Drone Delivery Canada (DDC) is expanding its commercial testing program to the United States at the New York Griffiss International Airport unmanned aircraft systems (UAS) test site in Rome, New York.
DDC anticipates that the U.S. Pilot Program will begin in this quarter of 2018 and run through the balance of the year.
The new initiative expands DDC’s testing program to include geographies within the U.S. using its Sparrow X1000 drone, which achieved Compliant UAV Status with Transport Canada in December 2017.
For testing, DDCs will use its proprietary FLYTE management software to support semi-autonomous flight, as well as BVLOS (beyond visual line of site) flights designed for commercial drone deliveries.
The Griffiss International Airport UAS test site in Rome is a Federal Aviation Administration (FAA)-approved facility designated to conduct research vital to integrating UAS into the national airspace system. The site is the fifth of six test sites that are operational in the U.S.
The U.S. testing initiatives will complement DDC’s extensive Canadian testing program scheduled for 2018, which will include testing its BVLOS capabilities at the Transport Canada-approved UAS Centre of Excellence in Alma, Quebec.
Drone operational rules have quite a few restrictions, largely aimed at keeping unmanned aircraft away from manned and commercial aircraft operations. The Federal Aviation Administration (FAA) has set a boundary limit for UAV operations to stay a minimum of 5 miles away from any airport. So it’s a little surprising that at least one airport is actually carrying on trials to fly drones within airport property.
The reason is birds. Most airports are large, open spaces where birds love to land in large numbers to seek food and to rest, so airports and aircraft have to cope with the problem of avoiding bird-strikes in the critical phases of take-off and landing.
Airports have used remotely compressed air cannons, and manually fired ordinance that “screams” or explodes making various forms of loud noise, or dogs or even hunting falcons of different species. Birds, however, become habituated to cannons and guns, and neither dogs nor hunting falcons can be relied on to actually herd birds away from runways.
All this is in an effort to drive flocks of birds away from runways and low-altitude aircraft traffic corridors. At high altitude, a bird strike is usually survivable and an aircraft still has sufficient energy to be able to glide in the event of a complete engine-out situation, giving the pilot time to find a landing place. U.S. Air’s Chesley Sullenberger was a great airman to save his passengers and aircraft, but he was also lucky to have the Hudson right there to ditch into. He was some cool dude when he put his Airbus A320 down on the river, once losing both engines at low altitude on take-off after flying through a flock of Canada Geese.
Enter Robird, a drone that looks — and behaves, in the right operator’s hands — like a female peregrine falcon, with flapping wing propulsion and attack moves emulating the predatory bird. Flown by a pilot and accompanied by an observer whose primary job is to ensure the UAV “bird” stays away from runways, the pair seeks resting flocks of birds that pose risk to aircraft within the boundaries of an operational airport.
https://youtu.be/-gc8kBmzOOI
Clear Flight Solutions in Holland has recently undertaken a trial at Edmonton airport in Alberta, Canada, where it obtained special flight clearance to fly within the airport grounds to demonstrate how its mechanical falcon could clear birds away from airport danger zones.
Of course, drones and aircraft don’t mix either, so flight rules within the drone systems (GPS/autopilot?) apparently include geofenced no-go areas corresponding with runways and approach areas, and there is a shutdown mode in case of loss of signal or other failure — avoiding runway incursion is all important.
Registration is back on
Since U.S. Federal Aviation Administration (FAA) regulations requiring registration of small UAVs (sUAV) and model aircraft were struck down last spring by the appeals court, the need to register has been in abeyance. However, Congress has rolled a new requirement back into the recently signed $700 billion National Defense Authorization Act, making registration of any sUAS or recreational model aircraft a legal requirement, subject to fines for lack of compliance.
The FAA has continued to advocate registration as a means to track wayward operators and to enforce separation of drones from manned aircraft. AUVSI has also continued to support the FAA position. A 2012 law, on the other hand, was said to prevent the FAA from making rules covering “model aircraft,” defined as “unmanned aircraft” flown for recreational purposes.
The new regulation within the Defense Authorization Act has now apparently clarified and overcome any contradictions — recreational model aircraft and drones all have to be registered.
DJI claims and counter-claims
The U.S. Immigration and Customs Enforcement’s (ICE’s) recent claims that manufacturer DJI could be spying for the Chinese Government have been refuted by DJI.
DJI has responded that allegations are wrong and that ICE should consider withdrawing or correcting unsupportable assertions. But claims persist that the Chinese government may be using information gathered by DJI UAVs to target potential assets for purchase.
A large wine producer in California used DJI UAS to survey its vineyards and monitor grape production, but soon afterwards a number of Chinese companies apparently purchased vineyards in the same area. So it’s being alleged that the companies appear to somehow have used DJI data.
DJI UAVs collects reflective images of leaves to calculate the nitrogen levels of plants using a specialized infrared scanner. The scanner enables growers to deduce how much nitrogen to add to the soil to optimize plant growth. Information on the location and stages of crop growth can also be collected. As of May, it’s been reported that DJI’s only customers using this particular scanner were wine producers along California’s Pacific Coast.
Most UAVs would seem to be capable of collecting location and geographic information data; however, these claims are being leveled at manufacturer DJI. In a website statement, DJI denied any wrongdoing but hinted that some of its data storage may have been compromised.
This story may be far from over.
Potential new aircraft control systems?
I recall climbing around in the fuselage of a Jet Provost training jet back in my apprenticeship years at BAE in the UK — I was wiring in auxiliary systems. But the thing I remember most was the mass of control cables running down the top center of the aircraft and winding their way to control surfaces via pulleys, with in-line tensioners and rubber lined holes to pass through bulkheads. I thought, How reliable could this be? Of course, it’s the way almost every aircraft control system has been constructed since Wilber, Orville and wing-warping. Up until we got fly-by wire and electrical actuators, that is — then mechanical cables became less prevalent, except for reversionary back-up.
But making surfaces pop up into the airstream around an aircraft is how we’ve been able to take off, maneuver and land aircraft/UAVs — up to now. Elevators, rudders, ailerons, leading and trialling edge flaps, speed brakes — all of them control pitch (up and down), yaw (left to right), roll and manage lift. These mechanical control surfaces sprout out of the wings and horizontal and vertical stabilizers, and provide control for the pilot, autopilot or onboard flight computer.
Now BAE Systems and Manchester University (MAN U) in the UK have come up with a different way to control a flying vehicle without using moving control surfaces. If the smooth surfaces of a stealth aircraft were to be never disturbed, the stealth radar signature of the vehicle would remain unchanged even during maneuvering — a handy enhancement to have to keep an aircraft as invisible as when it’s “clean” in level flight.
The BAE/MAN U innovation, incorporated into a new MAGMA drone, uses internal, redirected air from the engine to “blow” the aircraft into a different direction. The small demonstration UAV has apparently completed a successful first flight.
These innovations could both reduce mechanical complexity and improve the integrity of a stealth signature, by removing conventional control surfaces. Wing circulation control redirects supersonic air from the engine and blows it through the trailing edge of the wing. Thrust vectoring changes the direction of the aircraft’s exhaust.
When used together, these control the direction of the aircraft by manipulating the air around it. Hydraulic and electrical actuators have been replaced by air redirecting ducts and air blowers, which may simplify build and flight controls without making the air vehicle more visible to radar. Of course, taking additional airflow from the engine means the engine has to be more powerful to provide the additional airflow, so this doesn’t come for free.
The technologies being developed may enable cheaper, higher performance, next-generation aircraft. Its hoped that R&D will contribute towards technological improvements for advanced military aircraft. These trials are an important step forward in the exploration of adaptable airframes — along with other work to improve the performance of UAVs in collaboration with the University of Arizona and NATO Science and Technology Organization.
MicroPilot adds sense and avoid
MicroPilot in Manitoba, Canada, is a leading supplier of autoflight solutions for the UAS industry. The latest MicroPilot autopilots include integrated control datalinks, and they are small, lightweight and interface with a wide range of sensors. MicroPilot has now integrated its UAV autopilot with the FLARM sense and avoid system, adding an essential element for autonomous and beyond-visual-line-of-sight (BVLOS) operations.
FLARM is a traffic awareness and collision avoidance technology used by light aircraft and UAVs. When integrated with MicroPilot’s autopilot, the system alerts the autopilot of any close-by, suitably equipped aircraft. FLARM outputs the velocity and altitude of these detected targets, and the autopilot then decides how to avoid them.
FLARM collision avoidance systems, used by manned aircraft for more than a decade, now come with an ADS-B out option that broadcasts the UAV’s position to alert other aircraft to its location. Together, the MicroPilot autopilot and integrated FLARM system offer a unique combination of automated flight control and sense-and-avoid capability for UAS developers.
Summary
So bird-hunting, wing-flapping, bird-like UAVs being used to clear airports to prevent collisions between birds and aircraft; you will need to put down your $5 registration fee with the FAA if you want to fly your own UAV because new legislation has replaced that previously struck down in the courts; DJI and the U.S. ICE seem to be on some sort of a collision course; BAE and MAN U appear to be on the verge of a potentially revolutionary system with which to affect flight control of aircraft and a combined system for autoflight and collision avoidance — just a few of the many things happening this month in the UAV industry.
Each webinar provides an overview of the program, the application process, and the specific criteria and deadlines that companies and research groups will be required to meet. Registration is required; only register for one session as they cover the same content.
Tuesday, Nov. 21, 12–1:15 p.m. EST
Monday, Nov. 27, 12–1:15 p.m. EST
The pilot program was launched Nov. 2 to foster innovation and advances the integration of UAS into United States’ airspace to ensure U.S. global leadership in the emerging UAS industry.
“There’s already been tremendous interest in the program and more than 4300 people registered to attend our online webinars to learn how they can participate,” the FAA UAS Integration Office said in a statement. “It’s facilitating partnerships between state, local, and tribal government entities and private industry to gather operational and other data from advanced operational concepts, such as flights over people and package delivery. The results from the program will help to inform the development of future enabling regulations that will expand safe UAS operations and help to transition many of the new and novel operational concepts that we manage today by exception into routine, commonplace aspects of our everyday lives.”
Details about applying, timelines, and requirements are at FAA.gov/Go/DronePilot. Those interested can also subscribe to receive email updates from the FAA’s UAS webpage.
U.S. Secretary of Transportation Elaine Chao provided further details of the department’s new Drone Integration Pilot Program at a public event held Nov. 2 at the U.S. Department of Transportation (DOT) headquarters in Washington, D.C.
Chao was joined by hundreds of drone operators, industry leaders, members of the public, law enforcement and first responders, and local, state, tribal and federal officials.
The pilot program is designed to safely test and validate advanced operations through various partnerships across the country with oversight by the Federal Aviation Administration (FAA).
A Federal Register notice lays out the timeframe, requirements, and goals of the new program, which will pair local, state, and tribal entities with private sector players in the drone industry to develop and deploy new operational concepts that are not currently in widespread use.
The first step is for government officials to complete a Notice of Intent, signifying their intention to complete a full program application. Applicants will have 20 days to complete a Notice of Intent, followed by the requirement that they complete an application through the FAA/UAS Portal within 57 days. Within 180 days, initial program applicants who receive approval could begin deploying drones under the limitations coordinated and agreed to with the FAA. The program will last for three years.
After evaluating all the applications, DOT will select a minimum of five partnerships. Full details of the Federal Register Notice and Application process can be found here.
Webinars Scheduled. The FAA is hosting three webinars providing an overview of the program, application process and specific criteria and deadlines that must be met. The webinars will be held on the following times.
The pilot program will evaluate a variety of operational concepts, including night operations, flights over people, flights beyond the pilot’s line of sight, package delivery, detect-and-avoid technologies, counter-UAS security operations, reliability and security of data links between pilot and aircraft, as well as local management of UAS operations subject to FAA oversight.
Industries that could see immediate opportunities from the program include commerce, photography, emergency management, precision agriculture, and infrastructure inspections and monitoring.
The program will help tackle the most significant challenges in integrating drones into the national airspace while reducing risks to public safety and security. The program is designed to provide greater regulatory certainty and stability to local governments and communities, UAS owners and operators who are accepted into the program.
In less than a decade, the potential economic benefit of integrated unmanned aerial systems into the nation’s airspace is estimated to equal up to $82 billion and create up to 100,000 jobs,, according to AUVSI’s The Economic Impact of Unmanned Aircraft Systems.
Chao told attendees the program application and deployment process will move quickly because a priority for DOT is encouraging innovation in the drone industry while maintaining safety for communities involved.
“The drone pilot program will accelerate the safe integration of drones into our airspace by creating new partnerships between local governments, the FAA, and private drone operators,” Chao said. “These partnerships will allow local communities to experiment with new technologies like package delivery, emergency drone inspections, and more, on terms that work for them and in ways that support a unified and safe airspace.”
“This program will put community and industry partnerships at the leading edge of aviation technology,” said FAA Administrator Michael P. Huerta. “What we learn through testing operational concepts in these communities will be invaluable and give us clarity on rules that ensure safety and continued innovation.”
“More and more businesses and public safety providers are embracing UAS to expand and enhance their service offerings,” said Brian Wynne, president and CEO, Association for Unmanned Vehicle Systems International. “This growing demand illustrates a new renaissance in aviation and technology, which requires sustained collaboration and support by government at all levels.”
U.S. Secretary of Transportation Elaine Chao has launched an initiative to safely test and validate advanced drone operations in partnership with state and local governments in select jurisdictions.
Prospective local government participants are asked to partner with the private sector to develop pilot proposals. After evaluating all of the applications, USDOT will invite a minimum of five partnerships.
The department also will publish a Federal Register Notice with more details about how applications will be evaluated and how the program will work.
More about the program is available on the DOT website.
The program will help tackle the most significant challenges in integrating drones into the national airspace while reducing risks to public safety and security, USDOT said. The program is designed to provide regulatory certainty and stability to local governments and communities, UAS owners and operators who are accepted into the program.
In less than a decade, the potential economic benefit of integrated unmanned aerial systems into the nation’s airspace is estimated to equal up to $82 billion and create up to 100,000 jobs, according to an economic report by the Association for Unmanned Vehicle Systems International (AUVSI).
The program will help the USDOT and Federal Aviation Administration (FAA) develop a regulatory framework to:
allow more complex low-altitude operations;
identify ways to balance local and national interests;
improve communications with local, state and tribal jurisdictions;
address security and privacy risks; and
accelerate the approval of operations that currently require special authorizations.
“This program supports the president’s commitment to foster technological innovation that will be a catalyst for ideas that have the potential to change our day-to-day lives,” Chao said. “Drones are proving to be especially valuable in emergency situations, including assessing damage from natural disasters such as the recent hurricanes and the wildfires in California.”
The pilot program will evaluate a variety of operational concepts, including night operations, flights over people, flights beyond the pilot’s line of sight, package delivery, detect-and-avoid technologies, counter-UAS security operations, and the reliability and security of data links between pilot and aircraft.
Industries that could see immediate opportunities from the program include commerce, photography, emergency management, precision agriculture and infrastructure inspections and monitoring.
“Stakeholders will have the opportunity through this program to demonstrate how their innovative technological and operational solutions can address complex unmanned aircraft integration challenges,” said FAA Administrator Michael Huerta. “At the same time, the program recognizes the importance of community participation in meaningful discussions about balancing local and national interests related to integrating unmanned aircraft.”
It’s been a couple of months since we ran an update on unmanned aircraft, so there are lots of news items to dust off and maybe look at more closely.
I suppose we’ve all seen those futuristic movies with masses of orderly air traffic traveling rapidly down invisible roads hundreds of feet above cities — maybe the Jetsons first got us thinking about this vision of tomorrow? Well, unmanned flying taxi demos in Dubai certainly caught my attention. Could this be the launch of the first phase of “airborne street traffic”?
Demo UAVs in Dubai, China
The two-seater UAV built by Volocopter demonstrated in Dubai has 18 rotors, and during the five-minute demo for the media, Crown Prince Sheikh Hamdan bin Mohammed was flown at around 200 meters over sand, rather than over a populated city. There surely could be a number of safety elements yet to be implemented before we see this become operational — but you have to start somewhere.
The Volocopter demo was preceded at the beginning of this year by the appearance of a single-seat Chinese demo vehicle. This smaller eight-rotor drone by EHang took a shot at being a future “over-city” cab.
Urbain Air Project
In the meantime, Airbus and HAX, a start-up investor, are seeking innovators to participate in a four-month program to advance developments in urban-air mobility — innovations which could speed-up development of “flying cars.”
The project is looking for technologies already being developed in:
Urban air transport vehicle technology
UAV sense and avoid technology
Airport runway and landing detection systems
Emergency safety systems for airborne vehicles
Required infrastructure for airborne transport vehicles
Autonomous airborne vehicle technology
Aerial maneuver decision making and support systems
Air traffic management systems
Aerial collision detection and avoidance systems
Battery packaging and management systems for airborne vehicles
Several startups could be funded with at least $100,000 each, and will be asked to spend four months in Shenzhen, China, turning their concepts into prototypes with support from HAX and Airbus engineers.
Safety Standards?
All interesting stuff, but at some stage someone has to take a serious look at the safety standards needed to protect prospective passengers. The existing designs appear to have some flight control redundancy, and there are hints of a possible loss of data-link reversionary mode, but there might be more significant work to be done before any regulatory agency such as the Federal Aviation Administration (FAA) were to validate system reliability. But good luck to these innovators and other companies who are working towards implementing this fascinating concept.
At the other end of the drone spectrum, Renishaw Canada recently showed off a drone made of titanium and produced using 3D printing.
The Firefly is a 3D-printed titanium rocket-powered drone that can fly at nearly supersonic speeds, with onboard telemetry and a spring-released wing. The Mach 0.8 drone has been produced by the Renishaw additive manufacturing group for an unnamed North American aerospace company. The drone can apparently house a number of miniaturized sensors for data collection.
Possible applications of this unique high-speed, short-duration drone could include data collection flying into storms and hurricanes, or perhaps for longer distance surveying when launched from a future Mars rover.
Boeing Acquires Aurora Flight
And on the business front, the recent news is that Boeing is in the process of acquiring Aurora Flight Sciences Corp. Adding Aurora as an independent operation alongside Insitu will probably lead to migration of technology between the two Boeing UAS units, which is presumably why Aurora is being acquired.
Aurora has focused on electric propulsion systems and automation and autonomy for robotic operations and UAVs. Aurora has also collaborated with Boeing in the past on rapid prototyping for drones, and structural assemblies for military and commercial applications.
As a unit of the Boeing Company, Aurora technologies for long-endurance aircraft, robotic co-pilots, and autonomous electric multi-rotor UAVs will have a better opportunity to make it to product level, and wider applications should be possible for these unique capabilities.
Based in Manassas, Virginia, with facilities and offices in five other states around the United States — including R&D facilities right next to Massachusetts Institute of Technology in Cambridge — Aurora employees more than 550 people. They also have an office in Luzern, Switzerland.
FAA Regulations Revisited
Finally, according to AUVSI, in the year since the FAA released the Part 107 regulations for the operation of small UAS (sUAS), users have requested more than 1,000 waivers to work outside the parameters of these regulations. The Part 107 regulations permit users to request such waivers, provided operations can be shown to be safe. The majority of these waiver requests were to operate at night — whereas the regulations only permit operation within Visual Line of Sight (VLOS) in daylight.
AUVSI argues that certain commercial operations have only been possible through the use of these waivers, and therefore the regulations should be revised to enable normal operations without the need to grant individual waivers on a case-by-case basis. The FAA’s position may be that until such operations can be proven to be safe over time, the agency wants to know who’s exceeding which parameters, and under what conditions — hence the need for individual written applications, so that analysis of safety aspects is possible. Then subsequent monitoring will show that levels of operation may be safely exceeded on a regular basis.
This is how aviation agencies have always managed aviation safety. A UAS operator might demonstrate operational capabilities, show an acceptable safety level, and thereby prove that pushing the envelope is okay. Sometimes it can take time, but with good visibility on both sides, it’s possible that progress could be made reasonably quickly.
Following successful test flights, Insitu’s ScanEagle helps combat Oregon wildfire.
UAV company Insitu and Esri have successfully completed test flights on a new way to support firefighting efforts using software for firefighters and first responders.
The flights were held at the Warm Springs Federal Aviation Administration (FAA) Unmanned Aerial System (UAS) Test Range in Oregon. The test site is a Pan Pacific FAA UAS Test Site for commercial UAS testing. The national FAA test site program facilitates the UAS industry in meeting strict customer needs and qualifications.
Insitu is a wholly-owned subsidiary of The Boeing Company.
A week after successfully completing customer acceptance test flights, Insitu, which has more than one million operational UAS flight hours, deployed its INEXA Solutions professional aerial remote sensing teams to aid firefighters in suppressing the Eagle Creek fire in Oregon.
Onlookers watch the fire burn in the Columbia Gorge on Sept. 4. The fire is now contained. (Photo: U.S. Forest Service)
Collaborating with customers to identify business challenges, INEXA Solutions professionals use a continually expanding suite of capabilities such as INEXA Control (ground-based command and control), INEXA Cloud, INEXA manned and unmanned air vehicles including ScanEagle, and INEXA sensors and analytics to provide custom solutions and answers to mitigate business challenges from seabed to space.
Coordinating with the Oregon Department of Forestry and other governing entities, Insitu’s ScanEagle system provided optimal, near real-time data for firefighters and first responders, resulting in heightened emergency response efforts, increased situational awareness and safety, and supported planning and resource allocation.
Equipped with electro-optical (EO) for daylight and infrared (IR) video for nighttime flights, along with mid-wave sensors, the ScanEagle surveyed fire lines at night over the Eagle Creek wildfire, which had spread to nearly 49,000 acres throughout the Columbia River Gorge region.
The ScanEagle can supplement manned firefighting fleets by operating during dense smoke and at night, when manned aircraft typically cannot fly. Infrared camera technology can penetrate smoke and gather and disseminate georeferenced still images of points of interest. These images allow geographic information system (GIS) specialists to perform analysis using Esri’s ArcGIS software.
“Throughout the difficult Eagle Creek wildfire, our thoughts have been with our friends and neighbors impacted by this unfortunate event,” said Mark Bauman, vice president and co-general manager, Insitu Commercial. “We stand prepared to assist local authorities with ongoing operations in any way we can, and we extend our gratitude to all of those working hard to contain the fire.”
ScanEagle poised for launch at Eagle Creek, Oregon, fire.
As the sole aviation overwatch within the temporary flight restriction, the ScanEagle provided persistent nighttime oversight and monitored the progression of the fire. Insitu coordinated manned and unmanned aviation assets and through data collection, analysis and integration capabilities, produced near real-time georeferenced spatial data (maps tied to specific known locations).
In this way, incident commanders, firefighters, and first responders had data that delivered updated incident perimeter maps, identified spot fires, located fire lines and hotspots, and provided near real-time video feed and still images of critical infrastructure, historical structures and more.
“Prior to pursuing any new effort, we consider the reasons we exist as a company — we call it our ‘why,’ explains Jon Damush, Insitu’s chief growth officer. “Insitu’s ‘why’ is to pioneer and innovate in all that we do to positively impact people’s lives and change the course of history,” he continues. “This statement guides our actions and investments, and is precisely why we are doing the things we are doing to help those in need with our unique technologies and professional approach to aviation.”
Hurricane Harvey is the first major catastrophe in which drones have been used on a large scale by both government and commercial operators, said Ken Long, an analyst at the Freedonia Group.
UAVs are also likely to find widespread use if Hurricane Irma either directly strikes or skirts the east coast of Florida early next week, as current projections show.
In addition to helping keep emergency workers safe by allowing them to look for people trapped by floodwaters and inspect damage in high-risk areas, drone use can speed up the recovery process. Drones can be flown over structures such as fuel tanks, power lines and railroad tracks before they can be reached by land, enabling government agencies and utilities to identify what is in most urgent need of repair.
They also allow insurance adjusters to more quickly process claims, enabling rebuilding efforts to get underway faster. Farmers Insurance reports that an insurance inspector using a drone can complete up to eight times the number of home inspections each day than he or she otherwise would be able to do.
When Hurricane Harvey first made landfall in Texas on Aug. 25, the Federal Aviation Administration (FAA) set up a temporary but extensive no-fly zone over Houston and nearby areas to help protect first responders in helicopters and other manned aircraft. This flight ban included all drone operations except those specifically approved by the FAA.
https://youtu.be/XRdUV4WqnDE
In the 10 days that followed Hurricane Harvey, the FAA issued more than 100 separate authorizations for drone use in the Houston area, according to the Wall Street Journal. Some of the applications for drone use were reviewed and approved by the FAA within hours, an unusually fast turnaround time for an agency that typically takes days or weeks to make decisions.
With the exception of a handful of flights conducted by media firms, all of the approved operations were for drones used in conjunction with, or on behalf of, government agencies. Drones were used to inspect bridges, roadways and power lines; assess the condition of oil refineries and water plants; and survey coastal damage.
As the flood waters continued to recede and flight restrictions were eased or lifted, insurance companies — including Allstate, Farmers Insurance, Travelers and USAA — began to use drones to assess property damage and speed claims processing.
However, drone use by insurance companies and other commercial users is limited by FAA rules that do not allow them to be flown above 400 feet, outside the visual line of sight of the operator, or above people not directly involved in their operation, unless a waiver is granted.
These regulations could change with a 2018 FAA reauthorization bill being considered by Congress.
“The demonstrated usefulness of drones in Hurricane Harvey response and recovery efforts could well influence the content of that legislation,” Long said.
Even if the current FAA regulations remain in place, U.S. commercial drone demand will expand rapidly from what is currently an extremely small market base, according to the Freedonia Group’s Drones (UAVs) study. “Non-military government use of drones will also climb at a robust rate through 2020,” Long said.
Both commercial and non-military government market gains will be fueled by further improvements in drone designs, making them more capable and easier to operate, customized for use in specific applications and cost-saving.
NASA’s UAS Traffic Management System was tested May 25 at the Nevada UAS Test Site. (Credit: Drone America)
On May 25, the Federal Aviation Administration (FAA)-designated Nevada UAS Test Site and its NASA partners flew five different unmanned aerial vehicles (UAVs) to test NASA’s Unmanned Aircraft System Traffic Management (UTM).
The flights demonstrated multiple operational scenarios, including parachute-initiated emergency supply deliveries and aerial survey operations.
The UAVs were flown beyond the pilot’s visual line of sight using strategically placed visual observers and sophisticated command and control, communication and detect-and-avoid technologies.
The test is part of a three-week national campaign, which NASA is leading in close collaboration with the FAA and industry partners on a more complex version of its UTM technologies at six different UAS Test Sites around the nation.
The Technology Capability Level 2 (TCL2) National Campaign began May 9 with the Nevada UAS Test Site as the first of six UAS Test Site to begin UTM operations this year.
The partners not only demonstrated drone flight capability, but also tested UAS traffic mapping, sensor and radar technology, all of which were connected through a NASA UAS service supplier network to NASA Ames Research Laboratory.
Six FAA UAS Test sites and industry partners integrate their technologies with NASA’s UTM research platform and test the UTM concept in a range of conditions representative of those in the U.S. Airspace, explaind Tom Prevot, UTM project manager.
“For the Nevada NASA Team, we flew the longest multi-faceted NASA UTM flights to date in Nevada,” Prevot said. “The beyond-line-of-sight missions we completed over a distance of 13 miles north of Reno, Nevada, and the multiple aerial parachute package-delivery missions performed were a first in the National Airspace System under the NASA UTM.”
Current testing of the UTM TCL2 Test marks the second year in a row NASA has taken its UTM technologies on the road to further assess and refine their capabilities. During April 2016, NASA and its partners tested TCL1, which involved line-of-sight operations, and then began the first phase of TCL2 demonstrations in October 2016.
Two more phases, TCL3 and TCL4, each progressively more complex and involving flying drones with specific tasks over increasingly populated areas, are scheduled for 2018 and beyond.
The aerial parachute package-delivery missions performed were a first in the National Airspace System under the NASA UTM. (Credit: Drone America)
“Our Nevada NASA partners did an amazing job in extending the body of airspace management and sense-and-avoid knowledge under the UTM and across the UAS Industry,” said Chris Walach, director of the Nevada UAS Test Site. “The National Campaign data provided to NASA from our two-week operation will go a long way toward advancing the UTM for the FAA and the UAS Industry.”
“At AirMap, we consider UTM to be a critical ingredient for a thriving drone ecosystem,” said Steve Willer, business development manager for AirMap. “The TCL 2 trials demonstrate that technologies for geofencing, data exchange, and more can enable safe and sophisticated drone operations, even beyond line of sight. Along with NASA, the FAA, and NIAS we’re excited to show how UTM can chart a safe course for the drone ecosystem.”
“Drone America is a proud participant in a Nevada Institute for Autonomous Systems (NIAS) led NASA Unmanned Traffic Management (UTM) program at the Reno Stead Airport,” said Mike Richards, president and CEO of Drone America. “The safe integration of Unmanned Aerial Systems (UAS) into the National Airspace System (NAS) is critical to the future of this industry. Drone America is fortunate to call Nevada our home. Working in a state that is very supportive and business friendly makes a tremendous difference to our future sustainability. Our partnership with NIAS and NASA will not only contribute to successful testing, this partnership will pave the way for future generations to experience the true value of autonomous systems.”
“Carbon Autonomous Systems of Reno, in conjunction with their partner SmartPlanes of Skellefteå, Sweden, successfully took part in the planning, coordination, and flying in the most recent TCL2 NASA / NIAS UAS/UTM exercises conducted at the Reno Stead Airport UAS Test Range of the Nevada FAA UAS statewide test complex,” said John Hammond, chief pilot for Carbon Autonomous.
NIAS was also supported by Delair-Tech and SensoFusion who provided UAS and drone detection UAS technologies, which were also tested during this NASA UTM TCL 2 Test.
“We have been designing, manufacturing, and operating UAVs in the civilian airspace for almost 10 years in 100 countries,” said Benjamin Benharrosh, co-founder and head of Delair Tech North America. “This landmark agreement with NIAS, and the associated data collected for the UTM system designed by NASA at the Reno UAS Test Site will push our traffic management technology to a new level of precision and insight. We are thrilled to collaborate with NIAS on solutions that represent a new era for the commercial UAV market and a better presence of Delair-Tech in the U.S.”
“We’re excited to be shaping the future of air traffic management as an official partner of the NIAS by providing our counter-UAS solution, AIRFENCE, in the ongoing NASA UTM project. AIRFENCE is playing an active role in detecting, locating, and tracking UAS as part of the project, providing rich data to NASA as they develop their UTM system,” said Kaveh H. Mahdavi, Sensofusion VP of operations.
“NASA is one of Nevada’s most valuable partners. We appreciate the opportunity to support NASA’s UTM development. It is truly cutting-edge technology and will be instrumental in integrating UAS into the national airspace,” said Tom Wilczek, Aerospace & Defense Industry Representative for the Nevada Governor’s Office of Economic Development.
A May 19 meeting convened by the American National Standards Institute (ANSI) confirmed there is broad-based support among key stakeholders from the private and public sectors for ANSI to establish an Unmanned Aircraft Systems (UAS) Standardization Collaborative (UASSC).
The UASSC will work to coordinate and accelerate the development of the standards and conformity assessment programs needed to facilitate the safe, mass integration of UAS (drones) into the national airspace system of the United States.
Initial priority areas of focus are expected to include:
UAS airworthiness
command and control systems
remote identification
flight operations, including operations over people and beyond visual line of sight
licensing, training, qualification and certification
sense and avoid systems
safety and risk management
An initial kick-off meeting is anticipated in the third quarter of 2017. To stay up to date regarding future developments, email Jim McCabe, ANSI senior director, standards facilitation, at [email protected].
The collaborative will also focus on international coordination and adaptability, with the goal of fostering the growth of the UAS market. The work effort will entail the development of a standardization roadmap to identify existing standards and standards in development, define where gaps exist and recommend additional work that is needed, along with a timeline for its completion and organizations that can perform the work.
ANSI Standardization Collaboratives are formed to support emerging technologies and national and global priorities by advancing cross-sector coordination in the development and compatibility of standards and conformance programs.
Ultimately, the purpose of such initiatives is to describe the current standards landscape, articulate standardization needs, inform resource allocation for standards participation, and drive coordinated standards activity while minimizing duplication of effort.
As a neutral facilitator, ANSI has a successful track record of having convened a number of such collaboratives in areas as diverse as homeland security, electric vehicles, energy efficiency in the built environment and, most recently, additive manufacturing.
The May 19 meeting drew close to 70 participants representing more than 40 organizations from industry, trade associations, standards developing organizations (SDOs), federal agencies, academia and others. The public- and private-sector co-chairs for the meeting were Earl Lawrence, director of the UAS Integration Office, Federal Aviation Administration, and Brian Wynne, president and CEO of the Association for Unmanned Vehicle Systems International (AUVSI).
ANSI has been in dialogue with numerous stakeholders over the past year on this topic, including via panel discussions during the 2016 ANSI Joint Member Forum and at the April 2017 ANSI Company Member Forum. A number of SDOs already are involved in UAS standardization, underscoring the need for coordination to achieve a coherent set of standards.
“Given our history of bringing public- and private-sector stakeholders together to identify standardization needs to support new technologies, ANSI is well suited to facilitate the need for standards coordination in this exciting new technology area,” said ANSI president and CEO S. Joe Bhatia.
Raytheon Company has launched its GEO 6 satellite payload into orbit for its 12-year mission. It is the latest payload to support the Federal Aviation Administration’s (FAA) Wide Area Augmentation System (WAAS), which enhances the reliability and accuracy of GPS signals for directing air travel.
The Raytheon-developed payload is a key element of WAAS, which offers commercial, business and general aviation pilots more direct flight paths, greater runway capability and precision approaches to airports and remote landing sites without dependence on local ground-based landing systems.
“This latest payload launch is the next step in our journey with the FAA to bolster navigation safety and efficiency for commercial and general aviation,” said Bob Delorge, vice president of transportation and support services for Raytheon Intelligence, Information and Services.
In June 2016, Raytheon launched WAAS GEO 5, which was recently accepted by the FAA for integration into the operational WAAS system. Both WAAS GEO 5 and GEO 6 were launched to replace aging satellites and enhance GPS precision for the FAA. WAAS increases GPS accuracy from 10 meters to approximately two meters and supports nearly all of the national airspace.
The WAAS GEO 6 payload is hosted on a geostationary satellite, SES-15, owned and operated by SES. The satellite was successfully launched May 17 from Arianespace’s Guiana Space Center in French Guiana aboard a Soyuz launch vehicle.
More than $20 million for research on unmanned aircraft systems (UAS) was included in an appropriations package that Congress passed and the president signed into law last week to fund the federal government through the end of the fiscal year on Sept. 30. The funding for UAS research is $2.67 million more than last year’s budget request by the Federal Aviation Administration (FAA) to address a host of research challenges associated with integrating UAS into the national airspace system.
The measure’s section on appropriations for transportation agencies also includes $20 million above the 2016 budget request for the FAA’s air traffic control organization. The increase will provide for the hiring and training of new controllers and accelerating UAS airspace integration. The agreement also includes $11.5 million more than was requested for aviation safety activities for UAS integration, including the addition of six full-time positions to support the certification of new technologies and advance the FAA’s organizational delegation authorization (ODA) efforts and strengthen safety oversight.