News

Alpha 800 UAV to Support NATO’s Trident Juncture 2018 Exercise

The Spanish UAV manufacturer, Alpha Unmanned Systems will present the Alpha 800, gasoline-powered helicopter UAV, at NATO’s Trident Juncture exercise in Trondheim, Norway. From October 25th to November 7th, a live field exercise will take place, spanning air, sea and land areas of Norway. 45,000 participants from 31 nations are deployed for the event. During the exercise Alpha Unmanned will take part in the Enhanced Logistical Base demonstration, where leading players will show the future of military logistics. Alpha Unmanned Systems will exhibit its Alpha 800 helicopter UAV. The Alpha 800 is a tactical 14 kg gasoline powered helicopter that provides 2.5 hours of continuous flight with a 3 kg payload and 30 km of operating range. It is equipped with the lightest and strongest airframe in its class and a military-grade autopilot with high precision GPS and sensors. It is well suited for surveillance and for the delivery of urgently needed supplies. The Trident Juncture 2018 is an excellent event to carry out complex air operations, and it’s a great chance to highlight the Alpha 800, a reliable UAV platform “Made in Spain” and designed for hard work in challenging and complex environments. Find out more about the Alpha 800 at Unmanned Systems Source.

Aeromapper Releases the Talon Amphibious UAV for Long-Range Maritime Operations

The Aeromapper Talon Amphibious by Aeromao is the world's first fixed-wing drone for commercial maritime operations that can belly land on water or parachute down. With its dual cameras and 20km video link, it’s the perfect solution for observation, data collection and mapping.  

Talon Amphibious

There are very few Unmanned Aerial Vehicles (UAV) or drones that safely land on water. Thus the Talon Amphibious, with its watertight design, is a welcome solution for all UAV maritime and freshwater applications. Even better, this amphibious unit is affordable and multi-functional. Plus, true to its fixed-wing design, it offers extended flight time, substantial payload capacity, and extensive range. The UAV is simple to retrieve from the water using a small boat. Or, the operator can land on a beach. With a cruise speed of 60kph, +30km communication range and 2-hour flight endurance, it easily covers vast areas. As such, it saves both money and time. Plus, its internal GPS beacon makes locating and retrieving the UAV easy. The Talon Amphibious is quick to assemble and deploys by hand-launch from the shore or from a maritime vessel without disruption to the GPS system. Its waterproofed fuselage and internal marine-grade components that resist saltwater corrosion, make the Talon Amphibious system uniquely suited to life on the water. There are a range of customization options available for the Talon.  

Tried and Tested

The Talon Amphibious underwent extensive testing in some of the most challenging marine conditions. Original design inspiration for the UAV came from marine ecologist and field biologists. Their work conditions include maritime vessels and remote island locations. And though these locations may appear idyllic, they present many logistical problems and constraints when it comes to gathering data. Scientists needed a UAV which could endure harsh environments such as rain, wind and waves. The Talon successfully completed operations in the British Indian Ocean Territories (BIOT) as part of a scientific expedition led by the Zoological Society of London. This is the first time that a fixed-wing amphibious UAV was used in the UK Overseas Territories. The applications of a water landing unit in marine ecological surveys, fisheries management and maritime surveillance are vast. In addition, an MSc student from Imperial College London piloted and tested the amphibious UAV. He described the unit as: “An incredible tool for gathering vast amounts of ecological and habitat data, safe in the knowledge that we can easily land anywhere near the main vessel or on the ocean. In the tropics, rain clouds can often hit out of nowhere, and with this amphibious UAV, we no longer have to worry about rain water leaking in, either.” Over 25,000 images were collected during the ecological surveys and the scientists were able to analyse the images to calculate the abundances of sharks and birds. Their camera of choice was the Garmin VIRB which allowed for geotagging of each image. The Talon Amphibious is garnering plenty of interest in the research world. Scientists and managers from around the world are looking to implement this maritime solution into their coastal project operations.  

Learn more about the Talon Amphibious and find the entire line of Aeromao products at Unmanned Systems Source.

Fruity Chutes Releases Matrice 200/210 Parachute Recovery Systems

Fruity Chutes, the leading manufacturer of drone parachute recovery systems, adds to their line with the Matrice 200 and Matrice 210 Automatic Emergency Drone Parachute. Designed entirely with the end-user in mind, it is lightweight, easy to use and reliable. Users can pack and load the parachute, eliminating the need to send it back to the manufacturer after each use. Designed for several uses, it comes with a parachute rigger jig to make folding and packing easy. To launch the parachute the bundle provides the Harrier parachute launcher.  The Harrier features a high energy compression spring that quickly ejects the parachute out and away from the Matrice 200/210. The launcher has no regulatory or transportation limitations.  

Iris Ultra Light Chute

The centerpiece of the parachute system is the Fruity Chutes Iris Ultra Light Chute which weighs just 4.8 oz (135g). With a nominal rating of 13.6 lbs (6.2Kg) @ 15 feet per second (4.6Mps) descent rate after deployment it provides a nice gentle landing. The parachute can easily work at heavier load weights of 10Kg or more allowing operators to use optional heavier cameras or batteries without worry. The system is entirely self-contained and not reliant on the Matrice 200/210 power. As such, the parachute system works even if the copter’s battery has a complete failure.  The automatic trigger system (ATS) detects if the drone suddenly falls, rolls, or flips. Detection of a fall typically takes just 0.75 seconds, or about 16 feet of free fall.  The parachute ejects before the pilot notices there is a problem. The Skycat Rescue Radio is based on the Team Black Sheep Crossfire 250mw transmitter (1W also available) and the TBS Nano receiver. The system uses 868MHz (EU, Russia) or 915MHz (USA, Asia, Australia). When combined with the ATS the parachute can be both automatically deployed in case of a failure, or manually deployed by the pilot in command in case the pilot loses contact with the drone, such as a flyaway. Operation other than 2.4 Ghz allows the rescue radio, and the Matrice transmitter to avoid interference. All Fruity Chutes products have a 2 Year warranty against manufacturing defects.  

Shop Fruity Chutes' line of products, including the new Matrice 200/210 Parachute System, at Unmanned Systems Source.

FAA Approves Nine New LAANC Service Providers

The Federal Aviation Administration (FAA) announced nine new partners to its Low Altitude Authorization and Notification Capability (LAANC) initiative. LAANC is an innovative collaboration between the FAA and the drone industry. The initiative provides near real-time processing of airspace authorizations for Part 107 drone operators nationwide who fly in controlled airspace.  

LAANC Expands

Following the FAA’s successful prototype, the initiative was simultaneously opened to additional air traffic control facilities and to new industry partners. The five-month on-boarding process that began in April resulted in nine new LAANC partners. Those partners include: Aeronyde, Airbus, AiRXOS, Altitude Angel, Converge, DJI, KittyHawk, UASidekick and Unifly. The nine joined five companies – AirMap, Harris Corp., Project Wing, Skyward and Thales Group. All met the technical and legal requirements to provide LAANC Services.  

How it Works

LAANC uses airspace data, including UAS facility maps, which shows the maximum altitude around airports where the FAA may authorize operations under Part 107 in controlled airspace. Drone operators can interact with industry developed applications and obtain near real-time authorization from the FAA. LAANC, a foundation for developing the Unmanned Aircraft Systems Traffic Management System (UTM),is now available at nearly 300 FAA air traffic facilities across the country, covering approximately 500 airports. Next year, from January 7 to February 8 and from July 8 to August 9, the FAA will accept applications from parties interested in becoming LAANC service providers. This is not a standard government acquisition; there is no Screening Information Request (SIR) or Request for Proposal (RFP) related to this effort. Interested parties can find information on the application process here.

Transitioning Vehicles – Looks Can be Deceiving

Transitioning UAVs, which combine fixed-wing aircraft with a multi-rotor, seem to be a favored development craft these days.

The resulting vehicle combines the multi-rotor’s ease of takeoff and landing with the endurance of a fixed wing UAV. What's not to like?

 

Quad-planes and Tilt-rotors

There are two main types of transitioning vehicles: quad-planes and tilt-rotors. The quad-plane uses a separate set of motors and propellers for lifting than it does for forward flight. During hover, the forward flight motor is off and during forward flight, the lifting motors are off. The tilt-rotor shares lifting and forward flight motors. Two, or more, of the lifting motors/propellers tilt forward during the transition from hovering to forward flight. They tilt back to vertical during the transition back to hovering flight. Of course, there is a price to pay for the ability of a fixed wing UAV to hover: complexity, cost, and weight all increase. Drag also increase, which has significant effect on endurance. This effect is great enough that transitioning vehicles make much more sense for gas powered UAVs. It isn’t difficult to design a fixed wing UAV with an endurance of ten, or more, hours. Sacrificing a couple hours endurance for the ability to hover is a decent trade-off. In an all-electric UAV, the endurance is less and the cost of the ability to hover is a much larger percent of the UAV’s overall endurance.  

Propeller Considerations

When comparing a quad-plane style UAV to a tilt-rotor, the designer might consider the reduction in the number of motors an advantage. Again, this advantage comes at a cost related to the propellers’ pitch. The optimum propeller pitch for forward flight is different from the optimum pitch for hovering. Since a quad-plane uses different propellers for forward flight than it does for hovering, the designer is free to choose the most efficient propeller for each phase of flight. The designer of a tilt-rotor does not have this freedom. A compromise occurs between a propeller optimized for hovering versus one optimized for forward flight. As such, the designer must either accept less payload or less endurance. Another disadvantage of tilt-rotors is they must use electric propulsion. You cannot mix a gas engine for forward flight with electric motors for hovering. Endurance is not the only challenge when designing a transitioning UAV. Wind also presents some challenges, primarily when hovering.  

Vertical Stabilizer

When flying a quad-plane in a wind, the wind creates airflow over the wings and tail of the quad-plane and this generates forces that are a challenge for the quad-plane. The most obvious problem comes from the vertical stabilizer. If the vertical stabilizer is not aligned with the wind, it generates a yawing moment that tries to turn the UAV into the wind. The problem is that while multi-rotors have excellent pitch and roll control, their yaw control is weak. It is very easy for the torque generated by the vertical stabilizer to overwhelm the quad-plane’s ability to hold a heading when hovering in a wind. This can be a problem if the direction you are facing when your UAV transition to forward flight matters. For example, if hovering near a structure and the wind turns the quad-plane so that it is facing the structure, it cannot transition without hitting the structure. Tilt-rotors do not suffer from this drawback as you can control yaw by tilting one of the motors. This provides very strong yaw control.  

Airflow

Another problem is airflow over the wing when hovering in a wind. In order to hover in a wind, the quad-plane must tilt into the wind. This puts the wing at a negative angle of attack and the wing will generate lift in the downward direction. Now the lifting motors must lift not just the weight of the UAV but must also overcome the force generated by the wing. This is a significant challenge because quad-planes are usually heavy – near the maximum lifting capacity of its motors, and the wing’s downward force can seriously limit the UAV’s ability to climb when hovering in a wind. The usual solution to this problem is to use the quad-plane’s forward flight engine to help hold position. The quad-plane can then hold a more level attitude and the airflow over the wing can help the quad-plane climb. Note that using the forward flight engine only helps if the quad-plane is pointed into the wind. Tilt-rotors also suffer from this challenge. A tilt-rotor can tilt its motors into the wind to help hold position.  

Center of Gravity

Another complication with both a quad-plane and a tilt-rotor is the center of gravity. The UAV designer has essentially combined two UAVs into one and each of the two UAVs needs the center of gravity in the correct location. The multi-rotor works best if the center of gravity is located centrally between the motors. The fixed wing needs the center of gravity about a third of the distance between the wing’s leading and trailing edges. It is not difficult to arrange the correct center of gravity, but it is another detail that needs attention.   As with all UAVs, the designer of a transitioning UAV faces many trade-offs. The correct choice is dictated by the task the UAV must perform. Given the very poor yaw control of a quad plane and the tilt-rotor’s inability to combine gas and electric motors; it may be worth considering a hybrid of hybrids. A quad-plane with tilting motors to ensure adequate yaw control provides the best of both worlds and is likely worth the cost and weight of the extra tilting mechanisms.
 

Shop MicroPilot's complete line of autopilot solutions at Unmanned Systems Source.

Reliable Operation in a Multi-Drone Environment

From their military origins a few decades ago -- carrying sophisticated systems and running remote, cross-boarder missions -- drones are now commercial and industrial platforms. Today, drones play a significant role in the next generation of automated and autonomous vehicles. The vision of multiple drones filling in the public sky, running various missions smoothly is slowly becoming a reality.  

Operational Reality

In fact, drone operation in such an environment is so challenging that stable and reliable communication is crucial. The communication infrastructure must provide carrier-class availability, ensuring control and telemetry signals are available in real-time. And, that critical data flows between the drone and operation control centers. In addition, automated airspace management systems must guarantee full coordination between different vehicles using the same air space. These systems are called UTM (Unmanned Traffic Management) systems. The dynamic nature of the drone’s operation should have a ‘network’ planning perspective rather than a ‘link’ based perspective. All drones utilize RF (radio frequencies) to communicate with their respective ground stations and, eventually, with each other. As frequency bands and channels are scarce and are also used by other platforms such as Wi-Fi systems, interference is the major obstacle for reliable communication. The more drones in a given area, the more fragile each link becomes due to other system interference. This poses a significant challenge for inter-operability of multi-drones in a given environment.

Communication Challenges in a Multi-Drone Environment

For example, the delivery market is one of the most complex drone applications. It requires running multiple drones in parallel, by different service providers. Some of the related communication challenges include:
  • Near-End Interference – generated by other drones launched from the same or nearby network operating centers.
  • Far-End Interference – generated closer to the landing area, from Home Routers such as WIFI or other systems operating nearby such as agriculture drone systems.
  • In-Flight interference – from other drones flying nearby, Radio Control (RC) recreational vehicles.
  • BVLOS operation – flying in an urban area can generate signal loss and fading due to high-rise buildings and other obstacles.
  • Terrain Obstacles – rural operation may introduce signal fading due to Fresnel zone blocking by a hilly terrain.
  • Interoperability with mobile networks – utilizing dual combined communication can increase reliability but must include a smooth switch-over mechanism when the public network is congested or out of reach.
Each challenge is complex and requires a different solution. However, the overall requirements from a drone communication system operating in a crowded sky must include dynamic configuration, fast response to changes and transparency to the user. Eventually, the entire operation will be fully automated from takeoff to landing.

Solutions for Reliable Operation in a Multi-Drone Environment

There are different solutions for overcoming these and other challenges. Some relate to the core technology utilized by the communication systems themselves, such as features that can guarantee higher reliability due to diversity and redundancy. Others relate to switch-over mechanisms between different technologies, utilizing the LTE/5G networks for long range urban operation for example. Minimizing interference on one hand, and greater immunity to interference by switching frequencies in-flight on the other hand, are also crucial for a secured safe operation. By integrating and adopting such capabilities as a standard by the drone operator’s community, alongside with administrative and airspace usage coordination systems, we can overcome many of above challenges and guarantee a reliable and safe operation in a multi drone environment.  

Shop Mobilicom's complete line of data link solutions at Unmanned Systems Source.