GPS World

Tag: UAV

  • Tallysman Wireless Wideband Dual-Feed GPS L1/GLONASS/ Galileo Antennas

    Press-Release-Tallysman-TW4421_TW1421-W
    Photo: Tallysman

    Tallysman Wireless announces the TW4421 and TW1421 antennas, which offer a step forward in performance for small GNSS antennas, the company said.

    The TW4421 is a low-cost dual-feed magnetic mount antenna covering the GPS L1, GLONASS L1, Galileo and SBAS (WAAS, EGNOS & MSAS) frequency band (1574 to 1606 MHz). The TW4421 features a 25-millimeter dual-feed wideband patch element that provides excellent multipath rejection with a more linear carrier phase response, by virtue of a low axial ratio across the full frequency bandwidth, Tallysman said. It is especially suitable for high accuracy applications, and also offers high out-of-band signal rejection.

    The TW4421 is housed in a compact IP67 magnetic mount enclosure and is available with a wide range of connector options.

    The TW1421 embedded antenna is lightweight (30 gm) and features a very small footprint (35 mm diameter x 7.25 mm). The TW1421 is suited for use in applications where performance and small size are of paramount importance, such as extreme-sport-wearable tracking devices and UAVs.

    “Most small low-cost GPS/GLONASS/Galileo antennas are narrow-band devices with an elliptically polarized response at the GPS and GLONASS frequencies,” said Gyles Panther CEO of Tallysman Wireless. “The TW4421/1421 antennas feature a 40-percent wider bandwidth patch, with a dual-feed structure, which provides unparalleled multipath rejection previously only available in much larger, more expensive antennas.”

  • Trimble Launches Unmanned Aircraft System for Photogrammetric Aerial Mapping

    Trimble Launches Unmanned Aircraft System for Photogrammetric Aerial Mapping

    The Trimble UX5. Photo: Trimble
    The Trimble UX5. Photo: Trimble

    Trimble has introduced its next-generation Unmanned Aircraft System (UAS) — the Trimble UX5 aerial imaging rover with the Trimble Access aerial imaging application. The new solution builds upon the strengths of its predecessor, the Trimble Gatewing X100, to offer enhanced image quality and intuitive workflows. Combined with the Trimble Business Center photogrammetry office software module, the Trimble UX5 is the a complete UAS photogrammetric mapping solution specifically designed for surveyors and geospatial professionals.

    Trimble’s UAS for photogrammetric aerial mapping allows surveyors and geospatial professionals to collect data with an unmanned aircraft for large projects. A wide variety of traditional surveying applications such as topographic surveying, site and route planning, progress monitoring, volume calculations, disaster analysis and as-builts in industries such as surveying, oil and gas, mining, environmental services, and agriculture can now benefit from aerial imaging by allowing professionals to safely collect large amounts of accurate data in a short time.

    “With the recent introduction of the Trimble Business Center photogrammetry module and now the Trimble UX5 and Trimble Access aerial imaging application, Trimble continues to pioneer the development of UAS photogrammetry data collection and integration for geospatial professionals,” said Erik Arvesen, vice president of Trimble’s Survey Division. “The complete solution represents a significant leap in efficiency, transforming traditional workflows with faster data collection, easier processing and enhanced deliverables.”

    The new Trimble Access aerial imaging application is field software for planning UAS missions, performing flight checks and monitoring flights — all with intuitive workflows. The imaging application is used to define the project area, avoidance zones, and flight parameters as well as take-off and landing locations. In the field, it is used to perform pre- and post-flight checks and download the flight data and images after landing. The new wizard-like digital checklists give the operator a complete “to-do list” so critical steps are not bypassed or missed in the field that can enhance reliable and safe flights. The software also includes fixed post-flight procedures to ensure that operators do not leave the field with a dataset that is incomplete or inconsistent.

    The Trimble UX5 can provide a safer method to collect data compared to traditional surveying methods, Trimble said. Flights are fully automated, from launch to landing, and require no piloting skills. The operator facilitates the aircraft’s operation and built-in safety procedures can ensure safe and successful launches. Data collection can be performed remotely without exposing individuals to hazardous terrain, environmental contaminants or heavy equipment and machinery.

    The Trimble UX5 unmanned system in use at a construction site. Photo: Trimble
    The Trimble UX5 unmanned system in use at a construction site. Photo: Trimble

    The Trimble UX5 aerial imaging rover has been designed to follow the latest developments in the “prosumer” camera market, providing optimal image quality along with maximum photogrammetric accuracy.

    Incorporating a mirrorless 16-megapixel camera with a fixed focal-length external lens, the Trimble UX5 provides high-resolution imagery and accurate deliverables. The large field of view from the camera allows the UX5 to cover 50-75 percent more area to enhance efficiency and reduce operational costs. In addition to the increase in flight efficiency, the Trimble UX5 is capable of producing 3D surface deliverables with a ground sampling distance of approximately 2.4 centimeters (approximately 1.0 inch).

    Designed to operate in real-world conditions, the Trimble UX5 is capable of flights between 75 and 750 meters (approximately 246 and 2,460 feet) above ground level and can be flown in light rain and windy conditions, up to 65 kph (approximately 40 mph).

    The Trimble UX5 airframe is comprised of a carbon frame inside expanded polypropylene. Impact-resistant plastics and composite fibers are used for the aircraft components, including winglets and belly plate. This design and choice of materials results in a rigid aircraft with strong torsional stability and the ability to withstand rough landings.

    Performance enhancements also include the ability to execute steep landing approaches and thrust reversal for accurate and repeatable landings. The landing procedure starts 300 meters (approximately 984 feet) from the landing location allowing the UX5 to be used for jobs that have site restrictions such as buildings, towers or trees.

    Orthophotos, contour maps, point clouds, digital surface models (DSMs) and feature maps can easily be created from aerial images using the Trimble Business Center photogrammetry module. Single-click processing for stitching images streamlines the office process for generating powerful deliverables, Trimble said.

    The Trimble Business Center allows surveyors and other geospatial professionals to combine aerial photography with data collected from GNSS receivers, total stations, 3D laser scanners and more. By combining imagery from the Trimble UX5 and any Trimble VISION instruments, users can visualize their project from both aerial and terrestrial perspectives, measure points within the images and create 3D models of the infrastructure and terrain.

     

  • Riegl and Applanix Take Flight on UAV

     

    Riegl Laser Measurement Systems and Applanix Corporation announced today that the Applanix AP50 GNSS-inertial sensor system was successfully integrated with Riegl’s VQ-820-GU topo-bathymetric airborne laser scanner on board the Schiebel Camcopter S-100 UAV. The Riegl VQ-820-GU is specifically designed to survey sea beds and the grounds of rivers or lakes, and is well suited for combined land and hydrographic airborne survey.

    ap50
    Applanix AP50 GNSS-inertial system.

    The Applanix AP50 GNSS-inertial system is a GNSS-inertial sensor plus inertial measurement unit (IMU) in a compact form factor. It features a high-performance precision GNSS receiver and the Applanix IN-Fusion GNSS-inertial integration technology running on a powerful, dedicated inertial engine (IE) board.

    On board an unmanned aerial vehicle (UAV), the system is capable of penetrating areas that may be too dangerous for piloted aircraft or ground patrols. This can provide additional safety and security for its users.

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    Riegl’s VQ-820-G airborne laser scanner.

    “We really appreciate the professional and amicable cooperation with Applanix, which allows us to offer user-friendly and powerful, fully integrated solutions for dynamic data acquisition to the marketplace,” said Jürgen Nussbaum, Riegl director of international sales.

    In addition, Applanix will be a Gold sponsor at Riegl LIDAR 2013, Riegl’s international user conference taking place in Vienna, Austria, June 25-27.

  • UAV Aircraft to Fly Near Hermiston, Oregon, for Potato Research

    Oregon State University announced that two small, remote-controlled aircraft are expected to start flying over potato fields in the Hermiston area this month as part of Oregon State University’s efforts to help farmers more efficiently use water, fertilizers and pesticides to bolster yields and cut costs.

    While taking photographs, the aircraft will fly over 50 acres of OSU’s 300-acre Hermiston Agricultural Research and Extension Center (HAREC), as well as several crop circles totaling about 1,000 acres at a research cooperative farm west of Boardman. The flights will take place at least three times a week until the potatoes are harvested in the fall, beginning with a test run Wednesday at the Boardman farm.

    HawkeyeUAV
    Tetracam’s Hawkeye UAV

    OSU researchers will use various cameras on the aircraft to photograph the potato plants. The cameras will include ones that detect different wavelengths of light. One of these wavelengths, infrared, is reflected by plants, but unhealthy plants reflect less of it, and in infrared photographs sick plants are much darker. Researchers will also explore using other wavelengths of light to determine which ones will be most helpful in identifying troubled plants.

    Researchers aim to see if the cameras, which are capable of zooming in on a leaf, can detect plants that aren’t getting enough fertilizer and water. They’ll purposely reduce irrigation and fertilizer on some plants and will then see how quickly, if at all, the equipment detects the stressed plants. If it works, the scientists hope that the project will continue in subsequent years so they can test the cameras to also find plants that are plagued by insects and diseases. The idea is to help farmers take action before larger crop losses occur and it becomes more difficult and expensive to control the problem.

    “The key is to pick up plants that are just beginning to show stress so you can find a solution quickly, so the grower doesn’t have any reduced yield or quality issues,” said Phil Hamm, the director of HAREC. “This in turn can save money. It’s an early warning system for plants with issues as well as an opportunity for growers to reduce costs by being more efficient in water and fertilizer use.”

    Potatoes were chosen as the focus of the research because they’re a high-valued crop, expensive to raise and must be carefully managed to reduce internal and external blemishes and irregular growth spurts, said Don Horneck, an agronomist with the OSU Extension Service. One of Oregon’s leading crops, the state’s farmers sold $173 million of potatoes in 2012, according to the U.S. Department of Agriculture. But spuds are prone to devastating problems caused by diseases and insects, said Horneck, who is the lead researcher from OSU on the project.

    “They are one of the most difficult and expensive crops to grow,” he said, adding that it typically costs Hermiston farmers $4,000 or more per acre to grow them. That equates to about $500,000 for the average size of field in the area.

    OSU hopes that the aircraft it tests will reduce these costs. The aircraft that will fly over OSU’s land is called a HawkEye and is sold by a company called Tetracam. About the size of a suitcase and weighing only 8 pounds, its maximum flight time is 10-30 minutes. The hull-less, battery-operated machine is easy to operate and was made for farmers with plots of land that are less than one square mile. A motor and propeller allow it to take off on four wheels. A parachute keeps it in the air. Photos and videos of it are at http://bit.ly/10LDbjt.

    A delta-winged aircraft made of plastic foam will fly over the private farm. Made by Procerus Technologies and called a Unicorn, it has a wingspan of no more than 6 feet and weighs less than 6 pounds. A bungee cord launches it like a slingshot. A factsheet on it is at http://bit.ly/XTqioS.

    Procerus-Technologies-UAV-Test-Airframe
    Lockheed Martin Unicorn UAV

    OSU is inviting the public to see the HawkEye fly during its potato field day at its Hermiston research center on June 26.

    Allaying concerns about privacy, Hamm said, “These unmanned aircraft are for agricultural research only and will be used to do nothing more than that. This is about helping our local growers do a better job of growing crops, something HAREC has been doing for the past 102 years.”

    The Federal Aviation Administration has authorized the flights of the aircraft, which aren’t allowed to fly higher than 400 feet and must stay within sight of the operator, typically less than a mile away.
    OSU is leasing the aircraft from Boeing Research & Technology. n-Link, an information technology firm in Bend, is also a partner in the project. Ray Hunt, a plant physiologist with the USDA in Beltsville, Md., will collaborate with OSU’s Horneck on the data analysis.

    OSU aims to become one of the nation’s premiere universities using unmanned aircraft for research. It is using or has plans to use them in studies on natural resources, wildlife, land-use management, forestry, oceanography and engineering.

  • 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.

  • Thoughts on Mobile Devices, UAVs, and Cheap Data-Collection Software

    On the coattails of last week’s Geospatial Solutions newsletter outlining the United Nations’ five- to ten-year vision on geospatial information management, and my column on the mobile device operating system war, here are some more thoughts on those subjects.

    As the cost of GIS data collection devices (handheld, tablet) has plummeted in the past two years and smartphones have proliferated, the quest for inexpensive GIS data-collection software has intensified. It makes sense. When people were used to paying thousands of dollars for a GIS data-collection device, another US$800-$1,000 for GIS data collection software seemed reasonable. It might have added 15-25% to the total price of the system. With today’s inexpensive devices, sometimes data collection software ends up costing more than the device itself, thus pushing the demand for cheaper software. On top of that, as I discussed a couple of weeks ago, we are in the middle of a mobile device operating system war. Whereas it used to be a no-brainer that Windows Mobile (or some derivative of it) was going to be the dominant operating system and supported by software developers, that’s not the case any longer. Windows Embedded is going to be around, but it’s clearly not the dominant mobile device operating system it once was.

    Interestingly enough, GIS data collection software for iOS and Andoird have followed the iOS and Android price trends. The mobile devices running iOS and Android are inexpensive, sometimes free. You don’t see any iOS or Android GIS data collection software packages costing thousands of dollars. On the other hand, many Windows Mobile-based geospatial softwares cost upwards of US$2,000. Of course, you can make the argument that the Windows Mobile-based softwares are mature and feature rich. That’s true, as most of the iOS and Android-based softwares have a fraction of the capability, but I’d venture to say that most users don’t need many of the features they are paying for. I also agree with one of the trends outlined in the UN document in that I think open source might be where things are headed.

    • Free and open source software will continue to grow as viable alternatives both in terms of software, and potentially in analysis and processing.

    Ironically, open source GIS data collection software has been around for years. However, you probably don’t know about it because no organization is actively marketing it (if there’s no revenue, there’s no marketing budget). Software like gvSIG Mobile is a reasonably powerful GIS data collection product. A little quirky? Perhaps. But, if your budget is depleted and your requirements exceed the capabilities of the typical free or inexpensive software in the iTunes or Google Market, you might tolerate the quirkiness.

    gvSIG Mobile Open Source GIS Data Collection Software.
    gvSIG Mobile Open Source GIS Data Collection Software.

    The UN also predicts that geospatial data will trend toward open source.

    • Within five years the level of detail on transport systems within OpenStreetMap will exceed virtually all other data sources and will be respected and used by major organizations and governments across the globe.
    • Community-based mapping will continue to grow.
    • There is unlikely to be a market for datasets like those currently sold to power navigation and location-based services solutions in five years, as they will have been superseded by crowdsourced datasets from OpenStreetMaps or other comparable initiatives.|
    While I agree that the trend towards open source data is gaining traction, five years is a really aggressive timeline for phasing out the likes of TeleAtlas (owned by TomTom) and Navteq (owned by Nokia). These are the two major map database suppliers for virtually all GPS navigation devices used in vehicles around the world. I think there will be, for the forseeable future, a quanitifiable and valued difference between open source data and commercial geospatial data. Commercial users will pay for perceived quality and accountability, especially if the price differential is minimal. Consumer GPS users (vehicle navigation) might be a different story. A $30 difference in retail price can sway a consumer from one brand to another.
    More on UAVs for Mapping
    One of the first trends in the UN listed are:
    • There will be an increased demand for applications to be used with high-resolution imagery.
    • The use of Unmanned Aerial Vehicles (UAVs) as a tool for rapid geospatial data collection will increase.

    Trimble’s acquisition of Gatewing just last month supports this trend as well as the Obama administration’s accelerating the use of civilian UAVs back in February of this year via the National Defense Authorization Act of 2012.

    Cost-effective mapping UAVs are starting to emerge. In just this past week, Event 38 announced a small mapping UAV for under US$1,000.

    Low-cost E382 Mapping UAV from Event 38.
    Low-cost E382 Mapping UAV from Event 38.
    Augmented Reality

    As does the UN vision, I think augmented reality has a bright future for both commercial users and consumers.

    • Augmented reality applications will be pervasive, with the ability to view a whole range of data overlays on top of the real world.

    For professional geospatial users, the situational awareness possibilities are tremendous. Imagine the backhoe operator being able to “see” the underground infrastructure in order to avoid it. Imagine the park superintendent being able to “see” all of the underground irrigation and drainage lines by simply positioning a tablet computer towards the area of interest.

     

    Thanks, and see you next week.

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

  • Event 38 Announces UAV For Mapping

    Event 38 announced its first major product, model E382, a ready-to-fly mapping UAV. Based on the Ardupilot Mega 2.0 autopilot, the E382 is designed to take aerial photos quickly and easily.

     

     

    According to the announcement, equipped with a small point and shoot camera, the E382 can make five centimeter resolution maps from individual pictures stitched together. Digital elevation models and georeferenced orthorectified maps can be made using online services like DroneMapper.com.

    Event 38 reports that the E382 is capable of flying for just under an hour and can cover over 200 acres at a time on one charge. For larger areas, replacing the battery is quick and can be done in the field. Weighing in at under five pounds and made of soft, durable foam, the airframe is resistant to damage and can’t significantly damage anything on the ground. The 66″ wings come apart for easy transport to and from the job site.

    The basic kit consists of a ready to fly airframe with autopilot, motor and servos installed. Options are available to add on for those without any R/C gear like a controller, batteries and a suitable point and shoot camera. If you’re starting without any gear, a full system costs about $1,050. Training and on-site setup are available as well.

  • Unmanned Aerial Vehicles: Past, Present and Future Impact on GIS

    By Art Kakinski, GISP

    My first exposure to Unmanned Aerial Vehicles (UAVs) was in 1972, serving as a young Ensign on a WWII class destroyer. The UAV was called DASH(Drone Anti-Submarine Helicopter). It was a small, counter-rotating rotor drone helicopter used to extend the anti-submarine warfare (ASW) reach of a destroyer. It carried Mark46 torpedoes but could also carry nuclear depth charges. The disappointing characteristic of DASH is that it had a nasty habit of either disappearing over the horizon never to be seen again or, worse yet, crashing into the superstructure of its mother ship. 1970s technology just wasn’t up to the complex task of controlling such a vehicle.

    Enter 2012, and UAV technology looks like science fiction. My recent participation at the USSOCOM TNT exposed me to some new developments in military technology and UAVs in particular. Most of you are familiar with the better known UAVs such as the Predator, Global Hawk, or smaller Shadows, but the number of UAVs has grown exponentially with some of the most interesting developments occurring in small UAVs and persistent surveillance. With more than 100 UAVs in today’s market, it’s impossible to do a comprehensive column about UAVs, but just like the blind men looking at an elephant, the following is one GIS guy’s view of this growing market.

    Hot New UAV Systems

    Building on early lessons learned with vehicles like DASH, the Boeing A160 is a UAV helicopter, but the similarity to DASH ends there. Its design incorporates new technologies not previously used in helicopters, allowing for greater payload, endurance, and altitude than any helicopter currently in operation. The experimental program has ambitious goals of a 2,500-mile range and 24-hour endurance with a 1,200 pound payload. The 35-foot helo flies autonomously rather than relying on real-time human control with speeds over 140 knots.

    A reoccurring theme that has been presented at GEOINT and other ISR conferences is that many UAVs currently in use are proving to be almost as expensive to operate as manned aircraft. Because of this, engineers have been looking into alternate technology, including persistent surveillance. One example is the Long-Endurance Multi-Intelligence Vehicle (LEMV) a hybrid blimp and aircraft.

     

    The Lockheed Martin vehicle shown here will be tested in-theater this year. It is designed to operate unmanned and untethered at 20,000 ft. for weeks at a time carrying a 2,500-lb. intel payload. On first glance the LEMV looks like a sitting duck, but based on actual tests the low static pressure, lighter than air, aerodynamic lifting body is very survivable. At GEOINT, Maj. Gen. James O. Poss, USAF, said that if you are lucky enough to hit it from the ground with small-arms fire, it might come down next week.

    UAVs at TNT

    There were numerous UAVs at TNT, but the two that particularly caught my attention and imagination were two inexpensive vehicles that I believe could be game changers for the GIS community.

    One was a very light weight UAV from a small Ohio company called UAVision.They were flying UAVs that on first glance looked like toys, but the composite skins and advanced electronics quickly shattered that first impression. The vehicles are battery powered and almost silent in flight with loiter times of about 30 minutes. Weighing 4-8 pounds, they were easily hand launched and fly autonomously once in the air.

    The operator programs the flight path into a GIS display and the aircraft follows the programed path, ultimately doing a soft landing on to the grass next to the operator. Shown here is the live video feed from the camera on the UAV overlaid with the programed flight path (orange polygon). The resolution of the video was excellent and the image was surprisingly stable. They were also testing the ability to locate, identify, and track RFID tags from the air.

    This vehicle is designed to ultimately meet new UAS standards that are included in a recent FAA Bill. The bill, signed by the President February 14, includes important provisions regarding the integration of Unmanned Aircraft Systems (UAS) into the national airspace system. One provision could have a very rapid impact on the GIS community. It allows government agencies and first responders to fly very small UAS (4.4lbs or less) within 90 days if they meet certain requirements. The goal is to permit law enforcement and firefighters immediate access to these small systems for lifesaving purposes and to increase public safety. Some believe that this technology may be readily available for surveying and mapping within three years.

    Although 4.4 pounds doesn’t sound like a lot, UAVision’s current aircraft already has shown the ability to capture and geo-reference the imagery. 4.4 pounds seems to be a safety benchmark that puts the UAV in the same category as birds. Statistically, most manned aircraft can survive a collision with birds up to 4.4 pounds, so the low-flying UAV would pose a minimal hazard to manned aircraft. Unlike current big UAVs that have six- and seven-figure price tags, a complete UAVision system can come in as cheap as $30,000. I could easily envision GIS operations using these systems for surveillance or even low-cost imagery capture.

    The second vehicle that caught my attention was a hybrid air system from Sofcoast. Sofcoast created an aerostat the combines the benefits of a tethered balloon with the stability and directionality of an aircraft with control surfaces. This could be the most elegantly simple and low=cost solution to persistent aerial surveillance I’ve seen.

     

    The operator launches the aerostat silently using a modified fishing rod and reel. Once in position, the clear vehicle is very unobtrusive. It silently monitors the area below and has the added benefit of being almost invisible at night. I can easily see this being used for security during large public events or in response to natural disasters as a survivor search tool or to catch or deter would-be looters. To get an idea of the quality and stability of the video feed from the system, click on the following video:

    Future Systems

    There are numerous articles on the Internet that explain some rather exotic UAVs in development.

    The Propulsive Wing is a new patented aerodynamic platform that integrates an embedded, distributed cross-flow fan propulsion system within a thick wing. It looks like a fat flying wing but has the potential to carry very heavy payloads with very stable flight characteristics and short takeoff and landing.

    The Nano Hummingbird or Nano Air Vehicle (NAV) is a tiny remote-controled aircraft built to resemble and fly like a hummingbird, developed under the Defense Advanced Research Projects Agency (DARPA). The Hummingbird is equipped with a small video camera for surveillance and reconnaissance purposes and, for now, operates in the air for up to 11 minutes. It can fly outdoors, or enter a doorway to investigate indoor environments.

     

    Honeywell completed delivery of an initial order for 90 RQ-16 T-Hawk “hover and stare” micro air vehicle (MAV) systems to the U.S. Navy in December 2011, for use in detecting roadside bombs in Iraq and Afghanistan.

    Zephyr is a lightweight solar-powered UAV which was originally designed and built by the United Kingdom defense firm Qinetiq. The carbon-fiber aircraft uses sunlight to charge a lithium sulfur battery during the day, which powers the aircraft at night. It holds the current UAV endurance record with an 82-hour flight at an altitude of 61,000 feet.

    On the really creepy side are rumors of Nano UAVs the size of insects. Following is a video clip from the University of Pennsylvania showing a swarm of UAV quad copters flying in formation and showing an almost collective intelligence.

     

    The “fly on the wall” may soon be a reality, controlled by your GIS technician.

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  • Trimble Acquires UAV Mapping Company Gatewing

    Trimble announced that it has acquired privately-held Gatewing of Gent, Belgium, a provider of lightweight unmanned aerial vehicles (UAV) for photogrammetry and rapid terrain mapping applications. The acquisition broadens Trimble’s industry-leading platforms for surveying solutions. Financial terms were not disclosed.

    According to the announcement, UAVs in combination with photogrammetry are an emerging technology providing an innovative platform for flexible aerial imagery acquisition. Easy to use and flexible, UAVs provide users the ability to create orthophotos and Digital Surface Models (DSM) from aerial imagery for mid-sized areas previously only accessible at higher costs and with longer planning cycles. UAVs are used in a variety of applications including preliminary surveys for corridors and rights-of-way, volumetric surveys, high-level topographic surveys, land fill inspection, and much more.

    Trimble reports that Gatewing’s solutions include the X100 UAV and Stretchout desktop software for digital image processing and analysis. The X100 is an ultra-light, 2 kg (approximately 4.4 lbs) class UAV that allows fast and simple image acquisition. It consists of an airframe; an integrated GPS, inertial system and a radio; a 10 megapixel camera; and battery. Using the Trimble Yuma tablet computer, a predefined area is planned and the flight of the UAV is fully automated from launch to landing. The terrain is mapped through parallel flight paths and consecutive, overlapping camera shots during flight. The ground control station (GCS) is used to monitor the mission and allows an on-site image quality check. In addition, the GCS provides the operator with the option to intervene and abort the flight if needed. The image set consists of a number of digital images that are tagged with the GPS coordinates.

    Gatewing’s Stretchout desktop software uses advanced computer vision technology which automates raw image processing to deliver georeferenced orthophotos and accurate DSM. As an alternative to the desktop software, users can upload images to Gatewing’s cloud solution, which automatically processes the images based on the users’ requirements. After a few hours, users can download their georeferenced orthophotos and DSMs from the cloud server including feedback about the results for quality assurance.

    “The combination of UAVs and low-altitude photogrammetry as an image collection platform opens up new opportunities for surveyors to use aerial imagery for the rapid acquisition of high-density geospatial data,” said Anders Rhodin, director of Trimble’s Survey Business. “We are excited to add Gatewing’s unique aerial mapping system to Trimble’s portfolio of survey solutions.”

    “The Gatewing team is excited about the new ownership,” said Maarten Vandenbroucke, CEO and one of three founders of Gatewing. ”For Trimble to see the value in unmanned aerial systems for surveying and mapping applications means that the industry is truly ready for this exciting new technology. We are enthusiastic about how UAVs can revolutionize the landscape and open a complete new spectrum in remote sensing applications. I believe that being a part of Trimble will accelerate the pace in which UAVs will further be adopted by professionals.”

    The Gatewing business will be reported as part of Trimble’s Engineering and Construction segment.