Tag: OEM

  • STMicroelectronics and Allystar partner on GNSS applications and solutions

    STMicroelectronics, a global semiconductor company for electronics applications, is working with Allystar to develop and market GNSS solutions for automotive products and other applications. Allystar is a spin-off from CEC Huada Electronic Design Co. Ltd. and a Chinese GNSS chip designer.

    Allystar_logoGNSS solutions and technologies, including China’s BeiDou navigation system, are playing an ever-increasing role in many different domains, related to smart mobility. Specifically, enhanced-precision location technology enabled by multi-constellation GNSS solutions, in combination with radars, cameras and various sensors, will be a key enabler for autonomous cars.

    ST and Allystar are already co-marketing products for the automotive market and cost-competitive products for the consumer market.

    “GNSS positioning technologies are vital for a variety of services and applications and will be one of the key building blocks for autonomous-driving solutions,” said Marco Monti, executive vice president and general manager, Automotive and Discrete Group, STMicroelectronics. “Working closely with Allystar, the Chinese leader in GNSS/BeiDou solutions, allows ST to better address the enormous positioning market of China and Asia.”

    Allystar is the first Chinese company ranked in the international top 10 of GNSS chips, and has won many important prizes and awards in China recognizing its R&D excellence and innovation capability, according to a press release by ST.

  • Drones swarming indoors only one highlight of AUVSI Xponential

    Drones swarming indoors only one highlight of AUVSI Xponential

    Griff Aviation displays at AUVSI its UAS for demanding professional situations. (Photo: Allison Barwacz)

    The Association for Unmanned Vehicle Systems International‘s annual Xponential show, which took place May 8-11 in Dallas, Texas, seemed to be at least as large as last year’s in New Orleans, Louisiana.

    According to the Intel CEO Brian Krzanich’s keynote address, I was among more than 7,000 attendees and 650 exhibitors. Krzanich and the Intel folks dazzled us with live indoor drone flying and a demonstration of highly detailed bridge inspection using the Intel Falcon 8+ drone.

    Then we had a few Shooting Star light drones flying around in a small swarm — all before the show really got cooking. Management of big data was Intel’s pitch for the keynote, but all we nav guys wanted to know was how they flew those things inside.

    Intel set a Guinness World Record when the company flew 500 Intel Shooting Star drones simultaneously on Oct. 7, 2016, in Hamburg, Germany. The record for the Most UAVs Airborne Simultaneously beat a previous record of 100 set by Intel less than a year earlier. (Source: Intel Corporation)
    Intel shows off its light drones in October 2016. (Source: Intel)

    Attempts later in the show to establish their guidance recipe were met with a wall of silence from Intel. We know both drone types carry inertial. The Falcon 8+ has three and more than one GNSS receiver, and the light drone has inertial and GNSS, but Intel’s secret is that they use “wireless.” So something to determine where they are and in relation to the inspection article, and to others in the swarm, hooked up to inertial? Intel will tell us sometime later, they say.

    In the meantime, Intel promoted the Falcon 8+ heavily at its booth, with its configurable payload capability. Intel indicated that it hopes also to sell light-show swarms for event providers.

    The show was indeed huge, and it was impossible to touch base with everyone, so in no particular order and without any leanings towards anyone, I’ll try and capture some flavor of what went down at the Kay Bailey Hutchinson Convention Center at the AUVSI Xponential show.

    Duro – Piksi enclosure.
    Duro – Piksi enclosure.

    Swift Navigation/ Carnegie

    Swift released the rugged Duro enclosure for its Piksi Multi dual-band GNSS receiver. It’s yellow with lots of heat fins, and looks like it would survive being driven over. With dual-frequency real-time kinematic (RTK), Swift claims an all-time low price for board-level RTK.

    VectorNav

    Based in Dallas, VectorNav took advantage of home turf with a significant presence at the show. VectorNav released a number of use-case studies to illustrate the varied customer applications for its VN series of miniature, high-performance MEMS-inertial and GPS/INS modules. Applications include:

    • ground robotics for highly accurate, high-speed attitude data
    • a  medium-range UAV with GPS/INS for primary navigation
    • integrated lidar for mapping capabilities
    • autonomous ground vehicle module waypoint navigation with a number of system functions
    • high-precision antenna pointing
    • camera pointing with a gyro-stabilized gimbal.

    Gryphon Sensors

    Drone detection and prevention systems had a significant presence at AUVSI. Gryphon Sensors combines radar, RF direction finding and optical sensors in a integrated “intelligent drone detection system.”

    Gryphon has been around for some time, using technologies from military applications to also provide vehicle-mounted drone security and UAS traffic management (UTM) capabilities.

    Fortem Technologies

    Compact TrueView Radar
    Compact TrueView Radar

    Fortem has gone one step further with drone detection — its Dronehunter flies a drone within feet of an intruder, fires a net at the unwanted vehicle and takes it down. The company’s video encounter was at low altitude and the intruder was undamaged — for higher, larger vehicle take-downs, they have a net with a parachute.

    Other components of the system include a compact airborne radar for Beyond Visual Line of Sight (BVLOS) and a ground-based radar detection system.

    Countries

    Several country pavilions exhibited at the show, including China, Spain, France, UK, Denmark and Canada. Highlights included Drone Hopper, a Spanish firefighting drone concept; Chinese UAV antennas and avionics; a French “cluster” of drone-related companies; and Canada, which included a multi-rotor drone dealer and introduced the Foremost drone test range.

    Aeronix and Rajant

    Secure radios are key to any drone operations. Aeronix displayed a secure software-defined datalink product for providing data, video and voice onto and off drones. The company also introduced significant radio and interface capability for military and secure commercial operations.

    Rajant featured mesh radio systems, providing the wireless backbone in UAV applications in mining and on mine trucks. Once again, U.S. Department of Defense technology developed over many years has been spun off into commercial operations.

    Trimble

    It was good to see Trimble in force again at a trade show; the company had a nice booth with lots of people. We talked with Chris Wheeler about Trimble’s approach of providing an antenna with down conversion, integrated with an RTK software API on existing on-board computing hardware – it’s a good way to potentially reduce costs for UAVs.

    Sold through a software license, this reduced-hardware solution could be a new way to get high performance at much reduced prices for larger UAV fleets. It might be significant for lots of other OEM solutions too.

    Trimble-AUVSI

    AsteRx-m2 UAS receiver.
    AsteRx-m2 UAS receiver.

    Septentrio

    The recently released AsterRx-m2 receiver has an optional UAS interface board with record-and-store capability so that real-time images can be readily geo-coded. It directly connects to an on-board autopilot. Self-interference issues coming from existing UAV control electronics are minimized by further enhanced AIM interference mitigation processing on the –m2 receiver.

    NovAtel

    NovAtel’s military business group continues to make headway with the GAJT integrated anti-jam antenna with more than 600 sold to date. Other applications include the use of the anti-jam electronics processing solution in the GAJT anti-jam Antenna Electronics unit.

    If you were not convinced that these are rugged units designed for difficult outdoor applications, they were recently evaluated under firing conditions by the Canadian forces mounted on an M777C1 Howitzer — “No problem,” said Peter Soar, business development manager, Military and Defence.

    The anti-jam antenna electronics unit is well suited for UAV applications in signal-rich environments where GPS tracking might otherwise be untenable.

    Aspen Avionics

    As the FAA makes progress toward integration of UAS into the National Airspace System (NAS), the interest in using ADS-B (Automatic Dependent Surveillance) for UAV location awareness seems to be growing. ADS-B equipment on both manned and unmanned vehicles provides an output signal containing position, velocity and altitude which can be used by other similarly equipped aircraft and terrestrial/satellite tracking systems.

    Aspen Avionics supplies FAA-approved ADS-B equipment for manned and unmanned aircraft, as well as approved GPS navigation receivers for selected classes of certified navigation and landing.

    Rockwell Collins/Harris

    BVLOS demonstration work under the FAA Pathfinder program with BNSF Railway has continued, with significant technical contributions by both Rockwell Collins and Harris. Monitoring and control of the UAV during inspection flights along the BNSF track test-section in Clovis, New Mexico, was achieved through the deployed Rockwell radio network and CNPC-1000 datalink transceiver installed on a Latitude Engineering UAV. Reliability is now well established, and BNSF is able to operate without visual observers during regular inspections for bad track.

    Harris-ADS-BHarris has also provided extended ADS-B coverage throughout the BNSF test section and provided an aircraft-tracking feed from its FAA flight database, to ensure there are no manned aircraft conflicts during UAS track inspection flights.

    Insitu

    Insitu has conducted very successful business with military and government for many years with its ScanEagle, Blackjack and Integrator UAS. The company is now approaching the commercial world through a turnkey inspection service that it will now offer as its INEXA Solutions.

    The intent is not to just offer data collection by flying UAVs for customers, but to first put together the best business case, then collect and process data and deliver the information required.

    Lockheed Martin

    Lockheed Martin also is approaching the commercial market with a services offering: Commercial Aviation Inspection Services. LM’s UAS capability extends beyond the Stalker fixed-wing surveillance drone, the quadcopter Indago and the military-looking Fury heavy-payload fixed-wing vehicle, to include an autopilot, a vision-processing unit and a dual-sensor gimbal. The LM Hydra-Fusion Geospatial toolset provides post-processing capability for applications including construction, surveying, agricultural, inspection and tactical.

    AeroVironment

    AeroVironment is another company offering turn-key flight services, from UAS operations through to data processing and custom results. AeroVironment had two new product announcements to add to its extensive UAS capability: the Mantis electro-optical/infrared gimbal sensor suite, and the Snipe man-carried UAS.

    The Mantis is designed for installation on the AeroVironment Puma fixed-wing UAS to provide enhanced imaging capabilities, while the 5-ounce Snipe is small enough to be worn by an operator and can be rapidly deployed for close-in surveillance/reconnaissance.

    …And More

    Other news on the show floor:

    • Airbus Aerial is being established in the U.S. and Europe to provide imagery services for commercial industries, such as insurance, agriculture, oil and gas, and utilities as well as state and local governments.
    • Spirent promoted its GSS6450 portable GNSS record-and-playback simulator for UAV systems testing and verification.
    • Multi-rotor drone manufacturer DraganFly indicated that it has been in the UAS business since 1998, so it has lots of capability and experience.
    • Canadian UAV autopilot supplier MicroPilot continues to do well, and now claims to have 1,000 customers in 85 countries. Looking to future requirements for onboard systems that will make possible UAS integration into manned airspace, MicroPilot is now working toward airborne (RTCA DO-178C) software qualification.

    The 2017 AUVSI Exponential convention measured up to all its expectations and pre-show hype. The atmosphere was energetic and positive, with almost every booth getting the attention of attendees & the whisper of deals was everywhere in the many corridors and rooms of the huge Dallas convention center. The UAS industry didn’t only come to show off its wares, but also to do business.

    Several UAS flight centers were represented, each with the strong backing of its own home State and vying to attract test center users and to establish new UAS businesses. The industry is apparently ready and able to create those local jobs that have been forecast to grow out of new UAS applications.

    While attention has previously been on flying small UAS (sUAS, and there is now a set of FAA rules allowing controlled commercial operations to get underway, there did seem to be an growing expectation that work towards getting larger, longer endurance drones into commercial operations was coming into focus. Many fixed wing applications currently operate under FAA Certificates of Authorization (CoAs), so their scale of operations is limited. But on-going efforts to develop Sense & Avoid and BVLOS solutions are hopefully leading towards the next phase of larger UAS applications in the US National Airspace System.

    Tony Murfin
    GNSS Aerospace

  • GSA launches 2017 GNSS Market Report

    GSA launches 2017 GNSS Market Report

    GNSSMarketReport2017-coverWith an in-depth look at market opportunities and trends across eight market segments, the European GNSS Agency’s (GSA’s) annual GNSS Market Report serves as a key resource for navigating the fast-evolving world of satellite navigation technology and GNSS applications.

    The fifth edition, the 2017 GNSS Market Report, was released May 10 by Carlo des Dorides, executive director for the GSA, at the European Navigation Conference held in Lausanne Switzerland.

    According to the new report, the growing demand for precise location information, in combination with the ongoing evolution of GNSS technology, means that today’s GNSS market is bigger than ever.

    According to the 5th edition of the GSA’s popular GNSS Market Report:

    • The global GNSS market is expected to grow from 5.8 billion devices in use in 2017 to an estimated 8 billion by 2020.
    • The GNSS downstream market is expected to produce over € 70 billion in revenue annually in 2025. When the revenue created by added-value services is included, this number could more than double.
    • The global GNSS downstream market is forecast to grow by more than 6 % annually between 2015 and 2020. Following the declaration of Galileo Initial Services in 2016, chipset and receiver manufacturers and application developers are leveraging Galileo signals, and a number of Galileo-ready devices are already on the market.
    • By 2025, the installed base of GNSS devices in drones will reach 70 mln, more than twice the sum of other professional market segments combined.

    Regularly referenced by policy-makers and business leaders around the world, the GNSS Market Report serves as the go-to resource for an in-depth look at GNSS market opportunities and trends across an array of essential market segments.

    “Providing in-depth information on today’s GNSS market opportunities and a data-driven forecast of its evolution through to 2025, this edition is a must-read for anyone looking to successfully navigate this promising market,” des Dorides said.

    The GNSS Market Report takes a comprehensive look at the global GNSS market, providing a thorough analysis per market segment (Location-Based Services, Road Transportation, Aviation, Maritime, Rail, Agriculture, Surveying and Timing & Synchronisation), region and application type, including information on shipments, revenues and installed device base.

    The 2017 edition includes such new features as:

    • An expanded section on macro-trends like the Internet of Things (IoT), Smart Cities and Big Data.
    • Segment-specific user perspectives, with an emphasis on the increasingly stringent demands of today’s GNSS users.
    • The unique added-value that European GNSS (EGNOS and Galileo) brings to each segment and how Galileo is already enhancing the functioning of many applications.
    • A special feature on the important role that GNSS plays in the growing market of drones (i.e., UAVs/Remotely Piloted Aircraft Systems).

    The full 100-page report is available for download free of charge.

    Methodology

    The GSA GNSS Market Report is compiled by the GSA and the European Commission and was produced using the GSA’s systematic Marketing Monitoring and Forecasting Process.

    The underlying market model uses advanced forecasting techniques applied to a wide range of input data, assumptions, and scenarios to forecast the size of the GNSS market in terms of shipments, revenue, and installed base of receivers.

    Historical values are anchored to actual data in order to ensure a high level of accuracy. Assumptions are confronted with expert opinions in each market segment and application and model results are cross-checked against the most recent market research reports from independent sources before being validated through an iterative consultation process involving pertinent sector experts and stakeholders.

  • u-blox offers automotive dead reckoning firmware

    Positioning chip company u-blox is making available its latest automotive dead reckoning (ADR) firmware for navigation, Telematics, eCall and V2X applications for both OEM and after-market applications.

    Firmware ADR4.10 offers real-time, low latency positioning at up to 30 Hz using a combination of multi-GNSS, inertial sensor and vehicle speed data. The release also offers simplified installation, improved accuracy in dense urban environments and new messages for eCall.

    ADR4.10 is available now to OEMs using u-blox M8030-Kx-DR professional and automotive-grade chips. By the end of May, it will also be available on NEO-M8L ADR modules, including the new automotive-grade NEO-M8L-02A.

    u-blox ADR products are backed by specialist support at local and regional centers.

  • Hemisphere GNSS launches latest Vector Eclipse board, the H328

    Hemisphere GNSS launches latest Vector Eclipse board, the H328

    Hemisphere GNSS has released the Vector Eclipse H328, the next offering in its line of refreshed, low-power, high-precision, positioning and heading original equipment manufacturer (OEM) boards.

    The H328 is designed for robotics, autonomous vehicles, antenna pointing, marine survey, machine control and any application where high-accuracy positioning and heading is required.

    Hemisphere-H328The multi-frequency, multi-GNSS H328 is an all signals receiver board that includes Hemisphere’s new and innovative hardware platform and integrates Atlas GNSS Global Correction Service.

    Designed with this new hardware platform, the overall cost, size, weight and power consumption of the H328 are reduced. It offers scalability with centimeter-level accuracy in either single-frequency mode or full performance multi-frequency, multi-GNSS, Atlas-capable mode that supports fast real-time kinematic (RTK) initialization times over long distances, Hemisphere GNSS said.

    The H328 offers fast accuracy heading of better than 0.17 degrees at 0.5 m antenna separation and aiding gyroscope and tilt sensors for temporary GNSS outages. The 60 mm x 100 mm module with 24-pin and 16-pin headers is a drop-in upgrade for existing designs using this industry standard form factor.

    The latest technology platform enables simultaneous tracking of all satellite signals including GPS, GLONASS P-code, BeiDou, Galileo, and QZSS making it robust and reliable. The updated power management system efficiently governs the processor, memory, and ASIC making it ideal for multiple integration applications. The H328 offers flexible and reliable connectivity by supporting Serial, USB (On-The-Go with future firmware upgrade), CAN, Ethernet and SPI for ease of use and integration. Optional output rates of up to 50 Hz are also supported.

    Powered by the Athena GNSS engine, the H328 provides centimeter-level RTK. Athena excels in virtually every environment where high-accuracy GNSS receivers can be used, Hemisphere GNSS said. Together with SureFix, Hemisphere’s advanced processor, the H328 delivers high-fidelity RTK quality information that results in guaranteed precision with virtually 100-percent reliability.

    Integrated L-band adds support for Atlas GNSS global corrections for meter to sub decimeter-level accuracy while Tracer technology helps maintain position during correction signal outages. The H328 also uses Hemisphere’s aRTK technology, powered by Atlas. This feature allows the H328 to operate with RTK accuracies when RTK corrections fail. If the H328 is Atlas-subscribed, it will continue to operate at the subscribed service level until RTK is restored.

  • Inertial Sense to release tiny GPS-aided INS for drones

    Inertial Sense to release tiny GPS-aided INS for drones

    Inertial Sense will be releasing a high-quality, low-cost navigation system — the μINS — later this summer, the company said. The company made the announcement at AUVSI’s Xponential 2017.InertialSense-uINS

    Inertial Sense is a privately owned U.S. company that specializes in designing and manufacturing GPS inertial navigation technology for commercial and consumer products.

    Historically, quality GPS inertial navigation has been expensive and was only designed into a small number of systems. As the commercial and consumer drone industries grow, the need for an accurate, low-cost navigation system has become more apparent, Inertial Sense said.

    Acccording to Inertial Sense, the company’s engineers have invented a design that enables the technology to be smaller and less expensive.

    The μINS is a tiny sensor module that is designed to provide high-quality direction, position and velocity data for drones and robotic applications. It provides this data by fusing sensor data from GPS (GNSS), gyros, accelerometers, magnetometers and a barometric pressure sensor.

  • Panasonic collaborates with u-blox on RTK GNSS tablet

    Panasonic collaborates with u-blox on RTK GNSS tablet

    Panasonic Corporation, in collaboration with u-blox, has launched a tablet-using centimeter-level RTK GNSS technology.

    Toughpad, the newly born version of Panasonic’s professional grade notebooks family, is specifically designed for precision agriculture, machine control and robotic guidance applications in harsh environments and conditions. Embedded in the tablet is a u-blox NEO-M8 GNSS receiver module delivering high integrity and precision in demanding applications world-wide.

    The Toughpad FZ uses a u-blox NEO-M8 GNSS receiver module.
    The Toughpad FZ uses a u-blox NEO-M8 GNSS receiver module. Photo: Panasonic

    First successfully tested for collecting snow in Hokkaido, the Toughpad tablet uses Panasonic’s own satellite positioning technology combining a satellite radio receiver module, wireless WAN, and a single band real-time kinematic (RTK) GNSS receiver connected to an external antenna. The system enables high-precision positioning down to centimeter level in open sky conditions.

    “We needed a high quality, reliable and robust GNSS module for this tablet designed to be used in rugged environments,”  said Tetsuya Sakamoto, general manager, mobile solutions business division, development center at Panasonic Corporation. “The NEO-M8 from u-blox was therefore the right choice.”

    “It was very exciting to collaborate with a market leader such as Panasonic in developing a product that would guarantee precise positioning for a wide range of professional applications,” said Tesshu Naka, country manager at u-blox Japan. “This implementation will support the global expansion of the high precision market where u-blox is a key player.”

    Toughpad was first launched in Japan.

  • Septentrio’s newest receivers protect against jamming interference

    Septentrio’s newest receivers protect against jamming interference

    Septentrio has launched two new GNSS boards. The AsteRx-m2 and AsteRx-m2 UAS OEM boards provide GNSS positioning with interference mitigation technology on ultra-low-power boards. The boards are being showcased at AUVSI’s Xponential 2017 this week in Dallas, Texas.

    AsteRx-m2
    AsteRx-m2.

    The credit-card sized AsteRx-m2 and the AsteRx-m2 UAS offer all-in-view multi-frequency, multi-constellation tracking and centimeter-level real-time kinematic (RTK) position accuracy for low power. Both boards can receive TerraStar satellite-based correction signals for precise point positioning (PPP).

    The AsteRx-m2 and the AsteRx-m2 UAS feature Septentrio’s AIM+ interference mitigation system: an on-board interference mitigation technology that can suppress a wide variety of interferers, from simple continuous narrowband signals to complex wideband and pulsed jammers. The increasing levels of radio frequency pollution — coupled with the intrinsic danger of self-interference in compact systems such as UAS — makes interference mitigation a vital element in any UAS GNSS system, Septentrio said.

    AsteRx-m2 UAS receiver.

    The AsteRx-m2 UAS is designed specifically for unmanned systems. It provides plug-and-play compatibility for autopilot software such as ArduPilot and Pixhawk. Event markers can accurately synchronize a camera shutter with GNSS time.

    The board can be directly powered from the vehicle power bus via its wide-range power input. The AsteRx-m2 UAS works seamlessly with GeoTagZ software and its SDK library for RPK (reprocessed kinematic) offline processing to provide RTK accuracy without the need for ground-control points or a real-time datalink.

    “The market demands increasingly accurate and reliable GNSS positioning systems for inspection, mapping and aerial survey,” said Gustavo Lopez, product manager at Septentrio. “Septentrio’s answer is the AsteRx-m2 and the AsteRx-m2 UAS: offering multi-frequency and multi-constellation tracking as well as robust interference protection all for the lowest power on the market.”

    The AsteRx-m2 and AsteRx-m2 UAS are now shipping. Septentrio is located at stand 749 of Xponential 2017.

  • V2V countdown: Major players on how we get there

    We asked major players in the connected vehicles marketplace for their views on expected deployment timelines, remaining challenges such as reliable positioning technology, integration with existing systems, and the implications on autonomous vehicle technology.

    Curated and introduced by Chaminda Basnayake,
    Principal Engineer, Market Development,
    Locata Corporation

    State of the Industry: Connected Vehicles

    Intersection Movement Assist warns the driver if it is not safe to enter an intersection, for example, if another vehicle is running a red light or making a sudden turn. (Image: U.S. Department of Transportation)
    Intersection Movement Assist warns the driver if it is not safe to enter an intersection, for example, if another vehicle is running a red light or making a sudden turn. (Image: U.S. Department of Transportation)

    The U.S. Department of Transportation (USDOT) released a Notice of Proposed Rulemaking (NPRM) in December 2016 for the deployment of Dedicated Short Range Communications (DSRC)-based vehicle-to-vehicle (V2V) safety applications as part of the connected vehicles (CV) and automated vehicles (AV) initiative. If all goes well, this mean a V2V deployment mandate for new passenger vehicles likely starting in 2021 and reaching all new vehicles within 2–3 years.

    Standards required for V2V deployment were published in 2016 or before, including the V2V Minimum Performance Requirements SAE 2945/1, leading the way for commercial product development. The USDOT, which has been the catalyst behind V2V industry R&D starting from the automaker collaboration CAMP (Crash Avoidance Metrix Partnership) in 2001, is conducting CV Pilot programs in New York, Wyoming and Florida. These offer the opportunity for state DOTs, vendors and all other stakeholders to test the technology in real-life scenarios.

    Automotive OEMs have been developing this technology for more than a decade, and the NPRM is the beginning of a race toward integrating V2V to production vehicles. Deploying V2V technology requires the close cooperation of OEMs, their suppliers and many other stakeholders.

    The following transportation article captures the views of major players in the CV marketplace on expected deployment timelines, remaining challenges such as reliable positioning technology, integration with existing systems, and the implications on AV technology.


    V2V-Messages-Graphic-O

    Cadillac Communicates: V2V Now, Sensor Sharing Soon

    By Curtis Hay
    Technical Fellow, GNSS and Precise Maps,
    General Motors

    General Motors is the first automaker to offer V2V technology in North America with the 2017 interim model year Cadillac CTS. These V2V-equipped vehicles share information to alert drivers of upcoming potential hazards. Cadillac’s V2V uses DSRC and GPS, and can handle 1,000 messages per second from vehicles up to nearly 1,000 feet away. For example, when a car approaches an intersection, the technology scans the vicinity for other vehicles and tracks their positions, directions and speeds, warning the driver of potential hazards.

    GM continues to make technology investments in V2V to achieve greater global market volumes. We have been developing V2V technology for the past several years and are exploring potential enhancements to the V2V features currently offered. Nearly all global OEMs are developing V2V today, but market readiness, adoption and technology maturity vary greatly between regions and manufacturers. I expect other OEMs will begin to deploy V2V systems beyond model year 2017.

    We believe that autonomous vehicles will require some level of connectivity — there is no way around this. V2I connectivity is required for precise map updates, emergency call alerts, GNSS corrections, remote diagnostics, traffic and weather updates, and many more applications — both existing and emerging. V2V communication will also be an important technology to improve safety and reliability as autonomous vehicles become more broadly deployed.

    As a technical challenge, the limitations of GNSS are certainly understood by automakers for applications such as vehicle navigation, stolen vehicle tracking and emergency response services. Many recent advances in vehicle positioning technology mitigate the effects of urban multipath and poor sky view. These include higher quality micro-electro-mechanical systems (MEMS) sensors, low-cost lidar, visual inertial odometry, wheel encoders, precise maps and more GNSS satellites in view.

    We believe that high-confidence lane classification is becoming possible even in dense urban environments, thanks to these and other advancements. Infrastructure augmentation will certainly help, and these investments are gradually being made by state and local governments. However, technology development occurs at a faster pace inside the vehicle versus along our roadways.

    There is growing demand for low-cost, high-quality automotive cameras and radar components that will be critically important for CV and AVs. I expect some degree of sensor data sharing over V2V will enter the industry within a 4–5-year time frame. Today, not all automotive cameras are designed to provide real-time video output across a high bandwidth interface such as low-voltage differential signaling (LVDS).

    Furthermore, DSRC protocol and LTE Release 14 are not yet broadly accepted among competing OEMs. V2V innovations will occur as OEMs see what is possible, and customer demand for safety and reliability increases. Once the auto industry has passed the 50% milestone for market penetration of V2V vehicles, the rate of adoption will be much higher for new vehicle builds.


    Denso’s autonomous vehicle research and development ranges from head-up display to voice recognition and human machine interfaces.
    Denso’s autonomous vehicle research and development ranges from head-up display to voice recognition and human machine interfaces.

    Connectivity Paves Way to Autonomy

    By Roger Berg
    Vice President, North America Research & Development,
    Denso International America

    As we know, GM offers V2V in the current model year CTS, and Toyota deployed ITSConnect in Japan in 2016. So, multiple OEMS have cars on the road and appear to see the value of V2V.

    A retrofit V2V, a universally acceptable U.S. National Highway Traffic Safety Administration (NHTSA)-compliant solution that could be installed at a dealership, is an interesting concept that has been around in recent years. This will allow OEMs to comply with the rule much quicker. However, that concept is easier said than done, and it hasn’t been the focus of the industry up until now.

    I see connectivity as nearly a requirement to get to highly AV in the future. On a limited-access highway, connectivity is probably not a requirement, as there are predictable and infrequent “high anxiety” encounters. In an urban setting, however, many other elements complicate the necessary behavior and reaction; and therefore I see the most value from connectivity.

    Sensors such as cameras can detect the state of a traffic light with some level of certainty, but often the situation is complicated, such as the need to differentiate between a straight versus a turn signal. Even in highway scenarios, we can see how connectivity can favorably impact use cases like truck platooning and cooperative automated cruise control.

    For positioning, it may be that a terrestrial solution will be necessary in difficult GNSS environments such as New York. It’s clear traditional GNSS is not capable of performing at the level required for the cooperative crash avoidance capability that NHTSA desires. Ranging systems that operate as a part of V2I and high-definition maps with lidar could be potential augmentations. I can relate the latter to how humans drive: Although we are not aware of our position, we can certainly drive in Manhattan (with difficulty!) by observing lanes, curbs and other relative

    I envision V2V as part of a typical in-vehicle sensor suite at some point without exception; vehicles will eventually communicate what they see with their sensors to others via DSRC. Denso holds a patent that proposes to use on-board sensing to detect the presence of unequipped vehicles and send a proxy basic safety message (BSM) to other vehicles through DSRC.

    In the V2V NPRM, NHTSA defines benefits in terms of lives saved under full penetration, but we believe benefits can be shown under much lower levels. For example, in the Ann Arbor Safety Pilot, even with under 5% penetration, anecdotally the University of Michigan buses averaged about one warning every 150 miles during the trial, a significant number of warnings.

    ADDITIONAL RESOURCES


    cell-towers-W

    Cellular Networks Will Enhance Capabilities

    By Roger C. Lanctot
    Director, Automotive Connected Mobility,
    Strategy Analytics

    We think the best-case U.S. V2V deployment scenario might be 2021 — but given the challenges in security management, the ongoing testing of spectrum sharing by the Federal Communications Commission (FCC), and the lack of infrastructure support — we think an even later commencement is likely. This means that early 5G deployments will already be beginning.

    It is worth noting that the NPRM provides for alternative technologies as long as the performance requirements are met. The interest in DSRC in Europe has waned significantly, and Toyota appears to be the only company aggressively investing in Japan. China appears to be heading towards 5G for V2X.

    In our view, given the vast uncertainties, it makes little sense to proactively add a box that will add cost along with driver distraction and security vulnerabilities. Vehicles will benefit from connectivity regardless of the technology used, but many more miles must be driven before a level of sufficient confidence is reached to integrate V2V with safety systems.

    We believe DSRC-based V2V is decades away from delivering a reliable and warrantee-able or life-saving value proposition. Even NHTSA has suggested it may take as long as 20 years before significant value is returned to the manufacturers, let alone the consumer, making the investments today.

    We do not think the industry is prepared to integrate safety systems with V2V for a broad range of reasons — GNSS vulnerabilities in urban canyons being one of them. This is the scenario in which additional sensors and high-definition maps can add to location accuracy. Details not only on the road, but also on the location and geometry of buildings, trees, street furniture and more can be gathered by sensors during the mapping process. The vehicle camera and/or lidar sensors can then be used to position the vehicle against this map.

    We think a base map will be generated by the mapping entity using vehicles equipped with high-quality sensors and location technology, and then this will be updated by user-gathered data, as well as continued use of the mapping vehicles. This is the approach taken by the likes of TomTom, Mobileye and Civil Maps.

    Cellular networks are de facto infrastructure assistants today, and we expect those capabilities to be enhanced. Connectivity is a nice-to-have for AV — not necessary. With the onset of 5G this will change a little bit, but AVs will always have to be able to operate without a connection, in our opinion.


    AutonomousCarPic_NovAtel_O

    Connected Car a Critical Stepstone to Automated Vehicle and Driverless Driving

    By Jonathan Auld
    Director, Safety Critical Systems,
    NovAtel Inc.

    I think some OEMs and Tier1s will integrate the technology in advance of the full mandate and thereby reduce the time to widespread adoption. The benefits of V2V may not be fully realizable at first, but will increase as more equipped vehicles and infrastructure becomes available.

    It’s a false assumption that any one technology will resolve CV or AV positioning challenge. The challenging environments and user expectations for high availability and safety will require multiple sensors and systems.

    In this context, we see the CV as a critical stepping stone to the AV. CV provides a critical link for V2V communications in low/no-visibility/hidden-object situations as well as a pipe for critical mapping and road network information to the car. As part of this, the GNSS receiver plays a role in being an all-weather absolute position and time reference that can tie all the other sensors together. GNSS has its limitations, as do other sensors, which leads to the multi-sensor fusion approach for accuracy, availability and safety.

    The automotive industry’s understanding of GNSS performance is largely driving from the perspective of L1-only single- and dual-constellation receivers. In both the CV and AV use cases, there is a push for more accuracy from GNSS. When moving to a higher performance expectation from GNSS, issues come up that are new to the automotive industry.

    For consistent sub-meter-level performance, we start to consider multi-frequency receivers with correction/integrity services supporting them. This is where we see PPP (precise point positioning) as a key technology. Taking advantage of our global PPP correction network for corrections, authentication and safety services will make this performance possible. Also, antenna quality and location become more important. In urban environments where GNSS is less available, we expect a multi-sensory solution to aid GNSS through outages, but still keep lane-level performance as long as possible and safe.

    Given the significant challenges on the automotive environment, I would expect that new and innovative ways of gathering and sharing additional information between vehicles and the infrastructure will be developed. It’s entirely feasible that future systems will share as much data as is practical, with the cloud to allow for better map generation and data dissemination. All of this will be driven by the need to keep the systems as available as possible while still maintaining safety.


    V2X-System2_ubx-W

    Dual-Band Carrier Phase for Lane Position

    By Rod Bryant
    Senior Director, Positioning Technology,
    u-blox

    We expect to see early adopters integrating the technology ahead of the mandate in selected models such as GM with Cadillac-CTS planned for this year. Depending upon the applications to be supported, DSRC fleet penetration of over 70–80% is probably needed for it to become a truly all-round sensor. That’s why the forthcoming legislation in the U.S. is so important for solving the chicken-and-egg problem, as well as the development of aftermarket V2X.

    The combination of CV safety applications with features that use in-vehicle sensors would be a natural evolution. Sooner or later every vehicle will be able to see what others see.

    For Level 4 AV systems, GNSS is needed to unambiguously identify the road segment. Highway pilot should not be used off the highway; for lane-accurate positioning with integrity on the urban highway and main roads, we are using dual-band carrier phase positioning with wide area State Space Representation (SSR) corrections and automotive-grade INS.  This combination of technologies can cope with the level of interruptions to carrier phase lock and the multipath distortion caused by bridges, signs, trees and buildings in such environments.

    As we move deeper into the urban canyon, additional measures will be needed.  More advanced multipath mitigation, terrestrial ranging and beamforming techniques could contribute to the solution. V2I ranging is a particularly attractive and obvious example. However other ranging sources could also be utilized. Various beamforming approaches are possible with various levels of disadvantage regarding the accommodation of antenna arrays into the car.

    Inevitably, there will be periods of unavailability of GNSS-based lane-level accurate position deep in the urban canyon when required protection limits cannot be met within the required level of integrity risk.  It is essential that these are managed properly in the reliance on different sensors at different times and, for lower levels of autonomy, in the interactions between machine and driver.

    We see automated driving as a related but separate evolution. The crux of the automated-driving problem is how to manage risk in such a complex scenario. Multiple sensors are being used by OEMs to determine the position of the vehicle with respect to roads and for collision avoidance. Those sensors include GNSS/IMU, radar and lidar, which have overlapping capabilities across conditions. This allows the decomposition of the Automotive Safety Integrity Level (ISO26262 ASIL) requirements.

    A combination of all of these sensors is required to meet the stringent safety goals. In that context, V2X will clearly play a role, but may not be seen as a prerequisite. The cooperative nature of V2X operation presents challenges for the application of functional safety methodologies like ISO26262. Partly for that reason, we do not expect the application of V2X to autonomous driving before 2025.

  • Launchpad: Reference clock, receivers, drones

    Launchpad: Reference clock, receivers, drones

    OEM

    Rakon RHT1490 series.
    Rakon RHT1490 series TCXO.

    High-Frequency TCXOs

    Ultra stable for low jitter and phase noise applications

    The RHT1490 series of high-frequency and low-jitter ultra-stable TCXOs are available in frequencies from 50 MHz to 204.8 MHz. It delivers telecommunications-grade stability with a low real mean squared (rms) phase jitter of <200 fs (12 kHz–20 MHz). The platform’s frequency output enables lower system jitter, allowing communication system architects to optimize noise budget and performance. It can serve as a reference clock for SyncE and packet clock requirements (ITU-T G.826x and G.827x). It works with both discrete and integrated IEEE 1588 solutions, providing medium-term stability for low loop bandwidth applications. Its ultra-low noise floor performance, combined with system phase locked loop filtering, helps achieve very low system clock rms jitter numbers required by reference clocks of physical layer devices for high -speed interfaces (40 G and 100 G applications).

    Rakon, www.rakon.com

    Reference clock

    50-channel 8835 GPS reference clock.
    Smiths Interconnect’s 50-channel 8835 GPS reference clock.

    Compact and configurable

    The 50-channel 8835 GPS reference clock serves satellite communications, defense and wireless applications. It has extreme power and interoperability options while maintaining GPS accuracy and reliability. Tracking GPS, the clock exhibits a frequency accuracy of <1 x 10-12 and a 1 PPS accuracy with <50 nanoseconds real mean squared. The proprietary oscillator steering discipline algorithm can enhance the rms accuracy of either the double-oven crystal oscillator or optional enhanced rubidium oscillator for greater depths of accuracy. It operates from –30° C to +60° C with a terminal node controller GPS receiver port.

    Smiths Interconnect, www.trak.com

    Survey

    Windows tablet

    Algiz 8X ultra-rugged tablet computer.
    Handheld Group’s Algiz 8X ultra-rugged tablet computer.

    Rigorously tested for tough environments

    The Algiz 8X ultra-rugged tablet computer is built for field workers who require a powerful, portable computer for mobile tasks. It offers communication features such as LTE and dual-band WLAN, along with an 8-inch projective capacitive touchscreen for outdoor use. Enabling glove mode or rain mode allows for operation in changing weather. The chemically strengthened glass survives an impact test in which a 64-gram steel ball is dropped on the screen 10 times from a height of 1.2 meters. The Algiz 8X has optional active capacitive stylus. Built-in features include Windows 10 Enterprise LTSB; u-blox GPS and GLONASS; WLAN a/b/g/n/ac; BT 4.2 LE; a rear-facing 8-MP camera with autofocus and LED flash; and 4G/LTE.

    Handheld Group, www.handheldgroup.com

    2D excavating system

    Topcon X-52 entry-level machine control system.
    Topcon X-52 entry-level machine control system.

    Cost-effective grade control

    The X-52 entry-level machine control system for excavation features the new intuitive MC-X1 controller, compatible with all brands and models of excavators. Its reliable and rugged TS-i3 tilt sensors detect the precise positioning of the boom, stick and bucket at all times. Later this year, the X-52 will be upgradeable to a full 3D system with GNSS. The X-52 not only allows operators to work faster and with better accuracy, but also promotes a safer work site by keeping grade checkers out of the trenches. The system is designed to pair with the GX-55 touchscreen control box to offer sunlight-readable indicate grade reference in any climate.

    Topcon Positioning Group, www.topcon.com

    GNSS RTK receiver

    Tersus GNSS' Precis-TX204 receiver.
    Tersus GNSS’ Precis-TX204 receiver.

    Integrated display and keypad for configuration without controller

    The Precis-TX204 receiver is a light-weight, rugged, all-in-one GNSS receiver with a built-in centimeter-accuracy RTK engine, onboard storage and versatile connectivity. The built-in battery can support up to 10 hours of continuous field work. Up to 16-GB SD card support makes field work easier, and the rugged enclosure enables the receiver to work in harsh environment. The receiver is designed for infrastructure applications such as providing differential data or logging observations; centimeter-level position and velocity information; precise tracking for internet of things; precise navigation for UAV and robotics. It supports GPS L1 and L2, and BDS B1 and B2.

    Tersus GNSS, www.tersus-gnss.com

    Transportation

    Aviation Receiver

    Esterline's CMA-6024 aviation GPS/SBAS/GBAS sensor.
    Esterline’s CMA-6024 aviation GPS/SBAS/GBAS sensor.

    High-performance GPS/SBAS/GBAS for all aircraft

    The CMA-6024 aviation GPS/SBAS/GBAS sensor, featuring an embedded VHF data broadcast (VDB) receiver, is a complete, self-contained, fully certified, precision approach and navigation solution certified to Design Assurance Level A (DAL-A). Designed as an easy-to-integrate solution for all aircraft, the plug-and-play standalone unit requires no specialized installation or integration support. The new CMA-6024 provides a navigation solution that is fully compliant with automatic dependent surveillance-broadcast (ADS-B) and Required Navigation Performance (RNP). The CMA-6024 includes SBAS Localizer Performance/Localizer Performance with Vertical Guidance (LP/LPV) and GBAS GNSS Landing System (GLS) GAST-C/D precision approach guidance for all aircraft. Built on the success of the CMA-5024, the CMA-6024 is the next step forward, adding a complete GBAS/GLS solution. All CMA-5024 receivers can be upgraded to a CMA-6024.

    Esterline CMC Electronics, www.esterline.com

    Electronic logging

    GPS Insight's Electronic Logging Device.
    GPS Insight’s Electronic Logging Device.

    Alternative to paper logs streamlines fleet management

    The GPS Insight Hours of Service solution has a feature set designed to streamline fleet management and ensure Federal Motor Carrier Safety Administration (FMCSA) compliance. Hours of Service bundles an Android tablet hardwired to a GPS tracking device. The ruggedized Electronic Logging Device (ELD) tablet features an intuitive user interface to ensure ease of use for all drivers. The management portal is web-based, secure and accessible via PC, tablet and smartphone. Features include messaging between drivers and dispatch; audible and visual directions using designated truck-specific routes; and e-logs combined with GPS monitoring, alerting and reporting. The GPS Insight Hours of Service Solution offers a simple alternative to paper logs and provides many benefits beyond compliance.

    GPS Insight, www.gpsinsight.com

    UAV

    Professional drone

    DJI's Matrice 200 drone.
    DJI’s Matrice 200 drone.

    Rugged platform designed for aerial inspection, data collection

    The Matrice 200 drone series (M200) is built for professional users to perform aerial inspections and collect data. The folding body is easy to carry and set up, with a weather- and water-resistant body for field operations. It offers DJI’s first upward-facing gimbal mount, for inspecting the undersides of bridges, towers and other structure. It is compatible with DJI’s X4S and X5S cameras, the high-powered Z30 zoom camera and the XT camera for thermal imaging. A forward-facing first-person-view camera allows a pilot and camera operator to monitor separate images on dual controllers. Obstacle avoidance sensors face forward and up and down, and it has an ADS-B receiver for advisory traffic information from nearby manned aircraft.

    DJI, www.dji.com

    UAV data analysis tool

    PCI Geomatics' STAX UAV image alignment and analysis tool.
    PCI Geomatics’ STAX UAV image alignment and analysis tool.

    Designed to ease image alignment

    The STAX UAV image alignment and analysis tool provides automated tools for aligning and analyzing UAV imagery without a full photogrammetric software suite. STAX was built to address the challenges of collecting and aligning multiple UAV surveys of the same location over time. By automating the alignment process, UAV operators can reduce or eliminate the use of ground control points that are traditionally installed and measured in survey sites. Relative corrections can be applied by using one of the surveys in a stack as a reference. Alternately, a highly accurate reference image of similar resolution over the area of interest can be used to automate the image alignment process. Once multi-pass UAV surveys have been aligned, customers can accurately make comparisons between surveys to measure changes over time or perform feature extraction. STAX provides tools to calculate vegetation indices as well as visualization and basic cartographic capability. Stacked data sets
    can be exported for deeper analysis.

    PCI Geomatics, www.pcigeomatics.com

    SATCOM terminal

    Gilat's BlackRay 72Ka.
    Gilat’s BlackRay 72Ka.

    Enables long-endurance missions for very small UAVs

    The miniature, lightweight BlackRay 72Ka terminal enables long-endurance missions for very small UAVs. The ultra-compact airborne SATCOM terminal for unmanned aircraft systems delivers exceptional throughput for its size. Tactical, long-endurance unmanned aircraft systems (UAS) are commonly used to gather and send intelligence, surveillance and reconnaissance information to ground stations in real time. Reliable, high-performance satellite communications are crucial for ensuring uninterrupted broadband connectivity in beyond line-of-sight missions. Weighing less than 5 Kg, the BlackRay 72Ka combines high performance and throughput with minimal footprint.

    Gilat Satellite Networks, www.gilat.com

    Hydrogen drone

    MMC's HyDrone 1800.
    MMC’s HyDrone 1800.

    Long endurance aircraft equipped for military applications

    The carbon-fiber HyDrone 1800 is designed for use in tough conditions. The drone is wind-resistant, rain-resistant, cold-resistant and lightweight. Its hydrogen fuel-cell technology provides a flight endurance of 4 hours — 50+ hours when combined with MMC tethered technology. The HyDrone 1800 achieves extended flight time while maintaining altitude limits of 4,500 meters with a payload capacity of up to 5 kg. Constructed for safety and durability, an auxiliary lithium battery starts the fuel cell and provides a backup power source. Hydrogen drones can be flown in extreme temperatures from –10° C to 40° C. Payloads include a thermal imaging camera, low light camera, laser equipment or zoom camera, making the system suitable for many military applications such as intelligence gathering, border patrol, aerial fire support, laser designation or battle management services to tactical military operators. MMC also offers packaged solutions in target acquisition and reconnaissance technology (ISTAR).

    MMC, www.mmcuav.com

  • Topcon’s new GNSS receiver boards have expanded constellation tracking

    Topcon’s new GNSS receiver boards have expanded constellation tracking

    Topcon Positioning Group has launched two new full constellation GNSS receivers for the original equipment manufacturer (OEM) market. The new B111 and B125 boards are designed for use with a broad range of positioning applications.

    Topcon_B125_Receiver-WThe boards utilize the GPS, GLONASS, BeiDou and Galileo constellations with the B111 tracking signals in the L1 and L2 frequency band, while the B125 adds signals in the L5 band. Both boards are designed to provide scalable positioning from sub-meter DGPS positioning to sub-centimeter RTK positioning.

    “The new boards both include 226-channel Vanguard Technology with Universal Tracking Channels, for reliable ‘all-in-view’ and ‘future-proof’ tracking,” said Jason Hallett, vice president of Topcon global product management. “The addition of BeiDou and Galileo constellation tracking along with GPS, GLONASS, SBAS and QZSS functionality ensures the boards provide the best performance available.

    “The dual-frequency B111 board has very low-power consumption and flexible communication interfaces, making it easy for OEMs to integrate the compact board into any precise positioning application, reducing their time to market,” Hallett said. “The B111 is also form, fit and function compatible with its predecessor, the B110, allowing a plug-and-play upgrade option to track BeiDou and Galileo.”

    The board also includes an SD-card interface designed to provide quick and easy support for datalogging in addition to Quartz Lock Loop technology for superior GNSS tracking in high-vibration environments.

    “The B125 board offers Ethernet connectivity for options for advanced OEM integration,” Hallett said.

  • Skydel teams with Noffz to increase presence in Europe

    Skydel teams with Noffz to increase presence in Europe

    Skydel, a GNSS test solutions company, has partnered with Germany-based Noffz to deliver SDX GNSS simulation to clients in Europe.

    Noffz creates test systems and solutions in the area of the Internet of Things (IoT) — especially in automotive RF-test applications around eCall, network access devices, telematics control units, infotainment/multimedia units and automotive radar.

    With nearly 30 years of experience, Noffz delivers worldwide turnkey solutions and PC-based measurement, as well as automation systems.

    “With their broad expertise in test solutions, Noffz is well positioned to bring Skydel’s SDX GNSS simulation solutions to clients located in Europe and beyond,” Skydel said in a blog.

    “Technology is constantly evolving,” reads the blog. “With the advent of new satellite constellations, such as Galileo, expanding needs for position and navigation in the transportation industry, and the growing threats of RF interferences, GNSS simulation is more than ever a key component in the arsenal needed to design and validate new products.

    “Skydel SDX delivers a new paradigm in GNSS simulation, featuring an exclusive mix of performance, flexibility and unique capabilities. With the addition of Noffz’s know-how covering multiple industries, we now have an outstanding team that’s ready to tackle today and tomorrow’s technological integration challenges.”

    Galileot will reach Full Operational Capability (FOC) in 2019. Simulation of the complete Galileo constellation is possible with Skydel's SDX GNSS simulator.
    Galileot will reach Full Operational Capability (FOC) in 2019. Simulation of the complete Galileo constellation is possible with Skydel’s SDX GNSS simulator.