GPS World

Category: Transportation

  • Google Maps Has Schedules for One Million Public Transit Stops

    Since 2005, Google has collaborated with hundreds of transit authorities around the world to make a comprehensive resource for millions of riders to find out which bus, train, subway, or tram can take them to their next destination. Today, Google Maps reports it has public transportation schedules for more than one million transit stops worldwide, in nearly 500 cities, including New York, London, Tokyo, and Sydney.

    In support of the database, Google is releasing an update to the Google Maps for Android app (version 6.10). Google said it has made some changes to the Transit Lines layer, so that the user can select a specific mode of public transportation (train, bus, tram, or subway) to display on the mobile map, hiding the other modes. This is helpful in areas where there is a tight concentration of several types of public transit, Google said.

    Left: Mobile map with all modes of public transit shown; Right: Transit Lines layer in Subway mode (Source: Google)

    Google also reported an update to the layout of station pages to be more useful. Users open it by tapping on the name of the station on your mobile map.

    Updated station pages show departure times, lines serving the station and the distance to nearby stations

     

    In addition to these new transit features, Google has updated region highlighting, My Places, and Location History displays in Google Maps for Android:
    • When a user searches for a city or postal code, the borders of that region are highlighted.
    • Under My Places are new tabs that help users access information from a single place.
    • If Location History is enabled, users can browse the places they’ve been on a daily basis with an updated Location History dashboard.
    Update to the latest version of Google Maps for Android in the Google Play store.

  • TomTom Business Solutions Debuts Software Alliance Program

    TomTom Business Solutions has launched the TomTom Software Alliance Program, a software integration, marketing, and sales program that delivers additional value to commercial fleets by integrating core TomTom fleet management technology with industry leading software, the company said. TomTom already has more than 100 industry leading software partners from the office automation, CRM, ERP, and Field Service Automation sectors as well as specialized industry software for towing, service, and transportation fleets.

    TomTom’s Software Alliance Program provides easy access to TomTom Business Solutions’ set of APIs, enabling the development of integrated “over-the-road” vehicle and driver management capabilities, the company said. Leveraging these APIs and the company’s industry-leading map data, IQ routes, and HD traffic, TomTom and its partners can rapidly deploy a host of solutions including: quickest ETA vehicle assignment, real-time ETA calculations, two-way communications for dispatching and work-order flow, integrated turn-by-turn navigation, real-time GPS tracking, and driver safety features.

    “Our fleet customers are already realizing a high degree of value from TomTom’s fleet management solutions and our value-added software partners,” said Michael Geffroy, vice president, TomTom Business Solutions. “Our decision to make more of our core technology freely available to more software companies shows our commitment to partnering. We believe our new Software Alliance program will lead to greater levels of innovation and value-add to a broader range of commercial fleets.”

    “Working with TomTom, we have significantly increased the value of our solution for our customer, and this has enabled us to generate more revenue and profits to our company,” said Jim Weaver, CEO of Tracker Management. “We are very excited about exploiting the new APIs to factor real-time traffic info into our capabilities.”

    “TomTom is an essential component of our solution and path to market,” said Greg Wietholter, president of Route Solutions. “Having a partner with a clear focus on developing over-the-road management solutions allows us to focus on our core competencies. The new software alliance program gives us more opportunities to remain competitive and on the leading edge of technology.”

  • TMW Systems Partners with FleetLocate to Provide an Integrated Approach to Trailer Utilization

    TMW Systems, provider of enterprise software to transportation and logistics companies, has announced a new partnership with Spireon. This partnership will provide for-hire carriers and private fleets with detailed information on trailer location, capacity, and trailer operations to improve utilization and compliance. The partnership provides pre-built integration between Spireon’s FleetLocate solution and TMW Systems’ TMW Suite and TMT Fleet Maintenance solutions.

    The TMW Suite integration with FleetLocate captures GPS position information from trailers, whether tethered or not. The TMT Fleet Maintenance now captures GPS position information and mileage. The integration provides automatic scheduling of preventive maintenance work based on actual miles traveled and automatically alerts the maintenance department when a trailer requiring repairs or maintenance enters the yard.

    The integrated solutions are being used by a number of fleets:

    • Bengal Transportation Services — Integration gives Bengal the benefit of viewing the entire fleet of trucks and trailers on one screen. Dispatchers have a complete view of tractors, trailers, drivers, and loads.
    • Coca-Cola Bottling Co. Consolidated — The integration provides CCBCC with a systematic way to track trailers within their TMW Suite dispatch system.
    • Matheson Trucking, Inc. — The integration provides Matheson with real-time updates when trailers move and also tracks accumulated mileage.  Operations and maintenance personnel receive a notification when a trailer is ready for service.

    “FleetLocate is a unique trailer platform that provides continual, real-time views of an entire trailer fleet,” said Scott Vanselous of TMW Systems. “Through the partnership with FleetLocate, our customers receive valuable operational and reporting capabilities within TMW Suite and TMT Fleet Maintenance software to improve utilization and reduce costs associated with their trailers.”

  • Trimble Adds RFID to its AllTrak Asset and Tool Management System

    Trimble introduced a new version of its Trimble AllTrak Asset and Tool Management System that includes an RFID scanner for its Trimble Nomad outdoor rugged handheld computer running the Microsoft Windows Mobile operating system. With RFID capabilities, the AllTrak System allows building construction contractors to more easily track and manage their jobsite assets and tools. In addition, the system increases return on investment by improving asset utilization and monitoring equipment to avoid losses.

    According to the announcement, using the Trimble Nomad with the new RFID scanner, contractors can perform a variety of functions such as asset check-in, check-out, transfers and inventory validation much faster than traditional bar code scanning by interfacing with small passive RFID tags fixed to the assets. With an effective range of 3 to 4 feet, RFID technology does not require line of sight for the tag to be read, making it an ideal technology for reading the tags of multiple assets that are in a pickup, service truck or tool crib. Users can also attach the ThingMagic USB RFID Reader to a desktop or laptop when a portable solution is not required.

    Trimble reports that by utilizing the popular RFID tag protocols “UHF EPC Gen2” or “ISO18000-6C”, the new Trimble AllTrak System is specifically designed for general contractors, as well as concrete, steel, mechanical, electrical, plumbing and site prep subcontractors who use tools with embedded or attached RFID tags that support these protocols. Trimble AllTrak distributors can also provide RFID tags that can be attached to assets.

    “With the acquisition of ThingMagic, we were able to bring their experience in RFID technology to existing platforms within the Trimble Building Construction portfolio of hardware and software solutions,” said Pat Bohle, general manager of Trimble’s Building Construction Division. “We chose the Trimble AllTrak System as the first product in the portfolio due to the logical affinity of delivering increased productivity to the process of tracking the physical whereabouts of tools and jobsite assets.”

    Trimble AllTrak with RFID support is available now through Trimble’s Authorized Distributors of layout solutions for MEP and Structures contractors.

  • Trimble Launches AP20-C GNSS Inertial OEM Module with MEMS Inertial Sensors

    Trimble AP series module

    Trimble has introduced the AP20-C, the latest addition to its AP Series of embedded GNSS-Inertial OEM boards plus Inertial Measurement Unit (IMU). Using a compact, custom-built IMU based on commercial Micro Electromechanical Machined (MEMS) inertial sensors, the AP20-C enables system integrators to achieve high-rate position and orientation measurements with exceptional accuracy, Trimble said.

    The announcement was made at AUVSI’s Unmanned Systems North America 2012 Conference and Exhibition being held this week in Las Vegas.

    Featuring proven Applanix IN-Fusion GNSS-Inertial integration technology, the AP20-C is an embedded GNSS-Inertial OEM board set plus IMU designed for continuous mobile positioning in poor signal environments and high-accuracy direct georeferencing of imaging sensors. The AP20-C delivers full, high-rate position and orientation measurements at 200 Hz, ensuring it can be used in the most demanding mobile environments without sacrificing performance. It is fully compatible with the industry-leading Applanix POSPac MMS office software for enhanced accuracy using network differential GNSS.

    “Compact in form and low in power consumption, the AP20-C can provide cost-effective, accurate, reliable and robust position and orientation measurements suitable for a broad range of survey and mapping applications, including airborne, terrestrial, and marine mapping as well as guidance for unmanned vehicle applications,” said Joe Hutton, director of Inertial Technology and Airborne Products at Applanix, a Trimble Company.

  • ABI Research: In-Car Nav Market Bottoms out at $22 Billion, New Services Key to Rebound

    ​The total in-car navigation market has been in continual decline for the last three years, but ABI Research believes it has now reached its lowest ebb. While pure navigation is unlikely to reach the highs of 2008 again, the overall market is reaching a revenue plateau, creating a solid platform on which connected in-car services can bring a new generation of revenue growth, the market research firm concluded.

    Senior analyst Patrick Connolly stated,” When we look at the decline from 2008 to 2011, there is a perfect storm of economic conditions, low-cost/free smartphone navigation, the decline of PNDs, and falling car sales. The market is forecast to reach a low of $22 billion this year, before fluctuating around the $22-$24 billion mark, as a new period of growth for factory-fitted solutions, coupled with smartphone solutions, will take in-car navigation towards saturation point in many regions by 2017.”

    Factory-fitted solutions will bring new revenue opportunities, especially for PND manufacturers, ABI Research said. But the real growth opportunity will be the additional revenues that in-car connectivity will bring. Companies are fighting for a near-30 million connected car platform market in 2017, with many of the winners and losers decided over the next two years.

    Practice director Dominique Bonte added, “The opportunity is there to leverage navigation, to bring a host of new services around driver performance, infotainment, car diagnostics, and insurance.”

    These findings are part of ABI Research’s GPS & GNSS Research Service, which includes additional Competitive Analyses, Vendor Matrices, Market Data, and Insights. In ABI Research’s quarterly service, “GPS&GNSS”, all forms of in-car navigation are considered, including factory fitted, aftermarket, PNDs, and smartphones.

  • Drone Hack: Spoofing Attack Demonstration on a Civilian Unmanned Aerial Vehicle

    By Daniel Shepard, Jahshan A. Bhatti, and Todd E. Humphreys

    
    Unmanned aerial vehicle (uav) used in the spoofing tests; owned by the University of Texas.

     A radio signal sent from a half-mile away deceived the GPS receiver of a UAV into thinking that it was rising straight up. In this way, the UAV’s dependence on civil GPS allowed the spoofer operator to force the UAV vertically downward in dramatic fashion as part of multiple capture demonstrations.

    In December 2011, Iran captured a U.S. Central Intelligence Agency (CIA) surveillance drone with only minor damage to the undercarriage of the drone, likely due to a rough landing when captured. An Iranian engineer claimed in an interview that “Iran managed to jam the drone’s communication links to American operators” causing the drone to shift into an autopilot mode that relies solely on GPS to guide itself back to its home base in Afghanistan. With the drone in this state, the Iranian engineer claimed that “Iran spoofed the drone’s GPS system with false coordinates, fooling it into thinking it was close to home and landing into Iran’s clutches.”

    Although the Iranian claims are highly questionable, this incident left many unanswered questions as to the security of GPS systems on unmanned aerial vehicles (UAVs). The CIA drone should have been guiding itself based on the encrypted military GPS signals, which would be incredibly difficult to spoof. However, some experts have conjectured that simultaneous jamming of the military signals and spoofing of the civilian signals might have worked if the drone had been programmed to fall back on the civilian GPS signals in the event that the military signals were jammed. This raises the question: How difficult would it be to spoof a UAV guiding itself based on civilian GPS signals?

    FAA Modernization Act

    In February of this year, Congress passed the FAA Modernization and Reform Act of 2012. According to the Library of Congress summary, this act “requires the Secretary [of Transportation] to develop a plan to accelerate safely the integration by September 30, 2015, of civil unmanned aircraft systems (UASes, or drones) into the national airspace system … [and] determine if certain drones may operate safely in the national airspace system before completion of the plan.”

    Such civilian UAVs would be primarily guided by civil GPS, which has been shown to be readily spoofable in the lab. This would create a significant potential hazard in the national airspace if the problem of civil GPS spoofing is not fixed. Thousands of civilian UAVs (operated by postal services, police departments, research institutions, and others) could populate the skies in only a few years while still being vulnerable to remote hijacking via GPS spoofing. The passing of the FAA Modernization Act further emphasizes the need to examine the vulnerability of UAVs to GPS spoofing.

    Test

    On invitation of the Department of Homeland Security (DHS), unclassified spoofing tests against a UAV were performed at White Sands Missile Range (WSMR) on June 19, 2012 during the DHS GYPSY test exercise. These tests demonstrated the capability of a spoofer, built by the University of Texas (UT) Radionavigation Lab, to commandeer a civilian UAV by influencing the position-velocity-time (PVT) solution of the UAV’s GPS receiver.

    The Spoofer. The civil GPS spoofer used for these tests is an advanced version of the spoofer reported in “Assessing the Spoofing Threat,” GPS World, January 2009. A schematic representation of the spoofer is shown in Figure 1. It is the only spoofer reported in open literature to date that is capable of precisely aligning the spreading codes and navigation data of its counterfeit signals with those of the authentic GPS signals. Such alignment capability allows the spoofer to carry out a sophisticated spoofing attack in which no obvious clues remain to suggest that an attack is underway.


    Figure 1. This spooler is capable of precisely aligning the spreading code and navigation data of its counterfeit signals with GPS signals.

    The spoofer is implemented on a portable software-defined radio platform with a digital signal processor (DSP) at its core. This platform comprises:

    • A radio frequency (RF) front-end that down-mixes and digitizes GPS L1 and L2 frequencies
    • A DSP board that performs acquisition and tracking of GPS L1 C/A, calculates a navigation solution, predicts the L1 C/A databits, and produces a consistent set of up to 14 spoofed GPS L1 C/A signals with a user-controlled fictitious implied navigation and timing solution.
    • An RF back-end with a digital attenuator that converts the digital samples of the spoofed signals from the DSP to analog output at the GPS L1 frequency with a user-controlled broadcast power.
    • A single-board computer that handles communication between the spoofer and a remote computer over the Internet.

    The spoofer works by first acquiring and tracking GPS L1 C/A and L2C signals to obtain a navigation solution. It then enters its “feedback” mode, in which it produces a counterfeit, data-free feedback GPS signal that is summed with its own antenna input. The feedback signal is tracked by the spoofer and used to calibrate the delay between production of the digitized spoofed signal and output of the analog spoofed signal. This is necessary because the delay is non-deterministic on start-up of the receiver, although it stays constant thereafter.

    After feedback calibration is complete and enough time has elapsed to build up a navigation data bit library, the spoofer is ready to begin an attack. Initially, it produces signals that are aligned to within a few meters with the authentic signals at the location of the target antenna but have low enough power that they remain far below the target receiver’s noise floor. The spoofer then raises the power of the spoofed signals slightly above that of the authentic signals. At this point, the spoofer has taken control of the victim receiver’s tracking loops and can slowly lead the spoofed signals away from the authentic signals, carrying the receiver’s tracking loops with it.  The target receiver can be considered completely captured when either of the following are true:

    • each spoofed signal has shifted by 2 µs relative to the authentic signals, or
    • each spoofed signal is at least 10 dB more powerful than the corresponding authentic signal.

    The latter option ensures that there is no significant interaction between authentic and spoofed signals by simultaneously jamming and spoofing.
    The UT spoofer and attack strategy have been tested against a wide variety of civil GPS receivers and have always been successful in commandeering the target receiver.

    Test UAV.  The spoofing tests targeted a University-of-Texas-owned Hornet Mini UAV supplied by Adaptive Flight, which is shown in the  opening photo. The Hornet Mini is roughly five feet long and weighs about 10 pounds when fully loaded. The Mini’s sophisticated avionics package loosely couples an altimeter, magnetometer, and a MEMS IMU package to a GPS receiver via an extended Kalman filter.

    The Hornet Mini is representative of UAVs used by law enforcement. Thus, the results of the spoofing tests with the Mini also apply to other similarly-designed UAVs, including those used in most civil applications, whose navigation systems are centered on civil GPS. It should be noted that no special alterations were made to the Hornet Mini for this test – it was in its “as sold” or “stock” configuration.

    Setup. A schematic of the setup used for the spoofing tests against the civil UAV at WSMR appears in Figure 2. The spoofer was located on a hilltop with the receive antenna on the far side of the hilltop from the transmit antenna as shown in Figure 3. The UAV site was located in a sandy basin approximately 620 meters from the transmit antenna.


    Figure 2. Schematic of the test setup.


    Figure 3. Aerial view of the test site showing the spoofer location on a hilltop and the UAV site 0.62 kilometers away.

    Procedure. The UAV was commanded by its ground controller to hover approximately 60 feet above ground level at the UAV site. After the initial ground control command was sent, the UAV maintained its hovering position automatically based on the navigation solution of its extended Kalman filter, which is based in part on GPS. At this point in the test procedure, the spoofed signals were not being broadcast: the UAV was only under the influence of the authentic GPS signals.

    The spoofer was then commanded to begin transmitting spoofed signals. To ensure seamless capture of the UAV’s GPS unit, the code phases of the spoofed signals were aligned to within meters of the authentic signals at the location of the UAV’s GPS antenna. The spoofed signals overpowered their authentic counterparts and instantly captured the tracking loops within the UAV’s GPS receiver.

    Immediately after capture, the spoofer induced a false velocity and corresponding position change in the UAV’s GPS receiver, drawing the position reported by the UAV’s extended Kalman filter away from the UAV’s commanded hover position. To compensate, the UAV’s flight controller responded by moving in the opposite direction. A safety pilot was on hand to prevent the UAV from drifting out of control.  This was necessary because by commandeering the UAV’s GPS receiver, the spoofer operator effectively breaks the UAV autopilot’s feedback control loop. The spoofer operator must now act as an operator-in-the-loop, which requires real-time, meter-level knowledge of the UAV’s true location.

    Results. Between tests WSMR and UT, the spoofer demonstrated short-term 3-dimensional control of the UAV. Thus, we conclude that it is indeed possible to hijack a civil UAV — in this case, a fairly sophisticated one — by civil GPS spoofing.

    Interestingly, the Hornet Mini relies only on its altimeter for direct measurements of its vertical position; the GPS-measured vertical position is ignored. This can be done with reasonable accuracy because of the Hornet Mini’s short flight endurance (~20 minutes). However, the GPS vertical velocity does affect the extended Kalman filter’s vertical coordinate estimate because the filter propagates GPS velocity measurements through a UAV dynamics model to form an a priori vertical estimate that gets updated with the altimeter measurements. This dependence on GPS velocity allowed the spoofer operator to force the UAV vertically downward in dramatic fashion in the final three capture demonstrations.

    Developing a full spoofer-based control system for a UAV is a difficult problem that, in addition to the requirement for real-time true position feedback, requires the spoofer to model the UAV’s feedback control behavior and to estimate the UAV’s desired path. Causing a UAV to spin out of control and crash is not difficult with a spoofer, but fine-grained control certainly is.

    Implications

    These tests have demonstrated that civilian UAVs will be vulnerable to control by malefactors with a civil GPS spoofer looking to hijack or crash these UAVs unless their vulnerability to GPS spoofing is addressed. There are several reasons why someone may want to spoof a drone including fear over drones invading people’s privacy. This poses a significant safety concern that could result in mid-air collisions with other aerial vehicles or buildings, not to mention loss of property.

    Constructing from scratch a sophisticated GPS spoofer like the one developed by UT is not easy, nor is it within the capability of the average anonymous hacker. It is orders of magnitude harder than developing a GNSS jammer. Nonetheless, the trend toward software-defined GNSS receivers for research and development, where receiver functionality is defined entirely in software downstream of the A/D converter, has significantly lowered the bar to spoofer development in recent years.

    As a point of reference, we estimate that there are more than 100 researchers in universities around the globe who are well-enough versed in software-defined GPS that they could develop a sophisticated spoofer from scratch with a year of dedicated effort. More worrisome is the fact that one does not have to build a sophisticated spoofer like ours, capable of aligning its signals precisely with authentic signals at the location of a chosen target, to spoof a civil GPS receiver. A low-cost off-the-shelf GPS signal simulator would not permit the kind of seamless attack we carried out, but would be adequate to confuse and disrupt the navigation system of a commercial UAV.

    Fixing the Problem

    There is no quick, easy, and cheap fix for the civil GPS spoofing problem. Moreover, not even the most effective GPS spoofing defenses are foolproof. Nonetheless, there are many possible remedies to the spoofing problem that, while not foolproof, would vastly improve civil GPS security. These defenses can be broken up into two categories: cryptographic and non-cryptographic defenses.

    Cryptographic defenses come primarily in two forms, spread-spectrum security codes (SSSC) and navigation message authentication (NMA), depending on whether the unpredictable digital signature is placed on the spread-spectrum code or the navigation data. These cryptographic signatures could be placed on WAAS signals or existing or future GPS signals to provide authentication of the source of the WAAS or GPS signals. A cryptographic defense implemented with appropriate checks to protect against certain variants of spoofing attacks, described in “Straight Talk on Anti-Spoofing,” GPS World, January 2012, would significantly raise the bar for a would-be spoofer. Several proposals for cryptographic methods are currently on the table including a proposal by Logan Scott to place SSSC signatures on GPS L1C signals that will be broadcast by GPS Block III satellites. However, the current proposals for civil GPS cryptographic authentication schemes are still at least several years away from implementation and have a 5-minute window between authentications of each individual GPS signal. These proposals have currently gained no ground in being implemented because of a lack of dedicated funds for development and implementation.

    There are also a number of promising non-cryptographic techniques for civil GPS spoofing detection that include jamming-to-noise power detectors (J/N meters), correlation profile anomaly defenses, and antenna-based defenses. J/N meters are simple and easily-implementable and would prevent a spoofer from simultaneous jamming and spoofing. However, a J/N sensor will not typically detect a spoofing attack in which the spoofed signals are only slightly more powerful than their authentic counterparts. The inclusion of a J/N meter does ensure that the authentic signals will also be visible as a corruption to the correlation curve during a spoofing attack, due to the difficulty of nulling out the authentic signal. This allows correlation profile anomaly defenses to be viable. However, these methods suffer from the difficulty of distinguishing multipath effects from a spoofing attack, particularly in mobile receivers. Antenna-based defenses also present an attractive option for anti-spoofing, but most of these methods require additional hardware (multiple antennas) and cost. One promising new antenna-based defense is currently under development at Cornell University that does not require multiple antennas. This defense involves an extension of the signal spatial correlation technque developed by the University of Calgary PLAN group. However, this technique is still under development, and receivers implementing this technique would likely be several times more expensive than current receivers.

    For details on potential spoofing defenses, see Todd Humphrey’s congressional testimony in “The System.”

    Recommendations

    We recommend that for non-recreational operation in the national airspace, civil UAVs exceeding 18 pounds be required to employ navigation systems that are spoof-resistant. Spoof resistance will be defined through a series of four canned attack scenarios that can be recreated in a laboratory setting. A navigation system is declared spoof-resistant if, for each attack scenario, the system is either unaffected by or able to detect the spoofing attack. Spoofing detection combined with an appropriate GPS-denied mode for the UAV to fall back on will significantly increase the difficulty of mounting a successful spoofing attack.

    Additionally, civil GPS receivers in many critical infrastructures (communications networks, financial trade centers, and the power grid) are also vulnerable to civil GPS spoofing. These critical infrastructures primarily rely on GPS for timing, which is also susceptible to manipulation with varying consequences depending on the application. A discussion of power grid vulnerabilities to GPS spoofing is given in “Going Up Against Time” in this issue of the magazine on page 34. We also recommend that GPS-based timing or navigation systems having a non-trivial role in systems designated by DHS as national critical infrastructure be required to be spoof-resistant.

    Finally, we recommend that funding be committed for development and implementation of a cryptographic authentication signature in one of the existing or forthcoming civil GPS signals. The signature should at minimum take the form of a digital signature interleaved into the navigation message stream of the WAAS signals. A better plan would be to interleave the signature into the CNAV or CNAV2 GPS navigation message stream. The best plan for implementing a cryptographic authentication signature would be to implement the signature as an SSSC interleaved into the spreading code of the L1C data channel. Inclusion of a cryptographic signature would greatly aid manufacturers in developing receivers that are spoof-resistant.

    Manufacturers

    The Hornet Mini UAV carries a µ-blox GPS receiver.

    Daniel P. Shepard is pursuing M.S. and Ph.D. degrees in aerospace engineering at the University of Texas (UT) at Austin. He is a member of the Radionavigation Laboratory.

    Jahshan A. Bhatti is pursuing a Ph.D. in aerospace engineering and engineering mechanics at UT and is a member of the Radionavigation Laboratory.

    Todd E. Humphreys is an assistant professor of aerospace engineering and engineering mechanics at UT and director of the Radionavigation Laboratory. He received a Ph.D. in aerospace engineering from Cornell University.

     

  • The System: Fly the Pilotless Skies: UAS and UAV

     

    
    Unmanned aerial vehicles and civil aircraft may co-habit the airspace after September 2015.

     As the U.S. Federal Aviation Administration (FAA) moves ahead with plans for unmanned aerial systems/vehicles (UAS/UAV) to have regular access to U.S. airspace by 2015, it has encountered several barriers. For UAVs to be treated like manned aircraft, their systems likley need to be qualified to the same standards as civil avioncs. This is a challenge, as each UAS has largely unique systems. UAS equipment standards are emerging, but threats to GNSS abound, requiring defense/mitigation.

    Demand for UAS has produced many different types flying in a range of applications. With no apparent standard avionics fit or uniform safety standards, each UAS type is basically configured for specific tasks. Commercial UAS applications continue to emerge, and major market growth is anticipated. One forecast indicates that the UAS market could reach $7.26 billion this year alone. The promise of new and better ways to reduce costs, improve safety, and increase operational efficiency feeds market expansion.

    However, in the United States the FAA currently requires each UAS commercial project desiring access to controlled airspace to obtain an FAA-approved Certificate of Authorization. While the FAA has made efforts to speed up approvals, this process slowed widespread commercial adoption of UAS. Nevertheless, opportunities abound in pipeline and transmission line inspection, crop spraying, law enforcement, security, and surveillance, survey/mapping, remote area mail delivery, and hundreds of other applications. The FAA may have felt some pressure to move forward, because Congress has put in place the Modernization and Reform Act of 2012, which calls on the FAA to fully integrate unmanned systems, including those for commercial use, into the national airspace by September 2015.

    UAS in the NAS. Meanwhile, a project called the Unmanned Aircraft Systems Integration in the National Airspace System (UAS in the NAS), undertaken by NASA’s Dryden Flight Research Center, seeks to reduce technical barriers related to safety and operational challenges associated with enabling routine UAS access to the NAS.

    Europe has also launched a study on the integration of UAS in non-segregated airspace for the future Single European Sky. The ICONUS study will be carried out by a consortium within the European air traffic management program called Single European Sky ATM Research Programme (SESAR). The study will drive the definition of the requirements, capabilities, and equipment which UAS will need to operate safely and efficiently in the coming European SESAR environment.

    The U.S. RTCA SC-203 committee is drafting UAS operational requirements, and there has been significant progress towards publishing Minimum Aviation Performance Standards (MASPS), including requirements for navigation. Europe has similar activities underway aimed at improving UAS access to its airspace.

    MOPS. The big picture is that requirements for unmanned aircraft are being brought into conformance with the standards applied to the performance and behavior of manned aircraft. Navigation requirements for UAS are expected to specify that systems will need to be qualified to Minimum Operational Performance Standards (MOPS). This means that on-board electronics, including GNSS systems, will probably need to be FAA Technical Standard Orders (TSO) qualified, just as they are now for manned aircraft.

    Why do we need to investigate certified avionics now? In the scheme of avionics, more than two years breathing space to certify UAS avionics systems is not a long time, not at all, until the September 2015 deadline. FAA airborne software and hardware qualification will take much time and effort to implement, and re-configuration of systems, interfaces, and operating procedures may take even longer.

    For Manufacturers. UAS makers have the option to move forward in stages. For instance, by selecting a few existing airborne-qualified OEM avionics, they could minimize the internal effort to comply. As the first UAS with certified avionics emerge, they will probably get good support from FAA to adopt U.S. operating rules for the NAS. Embedding an existing certified GPS receiver in UAS avionics will reduce the internal work needed and allow more effort for developing commercial market opportunities that look to quickly adopt UAS.

    Meanwhile, efforts are in full swing to change the U.S. and European navigation landscapes over the next few years. So it would be better to be ready with a capable GNSS receiver that is already built to meet the challenges of NextGen and SESAR.

    GPS III and Galileo. The L5 civil GPS frequency may be operational around the time that UAS unrestricted access becomes possible. GPS L1/L5 dual-frequency operations will enable higher navigation accuracy, reliablity, and integrity. The FAA is already developing NextGen WAAS to include L5, and revisions to the GPS MOPS to include L5 should begin shortly, in time for a usable GPS L5 constellation in 2015/2016. The FAA is already preparing for L5 avionics, and industry investigative work is underway. Its possible that GPS L1/L5 may meet the accuracy and integrity requirements for CAT II/III automated landings. In Europe, Eurocae work is expected to gain momentum for the Galileo E1/E5a MOPS as the Galileo satellite navigation system becomes operational.

    The new GNSS environment also includes WAAS/SBAS precision approach (localizer performance with vertical guidance, or LPV) capability: LPV is available now in the United States and will soon be in wider operation in Europe. Automatic Dependendant Surveillance (ADS-B) is rolling out in the United States and around the world. ADS-B is being mandated within the U.S. NAS as the means for air-traffic control to track all aircraft, so UAS avionics will need to include certified ADS-B Out capability.

    In one commercial instance, the Septentrio AiRx2 receiver comes out of the box as a certified L1 GPS with ADS-B and WAAS LVP, but is also ready for GPS L5 and Galileo E1/E5a.

    Even as greater steps forward enhance how GNSS is used in this wider definition of aviation that will soon include UAS, a team at the University of Texas demonstrated how a UAV could be maliciously side-tracked (see article on page 30 of this issue) —  reminiscent of the Iranian downing of a U.S. surveillance drone in December 2011.

    Admittedly the GPS on the vehicle in the UT test was not a qualified airborne receiver, but how could this happen when there was also an inertial sensor and a radio-altimeter on the UAV? A good question, which UAV manufacturers will need to consider when they implement their on-board Kalman filters, knowing that spoofing is now an additional threat to parry.

    Couldn’t we detect that high-power RF spoofing signal at the front-end of the GPS receiver? Even if only to tell the on-board systems that there could be hazardous misleading information about? Or run separate GPS and GPS/inertial position solutions, detect significant divergence, and set the same warning flag? And multi-constellation, multi-frequency receivers, and even controlled radiation pattern antennas — all things to investigate.  More work for the aviation receiver guys who labor tirelessly to improve GNSS integrity.

    Of course if you hijack a UAV with a high-power spoofer, you are also spoofing civil transports operating in the same airspace, so now there is the potential to trigger a Federal investigation. It will probably be easier to detect this stuff with moving airborne sensors rather than the fixed ground equipment used to find jammers on trucks at Newark airport, and lots of pilots likely providing real-time location information on radios if their GPS goes even a little haywire. All would help to quickly locate and shut down any spoofer. Nevertheless, it’s a threat to be mitigated.

    Fatal Crash. In South Korea, the effects of intermittent North Korean jamming of GPS to disrupt seal, land, and air navigation in the South may have contributed to the recent fatal crash of a Schiebel Camcopter S-100 drone, a 150-kilogram rotorcraft capable of 220 km/h flight. It should have coped with loss of GPS as the Camcopter has multiple inertial measurement units that allow safe operation and recovery in the absence of GPS signals. Emergency procedures to ensure a safe recovery in such a situation do not appear to have been correctly and adequately followed, manufacturer Schiebel alleges.

    NovAtel may have found one way to help mitigate spoofing on UAVs; the company released a combined civil/SAASM GPS receiver, the OEM625S, aimed specifically at UAVs. Granted, the idea is to add SAASM anti-spoofing capability to a number of UAVs which currently use NovAtel commercial receivers, mostly in military systems. That may be motivated by the desire to avoid further Iranian incidents!

    BAE Systems has been thinking of giving GPS a back-up for just those situations where jamming or even spoofing is detected. BAE’s Navigation via Signals of Opportunity (NAVSOP) system was just announced at the Farnborough air show in the UK and is still in research phase, but looks extremely promising. It interrogates the radio environment for the ID and signal strength of local digital TV and radio signals, plus air traffic control radars, with finer grained adjustments coming from cellphone masts and Wi-Fi routers. Mapping the location of all these sources might be quite an undertaking, and given that these are all non-safety-of-life commercial signals, the sources are subject to the vagaries of power outages, regular maintenance, and breakdowns. Nevertheless, with such a multitude of signals, NAVSOP could well turn out to be a viable back-up for GNSS.

    So, shared access to civil airspace, wider applications in commercial operations, and changes in equipment qualification, along with potential solutions for GNSS jamming and spoofing: lots to consider for the UAS industry.

    Taking It to the House

    U.S. House of Representatives Committee on Homeland Security; Subcommittee on Oversight, Investigations, and Management; Hearing, July 19, 2012:  Using Unmanned Aerial Systems Within the Homeland: Security Game Changer?

    Testimony by Todd E. Humphreys, Ph.D.; Assistant Professor, Cockrell School of Engineering, The University of Texas at Austin. [Excerpted. Prof. Humphreys is a co-author of the article “Drone Hack” in the August issue of GPS World.]

    The vulnerability of civil GPS to spoofing has serious implications for civil unmanned aerial vehicles (UAVs), as was recently illustrated by a dramatic remote hijacking of a UAV at White Sands Missile Range.

    Hacking a UAV by GPS spoofing is but one expression of a larger problem: insecure civil GPS technology has over the last two decades been absorbed deeply into critical systems within our national infrastructure. Besides UAVs, civil GPS spoofing also presents a danger to manned aircraft, maritime craft, communications systems, banking and finance institutions, and the national power grid.

    Constructing from scratch a sophisticated GPS spoofer like the one developed by the University of Texas is not easy. It is not within the capability of the average person on the street, or even the average Anonymous hacker. But the emerging tools of software-defined radio and the availability of GPS signal simulators are putting spoofers within reach of ordinary malefactors.

    There is no quick, easy, and cheap fix for the civil GPS spoofing problem. What is more, not even the most effective GPS spoofing defenses are foolproof. But reasonable, cost-effective spoofing defenses exist which, if implemented, will make successful spoofing much harder.

    I recommend that for non-recreational operation in the national airspace civil UAVs exceeding 18 lbs be required to employ navigation systems that are spoof-resistant.

    More broadly, I recommend that GPS-based timing or navigation systems having a non-trivial role in systems designated by DHS as national critical infrastructure be required to be spoof-resistant.

    Finally, I recommend that the DHS commit to funding development and implementation of a cryptographic authentication signature in one of the existing or forthcoming civil GPS signals.

    Complete testimony (PDF) covers:

    • The potential vulnerabilities of U.S. national transportation, communications, banking and finance, and energy distribution infrastructure;
    • What does it take to build a spoofer? Buy a spoofer?
    • Range and required knowledge of target.
    • Fixing the problem:

    •    Jamming-to-noise sensing defense;
    •    Defense based on SSSC or NMA on WAAS signals;
    •    Multi-system multi-grequency defense;
    •    Single-antenna defense;
    •    Defense based on spread-spectrum security codes on L1C;
    •    Defense based on navigation message authentication on L1C, L2C, or L5;
    •    Correlation prole anomaly defense;
    •    Multi-antenna defense;
    •    Defense based on cross-correlation with military signals.

  • Trimble Marine GNSS Receivers Support Marinestar Corrections for Offshore Dredging

    Trimble has announced that its latest generation of GNSS receivers for marine construction and hydrographic survey now support Fugro's Marinestar positioning services. Using satellite-delivered Marinestar corrections with Trimble SPS855 and SPS555H GNSS receivers, contractors can conduct dredging work up to 20 miles offshore, without relying on land-based infrastructure such as reference stations and radio networks. The Fugro Marinestar positioning service expands the operating environment for contractors using the Trimble marine construction GNSS receivers and enables decimeter accuracy for precise placement of dredging equipment and dredged materials.

    The Trimble SPS855 GNSS Modular Receiver provides accurate water level information and tidal height for a construction or dredging location, which is significantly more cost-effective than with conventional methods. Its modular design means the contractor can place the receiver inside the vessel cabin for maximum security and protection from the environment while mounting the GNSS antenna outside for optimized signal strength. The Trimble SPS555H Heading Add-on Receiver provides exact heading information for projects that require precise orientation of a dredging vessel.

    The Marinestar positioning service from Fugro offers two options:  Marinestar GPS — a high-performance, high-accuracy GPS augmentation service; and Marinestar GNSS — a high-performance augmentation service for both the GPS and GLONASS.

    The new Trimble SPS855 GNSS Modular Receiver and SPS555H Heading Add-on Receiver are available now through the Trimble Marine Construction distribution network. Subscription to the Marinestar GPS and Marinestar GNSS service is available for dredging and other marine construction applications through Fugro.
     

  • Telogis Acquires Fleet Management Company Navtrak

    Telogis, Inc., a platform for location intelligence, has acquired Navtrak, a mobile resource and fleet management company. This latest acquisition, along with the company’s strong organic growth rate, further positions Telogis as a fast-growing enterprise Software-as-a-Service (SaaS) provider of location-based intelligence solutions, the company said.

    “This acquisition broadens our customer portfolio with greater reach into small- and mid-sized markets, and complements our strong organic growth with large enterprises and OEM channels,” said Dave Cozzens, CEO of Telogis. “Our robust, scalable platform allows us to quickly integrate acquisitions, and we continue to pursue opportunities such as this that are advantageous for our business and customers.”

    Telogis provides enterprise SaaS applications to manage mobile workers and assets. The company’s strength is built upon an open platform approach that provides advanced solutions to manage every aspect of the mobile workforce, the company said.

    “Navtrak’s customers will now experience the benefits of a powerful location platform of SaaS applications, including Telogis Fleet, Telogis Route, Telogis Progression, Telogis Mobile, and Telogis Navigation,” said Cozzens. “This acquisition further accelerates our aggressive expansion plans for 2012. There is a large global market to address with our platform of SaaS applications, and we look forward to continuing to drive its innovation and growth.”

    This acquisition represents a continuing growth trend for Telogis, which has appeared on the Inc. 5000 list of fastest growing private companies for five consecutive years and has been named to the Deloitte Technology Fast 500 for four consecutive years. The company has been honored as one of the best workplaces in the region, and forged a partnership in 2011 that made Telogis the exclusive SaaS solution for Ford Motor Company’s Crew Chief commercial vehicle telematics system.

  • TomTom Launches Quarterly Congestion Index

    TomTom launches the first quarterly Congestion Index that accurately identifies and analyses traffic congestion in major cities across Europe. The report, initially covering 31 cities, finds Warsaw the most congested city in Europe.

     

    On average, journey times in Warsaw are 42% longer than when traffic in the city is flowing freely and 89% longer during morning rush hour. The TomTom Congestion Index, including individual city reports, can be found at www.tomtom.com/congestionindex.

    The TomTom Congestion Index is the world’s most accurate barometer of congestion in urban areas. The Index is uniquely based on real travel time data captured by vehicles driving the entire road network. TomTom’s traffic database contains over five trillion data measurements and is growing by five billion measurements every day. The overall congestion level for all the cities analysed in Europe is 24% – meaning journey times take 24% longer than when traffic is flowing freely.

    The top ten most congested European cities, ranked by overall congestion level, between January and March 2012 were:

    Warsaw, 42%
    Marseille, 41%
    Rome, 34%
    Brussels, 34%
    Paris, 32%
    Dublin, 30%
    Bradford – Leeds, 28%
    London, 27%
    Stockholm, 27%
    Hamburg, 27%
     
    “Over the years, with the help of our customers, we have built the largest and most accurate database of travel times in the world,” said Harold Goddijn; Chief Executive Officer of TomTom. “When we combine this travel database with our detailed real-time traffic information and routing technology, we can not only pin point congestion, but can guide drivers away from congested areas onto faster routes.”

    “Even when only a percentage of drivers use a different and faster route, the available capacity on the entire road network increases, which benefits all drivers,” Goddijn added.

    TomTom’s Congestion Index also compares congestion levels between January and March 2012 with the same period in 2011.  Based on this analysis, Bradford – Leeds in the UK saw the biggest increase in traffic congestion with journey times slowing significantly. Munich, Berlin, Marseille and Vienna all saw increased levels of congestion. Lisbon, Bern, Amsterdam, Milan and Rome all experienced a reduction in congestion levels.

    TomTom also launched the first quarterly Congestion Index that accurately identifies and analyzes traffic congestion in major cities across North America. The report, initially covering 26 major cities, finds Los Angeles to be the most congested city in North America. On average, journey times in Los Angeles take 33% longer than when traffic in the city is flowing freely and 77% longer during evening rush hour. 

    The Congestion Index compares travel time during non-congested periods (free flow) with travel times in peak hours. The difference is expressed as a percentage increase in travel time, representing the congestion level. The top ten most congested North American cities, ranked by overall congestion level, between January and March 2012 were:
     
    Los Angeles, 33%
    Vancouver, 30%
    Miami, 26%
    Seattle, 25%
    Tampa, 25%
    San Francisco, 25%
    Washington, 24%
    Houston, 23%
    Toronto, 22%
    Ottawa, 22%
     
    TomTom’s Congestion Index also compares congestion levels between January and March 2012 with the same period in 2011.  Based on this analysis, Seattle saw the biggest increase in traffic congestion, while Houston, Ottawa and San Francisco also saw increased levels of congestion. Conversely, Edmonton, New York, Boston, Minneapolis and Toronto experienced a reduction in congestion levels.

  • TMW Systems Certifies Integration with Rand McNally Devices

    Rand McNally has announced that its mobile communication systems are now certified and integrated with two applications from TMW Systems, Inc. As a result, fleets that use TMWSuite or TL2000 now can pull data from Rand McNally’s TND 760 and TruckPC in-cab devices through their TMW products.

    “Rand McNally has been a TMW Business Alliance Partner for decades,” said Scott Vanselous, CMO of TMW Systems. “By certifying integration with Rand McNally’s mobile communication and management systems, our customers have ready access to a full suite of Rand McNally solutions.”

    One customer is Freight Exchange of North America (F/X), a Chicago-based, North American full truckload carrier that operates nearly 300 power units from its terminals in Southern California, El Paso, Dallas, and Chicago. F/X has integrated information from Rand McNally’s TND 760 (Fleet Edition) with TMWSuite. For F/X, the integration allows for the use of real-time information from the in-cab device to dispatch trucks, receive automatic arrival and departure notification, match loads with available drivers, and track the progress of the driver’s daily workflow.

    “TMWSuite has been a tremendously successful tool to manage our operation. Rand McNally’s integration allows us to leverage our investment even further,” said Fred Alaimo, V.P. of Operations at F/X. “The TND 760 offered more functionality than other solutions we reviewed, and it’s priced significantly more competitively. The icing on the cake is that the drivers love the new device and have been quick to adopt and use the technology, making everybody a winner.”

    The TMW certified integration pulls critical data from Rand McNally’s in-cab systems via Rand McNally Connect software. The data provided by Rand McNally’s devices enable TMW products to deliver the following:

    • Automated and standardized driver daily workflows;
    • Notification of vehicle arrival and departure via Rand McNally’s automated geofencing capability;
    • Integrated turn-by-turn navigation, provided by Rand McNally’s IntelliRoute TND GPS software;
    • Automatically linked information — such as bill of lading numbers — from one form to another further simplifying the driver experience;
    • Integrated Hours of Service information into load planning and dispatching operations.

    “Having a certified solution with TMW’s industry-leading enterprise transportation management systems enables customers to confidently integrate the benefits of mobile communication, award winning navigation and fleet management,” explained Dave Muscatel, CEO of Rand McNally. “In particular, our TND 760 Fleet Edition device offers fast ROI recognition due to its cost effectiveness, ease of use and driver acceptance.”