The U.S. commercial drone industry is at an inflection point. After years of incremental progress, the FAA’s landmark Part 108 Beyond Visual Line of Sight (BVLOS) rule is expected to take effect later this year, unlocking a new era of scaled commercial drone operations across delivery, infrastructure inspection, public safety, perimeter protection and beyond. It’s a pivotal moment for drone operators to get ahead of the most significant regulatory shift the commercial drone industry has seen.
Today, AirData UAV announced it is joining the Commercial Drone Alliance (CDA), bringing its operational platform into the industry’s broadest coalition for drone policy and progress. As a member of the CDA, AirData will actively contribute to the policies and standards that will define the next chapter of the U.S. drone economy through the CDA.
Part 108 introduces sweeping new operational requirements across pre-, during and post-flight documentation, personnel roles, risk-categorized operational areas, and mandatory continuous data reporting, and AirData’s platform is already built to meet them.
“We are at a critical moment for the drone economy,” said Lisa Ellman, Chief Executive Officer of the Commercial Drone Alliance. “As the industry moves toward broader BVLOS operations and frameworks like Part 108, access to scalable, reliable operational data such as that which AirData provides will help to safely unlock the full potential of the drone economy.”
Credit: AirData UAV
AirData’s platform delivers the tools operators will need to meet Part 108’s requirements, including: checklists, automated compliance documentation, flight logging across every mission, and fleet-wide analytics that give program managers visibility into operational risk. With more than 61 million flights across 450,000 pilots and 850,000 drones globally, AirData has been building the compliance infrastructure the industry now needs.
As the industry’s leading policy advocate, the CDA has been central to advancing the regulatory frameworks. The CDA is an independent non-profit organization led by key members of the commercialdrone industry. It works to educate policymakers and the public on the safe integration of drones into the national airspace and to advocate for policies that enable commercial drone operations.
“We have long served as the intelligence backbone for drone operations,” Eran Steiner, CEO and founder of AirData UAV. “We look forward to leveraging our data, insights, and experience to enable scalable, compliant, and mission-critical drone programs, particularly as frameworks like Part 108 unlock the next phase of scaled BVLOS operations in the United States.”
AirData’s platform gives public safety agencies, enterprise operators, and drone programs of every size the maintenance documentation, pilot currency tracking, asset management, checklist discipline, and operational data history that regulators will expect when Part 108 takes effect.
Hamburg-based start-up Beagle Systems has begun building a nationwide network of landing and charging stations for drones.
In Hanstedt (Lüneburger Heide) in the Lower Saxony region of Germany, the first hangar has been set up with an unmanned aerial system (UAS). From there, every surrounding place in Lower Saxony can be reached in a short time.
The drone will be deployed from the Beagle Systems headquarters in Hamburg. Beagle Systems has the corresponding permits for flights beyond visual line of sight (BVLOS).
“The start in Hanstedt is an important step for us,” said Oliver Lichtenstein, one of the three founders of Beagle Systems. “From here we can reach an area of 780,000 hectares in Lower Saxony. As the first provider of drone flights, we are thus on call within a short time at the customer’s site.”
The drone flight can be controlled entirely from Hamburg; on-site personnel deployment is not necessary. This eliminates personnel costs as well as time spent traveling to and from the site. Because of this, Beagle Systems can carry out drone flights at a much lower cost than other providers.
“Our goal is to build a nationwide network of charging stations within the next few years,” said Mitja Wittersheim, COO of Beagle Systems. “An EU-wide expansion is then the next step.” The expansion of the network would allow drone specialists to access a ready-to-go drone from Hamburg for customers at any location within the European Union.
Beagle Systems is a drone-as-a-service provider specializing in long-range flights with unmanned aerial systems. The drones are already in use for the inspection and monitoring of large infrastructure facilities such as power grids.
The company also plans to tap into the multi-billion dollar market of delivery, courier and express services. The Beagle M drone used in Hanstedt was developed in-house. It has a wingspan of 2.50 meters and can transport a load of up to three kilograms.
Celestia Technologies Group (CTG) is taking part in the ADACORSA project, a European initiative designed to unlock the potential of long-range and beyond-visual-line-of-sight (BVLOS) drones and give Europe a world-class drone industry.
ADACORSA — Airborne Data Collection on Resilient System Architecture — is a major collaborative project launched in May 2020 that aims to demonstrate the safety and efficiency of drones or unmanned aerial vehicles (UAVs) in extended out-of-line-of-sight operation ranges.
Specifically, it draws on European expertise in developing sensor and communication technologies for UAVs to underpin their role and reliable capability in long-range applications, including observation, analysis and transport, taking them one step further toward being integrated into conventional airspace.
ADASCORA also seeks to increase public and regulatory acceptance of modern UAV or drone technology. More than 49 specialist companies from 12 European countries are expected to contribute know-how and practical support. The project also aims to research and develop innovative components and systems for airborne observation and detection, telecommunication and data processing along the electronics value-chain.
Task Forces Established
To meet ADACORSA’s ambitious targets, task forces have been set up, one of which will be led by CTG. The company will lead the development of electronic components for reliable and fail-operational environment perception and run one project demonstrator designed to integrate unmanned aircraft systems safely into the common European airspace and ensure that they operate correctly in a multi-unmanned aircraft system environment.
CTG is a Dutch supplier and part of a pan-European company group providing innovative technology products, systems and services to space, aerospace, defense, telecommunications and scientific markets.
Galileo + EGNOS Transponder
CTG will use its expertise in on-board UAV electronics to develop a lightweight, high-performance transponder capable of sending and receiving accurate identification and location data for unmanned aerial vehicles.
Positioning will be based on Galileo, supplemented by its European Geostationary Navigation Overlay Service (EGNOS), allowing all airspace users to know the location of the vehicle and contribute to safety while supporting other on-board systems such as detect-and-avoid equipment.
The transponder will be based on conventional aviation technologies such as Mode S Interrogator and Automatic Dependent Surveillance-Broadcast (ADS-B) and will integrate new concepts including network identification, meaning the vehicle can fly safely in various scenarios. These include in locations close to airports, in drone fleet operations and within the U-Space environment. U-space is a set of European services and procedures designed to support safe, efficient and secure access to airspace for drones.
ADACORSA has received funding from the ECSEL Joint Undertaking (JU) under grant agreement No. 876019. The JU receives support from the European Union’s Horizon 2020 research and innovation program and Germany, Netherlands, Austria, Romania, France, Sweden, Cyprus, Greece, Lithuania, Portugal, Italy, Finland and Turkey.
Spirent GNSS Foresight predicts where and when unmanned vehicles, air taxis and drones can operate safely and dependably beyond visual line of sight
Spirent Communications plc has launched Spirent GNSS Foresight, a cloud-based solution that lets operators know in advance where and when GPS or GNSS positioning is reliable for unmanned and autonomous journeys.
GNSS Foresight accurately predicts where and when unmanned vehicles, air taxis and drones can operate safely and dependably beyond visual line of sight (BVLOS), especially in urban areas where buildings frequently obstruct GNSS signals.
The service addresses a key issue facing developers and operators of unmanned aerial systems (UAS) and autonomous vehicles. Because GNSS performance can be unpredictable in urban and suburban areas from signals being obscured or blocked by buildings, autonomous systems have not been able to rely on GNSS for accurate positioning.
GNSS Foresight will be shown publicly for the first time at ION GNSS+ 2021 in St. Louis, Missouri (Sept. 22–24).
“Accurate, reliable GNSS performance is a key enabler of game-changing innovations that are shaping our future — autonomous drones, air taxis, cars and trucks,” said Spirent’s vice president of PNT Assurance, Jeremy Bennington. “GNSS Foresight overcomes navigation and positioning challenges by providing real-world situational awareness ahead of time for pre-flight, or for real-time performance improvement, through a cloud-based service. It can be used to determine areas that are always safe to fly or operate in, in addition to finding the exact time in a degraded area when specific operational requirements can be met. GNSS Foresight enables operators to enhance efficiency, safety and ROI through the resulting operational improvements.”
Spirent GNSS Foresight’s ability to accurately predict where and when autonomous systems will perform enables users to scale operations or services by expanding operational areas, reducing the number of system disengagements, and providing a greater level of safety and reliability assurance when reducing — or ultimately removing — human involvement in the driving or piloting task.
GNSS Foresight can produce forecasts using data from any of the world’s satellite constellations, and is of particular interest to the aviation and UAS sector, as well as the automotive industry. It will be shown publicly for the first time at ION GNSS+ in St Louis (Sept. 22–24).
The National Civil Aviation Agency (ANAC) of Brazil has approved beyond-visual-line-of-sight (BVLOS) flights using SenseFly‘s flagship eBee X fixed-wing drone.
ANAC’s decision means that the senseFly eBee X is officially approved for use in future BVLOS missions carried out by Brazilian drone operators. The drone received approval by demonstrating the safety requirements of the ANAC RBAC-E 94 Regulation for Unmanned Aircraft, through detailed engineering analyses and in-depth flight testing. Sensefly worked in collaboration with drone engineering and consulting specialists AL Drones and geotechnology company Santiago & Cintra.
Following the certification, senseFly eBee X operators in Brazil now only require a CAER (Special Airworthiness Certificate for RPA) waiver for the aircraft with Santiago & Cintra before flying BVLOS operations.
“The commercial drone industry in Brazil has been growing at a phenomenal rate. and we’re excited that the senseFly eBee X is at the forefront of these regulatory developments,” said Pierre-Alain Marchand, regulatory compliance manager, senseFly. “BVLOS is becoming an important tool for operators as they start to explore the potential of more advanced drone operations, and we’re pleased that our technology continues to help define frameworks and legislation in the country. Historic approvals passed in recent years has shown us that Brazil is one of the countries to watch for drone commercialization, so continue to watch this space!”
The authorization comes following approval of senseFly’s proprietary drone technology in 2017, where the use of drones for civil applications in Brazil were legislated as part of the RBAC-E94 regulation. SenseFly drones became the first and only in the country permitted to fly 400 feet in height with a 5 kilometer radius from a licensed pilot or observer, in contrast to previous VLOS operations that restricted use of drones to a 500-meter radius.
“The authorization of senseFly’s eBee X for BVLOS operations is another step towards commercialization of the sector,” said André Arruda, co-founder of AL Drones. “After years of collective hard work and effort from all parties, this certification presents a real opportunity for operators in the future to expand their mapping operations and achieve a robust return-on-investment. We look forward to seeing what this means for BVLOS operations in Brazil in the coming years.”
SenseFly’s eBee X fixed-wing drone is designed to suit a wide range of mapping jobs. At 1.6 kg (3.5 lbs.), eBee X is a lightweight, portable solution that is easy for a single person to operate. With an Endurance Extension option enabling a flight time of up to 90 minutes and single-flight coverage of up to 500 ha at 122 m (1,236 A at 400 ft.), the eBee X drone that offers users the high precision of on-demand RTK/PPK for achieving absolute accuracy down to 1.5 cm (0.6 in) without ground control points. This capability makes the eBee X suitable for BVLOS operations such as long corridor mapping missions for utility companies, expansive crop scouting in agriculture and by enterprise customers who desire a robust and professional drone fleet.
L3Harris provided a detailed digital map of Blacksburg, Virginia, to aid in the development of a Navigation Performance Forecast for UAVs, specifically for beyond-visual-line-of-sight flights.
L3Harris used a novel method of 3D map generation using a deep stack of high-resolution satellite imagery and artificial-intelligence technology without the time or expense of a site visit. This detailed mapping technology, known as multi-view photogrammetry, was used in a pilot study to determine the viability of using modern, automated, mapping technologies to build a scalable methodology that can be applied to very large-size mapping programs, potentially covering the urban areas of North America and Western Europe.
The company is using these 3D maps with its GNSS forecast technology to accurately predict GPS performance for UAS flight planning and operation. This prediction helps the unmanned aircraft service supplier and UAS operator ensure safe operations.
The L3Harris Geospatial Data Products team provided 2D and 3D products, including the vector map shown above.
Just a couple of pieces of drone news this month — who would imagine flying a fixed-wing drone into the plume of a volcano? And some new advances in tethered drone capability.
Global warming/climate change — a collection of words which can sometimes lead to disputes, disagreements and dismay. These words can fill people with enthusiasm for change and in others have them just shaking heads. I saw a video some time ago made by an eminent scientist who claimed that all the efforts made by humans to pollute over the centuries and the efforts being made now to help the atmosphere, were insignificant when all the junk kicked out on a daily basis by volcanoes around the world was taken into account.
Nevertheless, it’s for sure that the climate is changing — by human hand or by nature — some people are still seeking a scientific basis to establish if it can somehow be remedied — a greener approach which could stop or limit our ability to go on polluting the only world we have, or at least some version of curbing what we are doing to make things worse.
So it was exciting for me to see recent reports of an expedition from last year in Papua New Guinea where an international group used drones in an attempt to measure carbon dioxide, sulfur dioxide and hydrogen sulfide coming out of the active Manam volcano. The objective appeared to be direct sampling of the volcano plume to determine content, not just for measurement alone but perhaps also eventually maybe monitoring changes in gas content to forecast future eruptions.
A series of significant eruptions last took place 2004-2006, and again in 2014, but since then Manam has continued to be explosively active all the way up to the present day. It’s possible to climb almost 6,000 feet to the upper dome, but for more efficient regular monitoring the expedition wanted to demonstrate that a fixed wing drone, operated from a village 2.7 miles away, almost at sea level, would work better. Satellite data on emissions is also available, but apparently no predictions of CO2 content has so far been possible, so land based survey and direct sampling might greatly improve understanding.
Hand launched, with an internal parachute system for recovery, the Titan UAV, which can lift a payload of around 2 pounds to an altitude of 7,500 feet and has a range of more than six miles. For the trip to the volcano, two 4k cameras provided forward and rear views, oversized electric motors were installed to provide more thrust and onboard data capture allowed for subsequent analysis of the vehicle dynamics as well as the gas content of the environment. Live data was also transmitted real-time to the operator and monitoring crew and was also stored for later review. The autopilot on the drone is capable of automatic GPS waypoint navigation and manual flight mode may be engaged by the operator. The drone carries GNSS, barometric altitude, airspeed indication and IMU sensors.
The automatically flown flight path up 5,300 feet to one of the two volcanic outlets on the mountain followed a zig-zag path to a point offset from the smoking caldera, and if the drone failed to then turn and intercept the plume automatically, it was manually maneuvered in level flight into the smoke column. Plume intercept was interpreted as a steep increase in sulphur dioxide concentration, and at the same time there were increases forces on the drone, at times up to 2.5 g, with roll deviations up to 25 degrees and significant uplift. Not unsurprising rock and roll given the energy being released by the volcano.
After each plume intercept the drone then left the area and descended in a spiral to the launch site, being recovered by manual parachute release. Two flights were successful, yielding lots of data for analysis, but there was an upset while in the plume on the third flight and the vehicle was lost, thought to be related to pulsating increases in the velocity of gas released by magma in the crater and what looked like a 7-g increase in forces on the vehicle. The plume was figured to be between 1800 ft and 2,500 feet wide, using the length of time spent in the smoke column and the speed being flown.
The flights were all conducted under Beyond Visual Line of Sight (BVLOS) conditions as agreed by the local air control agency and significant drone design improvements and flight techniques for subsequent ‘volcano operations’ were recommended. Gas emissions were measured at 3,450 to 4,360 tons/day CO2 and 4,840 to 5,880 tons/day SO2 — so lots of carbon pollution from one of the earth’s most active volcanos, one of around 500 worldwide.
Tethered drones offer advantages for some specific applications such as longer flight times for surveillance. Recent outings by Elistair tethered drone systems have included crowd monitoring and TV coverage for Super Bowl in Atlanta, Ryder Cup golf near Paris France, traffic monitoring in Lyon France, TV coverage for the Alpine World Ski Championships in Sweden, Paris Le Bourget airport approach light monitoring, Trinidad carnival crowd monitoring, Kentucky festival crowd monitoring and communications relay, fire control exercises in Greece, New Year’s crowd monitoring in Vienna and crowd monitoring at Madrid’s soccer stadium.
The Orion 2 tethered drone (Photo: Elistair)
But endurance is a key element for longer term surveillance, so Elistair has come out with Orion 2 which has extended the previous 8-12 hours operations envelop all the way out to 24 hours — and added IP54 dust and water rating, so weather shouldn’t interrupt service.
The tether now extends up to 330 feet so the drone can see out further and it can now also lift a 4.5-pound payload such as a combined ISR (intelligence, surveillance and reconnaissance) and telecom platform. While streaming georeferenced electro-optical and infrared video, 4G/5G communications nodes may also be brought online at the same time.
So an insight into what it takes to fly a drone into active volcano emissions to move us further towards understanding climate change, and improvements in tethered drone endurance. Doubt many of would expect a drone to survive the extreme turbulence created by the energy released from a volcano, or would even try to do so, but one group has been successful and found a new way to monitor activity and measure bad stuff being pumped into the atmosphere. And if we can hover a multi-rotor drone in the air for 24 hours at about 300 feet, who knows what new applications will soon come out of it.
Altitude Angel and Inmarsat are collaborating to develop and deliver advanced flight tracking and management capability for UAVs.
According to the companies, they will build on Altitude Angel’s GuardianUTM platform to jointly develop a “pop-up UTM” capability that can be deployed anywhere it is required to manage beyond visual line of sight UAV flights, without the need for ground-based communications infrastructure. By utilizing Inmarsat’s global network of satellites and leveraging its experience in air traffic management communications, Altitude Angel’s pop-up UTM can be accessed rapidly and deployed worldwide, the companies added.
The pop-up UTM will be developed initially to address the unmanned traffic management needs of blue light emergency services and first responders who need aerial surveillance rapidly with little notice. The companies plan to release a commercial, industry-focused product soon after. Through this technology, emergency services will be able to remotely manage UAVs, increasing their range of safe operations in mixed airspace of manned and unmanned vehicles.
“The ability to almost instantly ‘pop-up’ safe, secure and fully operational UTM platforms in any environment, at any time, will give first responders, blue light services and aid organizations a valuable tool that could save countless lives,” said Phil Binks, head of air traffic management at Altitude Angel. “Altitude Angel and Inmarsat, in developing ‘pop-up UTM,’ will be able to bring connectivity, clarity and automated air traffic control services for UAVs in even the most challenging of circumstances.”
Altitude Angel is an aviation technology company delivering solutions which enable the safer integration and use of fully automated drones into airspace. Inmarsat is a British satellite telecommunications company, offering global mobile services.
Iris Automation released Casia 360, an onboard detect-and-avoid solution with a 360-degree radial field of view to enable commercial beyond visual line-of-sight (BVLOS) operations for unmanned aircraft systems (UAS).
According to the company, Casia 360 system has the ability to detect other aircraft in all directions. It then uses computer-vision algorithms to classify them, makes intelligent decisions about the threat they may pose to the drone, then triggers an alert to the pilot in command and automated maneuvers to safely avoid collisions.
Casia 360, a low size, weight and power system, is composed of two onboard controllers and five long-range optical cameras that provide a 360-degree field of view. The software is packaged in a self-contained embedded supercomputer that works with the machine vision cameras onboard, the company said.
“Casia 360 allows a drone to have a complete sense of its surroundings so it can avoid potential collisions from any direction,” said Alexander Harmsen, CEO of Iris Automation. “We developed this technology based on feedback from our customers and regulatory bodies around the world. It enables drones to be used for an even greater range of long-distance use cases and saves money, increases safety and unlocks applications across multiple industries: railway, energy sector, utility powerline inspections, package delivery, and life-saving search and rescue operations.”
Iris Automation, based in San Francisco, is an artificial intelligence and safety avionics company building collision-avoidance systems for autonomous vehicles.
MVT Geo-solutions, in partnership with Iris Automation, has been granted the first beyond-visual-line-of-sight (BVLOS) Special Flight Operations Certificate (SFOC) by Transport Canada using only onboard detect-and-avoid (DAA) systems.
The approval was granted based on the utilization of Iris Automation’s DAA system, called Casia, which provides commercial drones with automated collision avoidance maneuvers.
The waiver permits flights within the Unmanned Aircraft Systems (UAS) Center of Excellence’s controlled airspace Remotely Piloted Aircraft System (RPAS) test range in Alma, Quebec. This is the first BVLOS flight at the location leveraging only onboard DAA for air risk mitigation, and does not require ground-based observers or radar.
BVLOS flights unlock autonomous drone use for economically beneficial commercial applications including infrastructure inspection, mining, mapping, agriculture, emergency response and package delivery.
“Achieving the first BVLOS approval in Canada further validates our technology alongside multiple permissions we have already received from regulators in the U.S. and South Africa,” said Iris Automation CEO Alexander Harmsen. ”This technology is critical to safely integrate drones into the airspace along with manned-aircraft, and we look forward to unlocking commercial operations for our customers in Canada.”
Iris Automation’s onboard computer-vision DAA system is an effective, scalable and cost-effective technology to enable commercial BVLOS operations.
“The UAS Center of Excellence is looking forward to leveraging Iris Automation’s DAA system and existing flight expertise within our network to conduct BVLOS flights with MVT Geo-solutions,” said UAS Center of Excellence Director William de Keiser. “We will continue to develop our partnership with Iris Automation to provide training to local operators and enable BVLOS flights in Canada.”
The first BVLOS flights are scheduled to take place within weeks. The resulting data will inform more complex BVLOS operations in the future.
Kansas receives approval for first beyond-visual-line-of-sight drone flight in the nation using only onboard detect and avoid.
The Kansas Department of Transportation (KDOT) has received permission to conduct the first beyond-visual-line-of-sight (BVLOS) drone operation in the nation leveraging only onboard detect-and-avoid systems.
This is the first U.S. Federal Aviation Administration (FAA) authorized operation to fly without a requirement for visual observers or ground-based radar. It is the result of the 31-member Kansas UAS Integration Pilot Program (IPP) team efforts to advance drone technologies.
In a collaborative effort among Kansas State University Polytechnic Campus (K-State Polytechnic), Westar Energy, Iris Automation and KDOT, the Kansas IPP team will fly a nine-mile track to evaluate technologies to inspect power lines in rural Kansas. This approval is the first of its kind for long line linear infrastructure and is the first step to enable routine commercial infrastructure inspection across the state.
This is the first unmanned aerial vehicle (UAV) flight to leverage onboard sense and avoid systems alone for collision avoidance. It also marks the first required automated avoidance action.
Historically, all FAA-issued Part 107 BVLOS waivers have required visual observers or ground-based radar. These mitigations limit the possibility of true BVLOS flights, as they are typically prohibitively expensive and limit operations to pre-defined corridor areas with radar coverage.
This important milestone is facilitated by Kansas UAS IPP partner Iris Automation’s Casia onboard collision-avoidance system.
“The UAS industry has worked over 10 years to demonstrate the most significant commercial benefit of drone operations within the United States,” said Bob Brock, KDOT director of aviation. “We are proThe Applied Aviation Research Center on the K-State Polytechnic Campus, which assisted in development of the safety case that ultimately led to FAA approval, will be responsible for the training and flight operations with a cross-functional team from the KDOT IPP. Flights will take place over the next few months, providing the FAA with much-needed data on true BVLOS activity.d of the joint state, university and industry team that made this landmark decision possible.”
“The ability to fly BVLOS missions without ground-based radar or visual observers is a significant advancement, and Westar Energy views this as an opportunity to play a key role in shaping the future of UAS operations within the utility industry,” said Mike Kelly, Westar Energy Senior UAS coordinator. “Being able to operate under this waiver allows the Kansas IPP team the ability to research and develop truly scalable BVLOS UAS operations for the automated inspection of linear infrastructure.”
“We look forward to leveraging this waiver to integrate UAS technology into the transmission line inspection process,” said Kurt Carraway, UAS Executive Director of the K-State Polytechnic Applied Aviation Research Center. “We are certain that utilities will be able to quickly realize a return on investment while mitigating safety to their maintenance personnel and increasing the reliability of their infrastructure to the general public.”
“Flying rural missions like these without a human pilot onboard or costly radar on the ground is exponentially safer and more cost effective,” said Iris Automation CEO and Co-Founder Alexander Harmsen. “The FAA is trusting us to pave the way for a safer, scalable future together with this precedent-setting second approval of our system.”
The U.S. Department of Transportation selected Kansas Department of Transportation as one of nine participants in the FAA UAS IPP. This program allows state, local and tribal governments to conduct advanced UAS operations to gather data to assist the rulemaking process that will set the boundaries for UAS operations in the United States.
Grand Sky Business and Aviation Park and Harris Corp. have joined forces to enable the country’s first and largest unmanned aerial system (UAS) airspace to support beyond visual line of sight (BVLOS) flight operations and UAS Traffic Management (UTM) research.
Stretching up to 100 miles, this BVLOS “super corridor” is the most technologically sophisticated UAS airspace supported by multiple and redundant systems for cooperative and non-cooperative surveillance.
These surveillance capabilities make possible a wide range of UAS BVLOS applications in precision farming, oil and gas, infrastructure inspection, public safety, package deliveries, and others.
“Customers of Grand Sky will have access to a truly unique UAS operational capability, in addition to better facilities, comprehensive airspace surveillance, and wide operational areas,” Grand Sky Development Co. President Thomas Swoyer Jr., said. “We all benefit from efficient and safe BVLOS flight operations and a larger corridor with proven FAA collaboration and flight authorizations.”
The surveillance system combines data feeds from a network of advanced sensors and towers. Two long-range primary radars located at Grand Forks Air Force Base and at Hillsboro, North Dakota, provide detection of non-cooperative aircraft.
The Federal Aviation Administration (FAA) secondary radars and ADS-B network in the region, as well as local Harris ADS-B Xtend sensors, add additional layers of visibility for cooperative aircrafts in the airspace.
Aviation-grade displays help pilots and electronic observers monitor the airspace environment over the BVLOS corridor and safely steer UAS from approaching manned aircraft.
The combination of best practices in aviation safety management, proven technologies and experience with BVLOS regulatory approvals will make it easy for users of the airspace to advance UAS technology commercialization and routine, efficient flight operations.
UAS operators can work with Grand Sky and Harris to develop, test, and refine a variety of complex BVLOS concepts of operations and secure waivers from the FAA for large-scale use.
A full range of UAS operations can be supported for all types and sizes of unmanned aerial vehicles along the BVLOS corridor including a variety of airspace classes and execution of diverse defense, civil and commercial applications.
“This is another first for Grand Sky and North Dakota in leading the UAS Industry,” Harris Vice President and General Manager of Commercial UAS Solutions George Kirov said. “The size and complexity of the airspace opened to UAS BVLOS operations is unmatched in the UAS industry. The sophistication of the Harris BVLOS system at Grand Sky is also unprecedented — linking Harris’ most advanced suite of surveillance and detect-and-avoid services with a variety of surveillance assets that, together, ensure the highest level of UAS aviation safety.”
This partnership lays the foundation for larger and more capable surveillance corridors to enable UAS “highways” across the state of North Dakota and in support of expanding the variety of commercial UAS operations across the United States.
