — another innovative application of real-time kinematic or RTK GNSS technology. 


    “Innovation” is a regular feature that discusses advances in GPS technology and its applications as well as the fundamentals of GPS positioning. The column is coordinated by Richard Langley of the Department of Geodesy and Geomatics Engineering, University of New Brunswick. He welcomes comments and topic ideas.


    There is little doubt in the benefit gained from cooperative modes of road transport, as agents working together generally perform better. In simple terms, this is the holistic idea that the whole is greater than the sum of its parts, commonly known as synergy. On top of this clear advantage, the complex systems theory of emergence suggests that novel strategies will develop from the as-yet-undefined patterns and structures. It is clear, however, that to facilitate this development certain technological advances need to be achieved. In this case, individual road agents need to accurately identify their location, and communicate easily and safely with other agents. This is a shift away from protective and passive systems toward preventative and active transport safety.

    Cooperative driving, or vehicle-to-vehicle or vehicle-to-infrastructure driving (V2X), is proposed as the next major safety breakthrough in road transport. An example of the concept is shown in FIGURE 1 It involves agents in the road transport environment communicating on local and national levels in real time, to maximize the efficiency of movement, dramatically reduce the number of accidents and fatalities, and make transportation more environmentally friendly.

    Figure 1. Vehicle-to-vehicle communications as envisioned by the United States Department of Transportation.
    Figure 1. Vehicle-to-vehicle communications as envisioned by the United States Department of Transportation.

    In the U.S., the National Highway Traffic and Safety Administration has commented that connected vehicle technology “can transform the nation’s surface transportation safety, mobility and environmental performance,” with industry experts predicting the widespread uptake of the technology within five to six years. This provides an opportunity for road vehicles to share GNSS information.

    To an extent, this is possible with current technology. Communication is fairly pervasive and pretty robust, with the explosion in personal handheld mobile devices, using the GSM/GPRS, 3G, and 4G cellular communications networks. Positioning systems exist now that will provide a reasonably accurate and reliable location most of the time. However, the type of applications included in cooperative driving demand much higher performance from these positioning systems. For instance, as shown in the example in FIGURE 2, two vehicles approaching an intersection at relatively high speeds require accurate and reliable high output position information, and an ability to communicate with one another, in order to assess the likelihood of collision.

     Figure 2. Vehicles approaching a road intersection would benefit from V2X communication.
    Figure 2. Vehicles approaching a road intersection would benefit from V2X communication.

    These requirements are partly inter-linked, and can be mutually beneficial. For instance, communications methods can be used to share information to aid positioning, and some existing positioning systems can also be utilized to share information.

    Many recent solutions in vehicle tracking research have shifted the GNSS receiver to a supplemental role in the positioning system, favoring an inertial device as the core of the integrated solution. The clear advantage is that an inertial device operates continuously, although other sensors are required to achieve the required navigation performance. The GNSS receiver is demoted because of its inherent limitations, namely the requirement of a clear view of the satellites and the availability of correctional information.

    Most vehicle positioning research over the past two decades has focused attention on GNSS-centered systems, as evidenced by the abundant use of satnav devices used to assist in-car navigation. Despite its apparent monopoly over vehicle positioning in the commercial sector, the most
    successful systems developed to guide autonomous vehicles either relegate GNSS to one of a suite of sensors, or almost disregard it altogether. This is often due to its apparent lack of positioning accuracy or availability. Popular terrestrial positioning sensors include lidar, radar, image-based cameras, ultra-wideband (UWB), and signals of opportunity. Clearly, the combination of different complementary sensors is important, but it would be a mistake to discount the more advanced GNSS positioning techniques that are available, especially with the expansion of the four global GNSS services.

    Cooperative Positioning

    The positioning of GNSS receivers relative to one another is a common application in transportation, such as during the aerial refueling of an airborne fighter jet by a tanker. In this case, it is important to know accurately the relative position of the two airplanes, but not necessarily their absolute position.

    Relative positioning of road vehicles is more complex. By their nature, road vehicles are almost always close to other vehicles or road infrastructure, and there are many separate agents in each scenario. Vehicles can also travel large distances, and in terms of GNSS positioning, this may mean vastly different atmospheric conditions. Hence, relative positioning in road transport is useful if all GNSS receivers relate to the same datum, which in most cases is effectively absolute positioning.

    Some previous work carried out by others concentrated on using GNSS code (pseudorange) and Doppler measurements for the relative positioning of vehicles, because it offers a simpler implementation method and is not susceptible to the cycle slips attributed to carrier-phase measurements. However, this means sacrificing the higher accuracy solution available from carrier-phase measurements. A major obstacle to GNSS positioning for V2X applications is the likely scenario of mixed receiver and antenna technology between vehicles. This has a major influence on the performance of relative positioning. By comparing various V2X relative positioning solutions, researchers found that an increase in positioning accuracy was typically accompanied by a decrease in availability and an increased demand for transmission bandwidth between the vehicles.

    RTK GNSS Positioning. Real-time kinematic (RTK) GNSS positioning can be used to provide a solution at an accuracy of better than 5 centimeters (horizontal). This relies on the static reference receiver being located within 20 kilometers of the roving receiver, observing a good selection of common satellites with dual-frequency receivers.

    When RTK positioning is used, the distance to the reference station has a bearing on the successfulness of the integer ambiguity resolution. A short baseline will benefit from a closer correlation of errors, due to the GNSS signals traveling through very similar parts of the atmosphere. Assuming each receiver is observing common satellites, this similarity will typically result in a higher success rate in the ratio test using the common Least Squares Ambiguity Decorrelation Adjustment, or LAMBDA, technique. This is particularly important following a GNSS outage.

    GNSS positioning of road vehicles using RTK or network RTK (where a network of reference stations replaces a single RTK reference station) can provide highly accurate (< 5 centimeters), high integrity, real-time tracking information with little delay and at a high output rate. The proliferation of network RTK GNSS positioning systems has increased dramatically over the last decade. Network RTK GNSS positioning can minimize the spatial decorrelation of errors that is a characteristic of single-reference RTK positioning as distance increases between reference and rover receivers. This allows the wide mobility range demanded from automotive applications.

    The transmission protocol of network RTK corrections is typically RTCM v3.0 or higher, and the composition of the correction information varies depending on the commercial service provider. The most common type of correction message format is that for a virtual reference station (VRS), although the most comprehensive and versatile method is the master-auxiliary concept (MAC). See references in Further Reading for details.

    In V2X and other intelligent transportation systems (ITS) applications, the position must be accurate, reliable, available, and continuous. Previous research has shown that network RTK GNSS positioning can deliver a highly accurate and precise solution in an ideal observation environment. In one test, more than 99 percent of the observations lay within 2 centimeters of the truth solution, with a very small number of anomalous results of up to 20 centimeters.

    The availability of a network RTK solution is determined by the availability of GNSS signals and the network RTK corrections. As network RTK positioning uses carrier-phase observations, GNSS outages and cycle slips significantly affect the performance of a receiver. However, the re-initialization of the fixed integer ambiguity resolution following a GNSS outage (such as caused by an overhead bridge) can be relatively fast. But from a cold start, the ambiguity resolution can take up to two minutes. This limits the widespread adoption of the technology for vehicle positioning.

    NGI Road Vehicle and Electric Locomotive Testbeds. We have carried out research at the Nottingham Geospatial Institute (NGI) using state-of-the-art testing facilities. These bespoke in-house facilities allow repeated controlled experiments, and are a useful tool in the development of ITS and V2X technology.

    To test the positioning performance thoroughly and under real-world conditions, we carried out experiments using the NGI’s road vehicle, which is equipped with a collection of on-board ground-truth systems.

    Also, the roof of the Nottingham Geospatial Building (home of NGI) is the location of a remotely operated electric locomotive running on a 200-millimeter-gauge railway track. A photograph of the locomotive and plan of the track are shown in FIGURE 3. The locomotive can carry a selection of various positioning instruments, such as GNSS receivers, inertial navigation system (INS) devices, and tracking prisms, and can travel at a speed of over three meters per second. The position of the track is accurately known, and has previously been scanned at a resolution of 2 millimeters.

    Figure 3. The NGB2 reference base station and electric locomotive track on the roof of the Nottingham Geospatial Building.
    Figure 3. The NGB2 reference base station and electric locomotive track on the roof of the Nottingham Geospatial Building.

    Three control solutions are used to assess the performance of the cooperative positioning techniques in real-world tests: An RTK GNSS control solution provided by a local static continuously operating reference station (CORS); a network RTK GNSS solution based on the MAC standard; and a
    dual-frequency GPS/INS system. Each vehicle also can be independently tracked using survey-grade total stations or a proprietary UWB  positioning system.

    Sharing Network RTK Corrections

    If vehicles could communicate with one another on the road, this would help overcome the communication system limitation in network RTK positioning of road vehicles. For instance, if vehicle A has an external connection to a network RTK service provider (such as a mobile Internet connection) and a local connection to a second vehicle (B), then it could share its network RTK correction messages directly. Effectively, vehicle A would re-broadcast the correction information it has received from the corrections provider to the receiver on vehicle B. However, this would rely on the functional capability of the receiver of vehicle B, as network RTK real-time processing can be computationally intensive.

    Not all network RTK correction messages can be shared in this way, and the range over which the correction messages are still valid needs to be determined. As vehicles communicating with V2X devices are likely to be relatively close (a few hundred meters at most), the feasibility of sharing network RTK information is good. 

    However, the network RTK VRS technique may offer more advantages. It is the most common form of network RTK used around the world, and requires significantly less bandwidth (approximately 10 kilobits per second at 10 Hz). The rover receiver is also less burdened by processing requirements. A VRS system operating on buses in Minnesota restricts the baseline to 2 miles, by updating the VRS location every 2 minutes.

    Correction messages typically have a lifespan of 10 seconds. After this time, the receiver determines the messages to be too old and does not compute a fixed-integer position. It can, however, use the information to calculate a differential GNSS (DGNSS) position. Therefore, the relayed message must arrive at the receiver on vehicle B well within 10 seconds. Previous trials at NGI found that the typical message latency of the original correction message reaching vehicle A via a GSM/GPRS connection is 0.85 seconds. The additional V2X communication to transfer the message to vehicle B should not add a significant delay.

    Capturing Network RTK Messages. To demonstrate the potential benefit of sharing network RTK messages between vehicles, network RTK messages were captured on board a vehicle and shared with a second vehicle. Vehicle A is the NGI van, and vehicle B is the NGI electric train. Most off-the-shelf network-RTK-enabled GNSS receivers are designed to communicate directly with the network RTK server using a connected communication device (GSM modem, UHF/VHF radio, cell phone, and so on), which typically provides a stable connection to minimize data loss.

    To intercept the network RTK correction message, the GNSS receiver was set up to simply accept the correction message from a smartphone via Bluetooth. In this case, the connection to the network RTK service provider is established between the smartphone and the network RTK server. An application running on the smartphone (as shown in FIGURE 4) requests information from the network RTK server, logs the data, and passes the message directly to the Bluetooth-connected GNSS receiver on vehicle A. By intercepting the correction message, it can also be forwarded on to a second receiver, in this case on vehicle B.

    Figure 4. Flowchart showing the capturing and sharing of network RTK correction messages (left), and the NTRIP client program running on an Android smartphone (right).
    Figure 4. Flowchart showing the capturing and sharing of network RTK correction messages (left), and the NTRIP client program running on an Android smartphone (right).

    Sharing Messages with Second Receiver. FIGURE 5 shows the positioning solutions generated by a shared-network-RTK correction message. The original message was captured by the smartphone application operating on board vehicle A (the NGI van), and applied to GNSS observations made by a receiver on vehicle B (the NGI train). The baseline between the two vehicles was less than 100 meters, and the location of the VRS requested from the network RTK server was the NGI building (in geodetic coordinates to three decimal places). As Figure 5  clearly shows, the shared VRS corrections are equally valid for any receiver operating in the vicinity of the VRS. The thick red line is the fixed position of the train track, and the thin blue line represents the positions generated by the GNSS receiver using the shared network RTK corrections.

    Figure 5. Sharing the network RTK message from vehicle A to vehicle B.
    Figure 5. Sharing the network RTK message from vehicle A to vehicle B.

    The VRS message type was chosen because it requires much less bandwidth, takes less processing capacity, and is prevalent among legacy receivers. Network RTK users typically require download speeds of 1.8 kilobits per second (VRS) and 5.6 kilobits per second (MAC). This is well within the typical speeds available from cellular wireless communications, which offer 80 kilobits per second downlink speeds from 2.5G systems to beyond 40 megabits per second for recent 4G systems.

    The GNSS receiver on vehicle B is operating in an ideal location, with a clear view of the sky and a high number of visible satellites, which improves the probability of successful RTK ambiguity resolution.

    Generating Pseudo-VRS Corrections

    The potential benefit to GNSS positioning of using V2X communication between various road vehicles and infrastructure can be expanded by the implementation of pseudo-VRS positioning. This system resembles the children’s fairy tale Hansel and Gretel, where in order to help remember the route through a forest that guides them back to their home, Hansel drops markers along the path (in separate cases small white pebbles, and then breadcrumbs). By using the markers, the children can navigate their way through the forest, but without them they are left lost and disoriented.

    The pseudo-VRS system uses a similar principle, where vehicle A marks its path by leaving behind small packets of information that can be used by other nearby vehicles. The small packets of information are VRS-like, and are broadcast using V2X communication devices and technology. Like the breadcrumbs in the fairy tale that are eaten by birds shortly after being dropped by Hansel, these VRS-like packets of information have a short lifespan.

    VRS Requirements. It has been long established that a short baseline between reference and rover receivers leads to more accurate and successful relative GNSS positioning. A short baseline can effectively deal with satellite orbit and atmospheric errors, which become difficult to deal with as the baseline length grows, and is the reason why RTK GNSS positioning is typically limited to baselines shorter than 20 kilometers. A typical RTK baseline may be between 1 and 10 kilometers long, but it is still beneficial to reduce the baseline further, particularly if there is a large difference in elevation. This is enabled by the VRS network RTK technique. By using the observation data from several permanent reference stations that surround the rover location, a virtual reference station is created close to the location of the rover, including virtual observation measurements and position. This VRS information is transmitted to the rover, and the rover receiver treats the information like that of a real reference station. This technique can deliver better than 5-centimeter accuracy up to 35 kilometers.

    The principle builds on the transfer of measurements made at the real reference stations to the VRS. The carrier-phase measurement at the real reference station ( E-sr ), shown in Equation 1, is made up of the geometric distance between the receiver and satellite ( E-1a  ), the integer ambiguity ( E-1c  ), and the receiver and satellite clock bias (E-1b ). The key to the VRS technique is that the integer ambiguity and the receiver and satellite clock bias are not location dependent, so they can be transferred directly to the virtual reference station from the real reference station.

    E-1   (1)

    By differencing the carrier-phase equation of the real and virtual reference stations ( E-2b  and  E-2a, respectively), the ambiguity and clock errors are canceled. The result is shown in Equation 2.

     E-2  (2)

    By combining the carrier-phase measurement equations at the real and virtual reference stations, only two unknown terms remain. The first includes the position of the VRS (  E-2c ), which is, in principle, arbitrary and is typically the approximate location of the rover receiver. The second is the observable of the VRS ( E-2d ), which can now be obtained without actually measuring it. (In practice, the technique is a little more complex, as satellite orbit and atmospheric errors and biases need to be modeled for the VRS position). The VRS information can then be packaged using the RTCM standards and delivered to the rover receiver to enable network RTK VRS positioning.

    Pseudo-VRS. Using the established VRS techniques and standards described above, we propose to use the GNSS observations and subsequent position information to simulate the existence of a VRS (see FIGURE 6). Imagine vehicle A carries a GNSS receiver together with the means to calculate   its position accurately (for instance, it is also receiving differential corrections or has other positioning devices on board). So long as the receiver can successfully resolve the integer ambiguity, it can also produce each component required to describe a VRS. Clearly in this case, the receiver on vehicle A is a “real” reference station, but the existing VRS standards can be exploited to transfer this information to other local GNSS receivers. For instance, a receiver operating on vehicle B can use the information as a local real-time differential correction service.

    Figure 6. The flow of data during the generation and sharing of pseudo-VRS data.
    Figure 6. The flow of data during the generation and sharing of pseudo-VRS data.

    Because the VRS technique is well established (the most popular form of network RTK positioning), legacy receivers are able to take advantage of this pseudo-VRS information. RTCM standards are also well defined for the transfer of GNSS information in this form. 

    The pseudo-VRS information is valid for several seconds, so the delays introduced in transferring the information from one vehicle to a second can easily be accommodated. Like any communication device based on radio waves, V2X communication devices are likely to be subject to a level of delay and message loss that requires redundancy in the system. It is important that during one epoch the whole pseudo-VRS message is delivered, as there is little similarity between one epoch and the next. The original reference receiver is likely to be on a moving vehicle.

    Effectively, the pseudo-VRS imitates the VRS in Equation 2 by providing the virtual reference station coordinates and carrier-phase observable. The information is also delivered to the second receiver in the same format RTCM message. A slight difference here is that only one-way communication is needed — the original coordinates of the VRS do not need to be supplied by the second receiver.

    The pseudo-VRS processing is carried out using the RTKLIB open source software. RTKLIB has limited options to vary the position of the base station during RTK positioning, so the program is seeded with customized configuration files and run independently for each epoch. This creates an additional feature: The processing of each epoch has no effect on any other.

    Vehicle-to-Vehicle Communication. As we just consider the exploitation of V2X devices in this article, the nature of the communication medium is not under test. For this reason, off-the-shelf wireless routers (2.4 GHz) were used to communicate between vehicles, using fixed local IP addresses. However, the performance of the routers under cooperative driving tests is limited by range, multipath, and signal obstruction.

    Real-World Tests

    To generate significant test results, some of the following tests use recorded and replayed data.

    Test Setup. To test the performance of a pseudo-VRS positioning system, and the success of different configurations, real-world tests were carried out at the Nottingham Geospatial Institute. Two vehicles were used. Vehicle A was the NGI’s road vehicle, and vehicle B was the NGI’s electric locomotive. As the position of the locomotive test track is very accurately known, this can be used to measure the performance of the pseudo-VRS system.

    Vehicle A was equipped with six GNSS receivers, a tactical-grade INS system, and a wheel odometer, and tracked using a total station and 360º prism. This provided multiple position solutions to ensure significant results.

    Vehicle B was equipped with a GNSS receiver, and tracked using a proprietary UWB system for related V2X tests.

    Also, on the roof of the NGB, and lying inside the track perimeter, is the NGB continuously operating reference
    station. This hyper-local reference station allows local RTK solutions, and acts as a barometer of GNSS activity when tests are episodically carried out.

    FIGURE 7 shows an aerial image of the test scenario. The Google background shows the NGB to the west, and surrounding roads to the south and west (still under construction during the image acquisition). The thin yellow line is a ground distance of 100 meters. The red dots signify the position of vehicle A (in the east), and the purple dots show the position of vehicle B (on the roof of the NGB building). The accuracy of the Google image is unknown, and is used here purely for illustrative purposes.

    Figure 7. Aerial image of the test.
    Figure 7. Aerial image of the test.

    Test Results. These tests are designed to show the performance of a pseudo-VRS system using a V2X communication system. However, the results shown here were created using recorded raw data. The test results will help to design the correct RTCM message to share between vehicles in future tests.

    To simulate the operation of a pseudo-VRS system, vehicle A must share its known absolute position and some raw RINEX information for each epoch with vehicle B. Vehicle B can then use this information, together with its own observed RINEX data, for the same epoch to calculate its known absolute position. In practice, there will be a slight delay in the delivery of the information from vehicle A (much like in a traditional RTK system), so that information from concurrent epochs are unlikely to be used.

    The RTKLIB software cannot directly handle the variation of a base station’s coordinates (and output an absolute solution), so a small separate script was designed to utilize the processing capability of the software in a pseudo-VRS system.

    FIGURE 8 shows the results of pseudo-VRS positioning. During dual-frequency tests, 99.67 percent of observations achieved fixed ambiguity (1197/1201). During single-frequency (broadcast ionosphere) RTK, 61.45 percent (738/1201) observations achieved fixed ambiguity. The ratio test threshold was 2.0. Around the area of 454930E 339708N, the number of common visible satellites dropped from eight to seven, and then again from seven to six three seconds later. This caused each of the three solutions to degrade slightly. The dual-frequency RTK solution briefly lost its fixed ambiguity solution (for two epochs, or 0.1 seconds), before regaining the fixed solution. The single-frequency RTK solution could not achieve a fixed ambiguity solution again until the number of common visible satellites returned to seven (five seconds after the initial satellite was lost). The DGNSS solution saw a similar degradation in its solution during this period.

    Figure 8. Results from pseudo-VRS positioning.
    Figure 8. Results from pseudo-VRS positioning.

    The mean coordinate errors for the three solutions are 0.054, 0.707, and 0.323 meters (1 standard deviation, 3D), as shown in Table 1. This is compared to a solution calculated using the local CORS base station. The error in horizontal and vertical follows the typical ratio of 1:2. Test results were also completed using a lower pseudo-VRS update rate. At 1 Hz, the results prove even better. Although the latency of the correction is up to 1 second (positioning is calculated epoch by epoch), the results were better than updates at 20 Hz. The dual-frequency RTK solution achieved a fixed ambiguity at every epoch (100 percent), and when compared to the known track position appeared correctly fixed. The single-frequency RTK solution achieved a fixed ambiguity for 70.02 percent (897/1201) of the observations; a slight improvement over the 20-Hz results.

    Table 1. Results from pseudo-VRS positioning.
    Table 1. Results from pseudo-VRS positioning.

    Table 2 shows the performance of the pseudo-VRS system under different latency scenarios. This is important because a message transmitted by vehicle A may be delayed or newer messages may be disrupted. Once the latency of the correction message reaches 8 seconds, the performance of the positioning solution begins to drop. The number of fixed ambiguity solutions falls, and the resulting positioning accuracy also decreases. However, the solution can still deliver 20- to 30-centimeter accuracy with a message latency of up to 30 seconds.

    Table 2. Effect of message latency on positioning quality.
    Table 2. Effect of message latency on positioning quality.

    Conclusions

    This article has outlined the potential benefit of V2X technology to cooperative vehicle positioning. A vehicle that knows its absolute position accurately can assist a second vehicle to position itself using established GNSS techniques.

    The pseudo-VRS base-station location must have reasonably accurate coordinates. Without this, the correct integer ambiguity cannot be resolved, and there is the risk of an incorrect resolution giving false success. This requires good reliability and integrity of the position of vehicle A, a characteristic that can be provided by network RTK positioning but likely needs further support from alternative positioning solutions.

    Acknowledgments

    The authors acknowledge Leica Geosystems for the provision of an academic license for the SmartNet network RTK service. We thank Yang Gao and Qiuzhao Zhang of the University of Nottingham for their assistance and detailed discussion during the experimental tests. The work was supported by the U.K.’s Engineering and Physical Sciences Research Council. This article is based on the paper “A Fairy Tale Approach to Cooperative Vehicle Positioning” presented at the 2014 International Technical Meeting of The Institute of Navigation held in San Diego, California, January 27–29, 2014.

    Manufacturers

    For our tests, vehicle A (NGI’s road vehicle) was equipped with six Leica Geosystems AG GS10 GNSS receivers with individual AS10 antennas, an Applanix Corp. POS RS with Honeywell International Inc. CIMU tactical grade INS system, and was tracked using a Leica Nova TS50 total station. Vehicle B (NGI’s electric locomotive) was equipped with a Leica GS10 GNSS receiver and AS10 antenna.


    SCOTT STEPHENSON is a postgraduate student at the Nottingham Geospatial Institute (NGI) within the University of Nottingham, Nottingham, U.K.

    XIAOLIN MENG is an associate professor, theme leader for positioning and navigation technologies, and an M.Sc. course director at NGI. 

    TERRY MOORE is the director of NGI at UoN, where he is the professor of satellite navigation and an associate dean within the Faculty of Engineering.

    ANTHONY BAXENDALE is head of Advanced Technologies & Research at MIRA Ltd. (formerly the Motor Industry Research Association), an automotive consultancy company headquartered near Nuneaton in Warwickshire, U.K.

    TIM EDWARDS is a principal engineer responsible for intelligent mobility research activities within the Future Transport Technologies Group at MIRA Ltd. 


    FURTHER READING

    • Authors’ Conference Paper

    “A Fairy Tale Approach to Cooperative Vehicle Positioning” by S. Stephenson, X. Meng, T. Moore, A. Baxendale, and T. Edwards in Proceedings of ION ITM 2014, the 2014 International Technical Meeting of The Institute of Navigation, San Diego, California, January 27–29, 2014, pp. 431–440.

    • Intelligent Transportation Systems

    Proceedings of IEEE ITSC 2013, the 16th International IEEE Conference on Intelligent Transportation Systems, “Intelligent Transportation Systems for All Modes,” The Hague, The Netherlands, October 6–9, 2013.

    Overview of Intelligent Transport Systems (ITS) Developments in and Across Transport Modes by G.A. Giannopoulos, E. Mitsakis, and J.M. Salanoca, Joint Research Centre Scientific and Policy Report EUR 25223 EN, Institute for Energy and Transport, Joint Research Centre, European Commission, 2012, doi: 10.2788/12881.

    How Google’s Self-Driving Car Works” by E. Guizzo in IEEE Spectrum Blog, October 18, 2011.

    Elbow Room on the Shoulder: DGPS-Based Lane-Keeping Enlists Laser Scanners for Safety and Efficiency” by C. Shankwitz in GPS World, Vol. 21, No. 7, July 2010, pp. 30–37.

    “Driverless Cars” by R. Murray in Computing and Control Engineering, Vol. 18, No. 3, June-July 2007, pp. 14–17.

    • GNSS and Inertial Navigation Systems

    “GPS and Inertial Systems for High Precision Positioning on Motorways” by J.E. Naranjo, F. Jiménez, F. Aparicio, and J. Zato in Journal of Navigation, Vol. 62, No. 2, April 2009, pp. 351–363, doi: 10.1017/S0373463308005249.

    • Vehicle-to-Vehicle and Vehicle-to-Infrastructure Technologies

    “Implementation of V2X with the Integration of Network RTK: Challenges and Solutions” inProceedings of ION GNSS 2012, the 25th International Technical Meeting of The Satellite Division of the Institute of Navigation, Nashville, Tennessee, September 17–21, 2012, pp. 1556–1567.

    DOT Launches Largest-Ever Road Test of Connected Vehicle Crash Avoidance Technology, National Highway Traffic Safety Administration press release, August 21, 2012.

    “Relative Positioning for Vehicle-to-Vehicle Communication-enabled Vehicle Safety Applications” by C. Basnayake, G. Lachapelle, and J. Bancroft in Proceedings of the 18th ITS World Congress, Orlando, October 16–20, 2011.

    Can GNSS Drive V2X” by P. Alves, T. Williams, C. Basnayake, and G. Lachapelle in GPS World, Vol. 21, No. 10, October 2010, pp. 35–43.

    • Network RTK

    Network RTK for Intelligent Vehicles” by S. Stephenson, X. Meng, T. Moore, A. Baxendale, and T. Edwards in GPS World, Vol. 24, No. 2, February 2013, pp. 61–67.

    “A Comparison of the VRS and MAC Principles for Network RTK” by V. Janssen in Proceedings of  IGNSS2009, the 2009 Symposium of the International Global Navigation Satellite Systems Society, Gold Coast, Queensland, Australia, December 1–3, 2009.

    Introduction to Network RTK” by L. Wanninger, IAG Working Group 4.1: Network RTK (2003–2007). Online article. Last modified June 16, 2008.

    RTCM Standard 10403.1 for Differential GNSS (Global Navigation Satellite Systems) Services – Version 3, developed by RTCM Special Committee No. 104, Radio Technical Commission for Maritime Services, Arlington, Virginia, October 27, 2006.

    “Accuracy Performance of Virtual Reference Station (VRS) Networks” by G. Retscher in Journal of Global Positioning Systems, Vol. 1, No. 1, 2002, pp. 40–47.

    “An Overview of Multi-Reference Station Methods for cm-Level Positioning” by G. Fotopoulos and M.E. Cannon in GPS Solutions, Vol. 4, No. 3, January 2001, pp. 1–10, doi: 10.1007/PL00012849.

  • Berg Insight: Remote Patient Monitoring to Reach €19.4B in 2018

    Berg Insight estimates that revenues for remote patient monitoring (RPM) solutions reached € 4.3 billion in 2013, including revenues from medical monitoring devices, mHealth connectivity solutions, care delivery software platforms and monitoring services. RPM revenues are expected to grow at a CAGR of 35.0 percent between 2013 and 2018, reaching € 19.4 billion at the end of the forecast period.

    The findings are discussed in the report “mHealth and Home Monitoring” (PDF brochure).

    Savings attributable to payers and care providers will by far exceed this amount as connected care solutions can allow better health outcomes to be achieved more cost efficiently. The new care models enabled by these technologies are furthermore often consistent with patients’ preferences of living more healthy, active and independent lives.

    While the healthcare industry is advancing towards an age where connected care solutions will be part of standard practices, this progress is still far from uniform. “The growth in the remote patient monitoring market is today centred on very specific market verticals and regions. Most of the market growth in the sleep therapy segment has for instance occurred in the US and France, where frequent compliance audits are becoming more common,” said Lars Kurkinen, Senior Analyst, Berg Insight.

    He added that the telehealth market benefits from local and regional project financing in several European countries, whereas remotely monitored medication dispensers gain traction among home care providers in the Benelux and Nordic countries in particular.

    In addition to this, the first pharmaceutical companies have recently initiated rollouts of connected adherence monitoring solutions that are bundled together with specific drugs. “Another high-level development that will have a major impact on the use of connected care solutions in several countries during the coming years is the shift from fee-for-service reimbursement systems to pay-for-performance structures that emphasize cost-effective delivery of quality care,” said Mr Kurkinen. In the U.S., one example of this development is the large number of RFPs for telehealth solutions that are being issued due to the hospital readmission reduction programs.

  • Qualcomm Tops ABI’s GNSS IC Vendor Assessment, MediaTek Enters Top 3

    Qualcomm Tops ABI’s GNSS IC Vendor Assessment, MediaTek Enters Top 3

    GNSS-IC-WABI Research’s 2014 GNSS IC vendor matrix names Qualcomm as the leading GPS integrated circuit (IC) vendor, followed by Broadcom in second place. For the first time, MediaTek achieves a top three finish after another year of strong growth and robust shipments as a result of its targeted design strategy, ABI Research revealed in its “GNSS IC OEMs” report.

    The vendor matrix compares companies on 17 criteria across the broader categories of GNSS Innovation and Implementation. Qualcomm remains the dominant player with a strong ubiquitous location platform in IZat — this will be vital for success in high volume cellular handsets in 2015. It is also in a strong position to grow in other GNSS markets.

    Broadcom continues to compete aggressively through innovation, receiving the highest score for this category for yet another year. Already in 2014, Broadcom has announced its concurrent tri-band BCM 47531 IC and the BCM 4771 GNSS SoC designed for wearables, featuring a sensor hub and always-on capabilities. Finally, it has also announced its 5G Wi-Fi SoC, which supports its new proprietary FTM-based AccuLocate technology.

    u-blox has also moved up a position to fourth in this year’s assessment. It continues to grow revenue year-on-year, with little to suggest this will change in the coming year. It is also the first time u-blox has finished ahead of CSR, which was ranked fifth. CSR continues to transition and faces another arduous year in 2014. It will be 2015/16 when the effects of these tough decisions are proven out to be correct or not.

    MediaTek has now emerged as a major threat, taking third on innovation and 2012 market share rankings, following very impressive shipments of its combo ICs into local Chinese smartphone manufacturers. It is also strong on PNDs/recreational and cameras, with a growing presence in other markets. Its move to fully embedded GPS in 2013 should prove significant in driving market share in the future.

    Beyond this, STMicroelectronics also deserves a mention with its new Teseo III platform giving it significant design flexibility allowing it to compete aggressively in existing markets while expanding into new opportunities.

    Other companies discussed include:

    • Cambridge Silicon Radio (CSR)
    • Galileo Satellite Navigation
    • Intel Corporation
    • SkyTraq Technology, Inc.
    • Texas Instruments Inc.
  • LocationSmart Issued Patent for Location-Based Dynamic Status Reporting

    LocationSmart, a provider of cloud-based location and interactivity services, has announced the issuance of US Patent 8,666,373 by the U.S. Patent Office for location reporting based on the dynamic status of a user. The patent covers a system and method of determining location for the user, including dynamically determining a status of the user and allowing acquisition of the user’s location based on the determined status.

    The issued patent enhances LocationSmart’s cloud-based, cross-carrier location and interactivity platform that is powering the enterprise with location insights through a comprehensive set of web services application programming interfaces (APIs), the company said.

    This patent further covers the location reporting of a person based on a dynamically monitored status; for example, when an employee is on the job versus when the employee is on his or her own time. Reporting is responsive to the received location tracking request, based on current status and allowed permissions. This is significantly instrumental for monitoring and managing mobile workforces, LocationSmart said.

    “Knowledge of when to obtain location information based on dynamically changing status is fundamental to several of our key verticals,” said Mario Proietti, CEO of LocationSmart. “This patent strengthens the protection and rendering of our services for mobile check-ins and status reporting in the workforce management and transportation sectors.”

    The LocationSmart platform is employed by leading companies in a number of industries, enabling a multitude of applications including service assistance, proximity marketing, workforce check-ins, emergency alerting, mobile gaming and transaction verification.