Tag: OEM

  • Rohde & Schwarz offers test system for A-BeiDou LBS

    Rohde & Schwarz and MediaTek have successfully completed the verification of location-based services (LBS) in the U-plane and C-plane for Assisted Beidou (A-BeiDou), China’s GNSS satellite positioning system.

    The R&S TS-LBS test solution allows mobile manufacturers, chipset manufacturers, test houses and network operators to verify chipsets and mobile devices in order to obtain permission to operate them in a particular network.

    The successful A-BeiDou verification of the MediaTek device under test (DUT) using the Rohde & Schwarz test system marks an important milestone in the GNSS evolution of positioning and navigation. According to Rohde & Schwarz, this was the first time that the setup could be used to validate and verify a device for A-BeiDou location-based services.

    The R&S TS LBS from Rohde & Schwarz is a test system for testing GNSS and network-based LBS. It consists of an R&S CMW500 as the base station simulator and an R&S SMBV100A GNSS simulator. The R&S CMW500 provides assistance data to the DUT and the R&S SMBV100A simulates the BeiDou satellites. The R&S TS-LBS test system can be used to obtain GCF and PTCRB certification as well as network operator-specific certification for chipsets and mobile devices.

    “We are delighted to collaborate with MediaTek and to contribute our test and measurement expertise to the development of A-BeiDou location based services,” said Alexander Pabst, vice president of Systems and Projects within the Rohde & Schwarz Test & Measurement Division. “Rohde & Schwarz already has a strong global footprint with testing solutions for A-GNSS, such as A-GPS or A-GLONASS, and for OTDOA/eCID. Thanks to our close cooperation with our partners, Rohde & Schwarz is committed to accompanying the evolution from existing to new satellite systems such as A-BeiDou with our innovative test and measurement solutions.”

    “MediaTek is committed to developing and testing the latest mobile technologies and standards to drive the industry forward,” said TL Lee, general manager of the Wireless Communications Business Unit at MediaTek. “We have worked closely with Rohde & Schwarz to develop and validate the test solution for A-BeiDou LBS, verifying the A-BeiDou proof-of-concept trial system based on the R&S TS-LBS and MediaTek DUT. This represents an exciting step forward in the evolution of LBS technology, enabling the mobile ecosystem to verify chipsets and mobile devices on the new LBS technology.”

  • NovAtel’s OEM7 7.03.00 firmware offers new and enhanced features

    NovAtel’s OEM7 7.03.00 firmware offers new and enhanced features

    NovAtel’s OEM7 v7.03.00 firmware is now available on all OEM7 receivers. The OEM7700, OEM719 and OEM729 can be updated to the 7.03.00 firmware, which supports new features like the SPAN Land Vehicle technology, direct inertial measurement unit (IMU) connections and tracking of the NavIC Indian regional satellite system on the L5 frequency.

    The SPAN Land Vehicle feature provides performance benefits specifically for extended loss of GPS signals, robust alignment routines and improved attitude performance for fixed-wheel land vehicle applications. During extended periods of GNSS outage, typically in low-dynamic operating environments or in dense urban canyons, the SPAN Land Vehicle feature optimizes integrated GNSS+INS performance to maintain accurate position, velocity and attitude.

    To achieve this, NovAtel uses intelligent vehicle dynamics modeling and its patented Antenna Phase Windup Technology. Intelligent vehicle modeling identifies IMU errors in the integrated GNSS+INS system that accumulate after extended GNSS outages and reduces the impact of those errors within the SPAN solution.

    NovAtel’s Antenna Phase Windup technology is used to sense changes in direction and, when combined with intelligent vehicle modeling, corrects for IMU errors in attitude (roll, pitch, yaw).
    Users can now connect SPAN enabled OEM7 receivers directly to the ADIS-16488 and Epson G320N IMUs using an SPI interface, and to the STIM300 IMU using RS422, without the need for an interface card.

    OEM7 receivers with NavIC L5 frequency tracking enabled will be able to access the test signals of the Indian Regional Navigation Satellite System (IRNSS) before it becomes operational (targeted for early 2018).

  • UAV solutions to be showcased at Intergeo

    UAV solutions to be showcased at Intergeo

    Contributing Editor Tony Murfin is on vacation this month. In place of his column, we bring you an advance look at an important UAV show as applied to surveying and mapping, and a story about drone use in surveillance.

    In the zone

    Legal issues, international market analyses and best practices will take center stage at the Interaerial Solutions Expo (IASEXPO), which will take place Sept. 26–28 in conjunction with Intergeo 2017 in Berlin, Germany.

    At IASEXPO, the international UAV sector will be demonstrating the potential for civil and commercial UAV applications. IASEXPO will consist of an exhibition, forum and the FlightZone for UAV demonstrations. About 150 providers from 25 countries are expected to represent the young drone market at the IASEXPO.

    IASEXPO’s practical forum will cover the latest topics with renowned experts. Visitors don’t have to walk far to switch between market overviews and expert presentations. The aim is to efficiently combine the trade fair and talks.

    IASEXPO Forum 2016.

    Regulations. As Germany’s drone regulations come into force this year, the legal aspects of using and operating UAVs is a key focus of the practical forum. Multicopters and drones weighing more than two kilograms can now only be flown in Germany by someone who holds a “drone driving license.” Pilots will be able to take the drone license test at the trade fair.

    Frank Wichert from project management company procow will detail the requirements and reveal the precise procedure that pilots must follow. Speaker Ulrich Dieckert is a lawyer and expert on the approval process; he specializes in exceptions to operating bans that hinder drone work.

    Market prospects. Kay Wackwitz, CEO of Drone Industry Insights, will present economic analyses of application opportunities and limits for UAVs, and discuss market developments and collaborations.
    UAV Issue Manager Ralf Heidger from German traffic control (DFS) will discuss how DFS tackles the challenge of drones in the air space and tracking them within the air-traffic-management system.

    Best practices.
    First-hand reports will provid examples of best practices in using drones for surveying and inspecting buildings and industrial complexes. Friedrich Wilhelm Bauer from Hannover University of Applied Sciences and Arts will highlight use of thermal-imaging technology for inspections. Benjamin Federmann from Aibotix-Leica will discuss the economic benefits of using drones in surveying and construction.

    The German Association of Copter Pilots will weigh the question of whether to “make or buy” needed drones and services. Answers come from success stories in niche segments such as 3D modeling and smart framing. Maik Neuser from Westnetz and Carlo Zgraggen from Aeroscout will discuss inspections in the energy sector.

    Other topics will be the use of drones in agriculture, forestry and disaster relief. Antoine Cottin from Carbomap and Bobby Vick from Precisionmapper will speak to the practical forum on drones used for surveying forests.


    Drones on patrol

    UAVs will soon be a common sight over border zones, crime hotspots and city streets in South Africa, as public safety and security officials and police departments discover the cost saving and efficiencies offered by drone patrol “armies,” according to Airborne Drones, a South African-based manufacturer of enterprise-grade drones.

    Airborne Drones Vanguard 35-km long range surveillance drone ready to take flight. (PRNewsfoto/Airborne Drones)

    Drones provide a solution to the limitations of other surveillance methods such as GPS tracking, CCTV camera observation, biometric surveillance and ground patrols. Aerial surveillance is increasingly being harnessed for security monitoring — traditionally, with costly helicopters. Drone surveillance present an faster and cheaper method of data collection.

    Specialized security drones can enter narrow and confined spaces, produce minimal noise, and can be equipped with night-vision cameras and thermal sensors, allowing them to provide imagery that the human eye is unable to detect. In addition, UAVs can quickly cover large and difficult-to-reach areas, reducing staff numbers and costs, and don’t require much space for operators.

    Autonomous, long-range security drones are at the vanguard of new policing methods, accoring to Airborne Drones. “Offering live video feeds to ground control stations, these drones can range autonomously over pre-programmed flight paths for extended periods of time, allowing for ongoing routine patrols across wide areas such as borders, maritime regions and high security installations.

    Should an incident be detected, ground crews can then follow objects or intruders from a safe distance, providing visual support to safety and security teams. UAVs can provide detailed visual documentation of sites, enabling effective analysis, risk management and security planning.”

    Around the world. Numerous countries are rolling out security drones to support public safety and defense initiatives”, says Airborne Drones. Israel has long harnessed advanced drones for military surveillance, and recently sold a fleet of “spy drones” to the Irish army.

    The U.S. FBI has used drones for surveillance and tracking for several years. In Australia, the new $50 million Defence Cooperative Research Centre will develop long-range drones, automated vehicles and robots to help Australian soldiers fight the wars of the future. India is looking to military-grade UAVs for maritime and other surveillance and intelligence gathering.

    In June, Brazil’s São Paulo became the first Latin American city to use drones for public security surveillance, and in July, Hamburg, Germany, deployed surveillance drones for the estimated 100,000 demonstrators at the G20 summit. In Australia’s New South Wales, the authorities are using helicopter and drone surveillance along the coast to protect holiday-goers from rip currents and sharks.

    UAVs are also instrumental in managing transport infrastructure safety and security and event security, from event security infrastructure to spectator and crowd control and safety, to overall health and safety planning.

  • Applanix, Waterloo U collaborate on autonomous vehicle tech

    Applanix, Waterloo U collaborate on autonomous vehicle tech

    Applanix is collaborating on advanced research for autonomous vehicle guidance and control systems with the University of Waterloo Centre for Automotive Research (WatCAR) in Ontario, Canada. Applanix is a Trimble company.

    Applanix will provide WatCAR with its positioning and orientation system for testing autonomous guidance and control systems in real-world conditions. Applanix will also provide the Trimble GNSS-inertial board set for integration with car systems and sensors to enable precise positioning.

    The Applanix POS LV is a robust, reliable and repeatable positioning solution for on- and off-road vehicles. Applanix technology will be used by WatCAR to assess the performance of the guidance and control systems on board their autonomous vehicles.

    The testing will take place in challenging weather conditions and environments including on roads under repair, with lane reductions and closures, are wet or covered in snow, and where there is poor visibility.

    An SUV in an anechoic chamber at WatCAR.

    Applanix will also provide WatCAR with Trimble on-board GNSS-inertial board set designed for high-performance, high-volume original equipment manufacturer applications. These products, currently used in a variety of autonomous vehicle programs, include the Trimble AP GNSS-inertial board set that includes a high-precision inertial measurement unit.

    Small, rugged and low powered, the AP board sets provide the precise positioning needed for autonomous vehicle applications as they navigate their environment. Designed for use on all sizes and types of vehicles, the AP boards feature Trimble’s high-performance precision GNSS receivers and Applanix’ IN-Fusion GNSS-inertial integrated technology that produces uninterrupted position, roll, pitch and true heading measurements of moving platforms. Integrating easily with vehicle sensors, the AP board sets provide precise vehicle control when interacting with a constantly changing environment.

    The relationship with WatCAR will aid in improving the core technologies that deliver high-end systems capabilities for a variety of Trimble markets.

    The Waterloo Centre for Automotive Research in Canada conducts advanced research to further automotive innovation and competitiveness. From active safety to automated driving through lightweighting and advanced powertrains, 130 faculty researchers comprise the largest university-based automotive activity in the country. Leading-edge studies for industry partners around the world enhance vehicles, components and their materials with new approaches and integration of innovative technologies.

    “We are excited to collaborate with the University of Waterloo and WatCAR on this leading research in autonomous vehicle technology,” said Louis Nastro, director of land products at Applanix. “Applanix has been committed to meeting the needs of autonomous vehicle manufacturers for more than a decade, as first demonstrated in the early days of the DARPA Grand Challenge. And today, we are also part of many autonomous vehicle programs deployed worldwide in commercial applications.”

    “The Trimble AP products, first introduced in 2009, are designed for use in small, mass market vehicles where size, weight and cost factors are important,” Nastro said. “They have also been designed to easily integrate with the industry’s leading sensors, making them an ideal solution for autonomous vehicle navigation systems and sub-systems.”

    “We welcome the opportunity to work with Applanix, a leader in reference systems. Their technology identifies, with very high accuracy, the exact location of our vehicle at all times,” said Ross McKenzie, managing director at WatCAR. “Applanix is a valued industry partner and their team is great to work with. Going forward we anticipate a solution that will enable autonomous vehicles to traverse the real world reliably and safely.”

  • Polynesian Exploration launches high-accuracy navigation system

    Polynesian Exploration Inc. has launched its high-accuracy navigation system for demanding applications such as autonomous driving and unmanned aerial vehicles (UAVs).

    Polynesian Exploration is a navigation startup founded by a group of navigation-industry veterans in Silicon Valley in October 2016.

    The navigation system is designed to fully utilize the advantages of both GNSS and inertial navigation systems (INS) to provide centimeter-level position and velocity accuracy with dual frequency real-time kinematic, together with accurate attitude information (roll, pitch and heading).

    The system provides superior short-term stability against satellite signal outages and highly accurate heading whether the system is static or moving, Polynesian Exploration said.

    The rugged and waterproof system will be ready for shipment starting July 1.

    Polynesian Exploration described the demand for high-accuracy GNSS/INS solutions this way:

    By the year 2020, four GNSS are expected to be fully operational, which are GPS, GLONASS, Galileo and BeiDou. The abundance of measurements from multiple constellations around the world will enable unprecedented improvements in the accuracy, continuity and integrity of GNSS navigation systems.

    Although GNSS signals have grown to become ubiquitous, all radio-navigation systems are subject to radio frequency interference, short signal blockages and severe multipath errors in certain environments (such as urban canyons).

    INS can potentially mitigate integrity and continuity risks caused by those issues to a certain degree. Additionally, INS is able to compute and output user’s position, velocity and attitude at high frequencies. Reporting information to users at a high-frequency is essential for many vehicle control applications, such as self-driving cars, UAV flight stability or autonomous landing.

    We design our navigation systems with various performances depending on user demands, which include, but are not limited to, up to 400-Hz position, velocity, attitude outputs and meters to center-meter level position accuracy.

    They can also be operational in all weather conditions and will be available globally.

    Additionally, we are able to integrate special sensors for each unique application as requested by our customers. We are driven by customer satisfaction and strive to offer the best experience for our customers.

  • Location and context advances in Android

    Location and context advances in Android

    Plus access to raw GNSS measurements for all

    By Steve Malkos
    Technical program manager, Google

    Google’s annual developers conference in May, Google I/O, featured many announcements, accomplishments and 2017 plans. Of particular interest, the Android Location and Context Team’s talk “Android Sensors & Location: What’s New and Best Practices,” is available online.

    This followed a keynote by CEO Sundar Pichai on solving problems at scale with deep neural networks, machine learning algorithms and artificial intelligence (AI). He also spoke about a shift from a mobile-first model to AI-first. Google is doing this across every product area, applying AI and machine learning. Other keynotes updated Assistant, Photos, YouTube, Superchat, Android and VR (virtual reality).

    The Android Location and Context team — Marc Stogaitis, Wei Wang, Souvik Sen and myself — spoke about background location, location accuracy, activity recognition, Android sensor hub, Android sensors, and the future of location and context.

    Discussing why battery life is so important, we showed detailed graphs on the costs of accessing different parts of the phone subsystems like WiFi, GNSS and making data connections.

    Then we introduced Background Location Limitations (at the 4:30 point in the posted video) coming with Android’s latest operating system in Android O. These limits will prevent applications from misusing Android’s APIs in the background, thus saving its user’s battery. There were examples on how to make your app background ready for these upcoming changes.

    We showed plans for location accuracy improvements (12:50) coming later this year and comparisons of existing vs. upcoming solutions for the positioning algorithm.

    We covered the tools to help analyze GNSS measurements. How strong are the individual measurements? How accurate are the range measurements? With these tools, developers now have direct insight into the lowest layers of a GNSS receiver. Then came activity recognition algorithms (15:40) and how deep neural networks will improve the precision of these algorithms and help advance the field in activity recognition.

    I spoke spoke about the Android Sensor Hub (20:27), how Google is leveraging the capabilities of an always-on low-power processor in Android phones. The sensor hub allows Google to port algorithms such as Activity Recognition, Geofencing and Gestures from the main application processor into the low-power sensor hub. We then went into detail around the new sensor features (25;55) and improvements around the compass (28:34).

    Finally, we looked into the future (33:28). I covered Project Elevation, Accurate Indoor Location, and dual-frequency GNSS. Closing thoughts were around how more signals are going to be added into the low-power always-on compute domains so that the phone is more aware and intelligent, simplifying users’ interactions, augmenting human memory and knowledge, and assisting users understanding of themselves and the world around them.

    Access to Raw GNSS Measurements

    In related news, our new web page is up and operational!  This site provides all the details around GNSS Raw measurements in Android along with our analysis tools for anyone to download. Our previous site was accessible to people who signed up as a partner with Google, but now we have opened up this site to everyone.

    Android GNSS Analysis Tool: Shows how you can select and run the analysis on a per satellite basis. This tool now supports multi-constellation and dual frequency (L1+L5) by default

    Android apps typically access GNSS chipsets through a filter, which improves the GNSS location output for the majority of use cases. Filters use additional sensors, such as motion sensors, to improve the end user experience. However, filtering is not appropriate for some applications used by professionals such as researchers and original equipment manufacturer (OEM) developers. The Android Framework provides access to raw GNSS measurements on some Android devices. The page lists Android devices that support raw GNSS measurements as well as tools that help you log and analyze GNSS data.

    For more on Android and raw GPS measurements, see the GPS World Innovation article Precise positioning using raw GPS measurements from Android smartphones.

  • UAV update: GPS jamming, tethered drones, NASA UTM and space planes

    Drones and Interference

    Most UAVs now come with GNSS as the principle sensor for guidance, often with inertial aiding. And high-precision GNSS on a drone enables much quicker high-precision surveying — unless signal interference disrupts things and spoils your day.

    Septentrio is now fielding two high-precision receivers that can overcome a good proportion of most common interference. AsteRx4 and AsteRx-m2 receivers, equipped with AIM+, can not only overcome common (but illegal) chirp jammers (which can virtually blot out L1 GNSS signals), but also have a spectrum plotting capability. This spectrum plot can visualize potential onboard interference sources during integration, and help identify onboard jammers.

    GoPro Hero 2 camera pick-up monitored by an AsteRx4 receiver

    The GPS L1-band spectrum above has been disturbed by a GoPro camera installed without sufficient shielding on a quadcopter close to the GNSS antenna. The three peaks indicate harmonics of 24 MHz — the typical frequency for a MMC/SD logging interface. This problem was fixed in the lab by adding a shielded enclosure for the camera.

    Although chirp jammers only transmit at around 10 mW, they are powerful enough to block GNSS signals over several hundred meters on the ground. A UAV is much more vulnerable in the air as jamming signals travel further, without line-of-sight blockage from trees, buildings or other obstacles.

    The figure above illustrates how a 10-mW chirp jammer disrupts RTK positioning 1 km away in a high-end receiver. Even a low-end, less accurate and less sensitive consumer-grade L1 receiver loses positioning over several hundred meters. But with AIM+ activated, the AsteRx4 maintains an RTK fix throughout the (simulated) flight and shows no degradation in position.

    So, there are two benefits to using these Septentrio receivers on a drone — less likelihood of losing positioning capability from intentional jamming while airborne, and a built-in spectrum plotter.

    Tethered Drones

    We ran an article recently relating that the U.S. military was interested in tethered drone systems, presumably for short-range reconnaissance. Hard to understand why you might want to intentionally limit the operating range of a drone, but with power supplied from the ground, much longer mission endurance may also have advantages for certain civilian applications too. For instance, inspection of power plants, refinery stacks, on-shore and off-shore oil rigs and other such fixed-location critical installations may benefit from long duration capability, while tethered flight should still allow travel over the whole inspection area.

    Well, these same guys — Drone Aviation — just figured out how to adapt DJI Inspire drones to add a tether system. With a massive share of the commercial small drone market, DJI drones are the most common sUAV used in many civilian applications.

    So now realtors wanting detailed listing videos, news media, maintenance and insurance people inspecting tall buildings or bridges, and many others in the oil and gas industry, no longer need to worry about losing power during lengthy visual data collection. Maybe in exchange, management of how the tether locates during an inspection may become a concern, but the longer endurance trade-off may also be worthwhile for a lot of applications.

    FUSE system.

    The Drone Aviation FUSE system comes with a customized power pack and an “automated smart tension control winch case” with 200 feet of tether, and uses 110-volt ground power — which works well when supplied by a portable field generator.

    NASA Tests UAV Traffic Management

    In the meantime as small drone use increases, including overnight shipping companies who continue to pursue ways to make package delivery by drones in ways acceptable to the FAA, the looming crisis in UAV airspace traffic management (UTM) is getting a lot of attention.

    NASA has been cooperating with FAA for some time to investigate potential systems for low altitude drone traffic management, and recently concluded field tests at six FAA test sites across the U.S.

    The three-week campaign, known as the Technology Capability Level 2 (TCL2) National Campaign, has focused on flying small drones well beyond the pilot’s visual line of sight over sparsely populated areas at these test sites. Operational test scenarios have included simulation of package deliveries, agricultural surveys, search and rescue, railway inspections and video surveillance operations.

    NASA has signed up over 100 industry, academic and government partners for this UTM effort, who are collaborating together, sharing data and using their own resources for this investigation. Companies who are participating and who may have significant interest in the outcome of these tests are planning to fly drones in the national airspace for package and food deliveries, bridge, power line and rail inspections, and agricultural purposes — these include Amazon, Google, Intel, Flirtey, Drone America, Carbon Autonomous and NUAIR.

    NASA is currently assessing the data gathered during these recent tests, but plans are already in place for the next phase of tests — flying drones in denser traffic over more populated areas and also determining UAV/UTM responses to larger manned aircraft.

    And in related activities elsewhere, at AUVSI XPONENTIAL in Dallas last month the International Civil Aviation Organization (ICAO), an agency of the United Nations that coordinates aircraft operations between member countries around the world, announced a Request for Information (RFI) on UTM systems. The intent of the RFI is to advance international progress towards worldwide UTM adoption by first gathering the best ideas from governments and industry.

    BVLOS Demonstration in France

    In an effort to demonstrate practical, readily implemented Beyond Visual Line Of Sight (BVLOS) drone operations in France, Delair-Tech recently flew a UAV for 30 miles, simulating powerline inspection. Delair used a regular, commercial 3G cell-phone network to control the drone for this test – an innovative demonstration that long-distance drone operations can be safe and simple to achieve.

    Delair drone inspects powerlines in France.

    Delair-Tech acquired Gatewing — which was previously owned by Trimble — in 2016 and has also signed strategical distribution agreements with Trimble. The business not only includes the manufacture, turn-key operation and support of drones, but also includes data analysis and reporting. And in a sign that commercial drone operations are becoming more commonplace in France, and that there is likely a preference for local suppliers, the purchasing conduit for government agencies across the country has selected the Delair DT18 and DT26X as the choice for French government agencies purchasing fixed-wing unmanned aerial vehicles.

    Unmanned Space Plane?

    DARPA recently selected Boeing to complete advanced design work for the Experimental Spaceplane (XS-1) program — a new class of hypersonic aircraft aimed at rapid turn-round, low-cost access to space.

    Artist’s concept of the space-plane.

    The XS-1 program is expected to create a reusable unmanned aircraft, around the size of a business jet, which would take off vertically like a rocket and fly at hypersonic speeds. The vehicle would fly to a high suborbital altitude and release an expendable upper stage, deploying a 3,000-pound satellite to polar orbit. The reusable space plane would then return and land horizontally and — this is a key requirement for the program — be prepared for the next flight within hours or a few days.

    The XS-1 technology demonstration will therefore aim to fly 10 times in 10 days, with the final flight carrying the upper-stage payload delivery system. Its hoped the program will promote a commercially offered service with costs as low as $5 million or less per launch — a small fraction of the cost of today’s launch systems. The XS-1 technology demonstrator’s propulsion system will be an Aerojet Rocketdyne AR-22 engine, a version of the Space Shuttle’s main engine, which would be fired on the ground 10 times in 10 days to demonstrate propulsion readiness for flight tests.

    Phase 3 objectives include 12 to 15 flight tests, currently scheduled for 2020. After multiple shakedown flights to reduce risk, the XS-1 will to fly 10 times over 10 consecutive days, at first without payloads at speeds as fast as Mach 5. Subsequent flights are planned to fly as fast as Mach 10, and deliver 900lb to 3,000lb payloads into low Earth orbit.

    So, high-end receivers to help deal with both external and internal jamming, tethers for DJI drones enabling longer inspection flight capability, NASA testing and industry collaboration towards an air traffic system for drones, long-range drone operations using 3G cellular networks in France, and even a research program to develop an unmanned space plane — nothing ever stands still in the ever-evolving world of unmanned aircraft.

    Tony Murfin

    GNSS Aerospace

  • Septentrio releases 4.2 firmware for greater performance, security and functionality

    Septentrio releases 4.2 firmware for greater performance, security and functionality

    Septentrio has released version 4.2 firmware for the AsteRx4, AsteRx-U and the newly launched AsteRx-m2. The 4.2 firmware brings higher output rates, low and constant latency, support for TerraStar-C and a built-in NTRIP caster.

    AsteRx-m2 UAS receiver.

    The 4.2 firmware targets machine control applications delivering higher output rates with consistent and low latency. Maximum output rates have increased on all platforms: up to 100 Hz for the AsteRx4 and AsteRx-m2 and 50 Hz for the AsteRx-U, with latencies better than 10 ms and 20 ms respectively.

    TerraStar-C is now supported, bringing precise point positioning (PPP) horizontal position precision to 4 cm. In addition, Septentrio algorithms deliver fast PPP re-convergence making PPP even more attractive for positioning in difficult environments.

    For the AsteRx4 and the AsteRx-U, the 4.2 firmware enhances ease-of-use by including a built-in NTRIP caster. Correction data from the receiver is available for up to 10 NTRIP clients (or rovers) over the internet. The caster supports up to three mount points and can also rebroadcast correction data from a remote NTRIP server.

    “For machine control and automation, Septentrio receivers have unique low-latency behaviour which is constant and independent of the update rate.” stated Francesca Clemente, Product Manager at Septentrio. She continued: “The 4.2 firmware demonstrates Septentrio’s commitment to advancing performance and functionality of its products.”

  • GNSS Market 2017 report released

    MarketReports.biz has published a detailed market research study focused on the GNSS Market across the global, regional and country level.

    The GNSS Market 2017 report provides a 360-degree analysis of the market from the point of view of manufacturers, regions, product types and end industries.

    The research report analyses and provides the historical data along with current performance of the global GNSS industry, and estimates the future trend of GNSS market on the basis of this detailed study. The study shares “GNSS Market” performance both in terms of volume and revenue.

    Companies mentioned include Harxon Corporation, NovAtel, Trimble, Tallysman, JAVAD GNSS, Stonex, Sokkia, Spectracom and Leica Geosystems.

  • Inertial performance: Enhanced tightly coupled dead reckoning

    Inertial performance: Enhanced tightly coupled dead reckoning

    Exploring IMU specifications and correlating them to performance of a final product can be daunting, as differences between MEMS sensors are not always apparent. This article presents achievable performances in fusion technology across a range of IMUs among the best in their respective performance categories. 

    The number of available options in inertial navigation systems (INS) has grown substantially over the last several years. Major advances have been made not only in inertial measurement unit (IMU) technology, but also in the ability to exploit sensor information to its fullest extent. In both cases, the largest impact can be seen in the micro-electrical-mechanical systems (MEMS) sensors. MEMS sensors are typically much smaller, lower power and less expensive than traditional IMUs. The net result of these improvements is a proliferation of INS systems at much lower cost than were previously available and, therefore, greatly increased accessibility to technology that has historically seen limited deployment. Selecting the appropriate sensor and fusion solution for a particular application can be very challenging due to the large and confusing spectrum of solutions.

    The IMUs will be examined in the context of new enhancements to sensor fusion algorithms such as the use of INS profiles. The concept of INS profiles applies environment specific constraints to improve performance in certain types of vehicles, or motion profiles. External sensors such as odometers and dual antenna operation can also aid the solution considerably, but will be unused in this analysis except for occasional comparisons. These external aiding sensors are extremely helpful in many cases and are available to use with a proprietary tightly coupled GNSS+INS solution called SPAN, but this paper seeks to evaluate what performance can be achieved without such aids.

    Real-world test results will be examined using a selection of IMUs with the latest SPAN algorithms to illustrate what kind of performance can be achieved with different sensors in difficult conditions. Despite their major advances over the past few years, there are many challenges involved with utilizing MEMS technology to provide a robust navigation solution, particularly during limited GNSS availability or low dynamics. The measurement error characteristics of these devices have improved dramatically, but are still much larger and more difficult to estimate than traditional sensors. Advancements in SPAN sensor fusion algorithms have enabled these smaller sensors to achieve remarkable performance, especially in applications where environmental conditions allow for additional constraints to be applied.

    This testing focuses on the land profile, meaning the constraints applied to a fixed-axle vehicle. The test scenarios were selected in such a way as to provide results for ideal, poor and completely denied GNSS coverage.

    INS Profiles

    GNSS and IMU sensors are only one part of the overall INS system performance. The sensor fusion algorithms used to exploit the available sensor data to its utmost capability are equally as important. In this regard, several improvements have been made to the SPAN INS algorithms to enhance performance under a variety of scenarios.

    The largest addition to the SPAN product line is the introduction of INS profiles. That is, environment- and vehicle-specific modeling constraints can be utilized to enhance the filter performance. For example, the land profile, which will be examined in depth in this article, is intended for use with ground vehicles that cannot move laterally. The assumptions introduced for land vehicles, however, are not necessarily valid for different forms of movement, such as those experienced by a helicopter. Therefore, profiles have been implemented via command, and controlled as required by the user, allowing for maximum performance depending on the application at hand.

    The land profile is analogous to what has historically been identified as dead reckoning. It is a method that uses a priori knowledge of typical land vehicle motion to help constrain the INS error growth. In other words, it makes assumptions on how land vehicles move to simplify inertial navigation from a six-degree-of-freedom system to something closer to a distance/bearing calculation. The land profile takes the concept of dead reckoning, models it as an update type into the inertial filter and adds a few additional enhancements.

    Velocity Constraints / Dead Reckoning. Amongst other optimizations, the land profile enables velocity constraints based on the assumption of acceptable vehicle dynamics. This includes limiting the cross track and vertical velocities of the vehicle. Of all the enhancements, this is the one most colloquially referred to as dead reckoning.

    In its simplest form, dead reckoning is the propagation of a position without any external input. In this forum, external input generally refers to GNSS satellites. Without external input, dead reckoning is inherently dependent on assumptions of velocity and heading to propagate the position. These solutions have evolved by integrating inertial and directional sensors to provide more local input and improve the solution propagation. This also is not a perfect method, however, as inertial sensors have their own errors that grow exponentially over time. The land profile velocity constraints explain the bulk of optimizations SPAN has made to enable dead-reckoning performance in extended GNSS outage conditions.

    Explaining the velocity updates involves using the current INS attitude (  ); the vehicle attitude (  ) is estimated by applying the measured or estimated IMU body to vehicle direction cosine (  ). From this, the pitch and azimuth for the vehicle is estimated.Using the magnitude of the measured INS velocity in conjunction with the derived vehicle orientation, the vehicle velocity is computed, allowing the expected vertical velocity and cross-track to be constrained.

    A velocity vector update is then applied to the inertial filter to constrain error growth. The effects of this method are expected to be most apparent in extended GNSS outage conditions when the INS solution must propagate with no external update information.

    Phase Windup Attitude Updates. Some applications are inherently difficult for inertial sensors due to the fact that these systems are reliant on measuring accelerations and rotations in order to observe IMU errors. When traveling at a constant bearing and speed, separating IMU errors from measurements becomes challenging, so any application that does not provide meaningful dynamics is more demanding on inertial navigation algorithms. This type of condition commonly appears in applications such as machine control, agriculture and mining.

    Gravity is a strong and fairly well known acceleration signal, so the real difficulty in this type of environment is managing the attitude, and especially azimuth, errors. Attitude parameters become difficult to observe when the system experiences insignificant rotation rates about its vertical axis.

    External inputs can be used for providing input during low dynamic conditions when rotational observations are weaker. These are particularly helpful in constraining angular errors and include the same types used to assist in initial alignment: dual antenna GNSS heading, magnetometers, etc. However, as the goal of this testing is to demonstrate the achievable performance from a single antenna GNSS system, this type of external aid was specifically omitted.

    Utilizing a patented technique for determining relative yaw from phase windup, the system is able to distinguish between true system rotation and unmodeled IMU errors during times of limited motion. This is a novel way to extract additional information out of existing sensors rather than adding more equipment and complexity.

    The phase windup update is used to constrain azimuth error growth during low dynamic conditions that are typically not favorable to inertial navigation. However, it does require uninterrupted GNSS tracking and is therefore applicable only in GNSS benign environments. This approach is expected to show the greatest benefit in low dynamic conditions and be directly attributable to azimuth accuracy, but only in conditions where GNSS availability is relatively secure.

    Equipment and Test Setup

    We paired OEM-grade GNSS receiver cards with a selection of IMUs in different performance categories. Since the OEM GNSS platform is capable of tracking all GNSS constellations and frequencies, we configured each receiver to use triple frequency, quad-constellation RTK positioning. The receivers were coupled with a wideband antenna capable of tracking GPS L1/L2/L5, GLONASS L1/L2, BeiDou B1/B2 and Galileo E1/E5b signals.

    Three IMUs were tested: an entry-level MEMS IMU (UUT1), a tactical-grade MEMS IMU (UUT2) and a high-performance fiber-optic gyro-based IMU (UUT3).

    All GNSS receivers and IMUs were set up in a single test vehicle and collected simultaneously for all scenarios. IMUs were mounted together on a rigid frame, and all receivers ran the same firmware build that were connected to the same antenna.

    The tests were conducted using a single GNSS antenna with no additional augmentation sources, such as distance measurement instrument (DMI) or wheel sensor. These are extremely helpful in aiding the solution, but as previously mentioned, this testing seeks to demonstrate the possible performance without the benefit of additional aiding sources. Dependence on aiding sources is a very important distinction when comparing such systems.

    The GNSS positioning mode used was RTK via an NTRIP feed from a single base station with baselines between 5–30 kilometers. This was done to try to minimize GNSS positioning differences between the three systems. L-band correction signals were not tracked, and PPP positioning modes were not enabled.

    A basic setup diagram of each system under test can be seen in Figure 1.

    FIGURE 1. Equipment set-up (not to scale).

     

    Test Scenarios

    Four test scenarios will be examined using all the equipment and algorithms described above. They are: urban canyon, low dynamics, parking garage and extended GNSS outage.

    The urban canyon test is designed to show the performance of the system in restricted GNSS conditions. The challenge to this scenario is to maintain a high-accuracy solution when GNSS positioning becomes intermittent or even unavailable.

    The low dynamics test is intended to illustrate the benefits of the land profile, and specifically the phase windup azimuth updates in maintaining the azimuth accuracy.

    The parking garage test will show the efficacy of the velocity constraint models over the different IMU classes as the extended outage provides no external information to the INS filter whatsoever. Again, no other aiding sources were used.

    Urban Canyon Test. The urban canyon environment has been and remains one of the strongest arguments in favor of using GNSS/INS fusion in a navigation solution. Because urban canyons are common, densely populated and, of course, a demanding GNSS environment, they represent both an important and challenging location to provide a reliable navigation solution. Typically, they contain major signal obstructions, strong reflectors and complete blockages (depending on the city). For this reason, they provide an excellent use case for INS bridging to maintain stability of the solution.

    During most urban canyon environments, it is typically rare to incur total GNSS outages of more than 30 seconds. Therefore, this scenario examines the stability of the solution in continuously degraded, but not generally absent, GNSS. In this case, the coupling technique of the inertial algorithms rather than quality of the IMU dominates achievable position accuracy.

    The receiver platform is capable of tracking all GNSS constellations and frequencies. This provides a significant benefit to test scenarios, such as the urban canyon, where the amount of visible sky is significantly restricted. In this case, the more satellites that are observable, the more the tightly coupled architecture can exploit the partial GNSS information.

    Though position accuracy between IMUs is less apparent in this condition, attitude results remain separated by IMU quality, which is a major consideration for some mapping applications such as those using lidar or other sensors where a distance/bearing calculation must be done for distant targets.

    Test data for this scenario was collected in downtown Calgary, Canada. The trajectory (Figure 2) includes several overhead bridges for brief total outages and some very dense urban conditions.

    FIGURE 2. Urban canyon test trajectory.

    Table 1 shows the RMS error results of the three systems running both the default and land profiles. The first thing to notice is that the errors are differentiated by IMU category, though the differences are fairly small in the position domain thanks to the tightly coupled architecture. However, because GNSS information is partially available, the differences seen in activating the land profile are fairly modest, especially as the IMU performance rises.

    TABLE 1. RTK RMS errors for urban canyon.

    As the clearest benefits of the land profile are seen on the entry-level MEMS IMU (UUT1), these will be explored graphically in Figures 3 and 4. Figure 3 shows the position domain, and the RMS differences can be seen in a few cases where the default mode errors increased faster than the land profile. An example of this divergence is most obvious around the 1500-second mark of the test during periods GNSS is most heavily blocked.

    Low Dynamics Test. The low dynamics test is designed to emulate conditions experienced by machine control, agriculture and mining applications. In this situation, GNSS availability is generally not the limiting factor and can be used to control the low frequency position and velocity errors of the INS system. The difficulty is managing the attitude, especially azimuth, errors because attitude parameters are very hard to observe without significant rotations or accelerations (Figures 5 and 6).

    The low dynamics test was collected in an open-sky environment and consisted of traveling in a straight line on a rural road for roughly 2 km at an average speed of 10–15 km/h.

    As this type of scenario provides little physical impetus, the azimuth and gyroscope biases are not observable. The reason for this is due to the use of the first-order differential equations to estimate the navigation system errors. Essentially, the differential equations define how the position, velocity and attitude errors change (grow) over time based on each other and the IMU errors. The observability of a particular update is tied to additional states through the off-diagonal elements of the derived transition matrix with the accelerations and rotations experienced by the system.

    The overall RMS solution errors for RTK are provided in Table 2. As evident by the results presented, the position and velocity errors are clearly constrained by the continuous RTK-level GNSS position regardless of whether the land profile is enabled or not. The real differentiator in the land profile is the attitude performance due to the use of phase windup as a constraint. Moreover, the attitude improvements are certainly tied to IMU quality.

    TABLE 2. RTK RMS errors for low dynamics.
    TABLE 3. RTK RMS errors, parking garage (500s).

    UUT1 exhibited a noticeable improvement in the attitude performance, while the higher performance IMUs did not. This is not entirely unexpected as the precision of the phase windup is lower than that of the higher grade IMUs.

    Looking at the data graphically, Figure 7 shows the effect of land profile on positioning performance in this scenario. The two solutions are indistinguishable on the plot, and are all within standard RTK-level error bounds as was indicated in the RMS table.

    Figure 7 shows the attitude accuracy with and without the land profile enabled. Again, the largest gains are seen on the entry-level UUT1, so this is the graphic shown below. This shows how the error peaks of the azimuth estimates are constrained. All the sharp corrections in each plot correspond to the vehicle turning around at the end of each 2-Km line and illustrates how much more powerful a rotation observation can be in azimuth accuracy overall.

    FIGURE 7. UUT1 attitude error (std vs. land).

    Parking Garage Test. This test was carried out at the Calgary International Airport and was selected to show the INS solution degradation during extended complete GNSS outages. The test consisted of an initialization period in open sky conditions to allow the SPAN filter time to properly converge, followed by a 500-second period within the parking garage. During the interval within the parking garage there were no GNSS measurements available.

    Figure 8 provides a trajectory of the test environment. The time spent inside the parking structure is evident on the center bottom of the image.

    FIGURE 8. Parking garage test trajectory.

    Unlike urban canyon environments that contain partial GNSS information, this exhibits an extended period of complete GNSS outage. During this type of scenario, the IMU specifications become much more significant. IMU errors directly translate to the duration the solution can propagate before the accumulated low-frequency errors of the IMU grow to unacceptable levels. System performance during the outage degrades according to the system errors at the time of the outage and the system noise. The velocity errors increase linearly as a function of attitude and accelerometer bias errors. The attitude errors will increase linearly as a function of the unmodeled gyro bias error. The position error is a quadratic function of accelerometer bias and attitude errors.

    Position results from each IMU are shown for UUT 1 in Figure 9. This plot shows the error with the land profile on and off. Without the land profile, the second-order position degradation in an unconstrained system is clearly visible.

    FIGURE 9. UUT1 position error (std vs. land ).

    By enabling the land profile, the filter constrains IMU errors by utilizing a velocity model for wheeled vehicles. With the constraints, the position errors are startlingly reduced for UUT1 and then progressively less impactful as the IMU quality increases in UUT2 and UUT3, respectively. This makes sense as the IMU error growth is progressively smaller in those IMUs, so the effect of mitigating them is also reduced.

    Extended GNSS Outage Test. An extension of the parking garage test is to evaluate the performance in a much longer outage. Instead of 10 minutes, an outage of one hour was tested. Also, due to the extremely long GNSS outage bridging, the effects of adding a DMI sensor (odometer) will also be explored as they are able to be used as a major additional aiding source.

    Table 4. Percent error / distance traveled over 1-hour GNSS outage.

    The most common measure of dead-reckoning performance is error over distance traveled (EDT). Due to the very long duration outages in this test, the errors will be reported in error over distance traveled to conform to the typical reporting method. This test was conducted in a mixture of highways and suburban streets with an average speed of 65 Km/h, incorporating a moderate amount of dynamics.

    This effect can be seen over the duration of the entire outage as well in Figure 9. In this case, the points are the RMS error over several tests. and the light background shroud represents the one-sigma confidence as time progresses. The confidence increases over time as the overall distance traveled also increases.

    FIGURE 10. Land profile EDT with and without DMI aid over 1-hour GNSS outage.

    Results and Conclusions

    In testing a range of IMUs in some challenging scenarios, this paper has sought to illustrate what kind of performance is achievable using each kind of system. An added complexity is looking at what effect certain inertial constraint algorithms have on this solution.

    Although low-cost MEMs IMUs are continuing to greatly improve in quality and stability, the end application is still highly correlated to the overall performance of a selected INS system. For a great many applications, the MEMS devices in combination with a robust inertial filter can meet requirements and provide excellent value. However, some applications continue to require higher end sensors, and possibly post-processing to meet their needs.

    The ability of SPAN to utilize partial GNSS measurements such as pseudorange, delta phase and vehicle constraints means even low-cost MEMs are capable of providing a robust solution in challenging GNSS conditions. However, this tightly coupled integration is limited in cases where GNSS is completely denied or when in low dynamic conditions.

    INS profiles using velocity constraints, phase windup and robust alignment routines have been shown to provide substantial aid to the INS solution in tough conditions, such as GNSS denied or low dynamics. These improvements were shown to exhibit greater impact as the IMU sensor precision decreases. These abilities, in conjunction with the existing tightly coupled architecture of SPAN and the ever-increasing accuracy of MEMS, IMUs indicate that robust GNSS/INS solutions will continue to proliferate at lower cost targets. However, very precise applications such as mapping will continue to rely on higher quality sensors to meet strict accuracy requirements.

    ACKNOWLEDGMENTS

    The authors thank Trevor Condon and Patrick Casiano of NovAtel for collecting and helping to process the data presented in this article, and to Sheena Dixon for her tireless editing.

    Manufacturers

    NovAtel SPAN technology on the NovAtel OEM7 receiver is the testing and development platform for this research. NovAtel OEM7700 GNSS receiver cards and a NovAtel wideband Pinwheel antenna were employed. The inertial units under test were an Epson G320 (low-power, small-size MEMS IMU); Litef μIMU-IC (larger tactical-grade performance IMU still based on MEMS sensors); and a Litef ISA-100C (near navigation-grade IMU using fiber-optic gyros (FOG). Although all are excellent performers in their class and capable of providing a navigation-quality solution, the intent is to show the potential limitations that might arise due to the intended application.


    RYAN DIXON is the chief engineer of the SPAN product line at NovAtel Inc., leading a highly skilled team in the development of GNSS augmentation technology. He holds a BSc. in geomatics engineering from the University of Calgary.

    MICHAEL BOBYE is a principal geomatics engineer at NovAtel and has participated in a variety of research projects since joining in 1999. Bobye holds a BSC. in geomatics engineering from the University of Calgary.

  • Taoglas launches Axiom reference design for connected cars

    Taoglas launches Axiom reference design for connected cars

    Taoglas has launched Axiom, a reference design for a low-profile, compact multiple-antenna solution for the next generation of connected cars. Taoglas is a provider of GNSS, automotive and Internet of Things products.

    The reference design will help automobile manufacturers overcome one of the biggest challenges of the connected car: where and how to place the multitude of antennas needed for maximum performance.

    As many as 18 antennas are needed to power the next-generation connected car, including

    • multiple cellular antennas for network connectivity;
    • Wi-Fi for hotspot connectivity;
    • GNSS for navigation, emergency call systems and other location-based technologies;
    • satellite radio;
    • AM/FM antennas;
    • radar antennas for object detection;
    • Bluetooth antennas for smartphones and other devices, and
    • dedicated short-range communications (DSRC) antennas for vehicle-to-vehicle/infrastructure applications.

    Locating these antennas in a vehicle in close proximity to each other and additional electronics systems while minimizing interference and maximizing performance is extremely challenging from a design and RF performance perspective.

    Manufacturers also need to take into consideration both ease of installation and assembly, and antenna size to determine how they would best work with the vehicle’s aesthetics. Taoglas has worked with the automotive industry for more than a decade, providing antenna solutions to many of the major tier 1 automobile OEMs across the globe.

    The Axiom reference design incorporates Taoglas’ wealth of knowledge and expertise gained over the years into a roadmap to help automobile manufacturers more quickly advance antenna configurations that work for their particular make and model.

    “Getting that many antennas to work efficiently in a small space at a competitive cost is the number one challenge for the RF teams of automobile manufacturers,” said Dermot O’Shea, co-CEO of Taoglas. “While every car manufacturer will require a slightly different solution, having a multi-antenna reference design to work from allows them to see what they can do in terms of placement and size, and how that impacts performance — all without waiting months for a custom solution to test. They can take the prototype and test it in the field to prove out concepts. Using Taoglas’ Axiom reference design allows them move more quickly to market with solutions that work. We can also work with Tier 1 OEMs to integrate the elements of the Axiom antenna reference design quickly and efficiently directly onto the board of their telematic control units, achieving highest radiated power and sensitivity, while minimizing project time, cost and size, all in one single package.”

    Taoglas’ Axiom reference design has integrated nine antennas, including:

    • LTE Antennas: Four LTE antennas, each operating from 698 MHz to 6 GHz to fully cover LTE worldwide application bands.
    • Wi-Fi Antennas: Two Wi-Fi elements, supporting both 2.4 GHz and 5.8 GHz bands for Wireless Local Area Network.
    • GNSS Antenna: An active GNSS element to support GPS, GLONASS and BeiDou navigation systems. L1/L2 options available.
    • SDARS Antenna: One SDARS element to support satellite radio applications.
    • DSRC Antenna: One DSRC element, which supports V2V/V2X dedicated short range communication.

    Taoglas’ advantage is its ability to integrate all of the antennas required for the connected car in a confined space and maintain maximum performance. The Axiom reference design uses a compact PCB all with SMT-mounted components, and also incorporates a unique board-to-board connector option, allowing the antennas and electronics systems to coexist in a single space inside the vehicle, with no RF cables or additional connectors required.

    The Axiom reference design also helps auto manufacturers simplify manufacturing and assembly, with surface-mount solutions that feature the temperature and vibration resistance with the quality standards that manufacturers require. Installation is clipping the PCB into the telematics board.

  • Telit receives AT&T certification for automotive-grade module

    Telit’s 300-Mbps LE940B6-NA LTE Cat 6 module has received AT&T certification for use on the carrier’s North American LTE wireless networks. The smart module is the first 300 Mbps Cat 6 automotive-grade solution certified by AT&T, Telit announced in a press release.

    With advanced security features, the LE940B6 aligns with automakers’ vehicle roadmaps which include requirements for secure, high-speed mobile data that support next generation applications such as advanced diagnostics, infotainment and remote software updates.

    “The automotive industry is continuously raising the bar on internet connection speeds to the car,” said Yossi Moscovitz, CEO of Telit Automotive Solutions. “Along with higher speeds, there are increasing requirements for security, quality and environmental performance which Telit has achieved with the LE940B6. With certification of the North American LTE-Advanced LE940B6-NA module variant, auto makers can immediately start delivering car models in the United States with these new modules.”

    The LE940B6 powers the entire connected-car platform, supporting current needs while including advanced features that enable future integration of up-coming value-added, telematics and managed services.

    The module can run in-vehicle applications inside a secure processing environment from the built-in 64-bit application processor, storage and memory. Automotive application programs can run entirely and securely on the module itself protected by advanced cyber-security capabilities.