Tag: OEM

  • Spectracom, Satelles sync in multiple indoor locations

    Orolia has synchronized a Spectracom SecureSync high-precision time server with the new Iridium Satelles Satellite Time & Location (STL) time synchronization signal powered by Iridium satellites in several indoor environments in the field. Configured with an embedded STL receiver and a small patch antenna, the SecureSync synchronized with the STL signal in several challenging indoor locations. Indoor success can be attributed in part to use of a low-Earth orbit satellite-based signal 1,000 times stronger than GPS.

    The first successful synchronization was in the interior of a building in one of the most challenging urban canyons on Earth: downtown Manhattan on the 7th floor of the New York Stock Exchange. The second was in the interior of a conference center with multiple sources of potential signal interference during The Institute of Navigation event in Monterey, California. Additional successful indoor timing signal synchronization locations include MiFiD2 events near the Paris Stock Exchange, a multi-story building and inside Gibson Hall in downtown London.

    More GNSS challenged locations to come, the two companies promise.

    Other satellite signals — notably GNSS — have limitations indoors. The Satelles STL signal uses the narrow-band paging channels of Iridium, a one-way transmission from the satellite with a very high gain system. The STL signal is completely different from the wide band, lower gain two-way channel of the Iridium phone. The STL signal is 1,000 times stronger than GPS because it originates from the Iridium constellation of 66 satellites orbiting in a low earth orbit. It is also encrypted for high security, which greatly enhances the resilient PNT capabilities of the Spectracom product lines, specificallly the SecureSync precision time and frequency reference. SecureSync with integrated STL synchronization is available to order from the Spectracom website or by contacting a representative.

    “The new STL signal is the ideal solution for those needing increased security and reliability, applications such as high frequency securities trading, financial transaction time-stamping compliance and critical infrastructure timing,” said John Fischer, vice president of Orolia for advanced R&D. “It is not only an additional signal to back up traditional GNSS, it is also stronger and more secure, adding significantly to the resiliency of high performance systems and networks that must rely on precise time synchronization.”

    Having proven the ability to provide a strong and reliable alternative signal in various indoor field locations, the new globally accessible STL signal adds a significant safety net to any critical GNSS application. Adding to the mix of signals of opportunity the resiliency of positioning and timing for financial, defense and critical infrastructure is greatly enhanced.

    “Orolia is focused on providing Resilient PNT solutions, and by combining and layering technology in innovative ways we help our customers meet their mission goals,” said Rohit Braggs, vice president of Orolia’s PNT networks and sources. “This new satellite-based service provides a unique signal that augments Spectracom systems, enhancing our ability to effectively mitigate emerging GPS and GNSS threats.”

    Orolia is the parent company of Spectracom, McMurdo, Kannad, and Sarbe brands, focused on resilient positioning, navigation and timing (RPNT) solutions that improve the reliability, performance and safety of customers’ critical, remote or high-risk operations.

    Satelles has developed and deployed a real-time PNT service based on low-Earth orbit satellites, the Iridium constellation. Satellite Time and Location (STL) signals are highly secure, penetrate deep indoors, and are available anywhere on Earth.  Satelles partners with other companies to deliver secure time and location capabilities to government and commercial users worldwide.

  • 2017 Simulator Buyers Guide

    Cast Navigation iP-Solutions Racelogic Skydel Spectracom
    Spirent Federal Systems Syntony-GNSS Talen-x

    Cast-5000 GPS wavefront generator

    CRPA and Attitude Determination Receiver Testing

    5000layeredwhite-castnavThe CAST-5000 produces a single coherent wavefront of GPS RF signals to provide repeatable testing in the laboratory environment or anechoic chamber. The basic system generates four independent, coherent simulations that reference a single point and is upgradeable to support seven elements for CRPA testing. With an intercard carrier- phase error of less than 1 centimeter, the CAST-5000 is extremely accurate.

    The system generates a wavefront of GPS when its GPS RF generator cards are operated in a ganged configuration. Each generator card provides a set of GPS satellites coherent with the overall configuration. Several RF generator cards may be utilized together, ensuring phase coherence among the bank of signal generator cards.

    The CAST-5000 Controlled Reception Pattern Antenna (CRPA) tester allows a full end-to-end test of the antenna system. The CRPA antenna, antenna electronics and the GPS receiver can be tested as a unit with or without radiating signals.

    Features

    • Generates single coherent wavefront of GPS.
    • 6-DOF motion generation capability.
    • Complete SV constellation editing.
    • Post-mission processing via ICD-GPS-150/153.
    • Differential/relative navigation.
    • Antenna pattern modeling.
    • Waypoint navigation.
    • RAIM events.
    • Multipath modeling.
    • Spoofer simulation.
    • Satellite clock errors.
    • External trajectory input.
    • External ephemeris and almanac.
    • Several iono and tropo models.
    • Modifiable navigation message.
    • Modeled selective availability.
    • Time-tagged satellite events.
    • Selectable host vehicle parameters.

    www.castnav.com
    phone: 978 858-0130
    email: [email protected]

    iP-Solutions, Zero-C Seven Inc.

    Simceiver, Replicator, ReGen

    iP-Solutions brings its 10-year development for designated users — including the Japan Aerospace Exploration Agency (JAXA) COSMODE ionospheric scintillation monitor — to general users worldwide.

    MFR1iP-Solutions users have a complete GNSS lab at their disposal. They can simulate, record and process signals in real-time with the company’s receiver, and playback almost any GNSS signal.

    Moreover, users have complete control over the simulated signals in real-time and with high fidelity.

    iP-Solutions provides mid-level and high-end simulation solutions with the same level of accuracy and fidelity.

    Mid-Level Solution
    iP-Solutions’ mid-level Simceiver simulator allows multi-frequency simulation of various GNSS signals with all essential models. The additional ANSI C API allows users to modify existing models or introduce their own.

    iP-Solutions’ mid-level solution range even includes a comprehensive interference and spoofing laboratory.

    The Simceiver is controlled usign the comprehensive ReGen software, providing the user with great freedom to create any desired signal.

    High-End Solution
    ninja-hresiP-Solutions’ high-end Ninja simulator allows for multi-antenna controlled radiation pattern antenna (CRPA) and local-area augmentation system (LAAS) simulation.

    Academia
    iP-Solutions’ educational packages for academia combine hardware at a special academic price with academic versions of all the software and two textbooks authored by iP-Solutions’ lead engineer Ivan Petrovski and JAXA lead scientist Toshiaki Tsujii (published by Cambridge University Press).

    www.ip-solutions.jp
    phone: +81-3-3560-7747
    e-mail: [email protected] (Japan)
    [email protected] (Nth. America)
    [email protected] (International)

    Racelogic

    LabSat 3 Wideband
    LabSat is a cost-effective and intuitive GNSS simulator.

    Labsat_Lid-OffNew to the LabSat range of GNSS record and replay devices is LabSat 3 Wideband, which continues with the established reliability, cost-effectiveness, and simplicity of operation that are the benchmarks of the LabSat system.

    A recording bandwidth of 56 MHz allows for the capture of a very wide range of live-sky satellite signals:

    • GPS: L1 / L2 / L5
    • GLONASS: L1 / L2 / L3
    • BeiDou: B1 / B2 / B3
    • QZSS: L1 / L2 / L5
    • Galileo: E1 / E1a / E5a / E5b / E6
    • IRNSS: L5
    • SBAS: WAAS / EGNOS / GAGAN / MSAS / SDCM

    Depending on the desired bandwidth, recording resolution can be set to 2, 4, or 6 bit. Check out the GNSS frequency guide on the LabSat website — labsat.co.uk — to see exactly which signals can be recorded and at which resolution.

    Even with this greatly increased capacity over the original LabSat 3, the new simulator remains extremely easy to use: one-touch recording, no connection to PC required, battery powered for up to two hours, and with a removable 1-TB solid-state hard drive that can be replaced in no time, the LabSat 3 Wideband is convenient to use. It measures a compact 167 x 128 x 46 millimeters and weighs 1.2 kilograms.

    SatGen Wideband
    For product future-proofing, the soon-to-be-launched SatGen Wideband will allow for testing with signals not yet fully available, such as GPS L2C and L5 — further increasing the power and versatility of the new LabSat 3 Wideband.
    www.labsat.co.uk
    phone: +44 (0)1280 823803

    Skydel

    SDX: Software-Defined GNSS Simulator

    skydel-sdxSDX uses GPU-accelerated computing and software-defined radios (SDR) to create an advanced and fully-featured GNSS simulator. SDX is available as complete turnkey systems or software only.

    The software-defined approach offers many benefits:

    • COTS hardware offers economy of scale and eliminates dependency over dedicated hardware platforms.
    • Generic hardware allow users to repurpose their equipment for different projects.
    • Configurable output to test receiver at various entry point with RF, IF or IQ data.
    • Uncompromised performance with high dynamics and accuracy.
    • Record user interactions and export them to scripts to automate complex use cases intuitively. The export feature reduces the learning curve for advanced concepts.
    • Advanced signal customization (signal signature, private encryption, etc.)

    SDX Key Features

    • Multi-constellation (GPS, GLONASS, Galileo, BeiDou), multi-frequency (upper and lower L-band).
    • Selectable RF, IF frequency and IQ file data.
    • GPS encrypted codes.
    • Fully integrated jammers (static or moving) with over 120-dB jamming-to-signal ratio.
    • Multipath.
    • Additive pseudorange (PSR) ramps.
    • Message modification and corruption.
    • 1000-Hz update rate and high dynamics.
    • Space (LEO-GEO), air and ground vehicle with 6DoF trajectories.
    • Hardware-in-the-loop (HIL) integration.
    • Street maps integration.
    • Raw data logging.
    • Real-time receiver deviation analysis.
    • Powerful and simple API.
    • On-the-fly reconfiguration.
    • Windows and Linux compatible.

    SDX is ideal for design and validation of GNSS receivers, complex integration, academic research, NAVWAR and test engineering.

    Skydel engineering and research teams offer direct support to clients to ensure prompt deployment and integration, or review advanced customization requirements.

    www.skydelsolutions.com
    [email protected]

    Spectracom

    For mission-critical PNT applications

    Spectracom_GSG_highres_smallThe Spectracom GSG series of GPS/GNSS simulators are an essential tool to evaluate risk to jamming, spoofing or any other threat. Spectracom GSG-5/6 series simulators are easy-to-use, feature-rich and affordable, offering high value for hardening GPS-based systems compared to the limitations of testing from live-sky signals. The Spectracom platform approach allows users to buy what they need today and upgrade later. The adaptability of the GNSS RF generation platform can extend to applications for intelligent repeating and meaconing.

    Test Solutions

    • Position accuracy and dynamic range/sensitivity.
    • Simulate movements/trajectories anywhere on or above Earth.
    • Sensitivity to GPS impairments: loss of satellites, multipath, atmospheric conditions, interference, jamming and spoofing.
    • Conducted or over-the-air RF.
    • GPS time-transfer accuracy.
    • Effect of leap-second transition.
    • Multi-constellation testing.
    • Modernization signals/frequencies.
    • Keyless military SAASM, dual-frequency and survey-grade receiver testing.
    • Application packages for, RTK, CRPA (controlled radiation pattern antennas).
    • Hardware-in-the-loop (HIL) integration.
    • Test solutions for eCall and ERA-GLONASS Infrastructure Possibilities.
    • Zone-based indoor location (intelligent repeating).
    • seudolite applications.

    GSG-6 Series 64-channel, multi-frequency, advanced GNSS simulator is powerful enough for any cutting-edge test program. GPS, GLONASS, Galileo, Beidou, QZSS and IRNSS signals are available across multiple frequencies. The GSG-6 is designed for military, research and professional applications.

    GSG-5 Series 16-channel multi-constellation L1-band GNSS Simulator is designed for commercial development/integration programs. If the user is developing commercial products with GNSS capability, the GSG-5 will shorten test programs with confidence.

    GSG-51 single channel signal generator is designed for one purpose — fast, simple Go/No-Go manufacturing test and validation, ensuring the manufacturing line is operating at full capacity with confidence in quality.

    spectracom.com
    email: [email protected]
    phone: +1-585-321-5800

    Spirent Federal Systems

    GSS9000, CRPA Test System, GSS6450 RPS, GSS200D
    Spirent Federal provides simulators that cover all applications, including research and development, integration/verification and production testing.

    GSS9000GSS9000. The Spirent GSS9000 Multi-Frequency, Multi-GNSS RF Constellation Simulator can simulate signals from all GNSS and regional navigation. The GSS9000 offers a four-fold increase in RF signal iteration rate (SIR) over Spirent’s GSS8000 simulator. The GSS9000 SIR is 1000 Hz (1ms), enabling higher dynamic simulations with more accuracy and fidelity. It includes support for restricted and classified signals from the GPS and Galileo systems as well as advanced capabilities for ultra-high dynamics. It can evaluate resilience of navigation systems to interference and spoofing attacks, and has the flexibility to reconfigure constellations, channels and frequencies between test runs or test cases.

    CRPA Test System. Spirent’s Controlled Reception Pattern Antenna (CRPA) Test System generates both GNSS and interference signals. Users can control multiple antenna elements. Null-steering and space/time adaptive CRPA testing are both supported by this comprehensive approach.

    GSS6450. The GSS6450 RF Record Playback System (RPS) takes RF recording and playback systems to a whole new level of performance and flexibility, while being housed in a small (8.5 x 7.8 x 3 inch) portable case. The GSS6450 can record any GNSS signals currently available with bit depths up to 16 bits (I&Q) and bandwidths of up to 50 MHz. The flexible product structure allows the system complexity to grow with the user’s testing needs.

    GSS200D. A truly end-to-end solution that builds up a complete picture of interference activity at site of interest. It continuously monitors the GNSS frequency bands for interference, then captures and analyzes them. The GSS200D is a detection system that operates simultaneously on multi-frequency.

    Spirent Federal Systems
    1402 W. State Rd.
    Pleasant Grove, UT 84062
    www.spirentfederal.com
    [email protected]
    phone: 801-785-1448
    fax: 801-785-1294

    Key contacts: Jeff Martin, VP of Business Development and Sales
    Kalani Needham, Sales West
    Tyson Gurney, Sales East

    Syntony-GNSS

    Montage-gui-constellatorConstellator is Syntony’s cost-effective full soft multi-constellation GNSS simulator. Designed to test receivers against current and future signals, Constellator matches top-end processing performance and RF quality and offers utmost flexibility in simulation control.
    Constellator

    • performs fair-weather tests, but also is designed to subject receivers to suboptimal conditions, extreme situations and combinations of errors difficult to access in real-world tests — all of it finely controlled and indefinitely repeatable.
    • is compatible with other best-in-class test solutions providing GNSS component end-to-end system tests, including hardware in the loop.
    • core is software, ensuring that all future constellations, satellites and codes can be handled. Most functional upgrades will then be software-only.
    • is used in aerospace and defense (among others) for: multi-antenna receiver testing for spacecraft launcher, satellite onboard receiver testing (telecom and observation) and defense UAV receiver testing.


    Main Features

    • 128 channels (extensible) delivering high-quality satellite signals on six distinct frequencies (L and S band)
    • Hardware-in-the-loop testing at 10- to 100-Hz refresh rates
    • Extensive simulation options:
      • • Full-time and location control
      • Receiver trajectories with extreme dynamics
      • Background noise, interference and jamming/spoofing (two units)
      • Atmospheric propagation errors
      • Satellite errors
      • Multipath and obscuration
      • On-the-fly scenario modifications
      • Receiver attitude control
      • Very accurate spaceborne trajectories

    Main Simulation and Modeling Capabilities

    Receiver trajectories: Includes four spatial reference frames and trajectory editors for ground, marine, aerial and spatial motion and import facility.

    Hardware-in-the-loop:
    Receives receiver’s position updates from test-rig in real time and generates corresponding GNSS signals and messages.

    Atmospheric errors: Propagation issues can be simulated at individual signal level with different models provided for ionosphere and troposphere.

    Satellite error modeling options include orbital errors, onboard clock errors, satellite electronics (front-end) defects, satellite dysfunctions and signal fade, disappearance and “evil waveform” incidents.

    www.syntony-gnss.com
    [email protected]
    phone :+33(0) 581 319 919

    Talen-x

    BroadSim: The NAVWAR Simulator
    BSim_stacked-forward-facing_reflectionBroadSim was developed to simplify advanced jamming and spoofing scenarios with Navigation Warfare (NAVWAR) testing in mind. Powered by Skydel SDX, a 1000-Hz GNSS simulator engine, BroadSim is able to simulate multiple vehicles, constellations, and code types (military and civil). BroadSim is ideal for supporting real-world field tests, NAVWAR testing and jamming.

    Field Testing. Field testing GPS receivers to determine their performance and vulnerabilities in degraded or competing environments is becoming standard practice. BroadSim has proven to excel in field testing events due to its integrated GPS receiver allowing for built-in live-sky synchronization, four independent RF outputs, and a wide dynamic range with up to 0 dBm transmit power. A typical configuration for a live-sky field test would have BroadSim time synchronized to live sky, transmitting C/A, P, Y and M on L1 while simultaneously transmitting P, Y and M on L2 all at 0 dBm.

    NAVWAR. BroadSim is great for NAVWAR testing because of how easy it is to use and configure multiple vehicles. Talen-X has carefully designed the simulator such that users can easily create true signals using two RF outputs and spoofed signals using the other two RF outputs. BroadSim’s graphical user interface (GUI) is intuitive and designed to meet the demand of NAVWAR testing.

    Advanced Jamming. An innovative feature that has been added to BroadSim is the ability to generate jamming signals without any additional hardware. Using a simple interface, users can specify the jammer location, power level, waveform type and antenna pattern. BroadSim uses its 1000-Hz engine to compute the I/Q data incident on the user antenna for both the GNSS and jammer signals. This new paradigm of jamming simulation makes it easy to simulate complex jamming environments.

    www.talen-x.com
    phone: +1-319-382-5369
    email: [email protected]

  • SBG Systems rolls out new inertial nav series, Ekinox 2

    SBG Systems rolls out new inertial nav series, Ekinox 2

    SBG Systems has released a new generation of its advanced and compact inertial navigation systems. The Ekinox 2 series features new accelerometers and gyroscopes, enhancing attitude accuracy by a factor of two over the original Ekinox.

    SBG-Ekinox-2-IMU-W
    Photo: SBG

    The Ekinox series is a line of tactical grade MEMS-based inertial navigation systems, first released in 2013. The latest improvements come from a complete redesign of the in-house inertial measurement unit (IMU), integrating cutting-edge gyroscopes and accelerometers.

    With higher accuracy for the same form factor and price level, Ekinox 2 Series is designed for industrial-grade vehicle navigation, equipment motion compensation and data georeferencing. It provides a 0.02-degree roll and pitch, 0.05-degree heading and a centimeter-level position.

    Applications for the Ekinox 2 include hydrography, mobile mapping and antenna tracking. With new accelerometers, this new generation has also significantly improved its resistance to vibration. Finally, the addition of the BeiDou constellation improves signal availability in Asia.

    Compact and light-weight, the Ekinox Series has been designed to simplify installation operations. Configuration is made with an intuitive embedded web interface where all parameters can be displayed and adjusted. For example, users can choose a profile (vessel, plane, car, etc.), and the 3D view will provide a visualization of settings such as the sensor position, alignment and lever arms.

    The Ekinox 2 Series is ITAR Free. The product line will be available during the second quarter of 2017.

  • Telit offers new series of smart GNSS antenna modules

    Telit offers new series of smart GNSS antenna modules

    SE868K7-Ax_dynamicTelit, a global enabler of the Internet of Things (IoT), has introduced advanced positioning modules in the SE868xx-Ax family featuring multi-constellation GNSS receivers with 9 square millimeter patch antennas.

    Telit’s SE868Kx-Ax series offers high performance for space-constrained applications such as wearables, tracking, telematics and security. The new integrated antenna modules include advanced features that significantly increase RF sensitivity, allowing for a much simpler integration without external components.

    The SE868K3-A/AL is a multi-constellation GNSS variant with flash memory and a GNSS core.

    The SE868K7-A/AL is a GPS variant with ROM memory and a GPS core.

    The new module variants are designed with the same, ultra-compact 11 square millimeter cavity PCB package as the other modules in the series, with the bonus of a second low noise amplifier (LNA) and surface acoustic wave (SAW) filter. Footprint compatible with other modules in the family, the SE868Kx-Ax series includes variants with multiple interfaces and a combination of features including:

    • Ultra-compact 11 x 11 mm “cavity” PCB package
    • Standard variant with integrated 9 millimeter by 9 millimeter by 4 millimeter SMT antenna
    • Low-profile variant with 9 millimeter by 9 millimeter by 2 millimeter antenna
    • Additional LNA and SAW filter
    • Real time clock (RTC) and temperature compensated crystal oscillator (TCXO)
    • Jamming rejection
    • Pin-to-pin compatibility with other modules in the series
    • Ephemeris file injection (A-GPS)
    • Satellite-Based Augmentation System (SBAS) compliant

    With the different options available in the SE868Kx-Ax series, customers can design once and interchangeably mount the solution most appropriate for the environment, Telit said. This enables developers to select the right technology for their use case without having to redesign the entire application when it comes time to transition.

    “The SE868Kx-Ax series is an exciting enhancement to our positioning product portfolio,” said Felix Marchal, EVP GNSS and short range, Telit. “Our commitment to excellence is reflected in the years of experience releasing breakthrough positioning modules and solutions. This latest release specifically addresses the integration challenges that IoT developers face today. Leveraging the low-profile and SMT mounting options that do not compromise the host PCB, developers can take advantage of the most important and advanced features available in positioning technology tangibly booting the efficiency of global design efforts, schedules and budgets.”

    The Telit IoT Know How program assists customers to accelerate the deployment of cost-effective and future-proof solutions integrated with GNSS from idea to market, the company said.

    The variants will be available in the second quarter of 2017. Telit is exhibiting them at Embedded World 2017, Nuremberg, Germany, March 14-16, located at hall 3, booth 3-518.

  • The state of the UAS/UAV industry

    The state of the UAS/UAV industry

    Assessing the health of an entire industry is not an easy task, but talking with industry leaders and looking for examples of growth and investment can help.

    Our “State of the UAS/UAV Industry” inquiries have lead to discussions with General Atomics, Association for Unmanned Vehicle Systems International (AUVSI), Aeryon Labs and SensoFusion. SensoFusion might be a little well less known that the others, but we felt the need to include the views of an anti-drone system supplier to counterbalance the industry’s perception of itself.

    Discussions included questions around the following issues:

    • The level of maturity of common technologies in use on UAV platforms and systems?
    • The level of maturity of integration of those technologies?
    • A sketch portrait of the industry?
    • Rough numbers or percentage of small players versus large ones?
    • The rate of consolidation of companies (has it happened or has it yet to happen?)
    • The financial underpinnings of the market — does it have real “legs” or will it be like the first Internet boom/bust?

    If we start with a top-level overview of the industry, as a whole we find that on the commercial side it’s an industry trying to figure out what it is and who its customers might be. But there is also a well-established military part of the industry that is quite mature. A large number of multi-rotor UAV suppliers use simple handheld controllers, all aimed at different applications where they are seeking a niche. The FAA’s release of regulations last year for use of small unmanned vehicle systems (sUAS) has provided a real boost to many more commercial pay-for-service ways these vehicles are now being used.

    Multi-rotor UAVs are being put to use in surveying, filmmaking, newsgathering, real estate, crop and pipeline inspection, firefighting, law enforcement, security, search and rescue, and disaster monitoring and relief, just to mention a few applications. And, of course, home/hobby flying your own drone in your backyard or open areas has fueled the Chinese DJI drone manufacturers’ growth significantly. While the FAA requires registration of these private drones, it has not prevented an increase in commercial passenger aircraft pilot reports of UAV incursions into controlled airspace, which appear to be on the increase.

    Then there are small, medium and large fixed-wing UAVs that appear to have been mostly developed for and used by the military. Hand-launched surveillance drones for small groups of ground troops; mid-sized, longer range surveillance drones finding applications in commercial inspection; and the bigger General Atomics Predator type aircraft which have become the U.S. military’s search and destroy long-range vehicle, which can carry significant ordinance. At the top end, we have UAVs like Global Hawk which are used for very high altitude, long-endurance surveillance. Not forgetting target drones like the Northrup Grumman BQM-74E, which earns its living pretending to be an enemy anti-ship cruise missile for the U.S. Navy.

    Commercial Growth Anticipated

    Brian Wynne, president and CEO of the Association for Unmanned Vehicle Systems International (AUVSI), believes for the commercial segment that, “The UAS industry is primed for incredible growth. UAS are being used in all 50 states by industries like real estate, agriculture and the oil and gas industry for more than 40 different types of business applications, including aerial photography, emergency management and utility inspection.”

    More than 500,000 people have registered their UAVs with the FAA in the U.S., and around 20,000 of those are looking to start commercial operations. AUVSI expects more than 100,000 jobs will be created when UAS are integrated into and allowed to operate in the U.S. National Airspace System (NAS).

    However, Wynne went on to comment, “This this can only happen if the government puts in place a true, holistic plan for full UAS integration that includes flights over people, as well as beyond line-of-sight operations, access to higher altitudes and platforms above 55 pounds.” AUVSI estimates that in the first decade after full UAS integration into the NAS, these commercial operations could generate more than $82 billion is economic impact.

    Even before the FAA’s release of formal regulations (known as Part 107) for use of sUAS in June last year, more than 5,500 businesses received approval to fly for commercial purposes. AUVSI published a report that analyzed these applications — the analysis provides an overview of the developing commercial UAS industry in the U.S.

    AUVSI analysis of initial UAS applications.
    AUVSI analysis of initial UAS applications.

    Over 90 percent of these businesses make less than $1 million in annual revenue and have fewer than 10 employees. This also provides an indication that the engine behind this growth comes from small, independent business.

    Nevertheless, big organizations such as CNN are also exploring visual line-of-sight operations over people and safely using UAS for newsgathering in populated areas. PrecisionHawk is testing extended visual line-of-sight operations in rural areas, aimed at precision agriculture, and BNSF Railway is testing beyond visual line-of-sight (BVLOS) operations, in rural and isolated areas, for the inspection of rail system infrastructure. These tests are being conducted as part of the FAA’s Pathfinder Program.

    More recently, anti-drone systems have joined the party to help defend against unwanted UAV incursions into secure areas already protected by conventional systems like radar, acoustic and optical detection systems. Secure areas include such places as prisons, government buildings/facilities, utility companies (including nuclear power stations) and airports. Sensofusion in Finland is one such company, with its Airfence anti-drone system — one of three anti-drone systems tested last November by the FAA at Denver airport. The other systems were supplied by CACI International and Liteye Systems.

    Kaveh Mahdavi, VP of Operations for Sensofusion, thinks that, relatively speaking, the UAV industry is quite mature — what’s still being developed are systems to enable autonomous drone flight. The regulations published so far only address ground-pilot-controlled operations, even though BVLOS testing is progressing well.

    Anti-Drone Systems

    On the other hand, the maturity level of anti-drone systems range from proven to embryonic. As many as 50 companies with different technical solutions are vying to succeed in this new segment. But as the UAV segment continues to grow, so does the need for detection and prevention of drone incursions.

    These systems employ three basic technologies: radar, optical and RF. Radar and optical need direct line of sight and cannot see “over the horizon.” That makes them quite short-range, and detection and defense has to be exceptionally quick to prevent unwanted UAV flying visits. Whereas, the Airfence RF system is omnidirectional and can even detect UAS preparing for take off up to six miles away, as demonstrated at the Denver airport.

    So, intrusion warnings at a geo-fence distance of, say, 3-4 miles can be generated, and automatic defense/prevention is readily achieved. For instance, some utility companies want to have detection, warnings and control of intruder drones within a mile of their facilities.

    Mahdavi went on to describe how Airfence uses a library of drone control RF signatures for all known UAS, with new signatures being added on a regular basis. They can detect, intercept and directly take control of the offending vehicle. During the Denver tests, Airfence initially only detected one third of the target UAVs, but the RF signatures of all targets were acquired. Then, using remote engineering updates to the library, by day three all were detected. With lower prices, consumer drones are becoming a real threat for these sensitive areas.

    The anti-drone industry will no doubt face considerable consolidation over the next couple of years, but Mahdavi feels that Sensofusion is well placed with significant military and government business, which is funding their growth without external investment. “Securing the right contracts with the right customers,” as he says, has well positioned the company for now and the future.

    General Atomics Aeronautical Systems Inc. (GA-ASI), makers of the well-known Predator, Reaper and other Medium-Altitude Long-Endurance (MALE) drone systems, has been in this business for almost 25 years. GA considers its products to be proven, mature and resilient for the military and government markets that demand them to be so. The company uses “best of breed” in-house products and technology across the range of air and ground systems that make up its highly successful drone systems.

    In an effort to align with European customer interest, GA-ASI has been investing in a “certifiable” version of the Predator-B, recently named SkyGuardian. A derivative for marine applications will be known as the SeaGuardian.

    Just as military transport aircraft want to transit through civilian airspace and, in order to do so, have been equipping with certified navigation systems for a number of years, military drone operators want to be compatible with Europe’s high-density commercial flight regulations and to operate within existing air-traffic control corridors. To arrive in time for these European programs, GA-ASI has invested to get ahead of the market. This has entailed assessment of all on-board and ground components, and has led to upgrades and re-designs where necessary.

    “Nevertheless, on existing product lines, there is a large degree of commonality across common systems on multiple platforms,” said Mike Cannon, VP of international programs. Common systems include datalinks, power avionics, de-icing systems, and some airframe components.

    GA-ASI has developed and integrated its own flight control system in its aircraft for more than 20 years. This has proven to be a key element of the success for the Predator family of products. Because all these systems have been flying for so long, they have been proven and become very reliable, dependable elements of the company’s unmanned systems.

    Having said that, Hughes Network Systems has just announced that its Defense and Intelligence and Systems Division (DISD) has been selected by GA-ASI to provide satellite communications on the “Type-Certifiable” Predator B Remotely Piloted Aircraft (RPA) system. Working with GA-ASI, Hughes will customize the aircraft’s satellite communications system with modified Hughes HM series modems. The advanced modems will enable a significant increase in data transfer rates, using an enhanced waveform that ensures resilient and secure communications when operating in challenging environments.

    So, its very difficult for new start-up companies to enter this top level segment of the UAV market — its very expensive to develop, demonstrate and prove large airframes, control systems and avionics that customers can rely on. GA-ASI has a unique position alongside major suppliers such as Boeing, Northrup Grumman, Israel Aerospace Industries (IAI), and Lockheed Martin — however, Chinese UAS are beginning to show up in the marketplace, apparently as a result of significant, focused investment.

    Nevertheless, with an enviable position as a major supplier of platforms used in multiple applications, with sufficient internal resources to fund their initial vehicle developments, GA-ASI has secured a large number of programs with multiple follow-on orders and funding for increasingly more capable derivative UAS. As the company now looks towards the “certifiable” segment using another internally funded product launch, it is again reinforcing its leadership position in its chosen unmanned market segment.

    Small UAS by Aeryon Labs

    Meanwhile, the world of small unmanned air vehicles (sUAS) continues to thrive, given the release of FAA regulations last year, and many commercial applications are blossoming, using increasingly capable small multi-rotor drones. David Kroetsch, CEO and co-founder of Aeryon Labs in Ontario, Canada, thinks that the sUAS segment is maturing from an early adoption phase into providing utility to a growing number of organizations. Aeryon is an established player in the sUAS market and has been around for more than 10 years, so it has also had time to prove its platforms and internal systems. Aeryon also built its own flight-control hardware and software, which enables the company to gain substantial power savings and get longer endurance from how it automatically manages rotor speeds.

    “The quad platform has been around since 1938, so the concept is hardly new; however, over the last decade, Aeryon Labs has substantially matured and ruggedized our platform, the Aeryon SkyRanger sUAS,” said Kroetsch. Their focus is on not only on the UAV platform, but also on supplying complete systems that meet the various needs of their customers. With electro-optical and thermal-imaging camera payloads and an on-board georeferencing data collection/processing system, Aeryon provides integrated solutions for customers, such as AeryonLive Video and Telemetry and AeryonLive Fleet Management using real-time software tools.

    For the oil and gas industry, providing compatibility for off-line flight planning software inputs and importing compatible aerial imagery into existing GIS systems is a significant feature for these customers. The SkyRanger UAS has benefited from many years of use in the field, and has been designed with modularity and ease of use with snap-on/off parts that make operating in bad weather a lot easier.

    Aeryon’s business is currently 50%military, 25% oil and gas and 25% public safety (such as rapid traffic accident data gathering). Other entrants to these segments might find it easy to put together an unmanned system from parts bought on the internet; what comes considerably harder is proving reliability and interoperability with existing customer systems. Actually, to develop an industrial-grade UAV takes lots of investment and requires experience gathered over many years. Customers have learned how to differentiate between those dabbling in the market and those with serious capabilities.

    Consolidation is inevitable in this market segment — perhaps within the next six months, certainly over the next two years — just because there are so many companies trying. Investment is getting harder to find for these start-ups and it may be too late for most, as the leaders are already well established.

    “It’s essential to pick a niche within the increasingly competitive UAV industry,” Kroetsch said. “This is why Aeryon chose early on to focus on enterprise-level offerings in commercial, public safety and military.”

    Recall what happened to 3D Robotics. Even though 3D Robotics raised many millions in funding, its Solo quadrotor fell from grace, perhaps due to continuing design issues and being higher priced compared to rapidly declining DJI Phantom 3 prices. “‘Competition and consolidation look to be very similar to that which happened with digital cameras,” Kroetsch said.

    For Aeryon, being Canadian appears to be an advantage right now, as U.S. export regulations seem to be handicapping U.S. drone manufacturers. Aeryon sells in 35-40 countries because its product does not contain military-restricted components and only uses commercial parts. Canadian regulations for drone system exports do not prohibit world–wide sales for such products, while U.S. regulations can be difficult for U.S. suppliers to negotiate.

    Nevertheless, unexpected hurdles to adoption still exist, such as company policies related to health and safety, union restrictions, and potential internal clashes on responsibility for implementation. But with 100% test, and a hardened design for tough environments, Aeryon sees itself well positioned to grow in its chosen industrial sector.

    Conclusion

    This has been a brief and incomplete overview of the UAV/UAS industry — a first try, if you will. Nevertheless, it’s a summary that we can use a benchmark for where we are right now, and a departure point for future growth.

    We have quite mature capability in both large and small UAS, with integration focused on flight-control and navigation systems. The larger UAS enjoy a relatively mature market with established suppliers of lower numbers of expensive systems, while the sUAS segment is larger, younger and less expensive, with not as many barriers to entry.

    Nevertheless, there are mature industrial segments with harder, more integrated requirements that make it hard for new entrants to climb the steps into more difficult commercial operations. The recreational segment is dominated by DJI, and it remains strong with well-performing, easy-to-operate drones.

    Because of the ease of access to smaller drones, despite FAA and other countries’ regulations, people seem to want to penetrate secure facilities such as utilities, airports, military bases, prisons and other government locations. Therefore, anti-drone systems using optical, radar and RF are becoming available, and facilities are being equipped to prevent unwanted drone incursions.

    AUVSI xPONENTIAL

    I’ll be roving the show floor at the upcoming AUVSI xPONENTIAL show in Dallas, and I welcome your added insight, from all corners of the UAV industry, for a continuation of this assessment in an upcoming Professional OEM & UAV e-newsletter column (subscribe free at gpsworld.com/subscribe).

    Tony Murfin
    GNSS Aerospace

  • OriginGPS launches ultra-compact GNSS module

    OriginGPS launches ultra-compact GNSS module

    OriginGPS has released its new ORG 4500 series, which is a fully-integrated product that supports ultra-compact applications for both GPS and GLONASS.

    The ORG 4500, kin to the ORG 4400 series introduced in 2016, addresses the increasing demand for high precision with the smallest possible footprint, and takes the company’s ultra-small form factor to a new level.

    OriginGPS ORG 4500 is designed for ultra-compact IoT applications such as wearables, smartwatches, clothes and pet trackers, drones, connected cars, and health testing and tracking devices.
    OriginGPS ORG 4500 is designed for ultra-compact IoT applications such as wearables, smartwatches, clothes and pet trackers, drones, connected cars, and health testing and tracking devices.

    “The newest GNSS product perfects the industry’s most comprehensive GNSS/GPS family of solutions,” said Haim Goldberger, CEO of OriginGPS. “Our modules readily resolve the industry’s acute pain points of unreliability and sensitivity in the commercial, engineering and defense sectors, enhancing the quality of experience and helping our customers remain competitive.”

    OriginGPS offers a range of fully-integrated GNSS/GPS and antenna solutions, encompassing a wide gamut of standard and essential tools for navigation. The small form factor and high sensitivity of OriginGPS’s modules enable new business models, like “machine as a service,” and are suited for a variety of applications, such as wearables, like smart watches and pet tracking, as well as smart cities and drones.

    OriginGPS modules are deployed around the globe in key sectors, such as transportation, civil engineering, precision agriculture and time reference.

    Narrowband IOT platform. Ramping up the race to offer the best Narrowband IoT (NB-IoT) products, OriginGPS continues to expand its presence in the global navigation market with a steady stream of new IoT-enabled solutions, such as its recently released IoT platform (ORG 2100).

    A key theme again at this year’s Mobile World Congress was the Internet of Things, with an additional focus on the challenges of ensuring interoperability of home and industrial applications. OriginGPS’s IoT Platform effectively removes usability challenges with a plethora of customizable sensors, such as temperature, pressure, accelerometer, light and humidity.

    OriginGPS will showcase its range of mini + mighty GNSS/GPS modules at Embedded World 2017, Germany, March 14-17, hall 3, booth 121.

  • Antenova reveals chip antennas for new NB-IoT standard

    Antenova reveals chip antennas for new NB-IoT standard

    Antenova's new NB-IoT antenna "Latona."
    Antenova’s new NB-IoT antenna “Latona.”

    Antenova Ltd., manufacturer of antennas and RF antenna modules for machine-to-machine and the Internet of Things (IoT), has developed a new antenna for the new narrow-band IoT (NB-IoT) standard that was ratified in 2016. The company showcased the antenna at Embedded World in Nuremberg in March.

    The antenna is small, measuring 20 x 11 x 1.6 mm, and is built to a novel design that allows it to perform well within a device while being easy to integrate onto a small printed circuit board (PCB).

    The new chip antenna in the company’s lamiiANT antenna family is named Latona (part no. SR4C033)

    Narrow-band IoT is the latest mobile broadband standard. It uses the 3GPP licensed network spectrum, which is secure and free from interference, and offers the combined advantages of low power, long range and the ability to penetrate walls and metal barriers.

    “Narrow Band IoT will be good for connecting devices in locations where the signal distance is in kilometers and for locations in basements and underground.” explains Antenova’s CEO, Colin Newman. “It could be the enabler for some of the IoT applications that are emerging that are not suited to the established telecoms networks, where the data throughput is quite low and infrequent. We see these antennas being used for smart metering, agricultural technologies, building automation and smart city applications with lighting, waste bins and parking spaces.”

    As with all of Antenova’s embedded antennas, the NB-IoT antennas are designed for quick and easy integration onto a host PCB.

    Samples of Latona areavailable to order. Antenova provides full design, testing and tuning services for customers who are adding wireless capabilities to their IoT devices and other electronic products.

  • Sensor role reversal: How lidar can replace GNSS for navigation

    Airborne lidar/INS/GNSS: Algorithm Uses Fuzzy Controlled Scale Invariant Feature Transform

    Sensor role reversal: Lidar with its superior performance can replace GNSS in the integration solution by providing fixes for the drifting inertial measurement unit (IMU). Tests show its potential for terrain-referenced navigation due to its high accuracy, resolution, update rate and anti-jamming abilities. A novel algorithm uses scanning lidar ranging data and a reference database to calculate the navigation solution of the platform and then further fuse with the inertial navigation system (INS) output data.

    Recent rapid advances in laser-based remote sensing technologies, including pulsed linear, array and flash lidar systems, have fostered the development of integrated navigation algorithms for lidar and inertial sensors. In particular, trajectory recovery based on lidar point-cloud matching can provide valuable input to the navigation filter. Lidar/INS integrated navigation systems may provide continuous and fairly accurate navigation solutions in GNSS-challenged environments, on a variety of platforms, such as unmanned ground vehicles, mobile robot navigation and autonomous driving.

    In the case of airborne lidar/INS applications, the free inertial navigation solution is used to create the point clouds, which are subsequently matched to a digital terrain elevation model (DEM). The results are fed back to the platform navigation filter, providing corrections to the free navigation solution. This solution may be used to recreate the point cloud to obtain better surface data.

    However, depending on the lidar data acquisition parameters, INS drift during the time between the two epochs when point clouds are acquired could be significant. Besides the shift in platform position, the drift in attitude angles could more severely impact point-cloud generation, producing a less accurate point cloud and subsequently poor matching performance.

    This article describes a new lidar positioning approach, where the scale-invariant feature transform (SIFT)-based lidar positioning algorithm is used to match between the lidar measured point cloud and the reference DEM. The matching process is aided with fuzzy control: SIFT-based lidar positioning algorithm with Fuzzy logic (SLPF), where the threshold for SIFT is adaptively controlled by the fuzzy logic system.

    Based on the geometric distribution and the range difference variance of the matched point clouds, fuzzy logic is applied to calculate the threshold for the SIFT algorithm to extract feature points; thus the optimal matched point cloud is extracted in several iterations. When there are enough matched points in the final output of the SLPF, the platform position is calculated by using the least squares method (LSM). Next, for trajectory estimation, when applying the SLPF algorithm, frequent lidar updates can be used to correct small cumulative errors from the INS sensor measurements. A Kalman filter fuses the results of the SLPF algorithm with the INS system.

    This integrated algorithm can handle situations when there are less than three matched feature points being extracted by the SLPF algorithm, and yet they could still contribute to obtain a better navigation solution. Simulation results show that, compared to the existing algorithms, the proposed lidar/INS integrated navigation algorithm not only improves the position, speed and attitude-determination accuracy, it also makes the lidar less dependent on INS, which makes the navigation system work longer without exceeding a particular drift threshold.

    LIDAR ALGORITHM

    To eliminate the influence of INS error on the lidar positioning system, instead of creating a measured DEM based on INS ortho-rectification, we directly map the range data measured by lidar to the local stored DEM data. If a successfully matched feature point can be obtained, it means that we can get a point with absolute position and relative range towards the platform, which is similar to the satellite in GNSS positioning. After scanning of one area by lidar, when three or more such matched feature points, if not on a line, can be obtained, then we are able to form a full rank equation with the unknown variables of the platform position x, y and z.

    However, due to the effect of affine transformation, the standardized range dataset collected by lidar is significantly different from the elevation dataset belonging to the same area. Figure 1 shows an example of the large difference between the two datasets from the same area when the pitch angle of the platform is equal to 5° and the flying height is 2,000 m. In this situation, the traditional flooding algorithm or constellation feature point matching algorithm is incapable of extracting matched feature points from such different datasets.

    Figure 1. Comparison between SR and DEM data from the same area.
    Figure 1. Comparison between SR and DEM data from the same area.

    In response, we introduce the SIFT algorithm to the elevation map-matching procedure. Designed for image matching, the SIFT algorithm is invariant to scale, rotation and translation, and it is robust to affine transformation and three-dimensional projection transformation to a certain extent. Although SIFT is often used in image matching, each pixel from the image is a numerical point, which, in fact, has no difference with elevation data point. Before applying the SIFT, some processing on the lidar measured range data must be done.

    LIDAR RANGE DATA

    The scanning information of the lidar measured points are (α, β, r), where α is the angle between the laser beam and the negative Z-axis of the platform body frame, β is the angle from the laser beam to the plane of axis and Z-axis in body frame, r is the range between the laser head and the measured target, as shown in the opening figure.

    Due to the terrain relief, the lidar range data are irregularly spaced. Therefore, it is necessary to interpolate the collected data. Here we apply the Natural Neighbor Interpolation method.

    SIFT Algorithm, Fuzzy Control. For the lidar positioning algorithm, which is based on the absolute position and relative range of the ground-matched feature points, a point cloud with sufficient number of points of good geometric distribution is needed. In practice, however, the terrain undulation and the attitude of the airplane will affect the quality of the point cloud and the accuracy in the matching process. In addition, the selected threshold in the SIFT algorithm plays an important role on the quality of the matched point cloud.

    A Monte Carlo simulation, shown in FIGURE 2, illustrates the impact of the threshold on the number of successful matched points (normalized) and mismatched rate. For obtaining better matched point clouds, we have introduced a SIFT terrain matching algorithm assisted by fuzzy control, as shown in FIGURE 3.

    Figure 2. Relationship effect of threshold on the number of successful matched point (normalized) and error matched rate.
    Figure 2. Relationship effect of threshold on the number of successful matched point (normalized) and error matched rate.
    Figure 3. Working principal diagram of SIFT terrain matching algorithm based on fuzzy control.
    Figure 3. Working principal diagram of SIFT terrain matching algorithm based on fuzzy control.

    The algorithm mainly consists of two fuzzy logic controllers. Controller 1 calculates the initial threshold for the SIFT algorithm according to the gridded SR data terrain undulation degree λ, and the angle Θ between Z-axis in body-frame and Z-axis in navigation frame.

    Controller 2, which is responsible to adaptively changing the threshold at each epoch, has two inputs. The first one is the Normalized Points Area (NPA), which represent the geometric condition of the matched point cloud. The other one is the Relative Range Difference Variance, which indicates if a mismatch has happened. When the final matched feature point cloud is obtained, and the number of points is greater than or equal to 3, then the LSM is used to calculate the position of the platform.

    INS/LIDAR NAVIGATION

    Loosely and tightly coupled integration are the most common methods in navigation systems. Given the characteristics of the proposed positioning algorithm, the classical integrated navigation algorithm needs to be modified. In the loosely coupled approach, the lidar is unable to aid INS when flying through a flat region and/or flying with a large tilt angle, because the proposed lidar positioning method may have difficulty in extracting enough matched points to calculate a position.

    In the tightly coupled method, as the output frequency of matched point cloud is low and the geometry of the matched feature points is relatively poor, the integrated system may be extremely unstable. Here we propose a combined loosely and tightly (CLT) integrated navigation algorithm that when the lidar positioning algorithm can extract enough matched points for a navigation solution, the lidar-calculated navigation solution is used as the main observation.

    However, when the matched points are not sufficient to obtain a navigation solution, the baseline vector of the matched point that is closer to the projection of the platform center to the surface will be utilized as the observation. In this solution, lidar can still provide a certain degree of aid to the INS, once extracting matched feature points, even if less than 3.

    SIMULATION ANALYSIS

    In the simulation experiment, the 3D DEM data of 0.5-meter resolution is obtained from an open source named EOWEB. Then the DEM data is resampled to a higher resolution of 0.1 meter, which is used to generate the simulated, irregularly spaced, measured range data. On the basis of the original DEM (0.5 meter resolution), the proposed lidar positioning algorithm and lidar/INS integrated navigation algorithm are verified and compared with the traditional methods.

    Simulation of Lidar Algorithm. As shown above, the successfully matched points rate is very important for positioning, as once a mismatched point occurs, it may lead to a faulty navigation solution. In the simulation, the proposed SLPF is simulated under the condition of different aircraft tilt angle ϴ, from 0° to 10° with a step of 1° , at 5,000 different positions, which is the same simulation condition as in Figure 2. Comparison is made with the traditional constellation feature matching based lidar positioning algorithm (CLP) and the SIFT based lidar positioning algorithm without fuzzy control (SLP). The successfully matched points rate and the NPA value are shown in Figure 4.

    Figure 4. Successful points matched rate and the NPA value results under different aircraft attitude condition from three different algorithms.
    Figure 4. Successful points matched rate and the NPA value results under different aircraft attitude condition from three different algorithms.

    As can be seen from the figure, along with the increasing platform attitude angle, the successfully matched points rate of all the three algorithms has declined. However, compared to the CLP, both SIFT-based algorithms have a higher success matching rate due to the more stringent feature-point extraction approach. And due to the adjustable threshold mechanism, the SLPF could remove some of the mismatched points by raising the threshold; thus it is superior to the common SIFT algorithm in performance. The NPA values of the extracted point cloud from the three algorithms are shown in Figure 4(b). With the increased attitude angle, the NPA value of the matching feature point cloud decreases in all three algorithms. The CLP algorithm, however, is more sensitive to the projected range data, which makes the number of successful matching points drop sharply, and further affect geometric distribution of the point cloud. The gap between the SLPF and SLP shows that the fuzzy control module can help improve the geometric structure of the feature point cloud.

    Figure 5 shows the positioning error when applying the three different matching algorithms at 5,000 different areas. The SLPF algorithm is better than the other two algorithms in all directions. When the platform’s attitude angle reaches about 10 degrees, the north and east positioning accuracy of SLPF algorithm is still about 8 meters, and the height positioning accuracy is about 0.2 meters. The reason that the height positioning error is far less than the north and east positioning error is because of the matching point cloud distribution. Due to the airborne lidar scanning mechanism, the matched point cloud is all located in a relative small area at the bottom of the platform, resulting in the great component value in the height direction of each matched feature point baseline vector in the G matrix, and then affect the final positioning accuracy.

    Figure 5. Positioning accuracy under different aircraft attitude conditions with different algorithms.
    Figure 5. Positioning accuracy under different aircraft attitude conditions with different algorithms.

    Table 1 shows some detailed information as average number of matched points (ANMP) and matched points position error (MPPE) using the three methods. The MPPE is calculated in 3D space. It can be seen that when the tilt attitude is small, comparing to the CLP method, although the number of matched points extracted by SLPF is less, the matched points position accuracy is still much better, leading to a better localization result. Moreover, with the increasing platform tilt attitude, CLP and SLP have more difficulty in maintaining the number and accuracy of the matched points.

    Lidar/INS Algorithm. To validate the feasibility of the proposed integrated navigation algorithm, firstly, the motion trajectory of the platform must be simulated. As shown in Figure 6, the red line is the simulated platform true trajectory, which lasts for 1,400 seconds. During the trajectory, the platform undertakes the different motion states as acceleration, deceleration, climbing, turning and descent. Then the INS output data based on the true trajectory with the frequency of 100 Hz is generated. To verify the calibration performance on the INS in the integrated navigation algorithm, accelerometer and gyroscope drift noise is added to the INS output data. The green line shown in Figure 6 is the INS output data trajectory solution. At the end of simulation, the error to the east direction reaches 500 meters, and the north direction error reaches to more than 2,200 meters.

    Figure 6. Comparison between True trajectory and INS calculated trajectory.
    Figure 6. Comparison between True trajectory and INS calculated trajectory.

    At the same time of the INS outputting navigation solution, lidar also scans and calculates the position of the platform with 1-Hz frequency. Note that the speed of the aircraft is from 70 m/s to 100 m/s, and the maximum lidar scanning angle αmax is 20°. Figure 7 and Figure 8 show the number of matched points and the positioning error for each scanned terrain using SLFP. When the platform maintains smooth flying, the number of matched points can reach an average of 10, and the positioning accuracy is relatively high, less than 3 meters. Note, during the period, only in a few epochs are the number of matched points less than five. However, when the platform is climbing or changing flight direction, the number of matched points is obviously decreased due to the large tilt angle of the platform, and so does the number of successful positioning times. In this case, the position error is also increased dramatically, reaching about 10 meters error in east and north, and 0.2 meters error in height. Especially in the course of changing the direction of the flight, shown in Figure 7, during the periods of 720s–800s and 920s–1,000s, due to the larger roll angle, the SLPF could hardly be able to calculate the position through the LSM. During this period the lidar would occasionally output 1 or 2 matched feature points.

    During the simulation, the CLT and LC methods are used for data fusion and trajectory estimation comparisons. TC method is not added to the comparison because of slow convergence. The data fusion results are shown in Figure 9. It illustrates that the LC method and the CLT method have close positioning accuracy in the case of sufficient matched feature points. As can be seen in conjunction with Figure 8, when lacking matched points, the CLT method is superior to LC on positioning accuracy, especially in the height direction. In addition, the CLT integrated algorithm shows some improvement on the accuracy of estimating speed and attitude.

    Figure 10 shows the position error distribution when using four different lidar/INS integrated navigation methods for data fusion under the condition of different simulation trajectories. In the simulation, 50 1,400-second-long different trajectories, with flat areas, are generated with different platform attitude, velocity or acceleration. As can be seen from the figure, compared to other integrated navigation methods, the CLT method greatly improves the accuracy of navigation.

    Figure 10. Position error distribution when using four different lidar/INS integrated navigation method.
    Figure 10. Position error distribution when using four different
    lidar/INS integrated navigation method.

    During 84.26% of the simulation period, CLT could maintain the position error less than 3 meters; the rate with error that is larger than 15 meters is 1.2%. For the TC method, due to the frequent divergence of the data fusion filter, most of the position estimates are not available. In addition, after flying above a flat area, the voting-based constellation integrated method has poor matched point accuracy and successfully matched rate due to large INS drift error, which makes lidar unable to calibrate the INS. When using the constellation-based method, during only 32.35% of the simulation period, the error is maintained in 3 meters and most of the period, 54.9%, the position error is between 3 to 15 meters.

    CONCLUSION

    We propose a new lidar matching algorithm based on SIFT, which does not rely on the INS output data to generate measured DEM data, and can adaptively change the threshold of the SIFT algorithm to generate optimal matching between the point cloud and the DEM. Through verification of simulation, the algorithm is compared with traditional lidar/INS integrated navigation methods based on comparing achieved accuracies in estimating position, speed and attitude. Simulation results show that the SLPF algorithm has better reliability for feature points matching and robustness against the platform attitude than the traditional algorithms. The CLT method improves trajectory estimation accuracy, especially when flying over moderately undulating terrain or flying with large roll or pitch angles.

    ACKNOWLEDGMENT

    This article is based on a paper presented at the ION International Technical Meeting, January 2017. This research used an open-source GNSS/INS simulator based on Matlab, developed by Gongmin Yan of Northwestern Polytechnical University, China.


    Haowei Xu is a Ph.D. student at Northwestern Polytechnical University, where he received an M.Sc in Information and Communication Engineering. He is a visiting scholar at The Ohio State University.

    Baowang Lian is a professor at Northwestern Polytechnical University where he is also director of the Texas Instruments DSPs Laboratory.

    Charles K. Toth is a senior research scientist at the Ohio State University Center for Mapping. He received a Ph.D. in electrical engineering and geo-information sciences from the Technical University of Budapest, Hungary.

    Dorota A. Brzezinska is a professor in geodetic science, and director of the Satellite Positioning and Inertial Navigation (SPIN) Laboratory at The Ohio State University.

  • Spirent helps to improve search-and-rescue operations at sea

    Spirent helps to improve search-and-rescue operations at sea

    Test solutions by Spirent Communications plc have been used to improve maritime safety.

    Working with the Radio Technical Committee for Maritime Services (RTCM), Spirent has created test scenarios that simulate realistic satellite reception conditions at sea so that GPS distress beacon performance can be improved, allowing users to be rescued faster by search and rescue organizations.

    One of the first customers to use these scenarios to test its locator beacons is ACR Electronics Inc., a manufacturer of emergency lifesaving equipment. Its latest ACR and ARTEX products have been tested using a Spirent signal simulator, and have been certified as meeting the RTCM standards for cold-start time-to-first-fix, which specifies the time taken by a device when it is turned on to capture GPS signals and determine its location.

    ACR-Spirent-W
    Photo: Spirent

    The U.S. Federal Communications Commission (FCC) has now mandated that in future, any new products in the related categories must be tested using a GNSS simulator and the scenarios in the RTCM standards, which were developed by Spirent.

    “We are able to test the performance of our dual-frequency GPS/Galileo receivers using a Spirent simulator that can accurately simulate signals from different constellations to enhance the performance of our Emergency Position Indicating Radio beacons (EPIRBs, PLBs and ELTs),” said Bill Cox, Director of Engineering at ACR. “Our customers will soon be able to take advantage of a new confirmation system that will let them know that their call for help was heard.”

    “We are very pleased to have worked with RTCM and ACR to improve maritime safety”, said Martin Foulger, General Manager of Spirent’s Positioning Business Unit. “This project shows the importance of testing in realistic conditions to give better end-user experience, which in this case could be a matter of life or death. This will make lifesaving equipment more reliable both for maritime users and search and rescue agencies.”

    ACR-Spirent-resqlinkplus-W
    Photo: Spirent

    The RCTM discovered that Cospas-Sarsat 406MHz beacons with integral GPS receivers suffered from poor cold start performance, causing delays in providing accurate location information to Search and Rescue (SAR) authorities. It later discovered that this was because beacons tended to be tested on land in benign conditions, rather than in real-world oceanic conditions.

    It has addressed the issue by specifying a set of performance standards for Emergency Position Indicating Beacons (EPIRBs), Personal Locator Beacons (PLBs), Hand-held VHF Radios with integral GPS Receivers, Manoverboard (MOB) devices and Satellite Emergency Notification Devices (SENDs).

    Spirent was asked to develop a set of custom test scenarios that enable manufacturers to simulate realistic satellite reception conditions at sea in laboratory environments. Use of these scenarios enables manufacturers to better assess the performance of their products in the real world.

    Details of the FCC mandate can be found in the Federal Register, Vol. 81, No. 241, Dec. 15, 2016, Page 90739, FCC 47 CFR Parts 1, 25, 80 and 95.

  • u-blox and Digicom partner on narrowband IoT products

    u-blox and Digicom partner on narrowband IoT products

    Chip-maker u-blox is parntering with Digicom, a company that offers a wide range of hardware and software with cellular connectivity, to develop narrowband IoT (NB-IoT) products and solutions. Both companies have carried out a series of innovative and successful field trials of the new NB-IoT technology.

    The announcement reflects u-blox’s and Digicom’s eagerness to meet pent-up demand for Low Power Wide Area (LPWA) connectivity, as delivered by NB-IoT technology, standardized by 3GPP in June 2016.

    Digicom's narrowband IoT GPS tracker has u-blox inside.
    Digicom’s narrowband IoT GPS tracker has u-blox inside. Photo: u-box

    The benefits of NB-IoT over other cellular radio technologies include lower device complexity, ultra‑low power operation and support for > 50 k devices per single cellular cell. As NB-IoT operates on networks within the licensed spectrum, it also offers greater security and freedom from interference.

    It is therefore suitable for IoT and M2M applications requiring extremely low power consumption and better coverage even in shielded areas.

    The collaboration is driven by a complementary business relationship between the two companies. Digicom offers innovative solutions for the industrial markets using NB-IoT, with a particular focus on connectivity solutions for Smart Cities, Smart Buildings, Industry 4.0 in general and the Automotive industry. Digicom platforms are designed for the protection of vehicles, people and pets, offer ultra low power consumption and several years operation in battery mode.

    Embedded in Digicom’s products and solutions is for instance the u-blox SARA‑N2 NB-IoT module, which was announced in June 2016 as a cellular radio module compliant with 3GPP Release 13. Release 13 defined the NB-IoT cellular air interface standard, specifically targeting devices that need to communicate small amounts of data over long periods of time in hard-to-reach places.

    “We have collaborated with u-blox for a long time and the quality and innovation of their modules enable us to develop cutting-edge products and solutions,” said Stefano Galzignato, business line manager at Digicom.

    “We are excited to be part of this partnership, which showcases u‑blox as a global leader in developing NB‑IoT solutions for IoT applications,” said Stefano Moioli, u‑blox director of product management, cellular.

    The partnership is expected to grow steadily alongside a rising demand for Digicom solutions for IoT markets.

  • U-blox receives certification for Toby modules offering IoT access

    U-blox receives certification for Toby modules offering IoT access

    U-blox has received PTCRB certification of its TOBY-R202 and TOBY-R200 LTE Cat 1 modules for T-Mobile’s U.S. 4G LTE network.

    The u-blox Toby module.
    The u-blox Toby module. Photo: uBlox

    Both modules will be available for both of T-Mobile’s IoT Access packs, which offer simple IoT pricing with a Cat 1 module and support a broad range of industrial internet of things (IIoT) applications, reducing the cost for product makers to introduce new LTE devices on the network.

    The TOBY-R202 and TOBY-R200 modules deliver true industrial performance. They are robust and reliable with extended temperature range of negative 40 degrees Celcius to 85 degrees Celcius and manufacturing in ISO/TS 16949 certified production sites.

    LTE Cat 1 provides efficient power consumption with battery life lasting up to five years, depending on the application. In addition, TOBY-R200 includes a wider supply voltage input that allows for less expensive design and further lowers power consumption.

    “U-blox is a global leader in developing cellular modules designed for IoT and M2M applications,” said Drazen Drinic, product manager of cellular at u-blox. “We are excited to now have two LTE Cat 1 modules available to IoT product makers as part of T-Mobile’s IoT Access packs.”

    The u-blox modules will now be included in T-Mobile’s IoT Access packs, which provide product makers with a simplified launchpad for their IoT devices. For a limited time, customers can get unlimited data at 64 kbps for $20 per year per device, with up to $16 per certified module covered via a bill credit from T-Mobile upon activation.

    “T-Mobile’s low-cost IoT access packs give our customers industry-leading Category 1 chipset options to quickly launch their devices on the nation’s fastest 4G LTE network,” said Doug Chartier, senior vice president at T-Mobile.

    The two u-blox TOBY-R2 LTE Cat 1 modules support many IoT and M2M applications and are specifically targeted at those markets requiring industrial performance, such as smart metering, alarm and security systems, connected health, automotive and transportation, as well as smart payment solutions.

    They come in a compact 24.8 millimeter by 35.6 millimeter form factor and operate on LTE bands 2, 4, 5 and 12. TOBY-R202 provides fallback on 3G bands 2 and 5, while TOBY-R200 provides global 2G and 3G fallback. Thanks to u-blox nested design, migration between the TOBY-R2 modules and other u-blox 2G, 3G and 4G modules is easy, while enabling future-proof, seamless mechanical scalability across technologies.

  • GTOP launches Titan X1 multi-interface GNSS patch antenna module

    The Titan X1 GNSS antenna.
    The Titan X1 GNSS antenna.

    GlobalTop Technology, maker of positioning modules with embedded antennas, has launched the Titan X1, a compact multi-GNSS patch module for applications where small footprint, ease of integration and flexible interface options are essential in addition to robust positioning performance.

    At 12.5 x 12.5 mm, Titan X1 is one of the smallest embedded patch antenna GNSS modules based on Mediatek’s MT3333 chipset. It features a specially tuned (12 x 12 mm) GPS+GLONASS patch antenna that offers excellent performance for a module so small.

    Titan X1 offers a fully integrated design as standard, with a complete set of components including TCXO, RTC Crystal, SMPS, SAW filter and an additional LNA, all of which are considered vital for optimum performance.

    Titan X1’s introduces multi-interface support (UART, I2C and SPI), and includes external antenna detection circuit with interface so users don’t have to choose between compact size and advanced features.

    “We understand the growing need for ultra-small positioning modules, especially those with embedded antennas,” said Sam Khan, vice CEO of GlobalTop Technology. “But we don’t believe in compromising essential components and functions for the sake of a smaller size. With Titan X1 we show our commitment to making ultra-compact modules that lack nothing in terms of interfaces and functions compared to their larger counterparts. IOT devices are getting smaller but more complex with most devices featuring a wide array of sensors and connectivity modules. Being just a receiver radio, we believe that integrating a positioning module to an IOT device should be the easiest part of the development and Titan X1 is perfect for that.”

    Samples of Titan X1 are available now, with mass production starting March 30.