Swift Navigation, a firm specializing in GNSS positioning technology for autonomous vehicles, looks back on a year of progress in 2019 and forward to what’s ahead in 2020.
2019 highlights include the expansion of operations to Australia, continued Firmware Releases to improve Swift’s multi-band, multi-constellation GNSS receivers, the expansion of Skylark cloud corrections service across the United States and announcing a partnership with Arm to bring precise positioning technology to autonomous vehicle compute platforms.
While Swift is proud of these accomplishments, the company is most excited about its shift from a company providing RTK GNSS receivers to one that provides a full ecosystem of precise positioning GNSS solutions for autonomous and mass-market applications.
Swift has made it possible for customers and partners alike to incorporate Swift’s patented technology into a multitude of autonomous platforms.
From the receiver-agnostic Starling positioning engine that enables the accuracy of Swift GNSS receivers and opens it up for industry use, to cloud-based corrections delivered nationwide with Skylark, Swift is poised to bring precise positioning to those who can benefit from centimeter-level location accuracy the most — autonomous platforms and applications.
While Skylark and Starling work independently with many leading industry components and receivers, it is the two paired together that makes the precise positioning powerhouse that will make 2020 a pivotal year for Swift.
At this year’s CES, the following Swift partners and customers are showcasing how they are integrating Swift’s precision positioning solutions in their platforms:
Arm — a global leader in semiconductor IP — utilizes Starling to deliver a high-integrity, high-accuracy GNSS positioning solution enabling automotive OEMs, as well as Tier 1 and 2 auto suppliers, to integrate precise positioning into their sensor suite. Arm is hosting meetings by appointment on Level 2 of the Venetian at Veronese 2505 and Veronese 2506.
STMicroelectronics — a global semiconductor leader — provides GNSS measurement engines and ASIL-rated processors for autonomous driving and high-accuracy GNSS solutions. ST has integrated Starling on the ST ASIL-rated Telemaco Platform for OEM applications. ST is hosting meetings by appointment only at their Hospitality Suites during CES 2020.
Aceinna — a provider of sensing solutions — announced its OpenRTK330 precise positioning module at CES. The new OpenRTK330 is based on the ST TeseoV receiver and includes three ST ASM330LHH IMUs for inertial measurements. Skylark is the preferred corrections provider for the OpenRTK330 and evaluation kits. Aceinna will be demonstrating its new module in booth 6738 in the North Hall Automotive pavilion.
See Swift in action at the CES locations above or contact the Swift team at [email protected] to schedule a meeting.
Module designed for developers creating guidance and navigation systems for autonomous vehicles, robots, drones, industrial, construction and agricultural machinery
Aceinna launched its OpenRTK330L at CES 2020, the massive annual consumer electronics show taking place Jan. 7-10 in Las Vegas. The company is located at Booth 6738, CES North Hall, Automotive Pavilion.
OpenRTK330L is a low-cost,high-performance triple-band RTK/GNSS receiver with built-in triple redundant inertial sensors. Designed to replace the expensive and bulky precision RTK/INS systems used in today’s autonomous systems, the compact navigation solution meets the challenging performance, reliability and cost requirements of the automotive market along with the needs of robot, drone, construction and agriculture systems, Aceinna said.
Demonstration Drive
Aceinna is demonstrating its GNSS/INS-based autonomous vehicle localization technologies on its test vehicle, which drove from Silicon Valley to Las Vegas.
The company is recording live drive-test data that demonstrates how its precision positioning solutions provide high accuracy and reliability. Precision location capability is critical for all levels of autonomous driving.
OpenRTK330L includes a triple-band RTK/GNSS receiver coupled with redundant inertial sensor arrays to provide cm-level accuracy, enhanced reliability, and superior performance during GNSS outages.
The OpenRTK330L integrates a precise 2 Degree/Hour IMU to offer ten to 30 seconds of high accuracy localization during full GNSS denial. This enables autonomous system developers to safely deliver highly accurate localization and position capabilities in their vehicles at prices that meet their budgets.
Image: Aceinna
OpenRTK330L’s embedded Ethernet interface allows easy and direct connection to GNSS correction networks around the world. OpenRTK330L’s CAN bus interface allows simple integration into existing vehicle architectures.
The multi-band GNSS receiver can monitor all global constellations (GPS, GLONASS, BeiDou, Galileo, QZSS, NAVIC, SBAS) and simultaneously track up to 80 channels. The module has RF and baseband support for the L1, L2 and L5 GPS bands and their international constellation signal equivalents.
The inertial measurement unit and dead reckoning function contains a total of 9 accelerometer and 9 rate gyro channels based on Aceinna’s unique triple redundant six-axis IMU array. By integrating a triple-redundant IMU array, the OpenRTK330L is able to recognize and utilize only valid sensor data, ensuring high-accuracy protection limits and certifiability under ISO26262 standards.
Open Navigation Platform
“The combination of a triple-band GNSS receiver and a high-precision IMU has enabled us to make a remarkably accurate, small, reliable and cost-effective GNSS/INS solution,” said Mike Horton, CTO of Aceinna. “The OpenRTK Precise Positioning Engine optimizes satellite tracking and high RTK fixes rates while integrating seamlessly with Aceinna’s open-source, developer-friendly Open Navigation Platform.”
The Open Navigation Platform allows custom embedded application development on top of Aceinna’s positioning engine and dead-reckoning algorithms. Autonomous solution developers have full access to all resources on the OpenRTK330L module including the GNSS receiver measurement data, IMU measurement data and all interfaces.
The OpenRTK330L GNSS receiver supports GPS (L1 C/A, L2C and L5), GLONASS (L1OF, L2OF), BeiDou (B1I, B2I), GALILEO (E1, E5a, E5b, E6) QZSS (L1 C/A), and NAVIC. The IMU sensor array includes a triple-redundant, 3-axis MEMS angular rate sensor, and a triple-redundant, 3-axis MEMS accelerometer.
Hardware also includes, Ethernet, UART, SPI and CAN interfaces for versatile integration into a host system. Additional specifications include operating temperature range of -40C to +85C, and qualification to standard automotive shock and vibration levels.
Septentrio’s GNSS devices are being used for high-accuracy positioning solutions by two companies.
Compact multi-frequency GPS/GNSS receiver module provides robust centimeter-level positioning for advanced driver assistance systems (ADAS) provided by NXP.
Septentrio and Analog Devices collaborate on high-performance GNSS/INS solutions.
Image: Sepentrio
NXP V2X Integration
NXP, a leader in communication technology for embedded applications, is integrating Septentrio GNSS technology into its V2X (vehicle-to-everything) reference design and development boards.
Septentrio, a leading high-accuracy GNSS positioning company, is providing to NXP its mosaic module. Mosaic is a multi-frequency, multi-constellation GNSS receiver that delivers accurate and reliable global localization even in harsh environments.
V2X technology enables cars to communicate with infrastructure as well as other vehicles, making driving safer and more efficient. It enables cars to “see” what’s around the corner or through the dense urban environment warning the driver about road works, traffic congestion and emergency vehicles.
Precise GNSS-assisted localization combined with V2X communication enables a wide array of ADAS functionality such as automatic braking if slowing traffic is detected ahead or truck platooning.
Septentrio’s mosaic is a compact high-accuracy GNSS receiver module which is integrated into NXP’s V2X development boards. True multi-frequency multi-constellation technology gives mosaic access to every possible signal from all available GNSS constellations including the U.S. GPS, European Galileo, Russian GLONASS, Chinese BeiDou and Japanese QZSS satellites.
Septentrio’s advanced, field-proven algorithms exploit this signal diversity to deliver maximum positioning availability even in difficult environments such as under foliage or in urban areas.
“Reliable lane-accurate positioning is vital for many road-safety applications of V2X, such as queue and emergency stop warnings or blind spot warning,” said Andrew Turley, NXP’s senior director of innovation and V2X business development. “Septentrio’s unique easy-to-integrate GNSS module provides field-proven, reliable and robust positioning. Integration of mosaic into our reference design gives our customers a direct solution for developing these and other advanced V2X services.”
”We are excited that NXP selected our GNSS solution for their V2X reference design,” said Jan Van Hees, business development director at Septentrio. “NXP is a world-leader in complete solutions for V2X communications for active safety systems and intelligent transport system (ITS) management. Working with NXP gives us an excellent opportunity to bring the best of V2X and reliable GNSS to our customers.”
Inside a car GPS signals can become “jammed” by nearby electronics or illegal devices called “jammers” which are used by some drivers to avoid road tolling. mosaic uses jamming-resistant signal processing making it robust against interference. Its design is centered around continuous, reliable high-accuracy positioning making mosaic suitable for safety-critical applications such as ADAS and autonomous navigation.
Consumer Electronics Show. The Septentrio mosaic GNSS module will be showcased at CES in Las Vegas, January 7-10. Visitors are welcome to see mosaic and talk to Septentrio GPS experts about V2X, ADAS, INS and other automotive positioning solutions in booth 1135 at the Paradise West Center. A personal meeting can be booked in the Septentrio Suite at the Westgate Las Vegas Resort & Casino.
Combining with Analog Devices on INS
In December, Septentrio announced a collaboration with Analog Devices. The two companies are combining Analog Devices’ high-quality inertial measurement units (IMUs) with Septentrio’s multi-frequency, multi-constellation GNSS receivers.
The resulting high-performance GNSS/inertial navigation systems (GNSS/INS) deliver centimeter-accurate positioning together with 3D orientation (heading, pitch and roll), suitable for applications such as automotive ADAS and industrial automation.
“We are excited to work with Septentrio,” said Tony Zarola, general manager of inertial sensors, Analog Devices. ”Septentrio’s GNSS technology provides a unique combination of accuracy and robustness which is aligned well with the capabilities of our sensors. The company’s deep know-how of GNSS and focus on providing reliable solutions even in harsh environments complements Analog Devices’ focus to solve the toughest engineering challenges for our customers.”
“ADI’s high-end industrial IMU systems are a reference in the industry and we are very pleased to be working together with them,” said Danilo Sabbatini, product manager at Septentrio. “Combining ADI’s IMU experience with our GNSS expertise enables creation of high-performance, easy-to-integrate systems that allow our customers to tackle demanding applications. As a result, customers can expect a faster go-to-market due to the interoperability between the GNSS and INS components.”
Septentrio will incorporate Analog Devices’ advanced industrial-grade IMUs into a selection of its GNSS/INS products. Working directly with Analog Devices allows Septentrio to provide faster and more efficient GNSS/INS integration solutions for high-volume customers. This collaboration promises a solid foundation for design and production of top-performance integrated positioning and inertial solutions, with first products available in spring 2020.
A roundup of recent products in the GNSS and inertial positioning industry from the November 2019 issue of GPS World magazine.
SURVEYING & MAPPING
IMU-RTK receiver
Increases GNSS availability and reliability
Photo: CHC Navigation
The i90 IMU-RTK GNSS series receiver is designed to dramatically increase GNSS real-time kinematic (RTK) availability and reliability. The i90 is powered by the company’s latest inertial measurement unit (IMU) and RTK technology to provide robust and accurate GNSS positioning in any circumstances. Unlike standard micro-electro-mechanical (MEMS)-based GNSS receivers, the i90 GNSS IMU-RTK combines a high-end calibration and interference-free IMU sensor with a state-of-the-art GNSS RTK engine and advanced GNSS tracking capabilities. The i90 is designed to increase the productivity and reliability of survey projects, with no complicated calibration process, rotation, leveling or accessories are necessary. A few meters’ walk will initialize the i90 internal IMU sensor and enable RTK survey in difficult field environments. The i90 GNSS automatic pole-tilt compensation boosts survey and stakeout speed by up to 20%.
Both accurate and rugged for machine control, logistics
The AsteRX-SBi has a rugged housing, making it suitable for machine control and other outdoor uses. (Photo: Septentrio)
Septentrio has expanded its GNSS/INS portfolio with the AsteRx SBi, a new housed GNSS/INS receiver. The ruggedized AsteRx SBi fuses high-accuracy GPS/GNSS with a high-performance inertial sensor to provide reliable positioning and 3D orientation for machine control and logistic applications. Within its rugged, waterproof enclosure, a high-performance GPS/GNSS is coupled with an industrial-grade inertial sensor to provide high-accuracy, reliable positioning and 3D orientation (heading, pitch, roll). Offering the flexibility of either single or dual antenna, the AsteRx SBi is designed for quick and easy integration into any machine monitoring or control system. Reliable location and 3D orientation data is streamed with a high update rate and constant low latency. Septentrio’s reliable centimeter-level positioning is based on true multi-frequency, multi-constellation GNSS (GPS, GLONASS, Galileo, BeiDou, QZSS) technology.
The Trimble X7 laser scanning system is designed for surveying, construction, industrial and forensic applications. It enables professionals to quickly and easily capture precise 3D scanning data to produce high-quality deliverables. The X7 features Trimble X-Drive technology, survey-grade self-leveling and a smart calibration system. It integrates streamlined workflows to provide automatic registration of point-cloud data in the field with Trimble Registration Assist, bringing scans together through self-leveling inertial measurement unit technologies and cloud-based software.
The Bluesky MetroVista range includes high-resolution imagery combined with high-accuracy, wide-scale 3D models. (Image: Bluesky)
The MetroVista city mapping service for Europe incorporates the Leica CityMapper hybrid airborne sensor designed for 3D city modeling and urban mapping. The sensor includes a vertical camera and survey-grade oblique cameras, and incorporates lidar to accurately collect elevation and infrared data. The MetroVista range includes high-resolution imagery combined with high-accuracy, wide-scale 3D models. CityMapper has already been used to capture MetroVista data for cities across the United Kingdom, including London, Manchester, Newcastle and Bristol.
The enhanced GSS9000 series GNSS constellation simulator has been updated to provide significantly improved capability, flexibility and performance to meet the test needs of high-performance navigation systems. It doubles the number of supported channels (320 in a single chassis) while maintaining its full performance specification in key areas such as signal iteration rate and low latency under maximum signal dynamics. These attributes, together with the ability to produce a comprehensive range of emulated multi-GNSS, multi-frequency RF signals, enables full and future-proofed testing of advanced applications. Greater signal flexibility is also built into the enhanced GSS9000 through its open application program interface (API) and flexible architecture. This delivers a highly sophisticated arbitrary waveform generator (AWG) capability.
Rx Networks has added NavIC constellation support to its real-time and predicted-assistance data service. The company’s technology partners — semiconductor vendors, mass-market mobile device manufacturers and network operators — now have global support for all satellite navigation systems and L1 satellite-based augmentation systems (SBAS) for any region around the world. Used daily by more than two billion devices, Rx Networks data is delivered via ephemeris in RINEX and via the Location.io interface, with predictions in SP3. Predictions for NavIC via the Location.io platform will be added in the first quarter of 2020.
Endura micro-electro-mechanical system (MEMS) timing solutions are designed for aerospace and defense applications including precision GNSS. They provide high performance in harsh conditions such as severe shock, vibration and extreme temperature. SiTime offers customers 5 million possible part numbers that can be created from 17 programmable products. Solutions accommodate 4 parts per trillion per g force of acceleration (50 times better than quartz); support for –55° C and +125° C operation; timing specifications conforming to MIL-PRF-55310; and Endura Super-TCXOs (temperature compensated oscillators) for use in GNSS applications.
Portos Team paired with the Ninja. (Photo: IP-Solutions)
Portos Team is a new GNSS RF signal record-and-playback system. It can record and play back — or simulate —multi-frequency, multi-system GNSS signals when paired with the company’s Replicator. It can do the same for CRPA signals when paired with the company’s Ninja. The Portos itself can also operate as multi-frequency or CRPA front end for a GNSS software receiver.
The DWM1004 module targets time difference of arrival (TDoA) tag applications that require years of battery life and a compact design. Based on the DW1000 chipset, the DWM1004C offers high-accuracy, real-time-location capability with a 6.8-Mbps data rate. It delivers more than five years of battery life. Real-time location systems (RTLS) enable managers to have a real-time view of their operations through data collected from connected objects such as tools, pallets, forklifts, badges and collars. The DW1000 is immune to multipath fading, with 2-centimeter precision in indoor environments.
The F9P Sirius RTK GNSS rover is designed to be mounted on a moving vehicle. The u-blox ZED-F9P module inside provides 1-cm position accuracy, a convergence time under 10 seconds and a navigation update rate up to 20 Hz. The rover has a built-in active antenna patch. It receives GPS, Galileo, Beidou and GLONASS signals, providing additional accuracy. It is designed to fit most setup designs as well as integrate easily into a vehicle. Its six-pin JST-GH connector makes it plug-and-play with the Pixhawk Pro 3 autopilot.
The VBOX Touch is a highly flexible GNSS datalogger with enhanced accuracy. The powerful hardware can be used diverse automotive tests such as acceleration, braking, speed verification, tire temperature monitoring, lap-timing and durability. The VBOX Touch comes preloaded with a sophisticated performance application that covers common use cases; applications can be downloaded from an online library. Racelogic can also write custom Python scripts based on customer requirements.
The LG69T GNSS module is an automotive-grade dual-band high-precision GNSS module that integrates dead-reckoning (DR) and real-time kinematic (RTK) technologies. The module facilitates open-sky positioning performance with an accuracy of up to 10 centimeters. It supports next-generation precision positioning capabilities for smart vehicles and autonomous driving scenarios. The LG69T module is based on ST’s STA8100GA, the latest automotive-grade dual-frequency positioning chip with 80 tracking channels and four rapid-acquisition channels compatible with GPS, BeiDou, Galileo, Navic and QZSS. The AEC-Q100-qualified dual-band module integrates multi-band RTK technology for centimeter-level accuracy. The LG69T module’s dead-reckoning capabilities feature an integrated inertial measurement unit (IMU) that provides continuous high-precision positioning.
The Coach II antenna with GNSS L1/L2/L5 is designed to provide greater precision and reliability for advanced rail communications systems, enabling next-generation positive train control (PTC) and passenger Wi-Fi. The Coach II features global multi-GNSS compatibility, dual-port 4G LTE / sub-6 GHz 5G NR and 802.11ac Wi-Fi / Bluetooth connectivity. It is AAR compliant for railway applications and is IP67-rated.
Includes new automotive package for Ellipse GNSS/IMU products
Photo: SBG Systems
New features have been added to the Ellipse product line with firmware update version 1.7. The update better answers needs of the autonomous testing and driving markets such as a CAN odometer. Users now have the choice to connect an external odometer (DMI) with pulses or use their car odometer with velocity information. New outputs include body velocity and slip angle, which calculate the drift angle between the vehicle’s assumed trajectory and its actual trajectory. For precision applications as well as low dynamics and reduced warm-up time, the new firmware allows users to run the Ellipse Kalman filter with no lever-arm estimation. This will ensure centimeter pass-to-pass accuracy for real-time kinematic (RTK) applications and allow operation in lower dynamics while reducing warm-up time. The firmware update also provides new features for advanced marine applications.
GNSS and inertial navigation sensors are meeting the challenges of extreme conditions, from freezing Arctic ice to the edges of steaming volcanoes, from high-speed aircraft over cities to the subways under them. Even beyond, into deep space.
IN THE ARCTIC
Wave Buoys Help Study Arctic Climate Change
Where the edge of Arctic ice transitions to open water, towering seas are smashing sea ice into melting pieces, with far-flung effects on climate and nature. Over recent decades, the Arctic has warmed more than any other region, leading to a significant reduction in sea ice volume. The combination of increased ice-free area and more mobile ice cover has led to the emergence of a seasonal marginal ice zone (MIZ) in the Beaufort Sea, north of Prudhoe Bay, Alaska.
The United States Office of Naval Research conducted a five-year study of the MIZ, which included intense field work in the freezing Arctic sea. Here, the ice is vulnerable to ocean surface waves that form in the open water, resulting from strong winds and frequent storms. Also studied were in-ice waves, where ice and water clash. The goal was to understand how both factors impact the ice floe melting.
The MIZ lies in the subarctic seas in winter and transitions into the interior of the Arctic Basin in summer. To investigate the MIZ’s dynamics, ONR engaged an international program of observations and simulations using several autonomous systems, including wave buoys. The wave buoys — officially designated the autonomous ocean flux buoys — integrate SBG Systems’ miniature inertial sensors.
The MIZ study comprised an international team of scientists from more than a dozen organizations.
Buoys for All Seasons. The program included 20 buoys deployed in the summer, and five in the winter, to quantify open ocean and in-ice wave characteristics and evolution. “We needed a very rapid and cost-effective solution to measuring directional wave spectra in the ocean,” said Martin Doble, oceanographer at the French UPMC School and member of the research program. “Time to deployment was very short, so an integrated solution, giving us good heave numbers straight out of the box, was essential. Delivery time of the units was also critical.”
Drilled into the ice, the summer buoys were powered with solar panels and equipped with SBG Systems’ IG-500A miniature attitude and heading reference system to detect both distant and near-wave effects on the local ice floe. Once the ice melted, the summer buoys continued to measure open ocean characteristics.
Five winter buoys were installed on the ice. These buoys were made of aluminum for better resistance and contained enough battery power to keep them going through the dark winter months. Every buoy also contained processing and control electronics, an SD card, a GPS receiver and an Iridium satellite modem and antennas to transmit the recorded data to its base station. Both summer and winter data from the buoys were used to quantify the wave attenuation rate.
Winter buoy installed on an ice floe. (Photo: SBG Systems)
By measuring the waves and ice, the buoys help scientists understand how waves are approaching and breaking up the sea ice. When winter approaches and ice begins to refreeze, the buoys help show how the waves interact with the ice as the temperatures change.
Calibration. The IG-500A inertial sensors were used for wave height and direction. IG-500A measures in real time the roll, pitch, heading (accurate to 0.35°) and heave (accurate to 10 centimeters). Every sensor is calibrated for bias, linearity, gain, misalignment, cross-axis and gyro-g from –40° to +85°C. The calibration is key to enabling the sensors to provide reliable data in the harsh environment.
Doble said the units were reliable, with no failures in the harsh Arctic conditions. They ran continuously for more than a year without requiring power cycling, and “the numbers look good, giving clear results.”
The data is helping researchers understand the physics that control sea ice breakup and melt in and around the ice edge. “We have this amazing picture of the ocean, atmosphere, and ice going from the fully frozen period in March to meltdown and breakup right through to freeze-up,” said Craig Lee of the University of Washington’s Applied Physics Laboratory.
The IG-500A sensors also delivered heave measurement, important for instrumented ocean buoys. During the project, SBG Systems released the Ellipse Series, and the new line replaced the IG-500 series. More accurate in attitude and more reliable (with an IP68 rating) for the same budget, the new miniature inertial sensors now provide a heave measurement that automatically adjusts to the wave period, resulting in higher performance.
Clear differences were measured between surface wave activity outside of the ice, and then moving into the ice, with huge attenuation as the waves enter the ice and die back quickly.
Current Arctic Program. Following the close of the MIZ project in 2015, the ONR launched a new project for 2016–2020, the Stratified Ocean Dynamics in the Arctic (SODA). SODA is also taking place in the Beaufort Sea, and is using the autonomous ocean flux buoys. The buoys are now equipped with SBG’s Ellipse-A sensors.
Why the Arctic Matters
“There’s no question that the Arctic sea ice extent is decreasing,” said Martin Jeffries, program officer for the ONR Arctic and Global Prediction Program. “Multiple sources of data — autonomous underwater gliders, ice-measuring buoys and satellite images of the marginal ice zone — were used to help understand why the ice is retreating.”
The implications for the U.S. Navy, and the world, are significant. If there were no sea ice in the Arctic at the end of summer, that would mean that the Arctic Ocean would, until the winter ice came in, be completely open — something unprecedented in living memory, Jeffries noted.
Naval leaders have made it clear that understanding a changing Arctic is essential for the Navy to be prepared to respond effectively to future needs.
“[T]he opening of the Arctic Ocean has important national security implications as well as significant impacts on the U.S. Navy’s required future capabilities,” said then Chief of Naval Operations Admiral Jonathan Greenert, in his introduction to the U.S. Navy Arctic Roadmap, 2014–2030, published in 2014. “The United States has a history of maritime homeland security and homeland defense concerns in the Arctic Region […] .”
In the period between 2007 and 2014, satellites recorded the eight lowest sea ice levels ever. A key goal of the MIZ and SODA programs is to use the new data collected to make better predictive computer models — ensuring safer operations for not only naval vessels, but also anticipated increased sea traffic by shipping and fishing industries; oil, gas and mining companies; and tourism operations.
Much of the data coming in to Arctic scientists is now from improved sensors, with greater ability to survive the harsh weather and ocean conditions.
Inside the Ellipse
Alexis Guinamard, chief technology officer of SBG Systems, described to GPS World the company’s most advanced sensor for extreme environments.
“Of course we have more precise sensors like Ekinox, Apogee or even Horizon, for ‘extreme’ precision. But for extreme environments, the more appropriate sensor line is the Ellipse series,” Guinamard said. “There are several key parameters that make them better for this kind of environment.”
Those features include a high-temperature calibration range, from –40°C to +85°C, which enables the sensors to operate at the same performance level in the most extreme temperature environments.
“While typical entry-level or industrial-grade sensors only provide a room temperature or basic temperature calibration, we have developed a calibration procedure used for both survey-grade and industrial-grade sensors using a precision two-axis rotary table with temperature chamber,” Guinamard said. “An advanced thermal modeling minimizes the calibration error over the full temperature range.”
Ellipse-D dual-antenna mini INS/GNSS. (Photo: SBG Systems)
The sensors work in highly dynamic and vibrating environments because their gyros operate well, changing position up to 900° per second. Similarly, their accelerometers can reach up to 40 g, with excellent behavior in vibrating environments. “We can typically install our sensors directly on the chassis of the vehicle, while lower grade sensors may require specific dampers that are complex to design and make it difficult to precisely align the sensor,” Guinamard said.
A GNSS interference-mitigation capability enables the sensors to perform in challenging GNSS environments.
With the Ellipse-D, high latitude operation is possible because it provides a dual-antenna heading that is insensitive to higher latitudes, Guinamard explained.
Saltwater-Proof. SBG Systems sensors typically have waterproof (IP68) enclosures that can deal with harsh conditions and sustain exposure to saltwater for a limited period of time. For long exposure to salt water, the company offers specific titanium enclosures. For instance, its Navsight series has a saltwater-proof inertial measurement unit.
Navsight marine solution. (Photo: SBG Systems)
The Navsight Marine Solution is a motion and navigation solution for hydrographers available as a motion reference unit (MRU), as an inertial navigation solution (INS) with embedded GNSS, and as an INS using a third-party GNSS receiver.
Navsight can be outfitted for demanding shallow- or deep-water environments to survey highly dense areas (bridges and buildings), as well as applications where only a single antenna can be used.
With the addition of the Horizon inertial measurement unit (IMU) to the Navsight line in January, which joined the Ekinox and Apogee IMUs, the line is suitable for large hydrographic vessels surveying harsh environments. The Horizon IMU is based on a closed-loop fiber-optic gyro (FOG) technology that enables ultra-low bias and noise levels, allowing robust and consistent performance.
Dust, noxious gas and loose rock near the summit makes volcanic surveying especially challenging. (Photo: Trimble)
AT VOLCANO’S EDGE
GNSS Tracks Magma on Mount Etna
Scientists seeking to better understand volcanoes are using GNSS to investigate one of the most active in the world.
Mount Etna, in eastern Sicily, Italy, has been erupting for hundreds of thousands of years. The constant activity makes it a popular tourist attraction — smoke often billows from the mountain and fiery lava spews down its sides.
Researchers flock to Mount Etna, too, to study the movement of magma — the hot fluid beneath the Earth’s surface from which rocks are formed when cooled.
To measure the vertical gradients of gravity on Mount Etna’s slopes and summit craters, geophysicists from Slovakia and Italy teamed up on a field campaign during which they used high-accuracy GNSS positioning with emphasis on accurate height measurements to collect gravimetry and topographic information.
The extreme environment and spotty cellular coverage on Mount Etna made using GNSS with real-time kinematic (RTK) or virtual reference station (VRS) a challenge. The geophysicists used the Trimble CenterPoint RTX correction service and Trimble R10 GNSS receivers to ensure reliable GNSS performance.
“On many points, especially the higher part of the volcano, Internet signals were poor or [there were] none at all,” said Juraj Papčo, a geodesist with the Earth Science Institute of the Slovak Academy of Sciences. “Only by using RTX were we able to collect real-time data. It performed well in higher elevations and difficult conditions.”
The project teams also used Trimble RTX to navigate to locations where they needed measurements. At each station, they collected static and real-time positions and later compared post-processed results with the real-time positions.
Dust, noxious gas and loose rock made approaching the summit especially challenging. Trimble RTX helped the Slovak-Italian team of geophysicists better understand volcanoes and anticipate volcanic events.
Researchers used high-accuracy GNSS positioning to collect gravimetry and topographic information. (Photo: Trimble)Prisms affixed to the track enable measurement of change and structural movement. (Photo: Topcon)
UNDER A METROPOLIS
Harsh Construction Environment Monitored
Deep beneath Paris, work is underway to expand the Metro, the city’s rapid transit system. The Grand Paris Express project encompasses a 200-kilometer-long network of railway lines — mostly underground — that will link the suburbs to the city.
The contractor responsible for monitoring construction of the first stage of the project’s infrastructure, Cementys, is using more than 100 instruments from Topcon’s MS series of robotic total stations because they can withstand the harsh construction environment.
Monitoring structural movement across the network is critical; the goal is to protect the surrounding Parisian structures and the people who live and work in them. Use of the monitors also ensures that the expensive equipment used on the project is not stolen.
Topcon’s MS Series robotic total stations continuously measure the angles and distances of prisms fixed to structures. As a result, site engineers know immediately when measurement change and structural movement occurs. The technology also includes Matrix Detection software to help increase the measurement system’s speed and accuracy. The company’s TSshield integrated security software, standard on all its total stations, provides remote locking and location positioning data to within 100 meters, depending on GPS and cellular coverage.
“We have been able to integrate this open technology perfectly into our global data management system, which also includes optical fibers sensors, vibrating wire sensors, and others,” said Cementys CEO Vincent Lamour.
Construction of the Grand Paris Express project is taking places in stages and is expected to be complete in 2030.
Photo:Position tracks from two laps of the race show that when the plane inverts and starts to track the reflected signal, the VN-300 GNSS/INS (blue trace) reverts to free inertial navigation and propagates the position based on inertial data. The trace follows a smooth trajectory through the next air gate until the GNSS data converges with the INS position. (Image: Google Earth with VectorNav Data)
ABOVE THE SEA
Flying High with Augmented Reality
The 2018 Red Bull Air Race World Championship in Cannes, France, made it easier for fans to follow along. Though pilots race one at a time, the new “Ghost Plane” augmented reality imagery provided fans with a real-time representation of each pilot’s flight, which challenges their speed, precision and skill maneuvering lightweight racing planes.
The Ghost Plane is driven by onboard telemetry data gathered during flight. For a pilot’s run to be accurately represented, the onboard telemetry system has to track position, velocity and attitude (yaw, pitch and roll) through high-dynamic maneuvers and in challenging environmental conditions.
While every Red Bull Air Race track layout is different, they all include a difficult vertical turning maneuver (VTM), where pilots pass through a gate and turn 180 degrees to reverse course quickly without exceeding the g limit.
Each plane is fitted with several GNSS receivers to track the plane, but dynamic maneuvers made during the race rapidly changes which satellites the GNSS receiver can track, which typically results in a loss of position fix.
To further increase the challenge for the telemetry systems, races are commonly held over water, which can reflect GNSS signals and create significant multipath errors at low altitudes. During the VTM, the plane can experience 300°/second angular rates and 12-g accelerations, during which GNSS tracking is typically lost because the antennas no longer point to the sky.
To make the Ghost Planes possible, a VectorNav VN-300 dual-antenna GNSS/INS (inertial navigation system) couples gyroscope and accelerometer data to propagate position and velocity estimates during loss of GNSS measurements through maneuvers such as the VTM.
The VN-300 combines two GNSS receivers with a 9-axis inertial measurement unit (IMU). It couples acceleration and angular rates from the IMU with position and velocity data from the receiver using a quaternion based Extended Kalman Filter (EKF). VectorNav algorithms work in conjunction with the state estimation filter, making the VN-300 more robust and intelligent, and enabling it to reject poor GNSS data and perform accurately in high-dynamic maneuvers and challenging operating conditions.
NEW EQUIPMENT
Antenna Designed for Challenging Environments
CHC Navigation’s latest GNSS antenna is an example of a product designed specifically for harsh environments.
AT311T antenna. (Photo: CHC Navigation)
The heavy-duty CHCNAV AT311T is designed for demanding applications subject to shocks and vibrations. With advanced filtering and robust signal tracking, it provides survey-grade GNSS signals to enhance position reliability for marine applications, machine control, precision agriculture and industrial automation.
Features include multi-constellation GNSS tracking using GPS, GLONASS, BeiDou, Galileo, QZSS, IRNSS and SBAS. Its IP68 water-resistant design makes it safe to use in extreme conditions with a wide temperature range (–40°C to +85°C). Its internal stacked structure enhances performance in high-interference environments, and the 40-dB signal gains, advanced signal filtering and multipath rejection design provide superior and robust GNSS signal tracking in challenging surroundings.
One of the two solar arrays on the InSight lander dominates this view of the plain of Elysium Planum, taken Dec. 4, 2018. (Image: NASA/JPL-Caltech)
IN OUTER SPACE
Exploring Beyond Earth
While GNSS isn’t useful on the surface of Mars, inertial navigation is a key technology for exploration of the red planet. For instance, the Northrop Grumman LN-200S sensor guided the Mars Opportunity rover, which explored Mars for 15 years until a storm struck in June 2018.
The LN 200S sensed acceleration and angular motion, with its data output used by the rover’s control systems for guidance.
The hermetically sealed unit, suitable for planetary and asteroid probes, helped position the rover’s antennae to relay photos and data to satellites. Opportunity beamed back 187,000 raw images, according to NASA.
Because IMUs don’t depend on satellites, they work well for deep space missions, Honeywell explained in a press release.
In November 2018, NASA’s InSight spacecraft landed on Mars to study the interior with a heat probe and listen for marsquakes with a seismometer. Aboard was Honeywell’s Miniature Inertial Measurement Unit (MIMU), an IMU that has been a part of Lockheed Martin’s Mars satellites and landers since 1998.
The MIMU is a three-axis strapdown device specifically designed for the satellite and deep-space-probe market (more than 500 MIMUs have been deployed throughout the solar system). It uses ring laser gyros to help control and stabilize a spacecraft during entry, descent and landing, as well as maintain orbit and payload orientation. The radiation-hardened design supports 15-year missions.
This tongue-in-cheek photo, courtesy of Racelogic, underlines how simulators help GNSS engineers “road test” multiple positioning products in multiple scenarios. (Photo: Racelogic)
The number of GNSS signals, the frequency and sophistication of intentional and unintentional threats to those signals, and the need for integration between GNSS and other positioning, navigation and timing (PNT) sources — especially for indoor and autonomous navigation — are continuing to increase, as is the number of new applications for GNSS. In response, manufacturers of GNSS simulators are creating new and improved models able to simulate all these new signals and scenarios.
Additionally, as GNSS chipsets continue to be further commoditized, simulator manufacturers must address the needs of new entrants into the GNSS receiver market that have lower accuracy requirements and require less technical expertise and, therefore, require units that are smaller and cheaper and have simpler interfaces.
No single manufacturer can address the full spectrum of challenges that these trends present. So, while their products overlap in capabilities and SWaP-C (size, weight, power and cost), each one has chosen its market niche and preferred mix of features.
Even on the deceptively simple question of definition (“What is a GNSS simulator?”), the seven manufacturers featured here give different answers, covering the following capabilities:
Simulating GNSS signals as well as inertial navigation data.
Enabling users to test hardware, software and new solutions in the lab before deployment.
Enabling users to test systems under pristine or extreme conditions, including error conditions.
Enabling users to test systems during rare, transitional and prohibited events.
Helping to retrofit existing equipment to new and emerging standards.
Innovations being introduced or developed include:
an anechoic simulator to test continuous radiation pattern antennas (CRPAs).
simulation of a full M-code modernized signal.
software-defined simulators.
increased automation of repetitive tasks.
the capability to record and replay real-world signals.
the capability to record and synchronize data on the conditions faced by a test vehicle.
While the universe of GNSS satellites and receivers continues to grow and evolve, the universe of GNSS simulators is keeping pace — or even a step ahead.
Click on the company to be directed to that section.
John F. Clark, Vice President, Engineering. (Photo: CAST Navigation)
In the lab, simulators allow users to “drive” a piece of equipment through 3D space, performing flight testing or checking equipment integration. Simulators also validate operational flight programs (OFPs) for pilots before they are fielded, to ensure that the software is working correctly.
Innovation. CAST’s latest simulator is the CAST 5000 wavefront generator. It allows users to drive GNSS and interference signals that represent a continuous radiation pattern antenna (CRPA), which consists of multiple, smaller antennas all combined into one unit. In real life, each one of those antenna elements is in a different location; therefore, when they receive signals from a jammer or any of the GNSS satellites, each one will see that signal in a slightly different phase from the other elements. “Our simulator allows us to present signals to these antennas that model the same type of phase differentiation that you see in real life,” Clark said.
Photo: CAST Navigation
Coming Next. CAST Navigation is constantly improving its software based on user feedback. “We are in the process of enhancing our user interface to make it much more powerful but also much simpler to use,” Clark said. Hardware is also being improved, with implementation of the latest available GNSS always on the list.
Looking Ahead to 2022. Jamming and spoofing are becoming more prevalent, not just for the military but also for consumers. Consumers are starting to encounter more instances of jamming, denying their phone the ability to track a GPS satellite or transmitting incorrect GPS data so the solution that their device gives them is not correct. “Our focus is on products and capabilities that help our customers simulate those types of environments and mitigate those kinds of reactions,” Clark said.
Jackson Labs Technologies Inc.
Said Jackson, President and CTO. (Photo: Jackson Labs)
Jackson Labs’ simulators take a position, navigation or timing signal, re-encode it into an RF signal through a GPS simulation procedure, and output a real-time RF signal that encodes the position, navigation and timing (PNT) information, within milliseconds, into an RF signal that can be fed into existing equipment. “We came up with a general-purpose simulator that is basically a no-frills, low-cost, highly accurate, highly stable, highly reliable, extremely small GPS-only simulator,” explained Jackson. “We only provide GPS L1 simulation, to keep the cost of the product down, because GPS L1 C/A code is the only code required to generate an accurate and assured PNT fix, and because we are looking at simulating to embedded systems, where you only need an L1 C/A code simulator.”
Photo: Jackson Labs
Coming Next. Jackson Labs’ simulators don’t require an external computer for data processing or control. That makes it possible for companies like Toyota to plug the unit into a car on the assembly line, and generate RF output that is fed into their GPS-based navigation systems to pass final quality-assurance checks on the production line. Jackson Labs expects to further reduce SWaP-C (size, weight, power and cost) requirements and potentially add other signals. “We are also looking to potentially combine our simulators with other product lines that we have, such as our comprehensive atomic clock product line,” Jackson said.
Looking Ahead to 2022. Jackson predicts that the sector will split into two paths: an industrial sector with units for manufacturing and deployment, and companies that introduce emerging GNSS systems at much lower price points, smaller SWaP, and with more modular deployment. Inertial navigation systems (INS) are critical for autonomous driving and assured capabilities during spoofing and jamming events, Jackson said. “It is not possible today to very easily simulate INS units.There is a market for innovation in terms of integrating what the military calls ‘assured PNT,’ which includes things like dual navigation.”
Orolia
Stéphane Hamel, Director, Testing and Simulation. (Photo: Orolia)
According to Orolia’s Hamel, a simulator’s purpose is two-fold: first, it must reproduce threats and second, it must prove the solution is working.
Innovation. When Skydel Solutions joined Orolia in March, it brought a professional software-defined simulator that makes possible fast prototyping and development cycles. It integrates advanced interference simulation and can simulate hundreds of threats simultaneously. “When you want to do a repetitive step, automation is the key,” Hamel said. “Our simulator can teach you how to automate, just by clicking on a button and generating source code.” In 2018, Skydel introduced an anechoic simulator to test Controlled reception pattern antennas (CRPAs). Also new is a waveform simulator, so CRPA units can be tested in a conducted (rather than radiated) way.
Image: Orolia
Coming Next. In the next three years, Orolia is looking at adding Galileo PRS, GPS M-code, or the next-generation signal. “Being software-defined means that we are very flexible and we can allow our partners to develop their own plug-ins,” Hamel said. “They can build custom signals, restricted or modernized signals. Our simulator will take care of the dynamics of the signal and our partners can focus on the characteristics of the signal, or the things that are secret, classified, or if they simply want to protect their IP.”
Looking Ahead to 2022. Resilience to serious spoofing and jamming threats is high on Orolia’s list, as well as ensuring secure or valid positioning, navigation and timing (PNT) in GPS-denied environments. Alternative signals, sensors and increased complexity require a simulator to address all of these. Companies that develop complex proprietary hardware platforms will be challenged to keep up with the increasing complexity. and a software-defined approach will be an advantage.
Racelogic’s first LabSat was a recorder with player — the signals were recorded outside, and then replayed in the lab. Racelogic’s simulators now also provide simulation of the signals using software to generate the signals as though they are being sent by the satellites.
Innovation. In 2018, Racelogic introduced the LabSat wideband, which uses the company’s SatGen software. It records at 56 MHz and up to 6 bits of resolution and streams the data to an internal SSD hard drive. It can also replay real-world simulations or ones generated with SatGen. For the automotive world, it records and replays signals such as CAN, RS232, RS485, IMU and other data channels, synchronizing them at the same time. VBOX allows users to record and replay video with the perfectly synchronized recording made on the LabSat. “You see exactly the kinds of conditions of the test vehicle or person who has been subjected to the test,” Thomas said.
Photo: Spirent
Coming Next. Racelogic is providing wider bandwidth, greater bit depth, and multiple channels in a small battery-powered device that records even more signals, including lidar, EtherCAT (an automotive Ethernet format) and CAN-FD (a faster version of the CAN format). It will be able to synchronize with multiple video cameras instead of just one in high resolution. “It is basically the same as what we are selling, but on steroids, and at a very similar price point,” Thomas said.
Looking Ahead to 2022. With multi-GNSS going mainstream, both chip manufacturers and simulator manufacturers will be challenged by the cost of test equipment. Chip makers need to be able to test the new signals on their production lines, while simulator makers will need to provide devices at a price point and ease of use for customers with less stringent or slightly less technical requirements. “They need a simpler interface and a smaller, cheaper unit,” Thomas said.
Rohde & Schwarz
Markus Irsigler, Product Manager, Signal Generators. (Photo: Rohde & Schwarz)
An increasing number of GNSS applications depend on multi-frequency GNSS.
Innovation. In response, Rohde & Schwarz added multi-frequency test capabilities to its entry-level and mid-range test solutions. “We have launched a new GNSS simulator based on the new mid-range vector signal generator R&S SMBV100B,” Irsigler said. A simple and flexible option concept allows users to turn the instrument into a full-featured and powerful GNSS signal source. It addresses a wide range of test applications, from single- and multi-frequency production testing to multi-frequency receiver characterization. The instrument can be equipped with an internal noise generator that allows users to simulate GNSS plus noise or CW interference without using additional external hardware.
Photo: Rohde & Schwarz
Coming Next. GNSS test solutions from R&S are based on general-purpose vector signal generators. With this approach, GNSS and other signals can be generated at the same time in the same instrument allowing coexistence and interference testing without additional external signal sources. As this results in test solutions that are compact and very flexible to use, R&S will continue to use this approach for upcoming product upgrades and enhancements as well as for its next generation of GNSS test solutions. The company’s upcoming activities will mainly focus on the high-end segment, where the R&S SMW200A with up to 4 RF outputs and up to 144 channels addresses multi-antenna and multi-vehicle GNSS test applications.
Looking Ahead to 2022. With the safety demands of autonomous driving or aircraft landing procedures, multi-frequency testing will become standard. Because such applications must be sufficiently robust against spoofing and jamming threats, there will be an increasing need to test navigation systems against such influences. “Simulating GNSS alone is not enough,” Irsigler said. “Test solutions for autonomous driving will require several other techniques and signals to be applied or simulated, such as RTK/PPP or outputs from other vehicle sensors to perform sensor fusion.”
Spirent Federal Systems
Roger Hart, Director of Engineering. (Photo: Spirent)
Spirent’s simulators test with “real-world” signals as well as allowing tests under pristine conditions or under extreme conditions that may never occur in the real world, including error conditions.
Innovation. In December 2018, Spirent released the SimMNSA, which provides a full M-code modernized signal solution. Until now, the GPS Directorate limited M-code simulation to either pseudo-M-code, which provides the same spread-spectrum but uses a commercial encryption standard, or a system of playing back a canned set of M-code limited to certain satellites and dates and times. With the policy change, Spirent can now implement M-code based on the modernized Navstar security algorithm (MNSA), and now offers both an M-code solution with the SimMNSA and a full Y-code with the SimSAAS.
Jeff Martin, Director of Sales. (Photo: Spirent)
Coming Next. Spirent plans to provide customers an increased channel count to help test multi-constellation, multi-frequency receivers against multipath, jamming and spoofing. “We are in a period of intense development in terms of AVs, UAVs, and so forth, which don’t use GNSS exclusively,” Hart said, explaining that Spirent is working on testing of GNSS/sensor-fusion platforms.
Looking Ahead to 2022. “As new interface specifications are released, we are proactive in developing new signals,” Hart said. Spirent also is supporting efforts to achieve assured PNT solutions. It is investigating interference-mitigation techniques such as algorithms, directional antennas, and other anti-jam technologies. Signal authentication is another need. “As the systems are becoming more integrated and networked, we are conscious of cyber-security threats and are looking in that area,” Hart said.
Photo: Spirent
Syntony GNSS
Cyrille Gernot, GNSS Receiver Development and Product Manager. (Photo: Syntony GNSS)
GNSS receiver manufacturers use simulators to ensure that their products are robust in challenging situations that can’t be clearly assessed using real-world data. “That’s where the GNSS simulator comes into play,” Gernot said, “by offering controlled and repeatable scenarios.”
Innovation. Syntony’s new pseudo-random-noise code (PRN code) server allows the GNSS simulator user to dynamically send the pseudo-random sequence modulating a carrier. It is especially useful for testing encrypted signals such as the GPS military signal or the IRNSS RS signal. “Access to encryption keys is extremely difficult for a simulator manufacturer to obtain,” Gernot said. “However, the simulator does not actually need to have knowledge of those encryption keys; only the resulting pseudo-random sequence to modulate is required.” The Syntony PRN server allows users to dynamically input their own pseudo-random sequences to be modulated on the target carrier into the simulator.
Coming Next. Syntony’s next simulator will simulate spoofing and synchronous multi-antenna signals for CRPA and antenna network testing.
Photo: Syntony GNSS
Looking Ahead to 2022. As the threat of spoofing and jamming increases, the receiver industry will have to develop countermeasures and mitigation strategies. One of the best methods remains the use of antenna arrays, Gernot said. “Antenna arrays allow for spatial discrimination that is especially efficient to counter spoofing, jamming or unintentional interferences.To meet the industry’s future demands, Syntony is already working on accurate simulation of antenna arrays while accounting for inherent errors such as inter-antenna phase and amplitude offsets and overcoming obstacles, including phase coherency at the output of the simulator RF channels.”
The OSA 5401 and OSA 5405 now enable power utility and broadcast networks to achieve sub-microsecond synchronization. (Photo: Business Wire)
Upgraded PTP grandmaster clocks deliver precise, robust timing in compact form factor
Adva has extended the capabilities of its compact Oscilloquartz PTP timing technology to enable power utility and broadcast networks to achieve sub-microsecond synchronization.
Now electricity companies can harness the accuracy needed for smart power grids, and media enterprises can meet key timing challenges, the company said.
The two upgraded solutions are the pluggable OSA 5401, a small PTP grandmaster clock, and the versatile OSA 5405, an integrated PTP grandmaster with dual GNSS antenna and receiver.
Both technologies have proved critical in the telecommunications industry, where they have been widely deployed across the globe. They offer outstanding precision and design density. Thanks to unique spoofing and jamming detection capabilities, they also provide high availability.
“This upgrade is big news for utility and media network operators looking to harness the most advanced innovation in their field. With our OSA 5401 and 5405 bringing new levels of accuracy and resilience to their infrastructure, they can reap the benefits of emerging bandwidth-intensive, latency-sensitive applications”
“This upgrade is big news for utility and media network operators looking to harness the most advanced innovation in their field. With our OSA 5401 and 5405 bringing new levels of accuracy and resilience to their infrastructure, they can reap the benefits of emerging bandwidth-intensive, latency-sensitive applications,” said Nir Laufer, senior director, product line management, Oscilloquartz, Adva.
“These devices are feature rich and incredibly efficient. But as well as their versatility, what really sets them apart is their extremely small footprint and low power consumption. This is key to bringing packet time distribution to the edge of network. With our technology ensuring sub-microsecond synchronization, smart grids can perform flexible, real-time decision making, as well as monitoring and automated maintenance. And for media companies, the possibilities for high-quality, interactive broadcasting from any location are enormous.”
The OSA 5401 and OSA 5405 now comply with the latest PTP profiles for time, frequency and phase synchronization in both power utility and broadcast networks. These include the IEC/IEEE 61850-9-3 Power Utility Profile for precise time distribution and clock synchronization in electrical grids with an accuracy of 1μs, and SMPTE 2059 for synchronizing video and audio equipment over packet networks.
By supporting NTP, both solutions also enable enterprises to run an on-premises NTP server for high levels of accuracy and uncompromised availability. What’s more, the OSA 5401 and OSA 5405 include advanced GNSS jamming and spoofing detection mechanisms, which are integrated in a centralized AI-based GNSS assurance toolkit.
Taking up zero real estate and using very little power, the OSA 5401 can be deployed in the most space-restrictive locations. Its capabilities include multi-constellation GNSS (GPS/GLONASS/BEIDOU) and accurate time and frequency recovery, even in challenging environments such as urban canyons.
Available in both indoor and outdoor variants, the OSA 5405 radically simplifies and extends the reach of GNSS antenna installation by allowing operators to forget about archaic and expensive RF cables and instead use simple Ethernet over copper cables or optical fiber.
With the OSA 5405, highly precise GNSS-sourced synchronization is supported by network-based SyncE and PTP backups for highly stable sub-microsecond timing accuracy.
“Our mission is to make precise, resilient and affordable timing available in every industry. Both our OSA 5401 and OSA 5405 have had a significant impact on communication service provider networks, supporting mass small cell rollout and the transition to 5G connectivity. Now we’re ready to bring accurate, reliable and cost-efficient PTP timing to the edge of power and broadcast networks,” commented Ulrich Kohn, director, technical marketing, Adva.
“One feature of these devices that will prove key to network operators in these industries is their unique spoofing and jamming detection capabilities. These work on two layers. Firstly, network elements identify disruption autonomously. Then, on top of that, a layer powered by AI analyzes information from multiple devices. Using machine learning, this delivers the highly sophisticated and extremely robust protection needed for machine type communication applications in energy grid protection and control,” Kohn said.
The UAS1 GNSS receiver module has been designed for UAV/UAS applications requiring centimeter accuracy in a small package. (Photo: Trimble)
Trimble has introduced a compact, high-precision GNSS board specifically designed for unmanned aerial systems (UAS).
The Trimble UAS1 has a simple connectivity and configuration to allow UAS system integrators to easily add satellite-based positioning — with the ability to upgrade its capabilities — using rugged connectors and Trimble’s easy-to-use software interface.
The new UAS1 incorporates the latest Trimble Maxwell technology with advances in high-precision GNSS positioning. Its GNSS engine with 336 channels is capable of tracking L1/L2 frequencies from the GPS, GLONASS, Galileo and BeiDou constellations for robust centimeter-level, real-time kinematic (RTK) positioning.
The compact board includes a broad range of receiver capabilities — from high-accuracy GPS-only to full GNSS features for positioning. Firmware options and features are password upgradeable, allowing functionality to be added as requirements change.
The receiver also supports fault detection and exclusion (FDE) and receiver autonomous integrity monitoring (RAIM). System integrators also have the ability to detect interference with the RF Spectrum Monitoring and Analysis tool embedded in the receiver.
“UAS manufacturers demand high performance, reliability and high-quality customized support for their positioning solutions,” said Thomas Utzmeier, general manager of Trimble’s Integrated Technologies Division. “The new UAS1 board delivers the latest GNSS technology in an easy-to-integrate form factor for UAV/UAS applications.”
Designed for easy integration and rugged dependability, the Trimble UAS1 has a Remote Network Driver Interface Specification (RNDIS) that enables manufacturers to access the web UI with the USB connector. As with similar Trimble embedded boards and modules, easy-to-use software commands can simplify integration and reduce development times.
Features also include integrated Trimble RTX technology, an industry-standard camera hot-shoe interface to geo-position photographs, and LED indicators for status checks. The Trimble UAS1 can also output to RINEX, a common postprocessing format.
The Trimble UAS1 supports Trimble CenterPoint RTX GNSS corrections, which enable precise and robust positioning without the use of a base station via a subscription service. CenterPoint RTX allows users to achieve better than 2-centimeter horizontal and 5-centimeter vertical accuracy.
Trimble’s UAS1 is suitable for UAS applications requiring centimeter accuracy in a small package. Manufactured and tested to Trimble’s highest quality standards, the compact design allows for easy setup, configuration and installation in a customers’
system.
Using a full metal shield (the form factor is 71 x 46 x 13 millimeters), the board’s design enables high-precision GNSS signal protection from electromagnetic interference (EMI) on the host UAS platform. In addition, the receiver is FCC- and CE-certified, which speeds compliance for the customer’s overall system and can reduce time to market.
Taoglas, a provider of next-generation internet of things (IoT) solutions, has launched Edge Locate, a GNSS L1/L2/E5 module that combines antenna, RF electronics and receiver technology to deliver reliable centimeter-level positioning.
Taoglas, in partnership with u-blox, created a smart antenna that uses multi-band GNSS technology, providing between 1- to 3-centimeter-level accuracy.
With Edge Locate, manufacturers can quickly and effectively build devices with centimeter-level positioning technology, without having to invest in costly and lengthy RF design, integration and testing processes.
The device features multiband GNSS positioning that can be used in conjunction with cost-effective real-time kinematic (RTK) positioning capability.
Traditionally, most IoT devices use single-band GPS technology, delivering on average 10-meter accuracy with existing GPS modules and antennas, Taoglas said in a press release. This enables location-specific, mission-critical services such as emergency response, smart infrastructure, precision agriculture and microbility mobility applications where precise location provides critical value to the IoT application.
Taoglas can also consult and install the RTK network in any global location for any IoT use case.
“Centimeter-level positioning is absolutely key to the next-generation of IoT enabled applications,” said Ronan Quinlan, Co-CEO of Taoglas. “Take an example from the burgeoning micro-mobility industry. When granting licenses from a trial, the city authorities would like to monitor the riders of e-scooters, ensuring riders are staying off footpaths, or parking in designated areas. The problem is that today’s legacy GPS solutions don’t often know which side of the road a scooter is on. Whereas with our solution, fleet operators can pinpoint within just a few centimeters where a device is located. We do this by working with our customers to enable the whole solution and we make sure it works reliably in real life.”
Edge Locate can greatly accelerate the latest GNSS multiband product launch plans by offering a plug-and-play product that uses a common connector for integration into any electronics device. It also connects directly to the Taoglas Edge board for immediately connectivity options.
Taoglas is exhibiting at Mobile World Congress Americas, Booth 2602 in the South Hall of the Los Angeles Convention Center.
OriginGPS has collaborated with Broadcom to create a new miniature module with L1 + L5 support provided by the BCM47758 chip, enabling ultra-accurate GNSS positioning. The module was developed for solutions requiring super-precision GNSS and a dual-frequency combination.
Photo: OriginGPS
The ORG4600-B01 is OriginGPS’ first dual-frequency GNSS module. The module enables customers to build solutions with sub-1-meter accuracy without implementing external components.
Measuring 10 x 10 mm, the ORG4600-B01 module supports L1 + L5 GNSS reception with one RF port, enabling the use of a low-cost, dual-band antenna delivering sub-1-meter accuracy performance in real-world operating conditions.
Alternate Build. An alternate build option allows for separate L1/L5 RF outputs when dual antennas are required. The ORG4600-B01 is suitable for solutions requiring ultra-accurate positioning, such as telematics, the Internet of Things (IoT) and auto OBD applications.
“This year has seen several satellites launched into orbit every month, most of them fitted with L5/E5 capabilities, and the Chinese and European Union governments plan to have their satellite constellations fully operational by 2020.” said Haim Goldberger, CEO of OriginGPS.
Developing the ORG4600-B01 module with the BCM47758 GNSS receiver chip by Broadcom Inc. was the fastest and surest way to add a high-quality dual-frequency module to our portfolio and meet our customers’ increasing requirements for ultra-accurate GNSS modules,” Goldberger said.
“Size is a crucial parameter in GNSS dual-frequency solutions,” said Prasan Pai, product marketing director for the Wireless Communications and Connectivity Division at Broadcom. “The collaboration with OriginGPS has created the industry’s smallest dual-frequency module with ‘no compromise’ quality. For our customers seeking an ultra-accurate GNSS solution in a compact form factor, the ORG4600-B01 fits the bill. The collaboration enables Broadcom to reach new markets, such as precision agriculture, security, children tracking and fleet management.”
“OriginGPS is interested in additional partnerships to enable bringing advanced solutions to market quickly,” said Haim Goldberger, CEO of OriginGPS.
OriginGPS is presenting its products with real-life demonstrations at MWC 2019, Los Angeles, Oct 22-24, Booth S2938.
NavCom Technology Inc., a wholly owned subsidiary of Deere & Company, has released the Onyx multi-frequency GNSS OEM board.
Offering integrated StarFire/RTK GNSS capabilities, Onyx features 255-channel tracking, including multi-constellation support for GPS, GLONASS, Beidou and Galileo. It also provides high-performance in GNSS receiver sensitivity and signal tracking as well as patented multipath mitigation, interference rejection and anti-jamming capabilities.
Photo: NavCom
The new Onyx GNSS OEM board is a fully upgradeable GNSS receiver, allowing the receiver to be upgraded from free differential GPS signal sources such as WAAS to increased accuracy services with integrated features with StarFire, through software optioning alone.
The software-enabled features are sold in convenient software bundles, but can also be purchased individually, to suit changing application needs. Integrated StarFire is now simply activated via an over-the-air licensing system that sends a StarFire license via satellite directly to the StarFire-capable receiver from NavCom’s StarFire operations center.
StarFire, NavCom’s global satellite-based augmentation system (SBAS), provides real-time global 5-centimeter accuracy without a base station.
“The release of Onyx advances NavCom’s ability to grow products and services meeting the customer driven demands of uptime, accuracy, and feature rich capabilities,” said Steve Ault, NavCom’s GNSS product marketing manager. “NavCom continues to innovate the StarFire technology through the advanced capabilities inherent to Onyx which will be fully realized over the life of this new product.”
The new GSAGNSS Market Report is now available for download. The report provides a comprehensive overview of the GNSS market and the global industry, as well as a focus on EGNSS differentiators and synergies with Copernicus, according to the publisher, the European GNSS Agency (GSA).
Areas covered include:
A general overview of the GNSS market and a global industry overview.
Analysis of macro-trends affecting GNSS, including climate change and the circular economy, big data, artificial intelligence, the silver economy, cyber security and the sharing economy.
A review of the main GNSS market segments in detail, including trends and developments, forecasts for future shipments, revenues and the GNSS installed base, and a look into GNSS user requirements.
GNSS in Space. This year, the report features the “Editor’s Special: GNSS for NewSpace,” a section that introduces GNSS receivers in satellites and their relation to the evolving space sector.
GNSS market monitoring is a key activity of the GSA. Market monitoring supports GNSS stakeholders in their planning and decision-making, and offers a clear tool to understand GNSS trends and evolutions.
Since its launch in 2010, the GSAGNSS Market Report has become the go-to-source for information on the dynamic, global GNSS market segments and applications.