Tag: OEM

  • Inertial Labs releases INS-DU GPS-aided unit for high-accuracy positioning

    Inertial Labs releases INS-DU GPS-aided unit for high-accuracy positioning

    The new INS-DU delivers high-accuracy RTK positioning for air, land and marine applications

    Photo: Inertial Labs
    Photo: Inertial Labs

    Inertial Labs has released a new GPS-aided inertial navigation system (INS). The INS-DU is a high-performance strapdown system that determines position, velocity and absolute orientation to any platform it is mounted to.

    The INS-DU has a dual-antenna u-blox GNSS receiver that provides 1-cm real-time kinematic (RTK) position from RTCM 3 RTK corrections and supports a wide range of GNSS constellations.

    Designed for UAVs, land vehicles and marine vessels, the INS-DU is an effective, low-cost solution that uses a range of aiding data for different applications. With highly accurate navigation in GNSS-denied environments, the INS-DU delivers a cost-effective GNSS-denied solution, according to Inertial Labs.

    One of the key elements to the success of the INS-DU is its use of the miniAHRS, which utilizes 3-axes each of precision magnetometers, accelerometers and gyroscopes to provide orientation of the device under measure. It contains cutting-edge algorithms for the motion of robots, unmanned and autonomous vehicles, and antennas.

    MiniAHRS mini fluxgate magnetometers have an advantage over commonly used magneto-inductive or magneto-resistive alternatives and have been a trusted North reference for more than 70 years.

    The INS-DU provides a full navigation solution for both GNSS and GNSS-denied environments. With custom interfaces and a power consumption of two and a half of a Watts, the INS-DU is a versatile solution fit for a wide variety of users with power consumption restrictions.

    In addition, the INS-DU contains our on-board sensor-fusion filter, state-of-the-art navigation, and guidance algorithms and calibration software.

  • Bynav introduces C1 GNSS receiver for GNSS mass market

    Bynav introduces C1 GNSS receiver for GNSS mass market

    Photo: Bynav
    Photo: Bynav

    Bynav Technology Co. Ltd. has released the C1 GNSS RTK OEM receiver and the A1 industrial-grade IMU-enhanced GNSS OEM receiver based on Bynav GNSS baseband ASIC Alita and RFIC Ripley. Bynav supplies GNSS high-precision receivers to the Chinese vehicle driver-testing market.

    The C1 GNSS RTK OEM receiver board measures 46 × 71 mm and supports dual-antenna heading and full-constellation, including GPS, BDS, Galileo, GLONASS, QZSS, NavIC and SBAS, as well as providing enhanced interfaces like UART serial port, Ethernet, 3 EVENT_IN, 3 EVENT_OUT, 1PPS and CAN bus for easy integration with an external inertial measurement unit (IMU), odometry, lidar or visual SLAM.

    The A1 GNSS/INS OEM receiver, measuring 46 × 71 mm and weighing 25 g, is integrated with an industrial-grade IMU (gyro 2.7deg/hr) with an embedded, deeply coupled GNSS+INS algorithm engine as well as tilt measurement algorithm to provide stable, high-precision position and attitude even in the event of GNSS outages.

    Most of the vehicle driver testing centers in China have automated their exams with the assistance of GNSS high-precision positioning. As a strategic partner of Duolun Technology, China’s driver-testing system integrator, thousands of drivers testing vehicles equipped with Bynav GNSS RTK receivers are moving around China every day.

    The R&D team of Bynav has taken part in the construction of China BeiDou Satellite Navigation System since 2002. With a powerful and experienced GNSS experts’ team and large-scale scenario verification on dynamic driver-testing vehicles, Bynav has successfully developed the high-precision GNSS baseband ASIC Alita and the RFIC Ripley which have been now integrated in the A1 and C1 products.

    The performance of the A1 and C1 have been verified and recognized by many domestic customers in the field of vehicle driver testing and autonomous driving.

    “We are committed to developing intelligent driving vehicles and commercializing them as soon as possible, in which the GNSS/INS receiver plays an important role to provide absolute position,” said Ying Long, deputy general manager of the Changsha Intelligent Driving Institute, a well-known autonomous driving company in China. “That’s why I started work together with Bynav for a cost-effective and high-performance positioning solution. Currently, the Bynav’s GNSS/INS receivers have been used in our unmanned sweepers, self-driving trucks and other products, and it comes out that the A1 performance is comparable to the world-class and high-end products we used.”

    Both receivers support dual-antenna heading and full-constellation and full-frequency tracking (including BDS-3 and L5), and provide SD card interface for raw data storage.

    Both C1 and A1 are now available for direct purchase. For wholesale price, contact [email protected].

  • Sensonor launches space-dedicated gyro and IMU modules

    Sensonor launches space-dedicated gyro and IMU modules

    Photo: Sensonor
    Photo: Sensonor

    Sensonor has launched two new navigation devices. The high-accuracy tactical-grade STIM277H gyro module and STIM377H inertial measurement unit (IMU) are based on experiences and requirements from serving customers in the space segment during the past decade.

    The modules have a hermetic aluminum enclosure with a glass-to-metal sealed electrical micro-d connector and a laser-welded lid to secure long-term hermetic operation.

    All parts are tested for fine and gross leak to conform to MIL-STD-883J, Class H. The hermetic enclosure protects the system from the external environment and ensures long-term reliability to meet requirements within the space segment and other applications needing exceptional long-term reliability.

    The design is tested for a 20+ years’ operating life through high-temperature operating life (HTOL) testing. STIM277H and STIM377H are electrically and mechanically backward-compatible with Sensonor’s other IMU and gyro modules, and provide users with an easy implementation into an existing design.

    The components come in dust-free clean-room packaging and have SurTec650 as the only surface treatment. The components are International Traffic in Arms Regulations (ITAR)-free, and have a range of features that can be configured by the customer.

    While the new part is still a commercial off-the-shelf (COTS) product and not space-qualified, Sensonor has carried out extensive radiation characterizations to understand the capability of the parts. This data is available on request from Sensonor or can be downloaded.

    The parts are a good fit for satellite attitude and orbit control systems (AOCS), launchers, portable target acquisition systems, UAV payloads, land navigation systems, turret stabilization, missile stability and GNSS-supported navigation systems.

  • Hexagon launches autonomy kits for agriculture with demo tractor

    Hexagon launches autonomy kits for agriculture with demo tractor

    Hexagon’s Autonomy and Positioning division has launched its first autonomy positioning and sensing kits for the agriculture market and validated these solutions in its new autonomous research and development tractor.

    Through collaboration between NovAtel and AutonomouStuff, both part of Hexagon, the autonomous positioning and sensing kits were developed as part of Hexagon’s Smart Autonomous Mobility solutions portfolio launched at CES in early 2020. NovAtel and AutonomouStuff created the solutions with agriculture machinery OEMs and robotic machinery manufacturers in mind.

    As a demonstrator vehicle for Smart Autonomous Mobility, the autonomous tractor features object detection and classification, simultaneous relative localization and mapping, absolute positioning through GNSS technology, and localization sensor fusing. Built to illustrate the viability of new positioning and sensing kits, the tractor incorporates safety-critical learnings with situational and environmental awareness, and manual remote control when needed. This platform validates how these solutions and capabilities accelerate autonomous development.

    Hexagon's autonomous research and development tractor validated the new kit. (Photo: Hexagon)
    Hexagon’s autonomous research and development tractor validated the new kit. (Photo: Hexagon)

    The positioning and sensing kits are optimized for autonomous agriculture applications, including products like the Smart7 antenna and autonomous robotic capabilities through the NovAtel OEM7 driver powered by the Robot Operating System (ROS). The kits also feature TerraStar GNSS Correction Services, ALIGN heading and relative positioning firmware, and SPAN GNSS+INS technology. Though designed for agriculture, the kits integrate seamlessly into other off-road autonomy applications.

    “These positioning and sensing kits provide developers with technology bringing assured positioning to autonomy in agriculture,” explained Michael Martinez, agriculture segment manager at Hexagon | NovAtel. “Robotic-machinery manufacturers or those experienced in autonomy may be unfamiliar with the unique challenges facing agriculture applications. Conversely, those experienced with agriculture may not have the expertise to integrate positioning and sensing products within autonomous solutions. We can help in both cases through these positioning and sensor kits, as demonstrated by our autonomous tractor.”

    The new autonomous positioning and sensing kit. (Photo: Hexagon)
    The new autonomous positioning and sensing kit. (Photo: Hexagon)

    “We’re excited to use this tractor as a platform to validate the human identification, obstacle detection and enhanced environmental awareness that our sensing kits add to our assured positioning solutions in agriculture,” said John Buszek, VP of products and services at Hexagon | AutonomouStuff. “The sensing and positioning technologies we’ve integrated on this demonstration platform showcase the Smart Autonomous Mobility portfolio, which enables and accelerates the development of autonomy in agriculture applications from prototyping to production.”

    For more than 30 years, NovAtel has delivered GNSS positioning solutions as a trusted provider for top precision agriculture companies. Combined with AutonomouStuff’s decade of expertise in autonomy and sensor fusion, they significantly reduce the barrier of entry into autonomy to accelerate the time to market for autonomous solutions in agriculture, construction, mining and other off-road applications.

    Learn more about their agriculture autonomy capabilities by taking a virtual tractor tour via their 3D interactive app or online at novatel.com/ag-autonomy.

  • GMV NSL launched: GMV merges UK company with Nottingham Scientific

    GMV NSL launched: GMV merges UK company with Nottingham Scientific

    GMV-NSL logoGMV Innovating Solutions Limited — the U.K. aerospace company belonging to the Spanish technology multinational GMV — has signed a merger agreement with Nottingham Scientific Limited (NSL).

    GMV trades in the aerospace, defense, ICT and intelligent transportation systems markets, while NSL is a U.K. leader in satellite navigation and critical applications.

    After the agreement, GMV becomes sole shareholder of NSL and sets up the company GMV NSL, to be integrated seamlessly into GMV’s set of companies. NSL was founded in 1998 by Vidal Ashkenazi, a former member of GPS World’s Editorial Advisory Board.

    Headshot: Vidal Ashkenazi
    Vidal Ashkenazi

    In 2013, as part of its international expansion, GMV rolled out a business development strategy in the U.K. This involved setting up a new company, which came on stream in late 2014 to join the suite of companies and offices in Spain, USA, Germany, France, Poland, Portugal, Romania, The Netherlands, Malaysia and Colombia.

    Working from its Harwell innovation center in Oxfordshire, GMV’s main U.K. business is Earth observation, space debris tracking, mission planning, flight dynamics, navigation, autonomy and robotics. Its principal clients include the European Space Agency (ESA) and the European Commission (EC), as well as U.K.’s space agency (UKSA), the Defence Science and Technology Laboratory (DSTL), Innovate UK, ASUK, Satellite applications Catapult and the Science Technology Facility Council (STFC).

    Set up in 1998 and with a solid and acknowledged track record in high-tech projects, NSL is a U.K.-based SME specializing in satellite navigation and critical applications. From its Nottingham head office in the East Midlands, NSL offers GNSS-based services, systems, solutions and intellectual property, helping to ensure that navigation and positioning are precise and reliable, secure and protected, resistant and robust. NSL’s major clients include UK Space Agency, ESA, U.K. Government departments, QinetiQ, Inmarsat, and the European Commission.

    GMV NSL, 80 strong, will be integrated into GMV’s set of companies, which closed 2019 with a staff of 2,176 and a turnover of more than €236 million. Membership of the GMV powerhouse will enable GMV NSL to rise to even greater challenges and tap into the opportunities offered by the U.K. market, especially the space market, not only in satellite navigation and in critical applications, but also in Earth observation, telecommunications and new technologies, with the overarching aim of winning pole position in Britain’s space sector.

    Jesús B. Serrano, GMV CEO (Photo: GMV)
    Jesús B. Serrano, GMV CEO (Photo: GMV)

    “This merger will enable the resultant firm to tap into significant commercial, technological and operational synergies, boosting GMV NSL’s rate of growth and winning it a place in the space programs of both the U.K. and Europe as a whole,” said Jesús B. Serrano, GMV CEO.

    “In our different ways, GMV and NSL are regarded as world leading space companies and this agreement will expand our capabilities and capacity enabling us to successfully tackle even greater challenges and consolidate GMV NSL’s position as the benchmark space company,” Mark Dumville, co-founder and director of NSL, added.

    The sheer quality of both teams and the like-mindedness of GMV and NSL on company values, heritage, technological excellence and client satisfaction were all deal clinchers in this merger agreement.

  • Tallysman Wireless acquired by Calian Group

    Tallysman Wireless acquired by Calian Group

    Effective Sept. 1, Tallysman Wireless Inc. was acquired by Calian Group Ltd. to expand Calian’s reach in the satcom industry to markets requiring smaller antennas used in end-user devices that need a different range of fidelities, according to Patrick Thera, president, Advanced Technologies, Calian.

    Calian is a publicly owned Canadian company listed on the Toronto Stock exchange. Its solutions include satellite gateways and infrastructure for RF communications, telemetry, tracking and control systems, space science and earth observation. Calian also provides leading-edge communication products for terrestrial and satellite networks.

    Based in Ontario, Canada, Tallysman designs, manufactures and sells a wide range of GNSS, Iridium and Globalstar antennas and related products into a market with a broad range of vertical applications that include precision reference systems, survey, timing, precision agriculture, unmanned and autonomous vehicles, marine and more.  The company also produces cloud-based wireless tracking systems over two-way radio systems and 4G category M cellular systems, for applications ranging from school buses to municipal public works.


    Development of Tallyman’s VeroStar antenna is the topic of the September issue’s Innovation column.

    FIGURE 2 . (a) VeroStar antenna element; (b) VeroStar antenna current distribution. (Images: Tallysman)
    FIGURE 2 . (a) VeroStar antenna element; (b) VeroStar antenna current distribution. (Images: Tallysman)

    The company is widely recognized as a technology leader and is the supplier of high-precision antennas to precision GNNS systems providers. Under the Calian umbrella, Tallysman will continue to operate as it has been, with no changes in product availability, fulfilment, support, management or engineering services.

    Tallysman will also continue to invest in research and development, and bring new and innovative GNSS products to the market, the company said.

    The definitive agreement is valued at up $24.5 million. Amount paid on closing is $15.7 million (net of cash received) and contains two earnout periods of $4M and $4.8M based on the achievement of a certain level of EBITDA performance over the next 30 months. Tallysman’s results will be consolidated and reported with Calian’s Advance Technology segment.

    “This important acquisition supports both customer diversification and service line innovation, two key pillars within our four-pillar growth strategy,” stated Kevin Ford, Calian president and CEO. “The Tallysman acquisition demonstrates Calian continued our focus on innovation and growth.  The wide range of products and applications Tallysman brings to Calian expands our product line and entry into new markets.  We are excited with the opportunity to support innovation in exciting growth industries such as autonomous vehicles, precision agriculture and wearables.  We could not be more pleased to welcome Tallysman to the Calian team.”

    Sampford Advisors acted as exclusive M&A advisor to Tallysman.

    “We are extremely pleased to join the Calian team,” said Gyles Panther, Tallysman president and CTO states. “We look forward to continuing, profitable growth of our core GNSS businesses with  products that we sell to a broad customer base. As a member of the Calian family, we also look forward to leveraging additional resources, new technologies and markets deriving from Calian’s deep expertise in satellite communications.”

    “Calian welcomes Tallysman to our team,” Thera said. “The Tallysman product line and services add a complementary component to our ground-based satellite communications business. GNSS is one of the fastest growing markets for satellite ground systems and we are excited to join forces with a leader in this field.”

  • Collaboration aimed at GNSS solution for IoT modems

    Collaboration aimed at GNSS solution for IoT modems

    Synopsys Inc. and Nestwave are collaborating to combine Nestwave’s geolocation software with the Synopsys DesignWare ARC IoT Communications Subsystem for a complete low-power GNSS solution for integration into IoT modems.

    The collaboration will provide designers with a power-efficient, high-accuracy GPS solution for battery-operated devices without the additional cost of a dedicated GNSS chip.

    The joint solution will be presented at the Synopsys ARC Processor Virtual Summit on Wednesday, Sept. 9.

    “Today’s advanced navigation systems are facing unique challenges when being implemented in power-constrained IoT devices,” said Ambroise Popper, CEO at Nestwave. “By combining Nestwave’s low-power geolocation software with Synopsys’ efficient ARC IoT Communications IP Subsystem, we can deliver a geolocation solution that offers greater accuracy, lower power consumption, and lower cost compared to existing GNSS solutions.”

    Ultra-low bandwith IoT applications

    The ARC IoT Communications IP Subsystem is an integrated hardware and software solution that combines Synopsys’ DSP-enhanced ARC EM9D processor, hardware accelerators, dedicated peripherals and RF interface to deliver efficient DSP performance for ultra-low bandwidth IoT applications.

    Nestwave’s GNSS solution takes advantage of the ARC EM9D processor’s efficient DSP capabilities and ability to add dedicated hardware accelerators or custom instructions using APEX technology to reduce frequency requirements, giving customers additional performance bandwidth.

    The ARC EM9D processor is supported by the MetaWare Toolkit, which includes a rich library of DSP functions, allowing software engineers to rapidly implement algorithms from standard DSP building blocks.

    Geolocation for emerging applications

    Nestwave has developed an ultra-low power, advanced GNSS solution for use in IoT applications. When integrated with an IoT modem such as NB-IoT, Cat M1, LoRa or Sigfox, the solution offers low-cost geolocation for emerging applications such as asset tracking, smart factories, and smart cities, without the need for an external GNSS chip.

    “Emerging IoT applications are demanding geolocation functionality with high-accuracy and ultra-low power consumption,” said John Koeter, senior vice president of marketing and strategy for IP at Synopsys. “The combination of Synopsys’ ARC IoT Communications IP Subsystem with Nestwave’s GNSS technology will help designers significantly improve geolocation performance, reduce frequency requirements and lower overall power consumption for battery-powered IoT applications.”


    Feature image: metamorworks/iStock/Getty Images Plus/Getty Images

  • Septentrio announces global partnership with Digi-Key

    Septentrio announces global partnership with Digi-Key

    Septentrio, a provider of high-precision GNSS positioning solutions, has partnered with Digi-Key Electronics, a global electronic components distributor. Digi-Key now offers mosaic-X5 globally for customers who need secure and reliable high-accuracy positioning in a compact and low-power form factor.

    Image: Septentrio
    Image: Septentrio

    Septentrio’s mosaic-X5 features complete multi-frequency multi-constellation technology and tracks every existing and future signal from all GNSS constellations.

    Such signal diversity coupled with advanced anti-jamming technology allows mosaic-X5 to deliver centimeter-level positioning with maximum availability even in challenging industrial environments. This makes mosaic-X5 an ideal positioning solution for applications such as robotics, automation, telematics and many more.

    “Our mosaic-X5 is an advanced GNSS receiver module without performance compromises. With its small form factor and low-power design, mosaic-X5 brings high-performance positioning to volume applications,” said Francois Freulon, head of product management for Septentrio. “Having Digi-Key as a distributor enables us to scale and reach out to find new markets and applications where secure high-accuracy positioning is required.”

    “Digi-Key is excited about the new partnership with Septentrio,” said David Stein, vice president of global supplier management for Digi-Key. “Demand for high-accuracy GNSS receivers with secure and robust positioning is growing strongly, as they continue to be implemented into new applications and devices. Digi-Key offers customers an easy path to order, develop and deploy with the latest technologies available, including Septentrio’s robust and precise GNSS devices, which have the latest anti-jamming and anti-spoofing technology.”

  • Applanix introduces OEM solution for direct georeferencing of airborne sensor data

    Applanix introduces OEM solution for direct georeferencing of airborne sensor data

    Photo: Applanix
    Photo: Applanix

    Applanix, a Trimble company, has introduced the Trimble AP+ Air OEM solution for direct georeferencing of airborne sensor data.

    The solution enables users to accurately and efficiently produce maps and 3D models without the use of ground control points.

    The Trimble AP+ Air is a powerful solution for manned platforms, yet small enough for use on unmanned aerial vehicles (UAVs). It is also compatible with virtually any type of airborne remote sensor, including photogrammetric cameras, lidar, hyper and multispectral cameras, and synthetic aperture radar.

    Comprised of next-generation compact, low-power hardware, the Trimble AP+ Air features dual embedded survey-grade GNSS chipsets, an onboard inertial measurement unit (IMU), an external IMU, and the all-new Applanix IN-Fusion+ GNSS-aided inertial firmware. It is configurable to support the direct georeferencing accuracy demands of low-flying UAVs to high-altitude manned platforms.

    “We have taken the most advanced features of Applanix direct georeferencing and Trimble GNSS technology and packaged them into a powerful new, compact and versatile solution,” said Joe Hutton, Applanix’ director of inertial technology and airborne products. “It provides the flexibility required by systems integrators to embed a single hardware solution that can then be configured to meet the different direct georeferencing needs of a specific sensor type, whether flown on a UAV or manned aircraft. It truly is an ‘integrate once, use many times’ solution.”

    The Trimble AP+ Air is fully supported by the Applanix POSPac MMS post-processing software, which features CenterPoint RTX post-processing for centimeter-level positioning anywhere in the world without the need for base stations. These capabilities make the solution ideal for integrators to produce a highly efficient airborne mapping system.

    For lidar integrators, the Trimble AP+ Air is compatible with the POSPac MMS LiDAR QC Tools for computing boresight as well as adjusting the relative accuracy of the POSPac trajectory being used to generate the point cloud. For integration with cameras, the solution is supported by the POSPac MMS Photogrammetry Tools for computing boresight and performing camera IO quality control.

    The Trimble AP+ Air OEM solution and POSPac MMS are available through Applanix sales channels.

  • Innovation: Design and performance of a novel GNSS antenna for rover applications

    Innovation: Design and performance of a novel GNSS antenna for rover applications

    Smaller and Better

    By Reza Movahedinia, Julien Hautcoeur, Gyles Panther and Ken MacLeod

    Innovation Insights with Richard Langley
    Innovation Insights with Richard Langley

    THE ANTENNA. This crucial component of any radio transmitting or receiving system has a history that actually predates the invention of radio itself. The first antennas were used by Princeton professor Joseph Henry (after whom the unit of inductance is named) to demonstrate the magnetization of needles by a spark generator. But it was the experiments of Heinrich Hertz in Germany in 1887 that initiated the development of radio transmitters and receivers and the antennas necessary for launching and capturing electromagnetic waves for practical purposes. It was Hertz who pioneered the use of tuned dipole and loop antennas–basic antenna structures we still use today. As communication systems evolved using different parts of the radio spectrum from very low frequencies, through medium-wave frequencies, to high frequencies (shortwave), and to very high frequencies and ultra-high frequencies, and beyond, so did their antennas.

    There have been significant advances in the design of antennas over the years to improve their bandwidth, beamwidth, efficiency and other parameters. In fact, antenna development, going all the way back to the first antennas, has been one of continuous innovation.

    GNSS antennas are no different. The antennas for the first civil GPS receivers were bulky affairs. Researchers at the Massachusetts Institute of Technology initially introduced the Macrometer V-1000 in 1982, and Litton Aero Service subsequently commercialized it. It used a crossed-dipole antenna element on a 1-meter square aluminum panel and weighed 18 kilograms. The Jet Propulsion Laboratory’s demonstration GPS receiver, unveiled around the same time, used a small steerable parabolic dish that had to be sequentially pointed at GPS satellites. Both of these antennas gave way to more practical designs. Also introduced in 1982 was the Texas Instruments TI 4100, also known as the Navstar Navigator. This dual-frequency receiver used a conical spiral antenna to provide the wide bandwidth needed to cover both the L1 and L2 frequencies used by GPS.

    Subsequently, in the mid- to late-1980s, GPS and GLONASS antennas using microstrip patches were introduced for both single- and dual-frequency signal reception. The basic designs introduced then are still with us and are used for single- and multiple-frequency GNSS receivers. Miniature versions are used in some mass-market handheld receivers and for receivers in drone flight control systems. Patch antennas have also been used as elements in survey-grade antennas. A number of other GNSS antenna topologies have been developed including helices and planar spiral designs. Antennas designed for high-precision applications often integrate a ground-plane structure of some kind into the structure such as choke rings.

    You might think after more than 30 years of GNSS technology development, that there is nothing new to be expected in GNSS antenna development. You would be wrong. In this GPS World 30th anniversary issue Innovation column, we look at the design and performance of an antenna that offers high performance even in challenging environments in a relatively small package. It is appropriate that it is unveiled in this column. After all, Webster’s Dictionary has defined innovation as “the act of innovating or effecting a change in the established order; introduction of something new.” This antenna might very well be a game changer.


    Global navigation satellite systems (GNSS) have continued to evolve and have become critical infrastructure for all of society. Starting with the awesome engineering feat of the U.S. Global Positioning System and then the more recently developed constellations from other nations, we now have available refined signal structures with ever-improving positioning, navigation and timing accuracy.

    Expanding use cases has led to the design of GNSS antennas optimized for many different applications. However, new antenna design commonly requires more than simple modifications to existing GPS antenna technologies. Design agility is needed to meet requirements such as wider bandwidth, sculpted radiation patterns (we frequently talk about radiation characteristics even for a receiving antenna assuming antenna reciprocity), optimized/reduced size, better efficiency, lower noise figure, or improvements in the more esoteric parameters such as axial ratio (AR) and phase-center variation (PCV). Nothing changes the widely unappreciated fact that the antenna is the most critical element in precision GNSS systems.

    In this article, we report on the research and commercial development of a high-performance GNSS antenna by Tallysman, designated “VeroStar.” The VeroStar sets a new performance standard for an antenna of this type and supports reception of the full GNSS spectrum (all constellations and signals) plus L-band correction services. The antenna combines exceptional low-elevation angle satellite tracking with a very high-efficiency radiating element. Precision manufacturing provides a stable phase-center offset (PCO) and low PCV from unit to unit. The performance, compact size and light weight of the VeroStar antenna element make it a good candidate for modern rover and many other mobile GNSS applications.

    DESIGN OBJECTIVES

    The design of an improved, high-level GNSS antenna requires consideration of characteristics such as low-elevation angle tracking ability, minimal PCV, antenna efficiency and impedance, axial ratio and up-down ratio (UDR), antenna bandwidth, light weight, and a compact and robust form factor.

    Low-Elevation Angle Tracking. Today’s professional GNSS users have widely adopted the use of precise point positioning (PPP) including satellite broadcast of the PPP correction data. PPP correction data is broadcast from geostationary satellites, which generally hover at low-elevation angles for many densely populated regions such as Europe and much of North America. The link margin of L-band signals is typically minimal, so that improved gain at these elevation angles is an important attribute. This issue is exacerbated at satellite beam edges and northern latitudes where the link margin is further challenged — a difference of just 1 dB in antenna gain or antenna noise figure can make a big difference in correction availability. A key design parameter in this respect is the antenna G/T, being the ratio, expressed in dB per kelvin, of the antenna element gain divided by the receiver system noise temperature, typically determined by the antenna noise figure. The G/T objective for this antenna was –25.5 dB/K at a 10-degree elevation angle.

    The gain of most GNSS antenna elements, such as patches and crossed dipoles, rolls off rapidly as the elevation angle decreases toward the horizon. The polarization also becomes linear (rather than circularly polarized) at the lower elevation angles, due to the existence of a ground plane, necessary to increase gain in the hemisphere above the antenna. Improved gain close to the horizon also increases the ability of the receiver to track low-elevation-angle satellites with a concomitant improvement in the dilution of precision parameters (DOPs; a series of metrics related to pseudorange measurement precision).

    Most of the commercially available GNSS rover antennas have a peak gain at zenith of about 3.5 dBic to 5 dBic with a roll-off at the horizon of 10–12 dB (dBic refers to the antenna gain referenced to a hypothetical isotropic circularly polarized antenna). Typically, this provides an antenna gain at the horizon, at best, of about –5 dBic, which is insufficient for optimized L-band correction usage. In some studies, different antenna types such as helical elements have been proposed to overcome this issue. However, their cylindrical shape and longer length makes them unsuitable for many rover applications. Furthermore, the helix suffers from back lobes that can make the antenna more susceptible to reception of multipath signals from below the upper hemisphere of the antenna.

    In the VeroStar design, we used wide-bandwidth radiating elements (referred to here as “petals”) that surround a distributed feed network. The petal design is important to achieve superior right-hand circularly polarized (RHCP) gain at low-elevation angles.

    Tight Phase-Center Variation. The phase center of an ideal antenna is a notional point in space at which all signals are received or transmitted from, independent of the frequency or elevation or azimuth angle of the signal incidence. The phase centers of real-life antennas are less tidy, and the PCV is a measure of the variation of the “zero” phase point as a function of frequency, elevation and azimuth angles. Correction data for phase-center variation is commonly encoded in a standardized antenna exchange format or Antex file, which can be applied concurrently for precision applications.

    The azimuthal orientation of rover antennas is typically unknown, so that errors for specific orientations of the antenna in the horizontal plane cannot be accounted for. The PCV correction data provided in an Antex file is usually provided as a function of elevation angle and frequency, but with averaged azimuth data for each elevation angle and frequency entry (noazi corrections). Thus, corrections can be applied for each frequency and elevation angle, but errors due to the variation in the azimuthal PCV cannot be corrected in the receiver. For real-time kinematic (RTK) systems, the net system error is the root-mean-square sum of the base and rover antenna PCVs. It is usually possible to accommodate larger base-station antennas, which can commonly provide PCVs approaching +/- 1 mm (such as those from Tallysman VeraPhase or VeraChoke antennas). In this case, the accuracy of the combined system is largely determined by the PCV of the smaller rover GNSS antenna. Thus, even with correction data, azimuthal symmetry in the rover antenna is key. In the VeroStar, this was addressed by obsessive focus on symmetry for both the antenna element structure and the mechanical housing design.

    Antenna Efficiency and Impedance. Antenna efficiency can be narrowly defined in terms of copper losses of the radiating elements (because copper is not a perfect conductor), but feed network losses also contribute so that the objective must be optimization of both. Physically wide radiating elements are a basic requirement for wider bandwidth, and copper is the best compromise for the radiator metal (silver is better, but expensive and with drawbacks). This is true in our new antenna, which has wide radiating copper petals.

    However, the petals are parasitic resonators that are tightly coupled to a distributed feed network, which in itself is intrinsically narrowband. The resulting wide bandwidth response results from the load on the feed network provided by the excellent wideband radiation resistance of the petals.

    This arrangement was chosen because the resulting impedance at the de-embedded antenna feed terminals is close to the ideal impedance needed (50 ohms), thus requiring minimal impedance matching. The near ideal match over a wide bandwidth is very important because it allowed the impedance to be transformed to ideal using a very short transmission line (less than one-quarter of a wavelength), which included an embedded infinite balun (a balun forces unbalanced lines to produce balanced operation).

    Each of the orthogonal exciter axes are electrically independent and highly isolated electrically (better than –30 dB), even with the parasitic petal coupling. To achieve the desired circular polarization, the two axes are then driven independently in phase quadrature (derived from the hybrid couplers).

    Thus, the inherently efficient parasitic petals combined with the absolutely minimized losses of the distributed feed network has resulted in a super-efficient antenna structure that will be difficult to improve upon.

    Axial and Up-Down Ratio. AR characterizes the antenna’s ability to receive circularly polarized signals, and the UDR is the ratio of gain pattern amplitude at a positive elevation angle (α) to the maximum gain pattern amplitude at its mirror image (–α). Good AR and UDR across the full bandwidth of the antenna ensure the purity of the reception of the RHCP GNSS signals and multipath mitigation. GNSS signals reflected from the ground, buildings or metallic structures such as vehicles are delayed and their RHCP purity is degraded with a left-hand circularly polarized (LHCP) component. Because the VeroStar antenna has more gain at low-elevation angles, a very low AR and a high UDR are even more important for mitigating multipath interference. The design objective was an AR of 3 dB or better at the horizon.

    A Light, Robust and Compact Design. The user community demands ever smaller antennas from antenna manufacturers, but precision rover antennas are typically required to receive signals in both the low (1160 to 1300 MHz) and high (1539 to 1610 MHz) GNSS frequency bands. An inescapable constraint limits the bandwidth of small antennas, so that full-bandwidth (all GNSS signals) rover antennas are unavoidably larger. To date, probably the smallest, high performance all-band antenna was the original Dorne & Margolin C146-XX-X (DM) antenna, which was in its time a tour-de-force.

    The overall objective for our antenna was to design a small and light-weight radiating element (given the full bandwidth requirement) with a ground-plane size of around 100 millimeters, element height of 30 millimeters or lower, and a weight of 100 grams or less. Ideally, it would be possible to build a smaller version, perhaps with a degree of compromised performance. The applications envisaged for the VeroStar included housed antennas (such as for RTK rovers) and a lightweight element suitable for mobile applications such as drones or even cubesats.

    ANTECEDENTS

    The central goal of this project was a precision antenna with a broad beamwidth and a good AR combined with a very tight PCV. The objective was to provide for reception of signals from satellites at low-elevation angles, particularly necessary for reception of L-band correction signals, which can be expected to be incident at elevation angles of 10 degrees to 50 degrees above the horizon.

    A starting point for this development was an in-depth study of the well-known DM antenna. This antenna has been used for decades in GPS reference stations (usually in choke-ring antennas). It exhibits a higher gain at low-elevation angles (about –3 dBic at the horizon) compared to other antennas on the market (typically –5 dBic or less) and fairly good phase-center stability in a compact design. The antenna structure consists of two orthogonal pairs of short dipoles above a ground plane, with the feeds at the midpoint of the dipoles, as shown in FIGURE 1(a). The antenna can be considered in terms of the ground-plane image, replacing the ground plane with the images of the dipole as shown in FIGURE 1(b). The antenna structure then takes on the form of a large uniform current circular loop similar to the Alford Loop antenna, developed at the beginning of World War II for aircraft navigation.

    FIGURE 1. (a) Dorne & Margolin (DM) antenna current distribution; (b) Alford Loop antenna. (Image: Tallysman)
    FIGURE 1. (a) Dorne & Margolin (DM) antenna current distribution; (b) Alford Loop antenna. (Image: Tallysman)

    But the DM antenna does suffer from some drawbacks. By modern standards, the feed network is complex and lossy with costly fabrication, which affects repeatability and reliability. The AR at the zenith is marginal (up to 1.5 dB) and further degrades to 7 dB at the horizon, a factor that becomes less relevant in a choke-ring configuration where the DM element is the most commonly used. However, we took our inspiration from the DM structure and give a nod to its original developers.

    The structure of the VeroStar antenna is shown in FIGURE 2(a). It consists of bowtie radiators (petals) over a circular ground plane. The petals are coupled to a distributed feed network comprised of a simple low-loss crossed dipole between the petals and the ground plane. The relationship between the petals and the associated feed system provides a current maximum at the curvature of the petals instead of at the center of the antenna as seen in FIGURE 2(b), and in this respect achieves a current distribution similar to that of the DM element.

    FIGURE 2 . (a) VeroStar antenna element; (b) VeroStar antenna current distribution. (Images: Tallysman)
    FIGURE 2 . (a) VeroStar antenna element; (b) VeroStar antenna current distribution. (Images: Tallysman)

    This arrangement increases the gain at low-elevation angles, which greatly improves the link margin for low-elevation angle GNSS and L-band satellites. The circular polarization of the antenna at low-elevation angles can be significantly improved by optimizing the petal’s dimensions such as its height, width and angle with respect to the ground plane. This solves the problem of asymmetry between the electric and magnetic field planes of the antenna radiation pattern, which usually degrades the AR at low-elevation angles. Based on the studies conducted in our project, it was found that the bowtie geometry of the radiators, as well as its coupling to the feeding network, can improve both the impedance and AR bandwidth. By these means, we were able to produce a very wideband, low-loss antenna covering the entire range of GNSS frequencies from 1160 to 1610 MHz. The matching loss associated with the feed network is under 0.3 dB, and the axial ratio remains around 0.5 dB at the zenith and is typically under 3 dB at the horizon over the whole GNSS frequency range.

    In the early stages of the project, we thought that just four petals would be adequate for our purpose. However, as we progressed with further experimentation and simulation, it became clear that increasing the number of petals substantially improved symmetry, but at the cost of complexity. Ultimately, we determined that eight petals provided considerably better symmetry than four petals with an acceptable compromise with respect to feed complexity.

    MEASUREMENTS

    The far-field characteristics of the VeroStar antennas were measured using the Satimo anechoic chamber facilities at Microwave Vision Group (MVG) in Marietta, Georgia, and at Syntronic R&D Canada in Ottawa, Ontario. Data were collected from 1160 to 1610 MHz to cover all the GNSS frequencies.

    Radiation Patterns and Roll-Off. The measured radiation patterns at different GNSS frequencies are shown in FIGURE 3. The radiation patterns are normalized, showing the RHCP and LHCP gains on 60 azimuth cuts three degrees apart. The LHCP signals are significantly suppressed in the upper hemisphere at all GNSS frequencies. The difference between the RHCP gain and the LHCP gain ranges from 31 dB to 43 dB, which ensures an excellent discrimination between the signals. Furthermore, for other upper hemisphere elevation angles, the LHCP signals stay 22 dB below the maximum RHCP gain and even 28 dB from 1200 to 1580 MHz.

    Figure 3 also shows that the antenna has a constant amplitude response to signals coming at a specific elevation angle regardless of the azimuth angle. This feature yields an excellent PCV, which will be discussed later.

    FIGURE 3 . Normalized radiation patterns of the VeroStar antenna on 60 azimuth cuts of the GNSS frequency bands. (Data: Tallysman)
    FIGURE 3 . Normalized radiation patterns of the VeroStar antenna on 60 azimuth cuts of the GNSS frequency bands. (Data: Tallysman)

    FIGURE 4 shows a comparison of the VeroStar roll-off (that is, lower gain at the horizon) with six other commercially available rover antennas measured during the same Satimo session. The VeroStar roll-off is significantly lower than the other rover antennas. The amplitude roll-off from the VeroStar boresight (zenith) to horizon is between 6.5 to 8 dB for all the frequency bands.

    FIGURE 4. Comparison of the VeroStar roll-off versus six commercially available rover antennas. (Data: Tallysman)
    FIGURE 4. Comparison of the VeroStar roll-off versus six commercially available rover antennas. (Data: Tallysman)

    High gain at low-elevation angles (low roll-off) will cause the antenna to be more susceptible to multipath interference. Multipath signals are mainly delayed LHCP and RHCP signals. If they arrive at high-elevation angles, there is no issue because the AR of the antenna is low at those angles — thus there will be minimal reception of the multipath signals. However, in conventional antennas, low-elevation-angle multipath degrades observations due to the poor AR performance and low UDR. At lower elevation angles, our antenna has exceptional AR performance and good UDR, which significantly reduces multipath interference. Measurements in a high multipath environment were performed with the antenna and compared to other commercial rover antennas. The measurements show that the phase noise at a 5-degree elevation angle is approximately 6 to 10 millimeters over all GNSS frequencies. The other antennas perform similarly, but have a higher roll-off. This shows that the VeroStar provides a strong signal at low-elevation angles and also has a high level of multipath mitigation performance.

    Antenna Gain and Efficiency. FIGURE 5 shows the RHCP gain of our antenna at the zenith and at a 10-degree elevation angle for all GNSS frequencies. The measurements show that the antenna exhibits a gain range at the zenith from 4.1 dBic at 1160 MHz to 3.6 dBic at 1610 MHz. The antenna gain at a 10-degree elevation angle varies from –1.45 dBic to –2.2 dBic and is maximum in the frequency range used to broadcast L-band corrections (1539 to 1559 MHz). The radiation efficiency of the antenna is between 70 to 89 percent over the full bandwidth. This corresponds to an inherent (“hidden”) loss of only 0.6 to 1.5 dB, including copper loss, feedline, matching circuit and 90-degree hybrid coupler losses. This performance is a substantial improvement over other antenna elements such as spiral antennas, which exhibit an inherent efficiency loss of close to 4 dB at the lower GNSS frequencies. With the integration of wideband pre-filtering as well as a low-noise amplifier (LNA), we measured a G/T of –25 dB/K at a 10-degree elevation angle.

    FIGURE 5. RCHP gain at zenith and 10-degree elevation angle. (Data: Tallysman)
    FIGURE 5. RCHP gain at zenith and 10-degree elevation angle. (Data: Tallysman)

    Axial Ratio. The AR values of the VeroStar antenna at different elevation angles are shown in FIGURE 6. The antenna has exceptional AR performance over all GNSS frequency bands and at all elevation angles, with the value no greater than 3.5 dB. This increases the antenna’s ability to reject LHCP signals caused by reflections from nearby cars or buildings. Therefore, the susceptibility of the antenna to multipath interference is greatly reduced.

    FIGURE 6 Axial ratio versus frequency of the VeroStar at different elevation angles. (Data: Tallysman)
    FIGURE 6 Axial ratio versus frequency of the VeroStar at different elevation angles. (Data: Tallysman)

    In FIGURE 7, the AR performance of the antenna at the horizon is compared to six commercial rover antennas. The VeroStar antenna has an average AR of 2 dB at the horizon (competitive antennas are typically around 6 dB), showing its ability to track pure RHCP signals and enabling outstanding low-elevation-angle multipath mitigation.

    FIGURE 7. Comparison of the VeroStar axial ratio at the horizon versus six commercially available rover antennas. (Data: Tallysman)
    FIGURE 7. Comparison of the VeroStar axial ratio at the horizon versus six commercially available rover antennas. (Data: Tallysman)

    Phase-Center Variation. We developed Matlab code to estimate the PCV from the measured radiation pattern. FIGURE 8 shows the maximum PCV of the VeroStar antenna and six commercial rover antennas for four common GNSS frequencies. It can be seen that the antenna has a maximum total PCV of less than 2.9 millimeters for all frequency bands, which is less than the other commercially available rover antennas tested. Furthermore, the PCV of the antenna does not vary significantly with frequency. This comparison confirms the exceptional low PCV of our antenna.

    FIGURE 8. Comparison of the VeroStar maximum PCV at the horizon versus six commercially available rover antennas. (Data: Tallysman)
    FIGURE 8. Comparison of the VeroStar maximum PCV at the horizon versus six commercially available rover antennas. (Data: Tallysman)

    LOW-NOISE AMPLIFIER DESIGN

    The best achievable carrier-to-noise-density ratio (C/N0) for signals with marginal power flux density is limited by the efficiency of each of the antenna elements, the gain and the overall receiver noise figure. This can be quantified by the G/T parameter, which is usually dominated by the noise figure of the input LNA. In the LNA design for our antenna, the received signal is split into the lower GNSS frequencies (from 1160 to 1300 MHz) and the higher GNSS frequencies (from 1539 to 1610 MHz) in a diplexer connected directly to the antenna terminals and then pre-filtered in each band. This is where the high gain and high efficiency of the antenna element provides a starting advantage, since the unavoidable losses introduced by the diplexer and filters are offset by the higher antenna gain, and this preserves the all-important G/T ratio.

    That being said, GNSS receivers must accommodate a crowded RF spectrum, and there are a number of high-level, potentially interfering signals that can saturate and desensitize GNSS receivers. These signals include, for example, mobile-phone signals, particularly Long-Term Evolution (LTE) signals in the 700-MHz band, which are a hazard because of the potential for harmonic generation in the GNSS LNA. Other potentially interfering signals include Globalstar (1610 to 1618.25 MHz), Iridium (1616 to 1626 MHz) and Inmarsat (1626 to 1660.5 MHz), which are high-power communication satellite uplink signals close in frequency to GLONASS signals. The VeroStar LNA design is a compromise between ultimate sensitivity and ultimate interference rejection.

    A first defensive measure in the LNA is the addition of multi-element bandpass filters at the antenna element terminals (ahead of the LNA). These have a typical insertion loss of 1 dB because of their tight passband and steep rejection characteristics. However, the LNA noise figure is increased approximately by the additional filter-insertion loss. The second defensive measure in the design is the use of an LNA with high linearity. This is achieved without any significant increase in LNA power consumption, using LNA chips that employ negative feedback to provide well-controlled impedance and gain over a very wide bandwidth. Bear in mind that while an antenna installation might initially be determined to have no interference, subsequent introduction of new telecommunication services may change this, so interference defense is prudent even in a quiet radio-frequency environment. A potentially undesirable side effect of tight pre-filters is the possible dispersion that can result from variable group delay across the filter passband. Thus, it is important to include these criteria in the selection of suitable pre-filters. The filters in our LNA give rise to a maximum variation of less than 10 nanoseconds in group delay over both the lower GNSS frequencies (from 1160 to 1300 MHz) and the higher GNSS frequencies (from 1539 to 1610 MHz).

    CONCLUSION

    In this article, we have described the performance of a novel RHCP antenna optimized for modern multi-constellation and multi-frequency GNSS rover applications. We have developed a commercially viable GNSS antenna with superior electrical properties. The VeroStar antenna has high sensitivity at low elevation angles, high efficiency, very low axial ratio and high phase-center stability. The lightweight and compact antenna element is packaged in several robust housings designed and built for durability to stand the test of time, even in harsh environments.

    The VeroStar antenna has sufficient bandwidth to receive all existing and currently planned GNSS signals, while providing high performance standards. Testing of the antenna has shown that the novel design (curved petals coupled to crossed driven dipoles associated with a high performance LNA) has excellent performance, especially with respect to axial ratios, cross polarization discrimination and phase-center variation. These features make the VeroStar an ideal rover antenna where low-elevation angle tracking is required, providing users with new levels of positional precision and accuracy.

    ACKNOWLEDGMENTS

    Tallysman Wireless would like to acknowledge the partial support received from the European Space Agency and the Canadian Space Agency.


    REZA MOVAHEDINIA is a research engineer with Tallysman Wireless, Ottawa, Ontario, Canada. He has a Ph.D. degree in electrical and computer engineering from Concordia University, Montreal, Quebec, Canada.

    JULIEN HAUTCOEUR is the director of GNSS product R&D at Tallysman Wireless. He received a Ph.D. degree in signal processing and telecommunications from the Institute of Electronics and Telecommunications of Université de Rennes 1, Rennes, France.

    GYLES PANTHER is president and CTO of Tallysman Wireless. He holds an honors degree in applied physics from City University, London, U.K.

    KEN MACLEOD is a product-line manager with Tallysman Wireless. He received a Bachelor of Science degree from the University of Toronto. 

    FURTHER READING

    • GNSS Antennas in General

    “Antennas” by M. Maqsood, S. Gao and O. Montenbruck, Chapter 17 in Springer Handbook of Global Navigation Satellite Systems edited by P.J.G. Teunissen and O. Montenbruck, published by Springer International Publishing AG, Cham, Switzerland, 2017.

    GPS/GNSS Antennas by B. Rama Rao, W. Kunysz, R. Fante and K. McDonald, published by Artech House, Boston and London, 2013.

    GNSS Antennas: An Introduction to Bandwidth, Gain Pattern, Polarization, and All That” by G.J.K. Moernaut and D. Orban in GPS World, Vol. 20, No. 2, Feb. 2009, pp. 42–48.

    A Primer on GPS Antennas” by R.B. Langley in GPS World, Vol. 9, No. 7, July 1998, pp. 50–54.

    • Tallysman VeraPhase GNSS Antenna

    Static Testing and Analysis of the Tallysman VeraPhase VP6000 GNSS Antenna by R.M. White and R.B. Langley, a report prepared for Tallysman Wireless Inc., Feb. 2018.

    Evolutionary and Revolutionary: The Development and Performance of the VeraPhase GNSS Antenna” by J. Hautcoeur, R.H. Johnston and G. Panther in GPS World, Vol. 27, No. 7, July 2016, pp. 42–48.

    • The Alford Loop

    “Ultrahigh-frequency Loop Antennas” by A. Alford and A.G. Kandoian in Electrical Engineering, Vol. 59, No. 12, Dec. 1940, pp. 843–848. doi: 10.1109/EE.1940.6435249.

  • Septentrio expands SECORX-S GNSS receiver product line

    Septentrio expands SECORX-S GNSS receiver product line

    Septentrio’s SECORX-S GPS/GNSS receiver product line offers sub-decimeter accuracy without the need for additional positioning service subscriptions.

    The mosaic-Sx module. (Photo: Septentrio)
    The mosaic-Sx module. (Photo: Septentrio)

    Septentrio has expanded its SECORX-S product line. The multi-constellation multi-frequency GNSS receivers of the SECORX-S family deliver sub-decimeter positioning out of the box, without the need for any additional correction service subscription or maintenance.

    Users benefit from always-on high accuracy provided by a PPP-RTK correction service integrated directly into Septentrio’s latest core GNSS technology. The SECORX-S product line, already including GNSS OEM boards, now also offers a compact mosaic-Sx module as well as a ruggedized receiver in an IP68 chassis, AsteRx SB Sx.

    By adding modules and boxed receivers to the SECORX-S product line, Septentrio brings its innovative approach of plug-and-play accurate positioning to industrial applications including precision agriculture, UAV, robotics and construction.

    The AsteRs-m2-Sx. (Photo: Septentrio)
    The AsteRs-m2-Sx. (Photo: Septentrio)

    Receivers of the SECORX-S family offer lifelong sub-decimeter accuracy in U.S. and Europe. The PPP-RTK correction service integrated in these receivers uniquely combines near-RTK accuracy with short convergence time.

    “By launching the SECORX-S product family a few months ago, we have taken a ground-breaking step towards easy-to-use and accessible high-accuracy positioning,” said Francois Freulon, head of product management at Septentrio. “Our SECORX-S product range now includes compact modules, versatile OEM boards as well as boxed receivers. With this expansion of the product family our customers now have the flexibility to choose from a wider range of receivers, the one that perfectly fits their needs.”

    For more product details visit the SECORX-S product page or contact [email protected]. To find out more about positioning correction services, see “Septentrio demystifies GNSS corrections.”

  • U-blox technology platforms support BeiDou-3

    U-blox technology platforms support BeiDou-3

    logoCurrent u-blox GNSS platforms — from u-blox M8 and beyond — support the recently completed BeiDou navigation satellite system modernizations, improving the availability of GNSS positioning services.

    The opening ceremony of the BeiDou-3 global navigation satellite system (GNSS) was held in Beijing on July 31, officially celebrating the expansion of coverage offered by the critical Chinese space infrastructure to a global user base.

    As a global supplier of GNSS positioning and wireless communication technologies, u-blox has been driving technological innovation and deeply involved in the Chinese market for many years.

    Tests conducted across China and Europe have shown that including the BeiDou system can improve the positioning accuracy of GNSS receivers when multiple navigation satellite systems are tracked concurrently. When signals are partially obstructed, positioning accuracy can be significantly improved by incorporating the BeiDou system.

    Data shows that in 2019, the overall output value of the Chinese satellite navigation and location service industry reached nearly 345 billion yuan, an increase of 14.4% over 2018, with the output value expected to exceed 400 billion yuan in 2020.

    Chart: China Satellite Navigation System Management Office Test Evaluation Research Center
    Graphic: China Satellite Navigation System Management Office Test Evaluation Research Center

    Additional Services Provided by BeiDou

    The BeiDou system provides a suite of additional services, including satellite and ground-based augmentation services, precise single-point positioning, precise timing and global short message services, laying a solid foundation for BeiDou’s ubiquitous navigation and tracking applications.

    Applications of GNSS technology continue to diversify, leveraging the all-weather, all-time, tracking, navigation and timing services it offers. GNSS technology is penetrating deeper into traditional industrial verticals, such as agriculture, forestry, animal husbandry and fishery, power and energy, as well as in railway and air transportation, including their infrastructure construction and management.

    At the same time, GNSS technology has become an indispensable and “smart” factor in emerging application fields such as the internet of things and the “internet of vehicles,” as well as in innovative applications such as autonomous driving, automatic parking and automatic logistics, and is now commonplace in many industrial and consumer use cases.

    “U-blox has been closely following the modernization of the BeiDou navigation system and is ready to work with partners in various industries to promote the expansion of industry applications, expand emerging markets and jointly create a green industry ecosystem,” said Hamilton Chen, China country manager at u-blox.