Författare: admin

Plowman Craven, a United Kingdom-based aerial surveying company, has launched the Vogel Freedom UAV data collection solution designed for owners and operators of rail networks.

The Vogel Freedom UAV solution aims to solve issues rail operators face in carrying out network surveys, including traffic disruptions and dangers created for workers needing access to infrastructure for ground point sensors.

The platform requires fewer ground points to deliver topographical surveys. It can also produce sub-5 mm accurate rail system models using off-track sensor placement.

Operating from offices in London and Hertfordshire, Plowman and Craven is one of the largest infrastructure surveying and inspection businesses in the U.K.

“We developed Vogel Freedom in response to ever-increasing industry challenges and needs,” Steve Jones, head of new business at Plowman Craven, said. “It removes previous limitations to surveying and can add substantial value… all while improving workers’ safety and ensuring a safe and efficient rail service for customers.”

GPS Innovation Alliance (GPSIA) member companies are leaders in technology, transforming the digital and physical world around us. With countless essential applications, GPSIA members improve the industries that feed, build, move and connect communities across the globe. In times of need, the GPS industry is proud to rise to the occasion, whether through agriculture technologies, surveying equipment, navigation systems, essential communications tools, or humanitarian relief efforts. Simply put, GPSIA members are continually investing in lifesaving services at home and abroad.

Take, for example, the urgent need for humanitarian relief created by the ongoing war in Ukraine. Trimble has stood united to support the many affected and displaced Ukrainians; in addition to contributing through the Trimble Foundation to relief efforts in Ukraine and neighboring countries, Trimble also has provided GPS signal corrections to Ukrainian farmers at no cost, supplied 3D scanners for surveying damaged buildings, and worked closely with The HALO Trust to support demining activities in Ukraine by providing funding and commercial surveying systems to assist in precision mapping of landmines and unexploded ordnances.

Lockheed Martin’s C-130 Hercules aircraft has assisted essential humanitarian relief across the globe. Since its inaugural flight in 1954, this aircraft has enabled aid delivery, natural disaster relief, medevac services, search and rescue and more. Now equipped with GPS technology, the C-130 fleet has provided aid across the globe for decades — with L3Harris’ missionization solutions often at work to maximize the C-130’s utility. Similarly, Collins Aerospace’s state-of-the-art navigational technology has provided essential support to U.S. Coast Guard helicopters, with avionics upgrades that help pilots save time in emergencies and enhance situational awareness.

More broadly, Garmin inReach satellite communication devices have helped more than 10,000 individuals access emergency services, providing critical communications in natural disasters and humanitarian emergencies. In 2022, a powerful underwater volcanic eruption and tsunami devastated the island nation of Tonga, severing traditional communications channels for several weeks. Roy Neyman, a sailor equipped with this Garmin device, set up a communication center at a local restaurant to allow other residents to reach family and friends. Over two weeks, Tonga residents sent about 1,600 messages to loved ones around the world, offering peace of mind in the face of unthinkable destruction. Similarly, Apple recently launched an “Emergency SOS” service, which led to one of the first successful rescue efforts of two people who had driven off a highway in the Angeles National Forest.

CalAmp’s Fusion routers enable lifesaving emergency services to more than 400,000 residents in Oakland, California. Equipped with GPS, LTE and WiFi technology, these routers help Oakland Fire first responders quickly locate emergencies and access additional resources, such as building layouts or fire records, to provide the best possible emergency response. CalAmp’s technology provides an essential service to residents of Oakland and can be adapted to meet the changing needs of the community.

As the world of agriculture has come to depend on GPS technology, John Deere’s GPS-based agricultural services have helped farmers become more efficient. In turn, this has allowed farmers to harvest more crops for the masses and meet the ever-growing demand for food. With the annual growth in food demand estimated to be 1.4% over the next decade, John Deere’s critical investment in food banks in Mexico and training for farmers in Africa will help to ensure that all communities are able to access the food they need.

Across industries and government, GPS technology makes for a safer, more connected world. GPSIA is proud of its members’ dedication to global humanitarian efforts as well as critical services close to home. By constantly innovating, GPSIA member companies are creating technologies that provide critical services for everyday emergencies, natural disasters, and humanitarian crises across the globe.

How do/will/should North Atlantic Treaty Organization (NATO) forces integrate GPS and Galileo for position, navigation and time?

“For improved resiliency, it would be a great move for NATO to integrate Galileo with GPS into their system. The ‘how’ will be difficult. Some of the challenges are that the EU consists of more than a single nation with which to negotiate complex security issues, such as whether NATO will be treated as a ‘third nation entity’ for the use of PRS. The initial Galileo development was difficult for all these reasons and the Europeans managed to sort it all out, so I’m confident that, if the desire is to do this, it can be done successfully.”

— Ellen Hall
Imminent Federal

---

“In the interest of operational robustness and the criticality of the use case, NATO should integrate GPS and Galileo capability at the earliest. Both GPS’ M-code and Galileo’s PRS are encrypted, providing anti-spoof capability and extra frequency diversity, making jamming of our forces more difficult. Crypto key management for both systems may be an extra burden, but a single receiver capable of operating with either system individually or both simultaneously would be key for interoperability — always a driving factor for NATO. The capability is available, and NATO should take advantage of it.”

— John Fischer
Orolia

China launched the Yaogan-34 04 remote sensing satellite from the Jiuquan Satellite Launch Center in northwest China on March 31 at 2:27 p.m. Beijing Time, reported China Aerospace Science and Technology Corporation.

The satellite will be utilized for surveying, urban planning, crop yield estimation and disaster prevention and mitigation.

The Yaogan-34 04 remote sensing satellite was carried into space by a Long Marc

The Yaogan-34 04 remote sensing satellite was carried into space by a Long March-4C rocket and successfully entered its planned orbit.

This was the 470th flight for the Long March carrier rocket series.

China will use the BeiDou satellite-based augmentation system (BDSBAS) to provide positioning services in railway surveys and construction, reported the China Railway Siyuan Survey and Design Group and Xinhua Net.

Four satellite-based and 12 ground-based observation stations will be placed along the Wufeng-Enshi railway section located in the Hubei Province in central China.

The BDSBAS and the BeiDou ground-based augmentation system aim to further enhance railway survey efficiency.

uAvionix has introduced truSky ADS-B spoofing detection for its SkyLine Uncrewed Aircraft System (UAS) beyond visual line of sight (BVLOS) services.

The uAvionix truSky validation process uses a network of low-profile deployed dual-frequency ADS-B ground receivers to evaluate each signal transmitted from the aircraft. The system then compares the received signals to confirm that the signal originated from the aircraft’s position.

When used within the uAvionix SkyLine platform, each aircraft track point is color-coded based on its confidence score. The validation score is then transmitted along with the position updates of the aircraft using SkyLine API.

TruSky is being piloted in numerous locations in the United States and is available as a component of uAvionix’s SkyLine UAS BVLOS service or as an API for integration into UAS GCS, UTM, or ATM platforms.

Precision agriculture (PA) — which uses electronic information to better manage spatial and temporal variability in crops, livestock, forestry and other biological systems — is profitable, as proven by the rapid and widespread adoption of GNSS guidance for mechanized agriculture. Other enablers of PA include variable rate technology (VRT), remote-sensing using satellites and unmanned aerial vehicles, geographic information systems (GIS) and soil sampling.

In my introduction to our January cover story, I requested pointers to any “independent, reliable and comprehensive study” as to PA’s return on investment. In response, Professor Won Suk Lee, of the Department of Agricultural and Biological Engineering of the University of Florida Gainesville, introduced me to Professor James Lowenberg-DeBoer, who has more than 30 years of worldwide experience in agricultural research, teaching, outreach and leadership and was the president of the International Society of Precision Agriculture. His research focuses on the economics of agricultural technology.

Dr. Lowenberg-DeBoer wrote to me that “thousands of studies of profitability of precision agriculture” using “a wide range of methods and assumptions” arrive at “a relatively consistent set of conclusions.” He detailed them in a chapter on the economics of PA he wrote for a book published in 2019 (Precision agriculture for sustainability, edited by Dr. John Stafford, Silsoe Solutions, UK and published by Burleigh Dodds Science Publishing) and pointed out to me that additional studies of the topic conducted since then have not altered its conclusions.

Lowenberg-DeBoer used adoption of PA as a proxy for its profitability, because, he wrote, “Farming is a business and technology is adopted if it provides benefits for the farmer and farm household.” He focused on PA for crops on relatively large-scale mechanized farms, but the same principles and general conclusions apply to livestock, forestry and other biological production systems and to medium and small farms.

“Since GNSS guidance was introduced for ground-based agricultural equipment in the late 1990s,” he wrote, “almost all economic studies have shown positive economic benefits which could be quantified and substantial qualitative benefits which were more difficult to measure.”
He reported that within about 10 years of the introduction of both lightbars and autosteer, GNSS was used by about 80% of the dealers. Adoption of PA sensors, on the other hand, was slower. “While GNSS guidance is being adopted quickly almost wherever agriculture is mechanized, VRT is more likely to be found in ‘hot spots’ where the profit potential and soil variability combine to motivate adoption.”

Advances in autonomous robots will further revolutionize agriculture, Lowenberg-DeBoer predicted. “Implementing cropping tasks with swarms of small robots will change agronomic practices and the geography of agriculture. For example, with robotic pesticide application, it might be possible to spray each pest individually instead of broadcast application. This could reduce the amount of pesticide applied by [more than] 90% and reduce the negative effects on beneficial species.”

For more on how GNSS is central to PA and how Lowenberg-DeBoer’s vision is beginning to take shape, see “Integrity Is Integral to Precision Agriculture.”

Matteo Luccio | Editor-in-Chief
mluccio@northcoastmedia.net

Precision agriculture has been around for more than 30 years and now covers the majority of U.S. farmland. It refers to the ability of farmers to observe, measure and respond precisely to the variability of soil and crop characteristics within and between fields by using maps of these characteristics and GNSS navigation. It enables them to reduce inputs of seed, water, fertilizer, pesticides and fuel while increasing outputs. It also enables them to work at night and in the fog and automate many functions at large feed lots.

For precision agriculture, GNSS integrity can mean the difference between, say, a robot protecting a vineyard by weeding and spraying pesticides or damaging it by straying onto the vines.

Autonomous Tractors, Mowers, and Feed Monitors

SITIA, a French company, has developed an autonomous tractor that is used by, among others, an organic vineyard in France’s Loire valley to tirelessly weed the narrow rows between the grape vines — compensating for the movement of young workers to cities. Thanks to the high accuracy and integrity of the Septentrio GNSS heading receiver inside, the autonomous tractor has decreased the damage to the vineyards by more than an order of magnitude compared to the traditional work done by a farmer with a manual tractor.

Renu Robotics, based in San Antonio, Texas, makes a robot for vegetation management, called Renubot. It uses machine learning, a form of artificial intelligence, to plan its route, optimize its energy consumption, perform self-diagnostics, collect environmental data and assess the topography that it traverses.

Navigation is based on a stored map of paths, a Septentrio RTK GPS receiver and sensors to avoid obstacles. A radio link enables the Renubot to communicate with a control center, for reporting and updates. When the Renubot returns to its recharge pod, it charges its lithium battery and performs updates and downloads.

Manabotix Pty. Ltd., an Australian company, has developed an automated system to monitor cattle in large feedlots, using GNSS, lidar scanning and other vision or perception technologies and artificial intelligence. This has greatly improved the accuracy and consistency of feedlot volume estimates, which for the previous 150 years had been the responsibility of a select few employees, who would visually gauge the amount of feed in concrete troughs. This visual inspection by humans was inherently imprecise, subjective, and inconsistent, often causing animals to eat too much or too little one day and get off their optimal growth curve or even become ill. Manabotix’s solution consists of a Septentrio AsteRx-U GNSS receiver and antenna, a lidar scanner, and an onboard processing platform.

Statistical Analysis

Integrity is a key aspect of all these applications. A part of delivering integrity is a statistical analysis called receiver autonomous integrity monitoring (RAIM), which was developed for such safety-critical applications as aviation or marine navigation. A refinement of RAIM, called RAIM+, takes this analysis to the next level as part of a larger positioning protection package.

For autonomous operation, it can be particularly hazardous to be overly optimistic about GNSS accuracy. This parameter is reported in the form of positioning uncertainty, which is the maximum possible error on the calculated position. It is especially necessary in challenging GNSS environments, where the receiver has a direct line of sight to only a limited number of GNSS satellites or where GNSS signals are degraded. RAIM alerts users when their receiver’s uncertainty strays beyond the limits they have chosen for their application.

Users can be deceived by a consistent position or movement — which can be consistently inaccurate. The positioning uncertainty gives them an indication of the extent to which they can rely on their receiver’s positioning accuracy at any given moment. The receiver operator can set an alarm limit, so that the receiver can flag situations when positioning uncertainty becomes too large.

The blue line in Figure 1 shows position uncertainty estimated by a GNSS receiver under favorable conditions, when the view of the sky is unobstructed, and the receiver has a direct line-of-sight to many satellites.

During favorable conditions, the positioning uncertainty stays well below the alarm limit because the calculated position is almost the same as the robot’s actual position. However, in challenging environments, the truthfulness of positioning uncertainty becomes most critical (see Figure 2).

For instance, when the view of the sky is partially obstructed by buildings or foliage, the receiver has access to only a limited number of GNSS satellites, making it harder to calculate accurate position. In such cases the receiver must report a higher positioning uncertainty, so that the system can take adequate action such as switching to lower speeds, staying further away from predefined boundaries, or stopping.

A low integrity receiver may keep reporting an optimistic positioning uncertainty, that stays below the preset alarm limit even when the calculated position is way off from the actual position. The number may look fine, but effectively it becomes a “robot on the loose,” no longer on its planned path with a risk of damaging itself and its surroundings.

Let us look at uncertainty limits in action during a GNSS car test in an urban canyon, where the view of the sky is partially obstructed by houses (see Figure 3). The orange lines are the positioning and its uncertainty boundaries reported by a Septentrio mosaic GNSS module in the car, while the red lines are the positioning and its uncertainty boundaries reported by another popular GNSS receiver. The white line shows the actual position of the car as it drives along the road. The orange uncertainty boundaries of the mosaic receiver are truthful and somewhat wider in this challenging environment, and you can see that the actual position always remains within these boundaries. On the other hand, the red trajectory jumps off course in a certain challenging spot on the road, with the actual position no more within the uncertainty boundaries, which remain too optimistic. In this case the competitor’s receiver gives a false sense of security and the system is unaware of its hazardous operation.

If the receiver depicted by the red line provided navigational information for an ADAS automotive system, for example, this could mislead the system into thinking that the car switched lanes. If the system then attempted to correct the trajectory by switching back to the “correct lane” this would result in taking the car off course and potentially hitting the sidewalk or even another car.

RAIM vs RAIM+

The underlying mechanism behind truthful positioning uncertainty reporting is RAIM, which ensures a truthful positioning calculation based on statistical analysis and exclusion of any outlier satellites or signals. Septentrio receivers are designed for high integrity and take RAIM to the next level with RAIM+, guaranteeing truthfulness of positioning with a high degree of confidence.

In Septentrio receivers RAIM+ is a component of a larger receiver protection suite called GNSS+ comprising positioning protection on various levels including AIM+ anti-jamming and anti-spoofing, IONO+ resilience to ionospheric scintillations, and APME+ multipath mitigation.

Septentrio has fine-tuned its RAIM+ statistical model with more than 50 terabytes of field data collected over 20 years. It removes satellites and signals which may give errors due to multipath reflection, solar ionospheric activity, jamming and spoofing, while working together with the GNSS+ components mentioned above. Because of this multi-component protection architecture, it achieves a very high level of positioning accuracy and reliability which goes well beyond the standard RAIM. The RAIM+ statistical model is adaptive, highly detailed, and complete, taking advantage of all available GNSS constellations and signals. The full RAIM+ functionality is also available in Septentrio’s GNSS/INS receiver line. User controlled parameters allow it to be tuned to specific requirements.

The diagram in Figure 4 shows RAIM+ in action during a jamming and spoofing attack on a Septentrio GNSS receiver. While AIM+ removes the effects of GNSS jamming, both AIM+ and RAIM+ work together to block the spoofing attack. Satellites with high distance errors, shown on the middle graph, are removed by RAIM+ since they do not conform to the expected satellite distance.

This example shows that even in the case of jamming and spoofing, Septentrio’s high integrity receiver technology delivers truthful and reliable positioning on which any autonomous system can count.

GNSS Design Around Reliability

GNSS receivers designed to be reliable strive for high integrity in both reporting of the positioning uncertainty as well as in RAIM+ advanced statistical modelling. This ensures that these receivers provide truthful and timely warning messages and are resilient in various challenging environments. Other technologies such as inertial navigation system (INS) can also be coupled to the GNSS receiver to extend positioning availability even during short GNSS outages. Quality indicators for satellite signals, CPU status, base-station quality and overall quality allow monitoring of positioning reliability at any given time. High-integrity GNSS receivers provide truthful positioning in autonomous machines such as the SITIA weeding tractor. They are also crucial components in safety-critical applications, assured PNT and any other application where accuracy and reliability matters.

BOREAL SAS and M3 Systems France, both subsidiaries of the Mistral Group, are collaborating on Mistral Group’s new corporate mission, Space4Earth, which aims to define the future of geolocated positioning by 2030. To work on the mission, both companies are consolidating space technology and UAV teams across two sites in the Toulouse, France, region with the goal of providing end-to-end solutions in the areas of automotive, drone, and space-based geo-positioning.

The Mistral Group has established its first multi-expertise center on Jean-Jaurès Avenue in Toulouse. Its location aims to stimulate internal collaboration. The location of the site will enable the Mistral Group to play a key role in the field of space innovation and long-range UAVs.

The second site, located in Lavernose-Lacasse, will house the InnovLab innovation center, which is dedicated to creating proofs of concept. The lab is equipped with advanced technological resources to enable company employees to work on the developments of UAV and GNSS projects. The overall objective is to develop new payloads and to develop integration methods to offer bespoke flying laboratories.

“Since February 2022, there has been an increase in jamming and/or possible spoofing of GNSS. This issue particularly affects the geographical areas surrounding conflict zones but is also present in the eastern Mediterranean, Baltic Sea and Arctic area,” the European Union Aviation Safety Agency stated in a Feb. 17 safety information bulletin.

On April 4, the United Kingdom’s Civil Aviation Authority followed with its own advisory adding that, in addition to the year-over-year increase, interference has intensified in recent months citing the same geographic areas of concern.

Both advisories list impacts to aircraft that include:

• loss of ability to use GNSS for waypoint navigation
• loss of area navigation (RNAV) approach capability
• inability to conduct or maintain Required Navigation Performance (RNP) operations, including RNP and RNP Authorization Required (RNP AR) approaches
• triggering of terrain warnings, possibly with pull up commands
• inconsistent aircraft position on the navigation display
• loss of automatic dependent surveillance-broadcast (ADS-B), wind shear, terrain and surface functionalities
• failure or degradation of a variety of air traffic management service and aircraft systems that use GNSS as a time reference
• potential airspace infringements and/or route deviations due to GNSS degradation.

Airspace infringement can be a real concern, especially in conflict zones or near belligerent nations.

GPS was first authorized for civil use because of just such an incident. In 1983, a Korean airliner accidentally trespassed into Soviet airspace and was shot down. Despite the fact that the GPS constellation had not yet been declared fully operational, in September of that year President Ronald Regan authorized its use in civil applications to help avoid similar tragedies in the future.

GPS-based navigation for aircraft was subsequently found to be so efficient and successful that the Federal Aviation Administration (FAA) planned to eliminate all the terrestrial navigation beacons it maintains for air traffic and rely entirely upon GPS. Despite a 2001 report from the U.S. Department of Transportation’s Volpe Center cautioning against such an action, this plan was not abandoned until several years later when an aircraft crossing the Atlantic lost GPS reception.

In recent years, aviation industry concerns about interference with GPS and other GNSS signals have intensified. These concerns have even included planned and announced military exercises that cause interference. Aviation industry groups have complained that the exercises disrupt and are too costly to their operations.

Safety of life has also been a concern.

In 2019 a commercial passenger aircraft was nearly lost to GPS interference in Sun Valley, Idaho. Flying a GPS-based approach through the mountains to the airport, low-level interference caused the aircraft to deviate from its course. In the words of the safety report filed with NASA, had a sharp-eyed radar controller hundreds of miles away not spotted the problem and intervened, “…that flight crew and the passengers would be dead, I have no doubt.”

This incident was cited by the International Air Transport Association (IATA) in a filing later that year urging international action. Along with other groups, it pressed the U.N.’s International Civil Aviation Organization (ICAO) concerning “An Urgent Need to Address Harmful Interferences with GNSS.” In 2020, ICAO issued a letter to all member states recommending action.

Similar concerns have been expressed by other international bodies as well.

In 2021 a EUROCONTROL seminar said that there had been a 2,000% increase in GNSS RFI incidents since 2018 as measured by voluntary incident reporting. Also, that 38.5% of European en-route traffic operated in regions regularly affected by interference.

The International Telecommunications Union, the U.N. body responsible for coordinating spectrum use, issued its own concern and warning in 2022. It cited more than 10,000 aviation-related incidents the previous year and, like ICAO, urged member states to take action to prevent such occurrences.

While interference with GNSS signals is unquestionably a concern for commercial aircraft, it is perhaps even more of a safety risk for smaller, general aviation users.

The only electronic navigation aids in many of these aircraft are consumer-grade GPS receivers. Since these are not certified by the FAA, they are only officially authorized for use to help pilots maintain “situational awareness” while they fly using visual reference with the ground. Interference with GNSS signals can cause disorientation and could result in aircraft becoming lost, running out of fuel, or straying into prohibited areas.