The Northrop Grumman EQ-4B Global Hawk autonomous aircraft converted to carry the Battlefield Airborne Communications Node (BACN) has now been delivered to the U.S. Air Force. (NGC photo)

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16/08/2018

Turkey to Offer ANKA MALE Drone to Indonesia

JAKARTA --- Turkish Aerospace, Turkey’s center of excellence in defence and aerospace industries held a workshop on August 14th, 2018 in Jakarta with an extensive participation of Indonesian Defence and Aviation Industry companies, regarding the possible cooperation on upcoming several bilateral opportunities such as Unmanned Aerial Vehicle System Tender of the Indonesian Ministry of Defence. With long experience in merging and integrating the capabilities of local and global companies, Turkish Aerospace is now exploring the opportunity to cooperate with Indonesian defence and aviation industry companies with unique and exclusive qualifications, in order to bring the already proven capabilities of the “ANKA Unmanned Aerial Vehicle System” to new heights, through the Indonesian UAV System Tender. As indicated and underlined repeatedly, Turkish Aerospace is ready to fine tune its persistent multi-role ISTAR (Intelligence, Surveillance, Target Acquisition, and Reconnaissance) system ANKA to satisfy the specific requirements of the Indonesian end-user, through integrating distinguished Indonesian suppliers into its supply chain. Turkish Aerospace is a global player in defence and aerospace industries through its capabilities in design, development, modernization, manufacturing, integration and life cycle support of integrated aerospace systems, from fixed and rotary wing air platforms to unmanned aerial systems (UAS) and space systems. The widespread product and activity range of Turkish Aerospace is an indication that this newly blossoming cooperation between Turkish Aerospace and Indonesian industry will not be limited to the UAV Systems. It will be a sustainable, long-term win-win relationship, in which all parties will find opportunities to advance their business goals in local and global markets in the medium run. ANKA, advanced Medium Altitude Long Endurance (MALE) class Unmanned Aerial System, performs day and night, all-weather reconnaissance, target detection/identification and intelligence missions with its EO/IR and SAR payloads, featuring autonomous flight capability including Automatic Take-off and Landing. -ends-
16/08/2018

Germany Orders Skeldar Helicopter Drones for Its Navy

On 3 August 2018, a procurement contract concerning a new, unmanned aerial reconnaissance system for the Navy was concluded between the Federal Office of Bundeswehr Equipment, Information Technology and In-Service Support and Elektroniksystem- und Logistik-GmbH. From the end of 2019 onwards, the SKELDAR V-200 unmanned reconnaissance system is expected to take off from the class 130 corvettes of the Navy. This was agreed between BAAINBw and ESG at the beginning of August in Koblenz. The new helicopter drone will make it possible to perform reconnaissance tasks even beyond the range of the ship’s own sensors. “By concluding this contract, we are strengthening the Navy with a significant unmanned, imaging reconnaissance capability and thus lay the foundation for future steps”, explains LTRDir Axel Hoffmann, who manages the project for BAAINBw. The contract was concluded with Elektroniksystem- und Logistik-GmbH (ESG) as main contractor and UMS SKELDAR and Lürssen Werft as subcontractors. The procurement project includes one unmanned aerial vehicle of the SKELDAR V-200 type, consisting of two unmanned aerial vehicles as sensor carriers, full system integration into the class 130 corvette, a spare parts package as well as training of the operator and maintenance personnel. -ends-
10/08/2018

Airbus Solar UAV Sets New Record for Longest Aircraft Flight

FARNBOROUGH, U.K. --- Airbus Defence and Space announced the successful landing of its first production aircraft of the Zephyr programme, the new Zephyr S HAPS (High Altitude Pseudo-Satellite). After taking off on 11th July in Arizona, USA, Zephyr S logged a maiden flight of over 25 days, the longest duration flight ever made. An application has been made to establish this as a new world record. This maiden flight of the solar powered Zephyr S proves the system capabilities and achieved all the flight’s engineering objectives. The previous longest flight duration record was also logged by a Zephyr prototype aircraft a few years ago, achieving then more than 14 days continuous flight, which already was ten times longer than any other aircraft in the world. This new record flight was supported by the UK government and reflects the UK Ministry of Defence’s position as the first customer for this innovative and potentially game changing capability. Zephyr is the world’s leading, solar–electric, stratospheric Unmanned Aerial Vehicle (UAV). It harnesses the sun’s rays, running exclusively on solar power, above the weather and conventional air traffic; filling a capability gap complimentary to satellites, UAVs and manned aircraft to provide persistent local satellite-like services. “This very successful maiden flight represents a new significant milestone in the Zephyr programme, adding a new stratospheric flight endurance record which we hope will be formalised very shortly. We will in the coming days check all engineering data and outputs and start the preparation of additional flights planned for the second half of this year from our new operating site at the Wyndham airfield in Western Australia” said Jana Rosenmann, Head of Unmanned Aerial Systems at Airbus. Zephyr will bring new see, sense and connect capabilities to both commercial and military customers. Zephyr will provide the potential to revolutionise disaster management, including monitoring the spread of wildfires or oil spills. It provides persistent surveillance, tracing the world’s changing environmental landscape and will be able to provide communications to the most unconnected parts of the world. -ends-
10/08/2018

Israel Lifts Veil on Anti-Drone Task Force

The use of drones has become widespread over the past years. Besides their advantages, there also exists the risk for malevolent use. The IAF has recently established a national task force meant to counteract the drone threat Several months ago, the IAF established a national task force meant to counteract the rising threat of drones. The task force was established as part of the "Magen" (Shield) Directorate, and its goal is to develop assistive technological capabilities for all relevant factors. "We established a national counter-drone task force in order to develop a proper response", said Col. A', Head of the "Magen" Directorate, at a panel discussing Israel's national preparation against the drone threat. "The task force is led by the IAF and includes the Technical and Operations Departments as well as the Administration for the Development of Weapons and Technological Infrastructure. The crew is in communication with all relevant factors, including the Israel Police and the Israel Security Agency. The work was previously handled by IAF service members alongside their routine work, but now a designated task force exists". Dangerous Potential "The IAF has dealt with the drone threat since the beginning of 2016, when it was realized that this was a threat which needed to be taken care of", said Lt. Col. D', Head of the Counter-Drone Task Force. "Since then, the 'Magen' Directorate has added counter-drone activity to their objectives. Events occurring in Israel and around the world led to the realization that drones may pose a threat. In the past, drones were only operated by hobbyists. However, technological developments which occurred over the last few years made drones and their operation much more common". Lt. Col. D' added: "Drones no longer need to be built – they are now purchasable. Certain advancements in the fields of sensors and photography led to the fact that drones can not only be easily operated, but also be used to easily perform missions. This makes them a threat – now, anyone can have a potentially harmful device in their hands". "Not the enemy" "Drones in general are not our enemy", emphasized Lt. Col. D'. "Drones are amazing and their use should be allowed. We see them develop throughout the world, from recreational use to commercial use in the fields of security and agriculture. Some companies predict that drones will act as their shipping carriers in the future. And yet, security forces from around the world are worried about the drones' malevolent potential". "There are suddenly many aircraft flying in the sky. This bears an influence on civilian aviation", said Lt. Col. D'. "Certain situations are potentially harmful, such as an aircraft preparing for landing before having a drone pass it by. This is not a terrorist event, but an event where an innocent civilian operated a drone in an unsafe manner which could have damaged the aircraft. Events of this sort have worried security forces across the globe, who then begun activity in the field of drones as a result". National Challenge Drones are a national challenge, and the IDF's operation in this field includes prevention of their incursion into Israel's territory, protection of strategic locations and defending the IDF's field of operation. Several drones have been intercepted as part of the IDF's routine security activity over the past year. "The task force is national and its missions aren't related solely to the IAF and the IDF", elaborated Lt. Col. D'. "The task force's counter-drone activity is also related to the Ministry of Defense, and should include protection of airports and detention centers, while also assisting the Israel Police in security. If someone from outside the IDF wants to take care of a drone which enters his airspace, he needs to be in communication with the IDF. When establishing the operation plan against the drone threat, we factor in the needs of every relevant factor in Israel and try to provide a focused response". -ends-
10/08/2018

Estonia to Develop Unmanned Land Systems with Finland, Latvia

Estonia, together with the ministries of defence of Finland and Latvia, is planning to develop unmanned land systems within the framework of the European Union’s Permanent Structured Cooperation. Germany, France and Belgium have also expressed interest in joining the project. ‘The same considerable growth that we saw with unmanned aerial vehicles (UAVs) 10-15 years ago can be expected in the near future for unmanned land platforms. The project’s ambition is, in cooperation with partners, to develop a solution for unmanned land systems, which would become the European standard,' said Kusti Salm, Director of the Defence Investments Department at the Ministry of Defence. An unmanned land vehicle, along with an autonomous control system, cyber defence solution and integrated network of sensors, will be developed within the framework of the project. The system’s initial functions are associated with improving situational awareness on the battlefield and raising the level of efficiency of the manoeuvring and transportation capabilities of troops. The result must be a reliable companion for a soldier on the battlefield, one that would increase his decision-making speed, reduce the load he is carrying, and increase his endurance and defence. ‘A reliable system is not exclusively vehicle oriented. True innovation emerges from the autonomous control system, and integration with sensors and other manned and unmanned platforms, such as UAVs, radars, control points, etc.’, added Salm. A total of EUR 30-40 million has been earmarked for use from the European Defence Fund, with participating countries also set to make a contribution. The start date for the planned project is the first half of 2019. In preparation for the project, Estonia has started, under the leadership of the Estonian National Defence College, a research and development project for raising the tactical level of unit combat capabilities for unmanned systems, which is being implemented in cooperation with the nine members of the Estonian defence industry consortium. The unmanned land system development project was submitted to the second application round for PESCO projects. The approval of EU ministers of defence is required in order to start projects that are being carried out within the framework of the European Union’s Permanent Structured Cooperation. -ends-
10/08/2018

India’s HAL Demonstrates 10-Kg Helicopter UAV

BENGALURU, India --- The Hindustan Aeronautics Limited successfully demonstrated flight of a 10Kg Rotary Wing (Helicopter) Unmanned Aerial Vehicles (RUAV) here in the presence of its Board of Directors, recently. The RUAV is of a 2-stroke petrol engine, twin blade main rotor and tail rotor, payload capability of 2.5Kg including live stream video camera and range of the vehicle is 8-10 Km with an endurance of one hour. The flight lasted for about ten minutes during which the Attitude Control Attitude Hold (ACAH) mode, Position Control, Position Hold mode (autonomous hover), low speed flight in forward, backward and sideward directions, were demonstrated. The video feed from onboard the helicopter was streamed live and shown on the dedicated video receiver. The status of the helicopter, its parameters and its real-time position on the map were also shown. To achieve self-reliance in the aviation field and to enhance its R&D efforts, HAL is working closely with premier educational institutes and has established chairs at IITs (Madras, Roorkee, Kharagpur, Bombay, Kanpur) and IISc Bengaluru. The RUAV is developed in association with IIT Kanpur and is the first outcome of HAL’s tie-ups with academia. With this demo, HAL’s Rotary Wing R&D Centre (RWR&DC) is well poised to employ its skills and capabilities to undertake development of Rotary UAVs of higher weight classes and weapons as payloads. The success is the testimony of the Industry-academia collaboration, says Mr. T. Suvarna Raju, CMD-HAL The RWR&DC at HAL is the unique R&D Centre in the country involved in Design and Development of Rotary Wing Platforms (Helicopters) Military and Civil operations. Advance Light Helicopter in its different variants (ALH-Dhruv, ALH-Rudra, ALH Wheeled version) is one of its star products and in service with the Indian Defence Forces. The Light Combat Helicopter is also designed and developed by this Centre and is under production for Indian Army and Indian Air Force. The RWR&DC having wide and varied experience, strong skill sets in development of Rotary Platforms has partnered with Indian Institute of Technology, Kanpur (IITK) to embark upon design and development of a Rotary Unmanned Air Vehicle (RUAV) for Defence and Para-Military Forces and homeland security. These efforts led to successful development of control laws, a full authority flight controller, also known as Fly By Wire system for helicopters and other associated technologies like autonomous navigation system, ground control system etc. -ends-
10/08/2018

Wind Tunnel Verifies Carrier Suitability of MQ-25 UAV Design

SAN DIEGO --- General Atomics Aeronautical Systems Inc. (GA-ASI) is proud to announce the completion of the fourth wind tunnel test of its MQ-25 design. MQ-25 is the U.S. Navy’s program to develop an unmanned refueling tanker that provides exceptional fuel give and more than doubles the strike range of the Carrier Air Wing. During this most recent low-speed wind tunnel test, the performance of the high-lift system and spoiler-based direct lift control (DLC) were verified in the presence of a heavily instrumented flow-through duct. The results were consistent with Computational Fluid Dynamics (CFD) predictions and further verified the aircraft’s ability to execute launch, recovery, waveoff, and bolter maneuvers on an aircraft carrier. “The wind tunnel testing helps us to accurately predict the aircraft’s suitability for carrier operations,” said David R. Alexander, president, Aircraft Systems, GA-ASI. “The test results allow us to verify the aerodynamic characteristics of the Unmanned Aerial Vehicle (UAV). These tests are critical to the validation of the system’s ‘up and away’ mission performance and will subsequently lower technical performance risk for the Navy customer.” Previously, GA-ASI also carried out a high-speed test at NASA Ames’ 11-foot transonic wind tunnel. Results from that test established the aerodynamic characteristics that are needed to verify the mission performance of the vehicle. Additional tests are planned during the EMD phase, such as flowing inlet, powered exhaust, and ice shape tests to further validate the aerodynamic design characteristics. EMD wind tunnel tests will conclude with a special high-speed test to focus on the safe separation of the Aerial Refueling Store and external fuel tank. “Completing these low speed and transonic wind tunnel tests further supports GA-ASI’s design verification and validates our long lead manufacturing activities,” Alexander said. “This will help GA-ASI to meet the Navy’s aggressive MQ-25 development schedule.” General Atomics Aeronautical Systems, Inc. (GA-ASI), an affiliate of General Atomics, is the leading designer and manufacturer of proven, reliable Unmanned Aircraft Systems (UAS), radars, and electro-optic and related mission systems, including the Predator, Reaper and Gray Eagle UAS programs of record and the Lynx Multi-mode Radar. -ends-
31/07/2018

Pentagon Selects 23 Firms for $794M Unmanned Undersea Systems

-- Aerojet Rocketdyne, Canoga Park, California (N66604-18-D-C801); -- Alion Science and Technology, Burr Ridge, Illinois (N66604-18-D-C802); -- AMERICAN Systems, Chantilly, Virginia (N66604-18-D-C803); -- BAE Systems Electronic Systems, Nashua, New Hampshire (N66604-18-D-C804); -- The Charles Stark Draper Laboratory Inc., Cambridge, Massachusetts (N66604-18-D-C806); -- DRS Power Technology, Fitchburg, Massachusetts (N66604-18-D-C807); -- General Atomics, San Diego, California (N66604-18-D-C808); -- General Dynamics One Source, Fairfax, Virginia (N66604-18-D-C809); -- Hamilton Sundstrand (UTC Aerospace); Windsor Locks, Connecticut (N66604-18-D-C810); -- Huntington-Ingalls (AMSEC); Virginia Beach, Virginia (N66604-18-D-C811); -- Hydroid Inc., Pocasset, Massachusetts (N66604-18-D-C812); -- L-3 Technologies, Northampton, Massachusetts (N66604-18-D-C814); -- Lockheed Martin, Riviera Beach, Florida (N66604-18-D-C815); -- MOOG, Elma, New York (N66604-18-D-C816); -- Northrop Grumman, Annapolis, Maryland (N66604-18-D-C817); -- Oceaneering, Hanover, Maryland (N66604-18-D-C818); -- Raytheon Co., Tewksbury, Massachusetts (N66604-18-D-C819); -- Rite Solutions,* Pawcatuck, Connecticut (N66604-18-D-C820); -- Science Applications International Corp. (SAIC), Reston, Virginia (N66604-18-D-C822); -- Systems Engineering Associates Corp.* (SEA CORP); Middletown, Rhode Island (N66604-18-D-C823); -- Southwest Research Institute, San Antonio, Texas (N66604-18-D-C825); -- Teledyne Brown Engineering, Huntsville, Alabama (N66604-18-D-C826); and -- Woods Hole Oceanographic Institute, Woods Hole, Massachusetts (N66604-18-D-C828), are being awarded a combined $561,160,000 cost-plus-fixed-fee, firm-fixed-price, indefinite-delivery/indefinite-quantity, multiple award contract to support research and development for the procurement of materials and services used to develop, build, fabricate and support the Unmanned Undersea Vehicle Family of Systems. This contract includes options which, if exercised, would bring the cumulative value of these contracts to $794,530,000. Each task order will be competed amongst the contract holders, and locations will be dependent upon each awarded task order. Work is expected to be completed by July 2023. Fiscal 2017 and 2018 research, development, test and evaluation funding in the amount of $57,500 ($2,500 minimum guarantee per contract) will be obligated at time of award. Funding in the amount of $10,000 will expire at the end of the current fiscal year. These contracts were competitively procured via the Federal Business Opportunities website, with 28 offers received. The Naval Undersea Warfare Center Division, Newport, Rhode Island, is the contracting activity. -ends-
31/07/2018

Lockheed to Develop Systems for Autonomous Convoy Program

DALLAS --- Lockheed Martin was selected by the U.S. Army's Tank Automotive Research, Development and Engineering Center (TARDEC) as the Integrated Systems Developer for its Expedient Leader Follower (ExLF) program. In this role, Lockheed Martin will lead a three-year effort to develop, integrate and test unmanned prototype systems for supporting leader/follower convoy activities within an asymmetric threat environment. Soldiers will conduct operational technology demonstrations using the prototypes developed in the ExLF program to establish operating procedures and shape future programs of record. "We are leveraging 15 years of experience in developing autonomous capabilities for our customers," said Gaylia Campbell, vice president of Precision Fires & Combat Maneuver Systems at Lockheed Martin Missiles and Fire Control. "Our goal as the Integrated Systems Developer is to help coordinate a number of systems and vendors in achieving mature, reliable autonomous convoys to support our warfighters in complex environments." Soldiers conduct resupply convoys within an asymmetric threat environment compounded by long sustainment missions, adverse weather/environment and night operations. These conditions adversely impact operator safety, degrade driver/operator situational awareness and reduce resupply efficiency. "The Expedient Leader Follower effort will equip a number of existing military ground vehicles with scalable robotic technology through the integration of modular kits, common interfaces and an open architecture to increase operator safety, improve situational awareness and increase resupply efficiency," Campbell said. Headquartered in Bethesda, Maryland, Lockheed Martin is a global security and aerospace company that employs approximately 100,000 people worldwide and is principally engaged in the research, design, development, manufacture, integration and sustainment of advanced technology systems, products and services. This year the company received three Edison Awards for ground-breaking innovations in autonomy, satellite technology and directed energy. -ends-
30/07/2018

US Army's New 3-D Printed Shape-Shifting Soft Robots Crawl, Jump, Grab

ADELPHI, MD. --- New 3-D printed robotic structures can squeeze in tight spaces like a crack in the wall of a cave, jump over trip wire or crawl under a vehicle -- all complex Army-relevant functions impossible for humans to perform safely. Investigators at the Army's Institute for Soldier Nanotechnologies, located at MIT, have developed a 3-D printing platform that can enable both the modeling and design of complex magnetically actuated devices. The new approach utilizes a 3-D printing platform fitted with an electromagnet nozzle and a new type of 3-D printable ink infused with magnetic particles. Their findings could lead to new biomedical applications, magnetic ink optimized to strengthen soft robotic functionality, and new on-demand flexible material systems for integration into Soldier systems. Soft robotic capabilities and manufacturing at the point of need are among the Army's top research priorities. This research is managed through the U.S. Army Research Laboratory's Army Research Office by Dr. Aura Gimm. This research provided new insight on ways to cause fast changes in 3-dimensional shapes of parts such as robot's limbs, she said. "The MIT group demonstrated this success using auxetic metamaterials -- synthetic composite materials that have an unusual internal structure and the unusual property that when exposed to external magnetic actuation, they shrank in both longitudinal and transverse directions. This is different from typical auxetic materials that do require direct mechanical contact, and when compressed they undergo contraction in the directions perpendicular to the applied force (this is called the negative Poisson's ratio). On the contrary, common materials expand in the directions orthogonal to compressive load. In one example from this research, through remote magnetic control, they caused a metamaterial structure to jump forward 120 mm within 0.7 s, which is very fast for the current state of the art. This jump was due to a rapid release of elastic and magnetic potential energy stored in that structure. "Such complex shape-morphing structures could have great potential for the Army, because they may help create soft robots - robots with pliable limbs similar to natural organisms. Compared to the current generation of rigid robots, soft robots could move much more dexterously on a complex battlefield terrain," said Army Research Laboratory Dr. Alex Hsieh. This technology may enable the future Army to fabricate magnetic 3-D printed structures that can crawl, roll, jump or grab in support of Army relevant needs. This research effort enables controlling the magnetic orientation of newly 3-D printed devices so that they are able to rapidly change into new intricate formations or move about as various sections respond to an external magnetic field. Functions demonstrated from these complex shape changes include reconfigurable soft electronics, mechanical metamaterial that can jump, and a soft robot that can crawl, roll, catch fast moving objects or deliver pharmaceuticals. Although other groups have fabricated magnetically activated materials to accomplish simple movements, this new approach enables both the modeling and the design of magnetically controlled device sections to perform complex Army-relevant soft robotic tasks. The approach is based on direct ink writing of an elastomer composite containing ferromagnetic microparticles and the application of a magnetic field to the dispensing nozzle while printing. The technique reorients particles along the applied field to impart patterned magnetic polarity to printed filaments. This method allows the researchers to program ferromagnetic domains in complex 3-D-printed soft materials to enable a set of previously inaccessible modes of transformation. The actuation speed and power density of the printed soft materials with programmed ferromagnetic domains are orders of magnitude greater than existing 3-D-printed active materials. "We have developed a printing platform and a predictive model for others to use. People can design their own structure and domain patterns, validate them with the model, and print them to actuate various functions. By programming complex information of structure, domain, and magnetic field, one can even print intelligent machine such as robots," said MIT Professor Xuanhe Zhao, an investigator at the Army's ISN. This work aligns with Army modernization priorities that support future Army operations through support of ARL's extramural basic research campaign and the Army's Robotic and Autonomous Systems Strategy. The Army's ISN Mission is to help the Army dramatically improve the protection and survivability of the Soldier by working at and extending the frontiers of nanotechnology through fundamental research and transitioning with Army and industry partners. The U.S. Army Research Laboratory is part of the U.S. Army Research, Development and Engineering Command, which has the mission to ensure decisive overmatch for unified land operations to empower the Army, the joint warfighter and our nation. RDECOM is a major subordinate command of the U.S. Army Materiel Command. -ends-

Analysis and Background

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09/05/2018

Will New US Drone Export Policy Hurt the Countries that Buy Them?

There’s a theory that, behind all the curtains and cacophony, that President Trump is a genius. “When Donald Trump described himself as a `very stable genius’, even some of his supporters sniggered,” Gideon Rachman wrote in the Financial Times shortly after the president made the claim in January. “But Mr. Trump has a legitimate claim to three other kinds of `genius’: political genius, instinctive genius and evil genius.” Let’s examine the evidence: The economy is humming, the Islamic State is on the run in Iraq and Syria, and North Korea is on the verge—again!—of pledging to end its nuclear-weapons program. You might want to add to that list his administration’s recent decision to loosen rules on the export of U.S. military drones. “Evil genius,” indeed. Narrow-minded “experts” (here’s looking at me!) have expressed concern that peddling such weapons around the globe isn’t such a good idea. But, tongue perhaps in cheek, the argument can be made that Trump, in pushing to seed the world with war-fighting drones, may be sowing fields of military frustration around the planet. That’s because, despite of all their gee-whizzedness, drones actually cost a lot, crash a lot, and kill innocent civilians a lot. Spread enough of them around the globe and you’d help ensure U.S. military superiority into the wild blue yonder. Military drones crash much more frequently than military airplanes. Last month, Defense News reported that the U.S. Army, far better trained than most others around the world, has suffered hundreds of drone crashes in recent years. “Since the outbreak of the wars in Afghanistan and Iraq, military drones have malfunctioned in myriad ways, plummeting from the sky because of mechanical breakdowns, human error, bad weather and other reasons,” the Washington Post said in 2014. More than 400 of the Pentagon’s 10,000 drones have crashed, the paper added. “Several military drones,” it noted, “have simply disappeared while at cruising altitudes, never to be seen again.” Talk about the ultimate in stealth aircraft, requiring repeated purchases. Fiendish! Add to that the fact that drones, despite the public perception, are not a cheap way to field an air force. The Air Force, for example, is spending more than $13 billion on MQ-9 Reaper hunter-killer drones. Winslow Wheeler, a veteran of defense-budget wars on Capitol Hill and the Government Accountability Office (and the former head of our own Center for Defense Information), crunched budget data several years ago to try to compare the cost of Reapers with piloted warplanes. His takeaway: the drone costs at least twice as much to buy, and fly, as warplanes like the F-16 fighter or A-10 attack plane. “Much of those higher costs are driven by the infrastructure needed to operate Reaper, which has an extensive infrastructure on the ground: the Ground Control Stations, satellite link, and the local control unit for take offs and landings,” he concluded. “Most of this support is not analogous to manned aircraft.” Trump, in pushing to seed the world with war-fighting drones, may be sowing fields of military frustration worldwide. That’s because, despite of all their gee-whizzedness, drones actually cost a lot, crash a lot, and kill innocent civilians a lot. For every “pilot” actually flying a drone, there’s a sensor operator eyeballing what it is seeing in real time, and firing its weapons. There are dozens of maintainers on the ground, keeping the drones flying at remote bases, and keeping their ground stations humming far below, and sometimes far away. Most critically, there are scores of intelligence analysts required to wring from the drones’ deluge of video the scraps of actionable intelligence that is the aircrafts’ reason for being. Drones’ tendency to crash also drives up their cost, both for a drone fleet and for the military supporting it. “The rapid rise in unmanned aerial vehicle (UAV) employment has been accompanied by increased attention to their high mishap rates which are several orders of magnitude greater than manned aviation,” an Air Force study notes. “Such high rates have negative implications for UAV affordability and mission availability.” Imagine that: foreign nations may have to cut their troops’ rations and bullets to keep their American-made drones airborne. Diabolical! Finally, there are the moral and legal issues associated with using drones against terrorists and the resulting civilian deaths that inevitably occur. The U.S. military is building drones bases around the world and harnessing artificial intelligence to improve the chances that its drones will kill the right people. But those strategies require huge investments that few nations can afford. That means that U.S. drones sold to foreign militaries are likely to kill even more civilians than U.S.-operated drones. An independent outside monitor, the London-based Bureau of Investigative Journalism, estimates that U.S. drones strikes have killed as many as 1,569 civilians, including 337 kids. That’s roughly 10 to 15 percent of the total deaths. But the emphasis needs to be on the “roughly”. No one, including the government pulling the trigger, can offer up anything but a crude guess of innocents who just happened to be in the wrong place at the wrong time. “The resentment created by American use of unmanned strikes…is much greater than the average American appreciates,” Stan McChrystal, who ran the war in Afghanistan, said in 2013 once he was out of his U.S. Army general’s uniform. “They are hated on a visceral level, even by people who’ve never seen one or seen the effects of one.” And drones have other complications that have been on display recently: the White House simply ignored a May 1 deadline, set by President Obama in a 2016 executive order, that requires an annual accounting of U.S.-caused drone killings. The same day, a federal judge questioned the authority of the U.S. to kill Americans abroad, usually via drones. Such vexing issues could tie up at least some punctilious foreign forces eager to try out their new weapons. Nefarious! Drones have a place in warfare, especially when trying to hunt down and kill terrorists. Unlike piloted aircraft, they can loiter far longer than manned aircraft over a suspected lair, looking for “patterns of life” that pinpoint bad guys and lead to their demise with a missile trigger pulled from thousands of miles away. They represent perhaps the Pentagon’s key post-9/11 innovation. "It just clicked: that if we could put a small weapon on this thing, we could do the entire cycle—find a target, kill it and assess it—from the same vehicle," John Jumper, who as an Air Force general is regarded as the godfather of the armed drone, told me shortly after 9/11. But we also have to remember that breakthrough military technologies rarely perform as advertised and have unintended consequences. Some, like manned aircraft, missiles and submarines have been “good” for war-fighting (whatever that means). Others, like aircraft carriers, may be fading into history as their utility is threatened by increasingly sophisticated missiles and subs. Take the atom, for instance, which had been ignored as a weapon until World War II broke out. Splitting it was designed to assure U.S. military pre-eminence, but that lasted only until the Soviet Union came up with its own A-bomb four years later. Then there was the boneheaded U.S. Army Davy Crockett battlefield nuclear weapon and harebrained U.S. Air Force schemes to develop nuclear-powered warplanes. The most deadly threats to U.S. security today are atomic arms, whether owned by Russia or China, Iran or North Korea. Nuclear weapons, in some ways, have become more trouble than they’re worth. Trump is unlikely to get the Nobel Peace Prize for ending the threat of atomic war on the Korean peninsula, as South Korean president Moon Jae-in of South Korea suggested April 30. But just maybe he’ll pocket it for his devilishly-clever “drones for peace” campaign. -ends-
17/04/2018

The US Navy’s Combat Drone Becomes a Flying Gas Station

When it comes to technology, the Pentagon is always pushing for more—more reach, more destruction, more dollars. That’s what makes the Navy’s quest for its first-ever aircraft-carrier-based drone unusual: what started out as a push for an unmanned attack drone evolved into a more modest goal of a spy drone, before surrendering to simplicity and deciding the drone’s mission would be to supply fuel to thirsty, and manned, Navy fighters. In the vast reaches of the world’s oceans, boosting your attack planes’ range by about 50 percent, to 700 miles or so, may not seem like much (it’s 6,000 miles from San Francisco to Beijing, after all). But if this aerial robot refueler can keep the Navy’s crown jewels—its aircraft carriers—beyond the reach of China’s land-based DF-21 carrier-killing missiles, it’s worth its weight in gold. That, in a nutshell, is why the Navy wants to buy pilotless MQ-25 aerial tankers. The tale of the MQ-25 Stingray tells us a lot about risk, and how much the U.S. Navy and the Pentagon are willing to take these days. It illuminates the basic challenge of military technology: leapfrog everybody else, with all the risk that entails? Or take the easier path, and risk being left behind? To put it gently, not all naval experts agree with the Navy’s choice. “We don’t need a mission tanker,” says Jerry Hendrix, a retired Navy captain who now directs the defense strategies and assessments program at the Center for a New American Security think tank. “We need an aircraft that can launch from outside the enemy’s weapons range and hit enemy targets.” Perhaps. But for those in the Navy who like the status quo, emasculating the drone does three critical things: -- It gives the Navy’s notoriously short-range F-18s the ability to fly deeper into harm’s way, helping to preserve their utility. -- It allows the Navy’s carriers to stay beyond a foe’s anti-ship missiles, prolonging their life, too. -- Finally, declawing the drone removes a threat to continued Navy funding for its manned F-18 and F-35 fighters, as well as an F-18 successor dubbed the F/A-XX. The Navy’s carrier-based warplanes find themselves in a bit of a pickle. About one of every four carrier-based F-18s is now burning through flight hours serving as a Rube Goldberg tanker for the other three. It’s kind of like dedicating that Tesla roadster in your driveway to ferrying gasoline in those little red plastic tanks for your riding lawnmower. This “buddy tanking” is wearing out F-18s well ahead of schedule, and removing those F-18 tankers from the carrier’s offensive punch. The only aerial tankers the Navy has to extend the range of its F-18 fighters are other F-18 fighters. (U.S. Navy photo by Mass Communication Specialist 3rd Class James R. Evans) While the Navy says the non-stealthy MQ-25 will eventually have minor spy-and-strike capabilities, that’s more of a sop to those bean-counters who fetishize multi-mission weapons (which is what the “M” in MQ-25 stands for; the “Q” stands for unmanned). The Navy plans to train pilots from its F-18s, F-35s and other aircraft to control the drones from the carriers. Beyond extending the F-18s’ range, they’ll be used to refuel returning fighters as they await their turn to land on their sometimes-congested flattops (because when they run out of gas, the pilot bails out and Davy Jones’ hangar gains a fine example of American technology). Three companies are vying for the contract—Boeing, General Atomics and Lockheed—and the Navy hopes to pick a winner later this year. It wants to spend $719 million developing the MQ-25 in 2019, but says it can’t predict the total cost of its goal of 72 MQ-25s until it selects a contractor (informal estimates are around $100 million each, or $7.2 billion for the entire buy). The drone is slated to begin operating in the fleet in 2026. The Navy’s drone history is long and convoluted. The service launched its pilotless program in 1999, with help from the Pentagon’s Defense Advanced Research Projects Agency (DARPA). This Navy-Unmanned Combat Air Vehicle, which flew for the first time in 2003, was designed to designate targets for follow-on piloted aircraft to attack. But then the Pentagon ordered the Navy and DARPA to work with the Air Force to develop the Joint Unmanned Combat Air Systems program, which called for drones to attack targets deep inside hostile territory. But the Defense Department scrapped that program in 2006. It told a happy Air Force to develop a new manned bomber instead. The Navy was ordered to “develop an unmanned longer-range carrier-based aircraft capable of being air-refueled to provide greater standoff capability, to expand payload and launch options, and to increase naval reach and persistence.” That became the Navy Unmanned Combat Air System, which led to the nifty Northrop X-47B, which made a series of historic carrier takeoffs and landings in 2013. But the Pentagon killed that program in 2016 after spending $1.4 billion on it because of—get this—a lack of money. A pair of former Pentagon officials said the decision represented “strategic malpractice of the highest order.” So the Navy began developing the Unmanned Carrier-Launched Airborne Surveillance and Strike system—UCLASS—which was intended to be a spy drone for friendly skies. But two years ago it trimmed its sails on even that scaled-back mission, switching its efforts to the Carrier-Based Aerial-Refueling System. That has become the program now known as the MQ-25 Stingray. Northrop, with all of that X-47B drone cred under its belt, bailed out of the MQ-25 competition last fall, apparently after it concluded that its X-47B couldn’t be efficiently retooled into the more modest flying filling station. “Despite 15 years of research and development…and clear guidance from the Secretary of Defense and Congress, the Navy is reluctant to embrace the innovation that a fully-capable unmanned strike aircraft could bring to naval forces,” a pair of Air Force procurement officials has written. The sea service, they added, “needs a much stronger internal [drone] advocate to lead the program through development and initial operational capability if the aircraft carrier is to avoid obsolescence in the coming decades.” The Air Force, of course, is not a disinterested observer when it comes to the future of aircraft carriers. Its boosters tend to think land-based Air Force warplanes make more sense. But, not surprisingly, they’re not alone in their assessment of the future of aircraft carriers. The Chinese are keen to modify their carrier-killing DF-21 missile so that it can be launched from a land-based bomber. If they can do it, the Chinese could emasculate the U.S. Navy’s carrier fleet overnight, with or without MQ-25s aboard. -ends-
28/07/2017

Autonomous Military Drones: No Longer Science Fiction

The possibility of life-or-death decisions someday being taken by machines not under the direct control of humans needs to be taken seriously. Over the last few years we have seen a rapid development in the field of drone technology, with an ever-increasing degree of autonomy. While no approved autonomous drone systems are operational, as far as we know, the technology is being tested and developed. Some see the new opportunities and potential benefits of using autonomous drones, others consider the development and use of such technology as inherently immoral. Influential people like Stephen Hawking, Elon Musk and Steve Wozniak have already urged a ban on warfare using autonomous weapons or artificial intelligence. So, where do we stand, and what are the main legal and ethical issues? Towards autonomous drones As yet, there is no agreed or legal definition of the term "autonomous drones". Industry uses the “autonomy” label extensively, as it gives an impression of very modern and advanced technology. However, several nations have a more stringent definition of what should be called autonomous drones, for example, the United Kingdom describes them as “…capable of understanding higher level intent and direction” (UK MoD, The UK Approach to Unmanned Aircraft Systems, 2011). Generally, most military and aviation authorities call unmanned aerial vehicles "Remotely Piloted Aircraft" (RPAs) to stress that they fly under the direct control of human operators. Most people would probably understand the concept of “autonomous drones” as something sophisticated, for instance, drones that can act based on their own choice of options (what is commonly defined as "system initiative" and "full autonomy" in military terminology). Such drones are programmed with a large number of alternative responses to the different challenges they may meet in performing their mission. This is not science fiction – the technology is largely developed though, to our knowledge, no approved autonomous drone systems are yet operational. The limiting factor is not the technology but rather the political will to develop or admit to having such politically sensitive technology, which would allow lethal machines to operate without being under the direct control of humans. One of the greatest challenges for the development and approval of aircraft with such technology is that it is extremely difficult to develop satisfactory validation systems, which would ensure that the technology is safe and acts like humans would. In practice, such sophisticated drones would involve programming for an incredible number of combinations of alternative courses of action, making it impossible to verify and test them to the level we are used to for manned aircraft. There are also those who think of autonomy meaning ”artificial intelligence” – systems that learn and even self-develop possible courses of action to new challenges. We have no knowledge that we are close to a breakthrough on such technology, but many fear that we actually might be. Autonomous drones – meaning advanced drones programmed with algorithms for countless human-defined courses of action to meet emerging challenges – are already being tested by a number of civilian universities and military research institutions. We see testing of “swarms of drones” (drones which follow and take tasks from other drones) that, of course, are entirely dependent on autonomous processing. We also see testing of autonomous drones that operate with manned aircraft, all from what the US Air Force calls (unmanned) "Loyal Wingman" aircraft, to the already well tested Broad Area Maritime Surveillance (BAMS) system of Poseidon P-8 maritime patrol aircraft and unmanned TRITON aircraft. We also see the further development of unmanned systems to be dispatched from manned aircraft, to work independently or in extension of the “mother aircraft”, for instance, the recently tested PERDIX nano drones, of which 100 drones were dropped from a F-18 “mother aircraft”. Such drones would necessarily operate with a high degree of autonomy. These many developments and aspirations are well described in, for example, the US planning document USAF RPA Vector - Vision and Enabling Concepts 2013-2038 published in 2014, and other documentation and even videos of such research are widely available. The prospects of autonomous technology, be it flying drones, underwater vehicles or other lethal weapon systems, clearly bring new opportunities for military forces. In the case of flying aircraft, we have learned that there are long lead times in educating pilots and operators. One of the greatest changes that will come from the development of autonomous drones is that military forces in the (near) future could develop great fighting power in much shorter timeframes than previously. It is important to note – and many have – that creating the infrastructure and educating ground crew for operating drones is no cheaper or easier than it is to educate aircrew. However, once in place, the drone crew and operation centres would be able to operate large numbers of drones. Similarly, legacy manned aircraft would be at the centre of a local combat or intelligence system extended with drones serving, for example, in supportive roles for jamming, as weapons-delivery platforms or as a system of multi-sensor platforms. Moving beyond the past limitations of one pilot flying one aircraft or one crew flying one drone to a situation where one crew could control large amounts of drones would quite simply be groundbreaking. These perspectives for new types of high-tech weapon systems – and the fears they raise – are the background for the research we conducted on autonomous drones and weapon systems. It is almost impossible to assess when these technologies will become widespread – this will depend on the situation and the need of states. However, the technologies are becoming available and are maturing and we would argue that the difficult discussions on legal and ethical challenges should be dealt with sooner, rather than later. The legal perspectives General rules apply but it is not that simple Autonomous drones, if and when they are used during armed conflict, would be subject to the general principles and rules of the Law of Armed Conflict. In this respect, autonomous drones are not to be distinguished from any other weapons, weapon systems or weapon platforms. As with any “means of warfare”, autonomous drones must only be directed at lawful targets (military objectives and combatants) and attacks must not be expected to cause excessive collateral damage. (end of excerpt) Click here for the full story, on the NATO website. -ends-
04/05/2017

Russia Works to Restore Positions In Drone Development

Unmanned aviation is a dynamically developing industry of modern aircraft construction. Technical and technological achievements boosted the design of new systems. At present drones are engaged by many armies of the world and used in armed conflicts. Our country used to have considerable achievements in the sphere and now works to restore its positions, expert Denis Fedutinov writes in the official blog of the United Aircraft Corporation. MOSCOW --- The former Soviet Union enjoyed a major experience in drone development also in the tactical class. Until recently the Russian army had old Strizh and Reis systems developed by the Tupolev Design Bureau yet in the 1970s and the Stroi-P complex with remote controlled Pchela craft designed by Kulon Research Institute and the Yakovlev bureau in late 1980s. Unfortunately, the economic plight of the transition period in the 1990s stalled the work. The initial pace was lost as a result, the designs got obsolete, the existing technical and scientific experience in the sphere was lost and the country began to considerably lag behind leading foreign producers. The interest in drones revived in Russia in mid-2000s mostly due to the effort of private companies which initiated some steps to create mostly small-class craft. The Russian defense ministry kept displaying little interest in drones for some years. The guideline was however supported by law enforcement agencies - the interior ministry, the Federal Security Service (including the Border Service) and the emergencies ministry. In early and mid-2000s the orders of the defense ministry for the design of domestic drones were very modest. The latest system in the arsenal of the Russian military was tactical Stroi-P with remote controlled Pchela craft designed at the end of the Soviet epoch. In the 1990s the system became morally outdated. In early 2000s the Kulon Institute of the Vega Concern upgraded the complex to Stroi-PD version. The Rybinsk-based Luch Design Bureau of the Vega designed another tactical Tipchak craft. As in the case of Stroi-PD the funds were appropriated mostly for R&D. The Vega Concern and the defense ministry signed a contract for the delivery of one such complex a year which was an absolutely symbolic action. Problems caused by the absence of modern reconnaissance and surveillance drones were exposed by the 2008 situation in Abkhazia and South Ossetia. The defense ministry tried to engage available drones but none of them was capable of fulfilling the mission. The Russian troops were actually blinded. In contrast the Georgian military efficiently engaged the drones bought from the Israeli Elbit Systems Company. As for Stroi-PD, it took off with the use of powder boosters which exposed the launch site. The flight itself could not be stealthy because of the noisy two-stroke engine. The Russian military also complained about the noisy Tipchak tactical drone designed by Vega. It was created in the Luch Design Bureau in Rybinsk. Former Russian Deputy Defense Minister Vladimir Popovkin said the drone was engaged in the operation in South Ossetia and performed poorly. Besides noise problems, the quality of reconnaissance data was low because of the line TV camera which failed to produce images corresponding to modern requirements. Besides, there were also problems with friend-or-foe system. The developments around the conflict with Georgia became the threshold which made the Russian defense ministry urgently take measures to rectify the stagnant situation with modern drones for the national armed forces. Initially foreign designs were purchased, as well as available systems of domestic companies. R&D to create perspective craft was launched. The first step was the purchase of drones from Israel which is the world leader in the sphere and then an additional batch of drones was assembled in Russia. Plans to buy Israeli drones were first voiced in November 2008 by General Chief-of-Staff Nikolai Makarov. As a result, the defense ministry acquired short-range Bird-Eye 400 and medium-range Searcher Mk II of the Israeli Aerospace Industries (IAI). According to the contract signed in 2011, the drones were assembled in Russia by the UZGA Works in Yekaterinburg under Zastava and Forpost brands correspondingly. Major modernization and localization of tactical Forpost production is being considered. The drone is to get some domestically-produced systems, including a secured communications line and state system of identification, as well as GLONASS-based navigational system, radio-technical reconnaissance and data transmission devices, digital aerial survey system and lateral visibility radar. (ends)
12/06/2015

Fly-offs for French Tactical UAV Competition Begin This Month

PARIS --- France’s defense procurement agency will begin the in-flight evaluation of competitors for the future SDT tactical UAV system later this month, allowing selection of the winner by year-end after a second-round review in the fall. The evaluations, each lasting one or two weeks, will take place at Istres air base in south-eastern France. The SDT evaluations will oppose two French companies offering foreign-designed airframes with subsystems and electronics tailored to French needs: Sagem, which is offering its Patroller, and Thales, which is offering the Watchkeeper developed by its British subsidiary, Thales UK, for the British Army. Watchkeeper will be evaluated in late June, and Patroller will follow in early July. Airbus Defence and Space, which had not been invited to bid for the Système de Drone Tactique (SDT) program, submitted an unsolicited offer earlier this year based on the Textron Systems Shadow M2 unmanned system, which it has dubbed Artemis. The company is waiting for feedback from DGA and the French army on its unsolicited offer before making a full-fledged bid. Uncertainties remain as to SDT funding The French army has not specified a number of aircraft or systems, but has defined an operational requirement, leaving industry to come up with proposals on how best to meet it. However, as it now operates 22 Sperwer tactical drones, it is likely that it will ultimately require about 30 Système de Drone Tactique (SDT) aircraft divided into four deployable systems. “The 2014-2019 Military Program Law calls for two complete and deployable SDT systems, comprising 14 operational and training aircraft, to be delivered by 2019,” a DGA spokesman told Defense-Aerospace.com June 10. He added that the competition was formally launched during the fall of 2014, and that it is proceeding as planned, but declined further comment because the competition is ongoing. There are some doubts, given the French air force’s large-scale procurement of Reaper MALE UAVs, the planned development of the Eurodrone 2020 MALE, and the availability of smaller tactical UAVs, whether the French army actually needs to spend so much money to buy large UAVs of its own. “The current worry is that the program might not be completed, as the requirements are very ambitious and demanding, and there is no officially-defined budget,” says a senior official of one of the competing companies. In fact, the SDT program was barely mentioned during May 26 parliamentary hearings on the update to the 2014-2019 defense program law. Gen. Jean-Pierre Bosser, the army chief of staff, simply said that “we expect our current interim SDTs to be replaced by an SDT system,” before moving on to other issues. All three competitors stress the high French content of their offers, the high proportion of production work that will take place in France, and the fact that their solution offers sovereign, autonomous capabilities entirely free of foreign interference, for both operation and support. Sagem, with its Sperwer, is the incumbent; its latest contract was awarded in December 2013, and funded five additional Sperwer systems for delivery in 2015. In addition to those already in service with the 61ème Régiment d’Artillerie, these UAVs will maintain French army capabilities until a replacement enters service by the end of the decade. The three competitors offer three totally different approaches to the French requirement. All three offer broadly similar sensors, but differ notably in their air vehicles, which range from Sagem’s optionally-piloted and self-deployable motor glider; Thales’ updated and “Frenchified” Hermes UAV to the much smaller, and optionally catapult-launched, Shadow M2 planned by Airbus DS. In fact, the difference in size is such that the 250 kg payload of Sagem’s Patroller is heavier than an entire Shadow air vehicle, while at 450 kg empty mass Watchkeeper is less than half as heavy as Patroller. In other words, Watchkeeper is twice as heavy as Artemis, and in turn Patroller is about twice as heavy as Watchkeeper, although they all carry similar types of payloads. Given France’s insistence on maintaining its independent deployment capability, the level of technical and operational sovereignty, and the control of the supply chain, is likely to weigh heavily during the final selection. Watchkeeper Goes French Sagem’s main competitor for the French SDT contract is Thales UK’s Watchkeeper , which was developed from the Elbit Systems Hermes 450 design and adapted to UK requirements. The British Army has ordered 13 Watchkeeper systems, for a total of 54 air vehicles, about 30 of which have been delivered to date. Watchkeeper was deployed by the British Army in Afghanistan. Several aircraft arrived at Camp Bastion, in Afghanistan’s Helmand province, in August 2014, and flew its first combat mission on Sept. 16, Lt Col Craig Palmer, the point man for UAVs at British Army HQ, told reporters here June 2. However, it will not attain Full Operational Capability until 2017, he said. Watchkeeper has flown about 500 hours with the British Army, Palmer said, of which 140 hours in Afghanistan and 360 hours from its base in Boscombe Down, in England. British troops prepare a Watchkeeper unmanned aerial vehicle for a mission at Camp Bastion, in Afghanistan’s Helmand Province. (UK MoD photo) “Watchkeeper was designed from the outset to generate information superiority [and] its world-class I-Master radar is what is actually adding value. It’s a game-changer” compared to the Hermes, which has no radar, Palmer said. The Watchkeeper variant Thales has offered to France is equipped with mostly French subsystems, including a secure datalink, the same Automatic Take-Off and Landing System (ATOLS) that Thales developed for Watchkeeper, and Thales’ own electro-optical sensors. For the time being, the French army has been offered a Selex ES surface search radar, but alternate radars can also be fitted. For the French proposal, the joint Elbit/Thales datalink fitted to UK Watchkeeper has been replaced by a Thales-developed TMA/TMG 6000 dual-mode (command and ISR data) datalink, and Thales Executive Vice-President for Telecommunications Marc Darmon says the company has all the Intellectual Property (IP) rights to this product, which is obviously significant for national sovereignty issues. “We bought the source codes and we largely re-wrote them, so we have total control of the system,” says another Thales executive, dismissing concerns that foreign companies are involved in the French Watchkeeper proposal. At present, 80% of Watchkeeper components are British-made, with another 15% coming from France and 5% from the rest of the world, according to Pierrick Lerey, strategy and marketing director for Thales’ UAV and ISR business. The company has formed a French suppliers club (equipefrancewatchkeeper.com) to update Watchkeeper’s main systems, including a new-generation electro-optical payload; a new Communications and ESM payload; a new imagery chain for full HD video; interconnection with the French military C4ISR network, a new ground station and a remote video terminal. The goal, Lerey says, is to bring French content up to at least 35% for the French program, since the Watchkeeper airframe and the (new) ground stations will continue to be built in the UK. Sagem’s Optionally-Piloted Motor Glider While its competitors opted for specific, UAV-sized airframes, Sagem preferred to use a civil-certified airframe for its Patroller, which is almost as large as a MALE drone but offers the advantage of being derived from a German motor glider, the Stemme S-15. Frederic Mazzanti, Sagem Vice-President and head of its Optronics and Defense Division, notes that this means it can self-deploy using civil airspace, that it can be used for training in unsegregated airspace with a pilot on board, and that it does not need tractors or other ground equipment because it was designed to be autonomous on the ground. Patroller’s size also means it offers lots of space for fuel and sensors, and the commercial origin of its airframe means it was designed for simple, straightforward repairs with little tooling, another plus for austere operations. A soldier shows the large sensor ball of Sagem’s Patroller UAV, a large, optionally-piloted aircraft that offers much greater range and payload than its competitors (Sagem photo) Sagem’s offer comprises triplex-redundant avionics, a new fourth-generation Euroflir 41 sensor ball with a 43-cm diameter and fitted with full HD color TV, visible and thermal imaging, and laser rangefinder and designator. Several synthetic aperture radars can be fitted, depending on the customer’s preferences, and several have already been tested. Most importantly, says Mazzanti, Patroller has the capability to operate radar and EO sensors at the same time, and also to transmit their imagery at the same time. This, he notes, is a unique capability in this category, and can multiply an ISR aircraft’s effectiveness by tracking several targets with different sensors at the same time. Most Patroller subsystems and sensors are produced by Sagem itself (EO sensor ball, navigation, datalink) while the others are French-made. Sagem also owns all property rights to the airframe, so the fact that no foreign company is involved guarantees manufacturing and operational sovereignty. With its Sperwer drones, which were operated in Afghanistan by several of the nine countries that have bought it, Sagem gained precious operational experience. The French army’s 22 Sperwers attained an availability rate of 80-85% with support from Sagem. “Our availability in terms of aircraft numbers never fell short of requirements,” Mazzanti said, adding that as operators of the S-15 have logged over 1,000 flight hours per year, there is no reason for Patroller not to attain similar levels. Sagem employs over 100 people at its French plants to build Sperwer drones and its components, and the company also has assembled a cluster of SMEs to which it subcontracts some of the work. All in all, Sagem says that French content of Patroller will attain 85% by value, as only the radar and airframe would be built overseas. With a payload of 250 kg, and a mission endurance of 30 hours, Patroller is a much larger aircraft than its competitors, but Mazzanti dismisses criticism that it may be too large for its intended mission. “It is air-transportable, it fits into a standard 20-foot container, it can land with a 20-knot crosswind and it can pull 5Gs, so its size and robustness are real operational advantages.” Outsider Airbus Teams with Textron Thales and Sagem both “offered large air vehicles that are closer to MALE size, but looking at the French army requirement we thought that a smaller drone, capable of being operated from close to the front line, would be a better match,” an Airbus official said June 9. Instead of offering one of its own UAVs, the company preferred to team with Textron Systems to prepare a bid based on a tried-and-tested UAV that more closely matches the French army requirement, and which is small enough for use at brigade or division, instead of corps, level. LEGENDE: Airbus DS has offered to “Frenchify” Textron’s Shadow to develop its Artemis UAV, which is much smaller than the two SDT competitors and doesn’t need a runway, as it can be launched from a catapult. (US Army photo) Airbus has not yet formally filed a bid, and will only announce its Artemis partnership with Textron next week at the Paris Air Show. The company has so far only submitted an unsolicited proposal to DGA, and is waiting for feedback before deciding whether to invest in a formal and comprehensive proposal. Nonetheless, company officials expect a positive response, and are encouraged by the fact that a team of DGA and French army observers will fly to Yuma, Arizona during the summer for a demonstration of the Shadow M2, which will not fly at Istres. Smaller also means cheaper, and Airbus says its offer – based on Textron Unmanned Systems’ upgraded Shadow M2 – would carry much lower acquisition and operating costs, and thus allow more intensive operations for a given budget, while its small size also facilitates transport and deployment. Shadow is operated by the US Army and Marine Corps and several foreign militaries, and over 300 air vehicles have logged over 1 million flight hours, including in combat. A competitive advantage that Airbus points out is that Shadow’s long service career, and different users, are such that the latest versions benefit from a wealth of technical and operational lessons learned. For Artemis, Airbus would modify the Shadow M2 air vehicle as little as possible to limit costs, but would replace its subsystems or adapt them to French requirements. These would include Airbus’ own Lygarion datalink, a modified ground station, and French sensor packages (radar and either electro-optical or signals intelligence) that are capable of simultaneous operation. Airbus plans to purchase full rights to the Shadow airframe and ground station, and so would control the entire system, ensuring “fully autonomous operations, as well as maximum growth potential, for the French customer,” according to a briefing document. It also says that a “significant” share of production and support – about 60% -- would take place in France, supporting French industry and jobs. In reality, a large share of production would remain in the United States, so French workshare would largely be made up by training and support, in addition to some key subsystems. -ends-
12/03/2015

UAVs: France, Germany and Italy to Launch European MALE Program

PARIS --- Three European nations will sign an agreement at the Paris air show in June to jointly fund initial studies for a Medium Altitude Long Endurance (MALE) unmanned aerial vehicle, French Defense Minister Jean-Yves Le Drian said here March 11. France, Germany and Italy will follow up by awarding a study contract in December to an industry group formed by Airbus Defence and Space, Dassault Aviation and Alenia Aermacchi. The initial contract is valued at a few dozen millions of euros. Ultimately, if the program progresses as planned, the nations plan to obtain an operational reconnaissance UAV by 2025. “Our effort in the field of surveillance drones and ISR will increase with, already this year, the launch of studies of the future European drone, with Germany and Italy, that France envisions for about 2025, ,” Le Drian said here during a March 11 press conference. An Italian defense official confirmed the agreement, which has not yet been made public in Italy, however adding “we will see whether it ultimately leads to a development program.” The three companies have been calling for such a government initiative for over two years, and in May 2013 took the unusual step of issuing a joint statement calling on their governments to “launch a European MALE program.…to support the capability needs of European armed forces while optimizing the difficult budgetary situation through pooling of research and development funding.” The companies have a double goal: to maintain the know-how and expertise of their military aircraft design offices, now that they have mostly completed work on current fighters, and to recover the UAV business that is now going to their US competitors – France and Italy operate General Atomics Predator or Reaper UAVs, like the UK, the Netherlands has just decided to buy some while Spain is also weighing buying some. “Originally, [our] idea was to prevent the procurement of Reaper drones by European governments,” but this didn’t work, Dassault Aviation CEO Eric Trappier said here during a separate March 11 press conference. “We’ve been working on this project for a long time, and we think we can develop a drone to replace the Reaper, which is an interim solution. We have asked our governments to state that an operational requirement exists, and we will be able to reply to that requirement.” In parallel, France is however continuing to boost its Reaper force, which is seeing intensive use in Africa, where it is supporting French and allied troops operating in Mali. France is due to receive a third Reaper aircraft in April, and will order a follow-on batch of three additional aircraft in August, according to a planning document released by Le Drian. “We are asking for a contract from the three governments covering initial studies,” Trappier said. “Initially, it’s a question of a few dozen million euros, although it will cost more once development is launched.” The three companies set out the details of their proposal in a second joint statement issued in June 2014, in which they proposed “a Definition Phase which has been prepared by joint development teams of Airbus Defence and Space, Dassault Aviation and Alenia Aermacchi and which is backed by an industrial agreement on workshare and a cooperative agreement to start the MALE2020 program.” The broad lines of the industry proposal have been retained, although the initial operational capability has slipped to 2025. One of the trickier problems to be solved is the integration of the future MALE UAV into general air traffic, Trappier said. The inability to fly in unrestricted airspace is one of the reasons for which Germany canceled the EuroHawk program – a variant of Global Hawk fitted with a German sensor package – after spending several hundred million euros on its development. -ends-
23/02/2015

An Introduction to Autonomy in Weapon Systems

Source: Center for New American Security Ref: no reference Issued Feb 13, 2015 23 PDF pages In this working paper, 20YY Warfare Initiative Director Paul Scharre and Adjunct Senior Fellow Michael Horowitz discuss future military systems incorporating greater autonomy. The intent of the paper is to help clarify, as a prerequisite to examining legal, moral, ethical and policy issues, what an autonomous weapon is, how autonomy is already used, and what might be different about increased autonomy in the future. (PDF format) Full text
13/11/2014

UK: Challenges & Opportunities of Drone Security

Source: University of Birmingham Ref: No reference Issued Oct 22, 2014) 96 PDF pages Drone technology, both civil and military, under proper legal regulation, can continue to deliver 'significant benefits' for the UK's national security policy and economy in the coming decades. That is the conclusion of a new University of Birmingham Policy Commission Report which launches today. But the Government, and especially the Ministry of Defence (MoD), should do more to reach out to the public over what the Commission sees as the globally inevitable use of drones in armed conflict and in domestic surveillance. The Report finds that over the next 20 years, drones – or what the Commission and the RAF prefer to call Remotely Piloted Aircraft (RPA) – will become an integral part of Britain's aerospace capability, providing both advanced surveillance and precision weapons delivery. They can support UK forces deployed overseas, as in Afghanistan, or help prevent mass atrocities, as with the British Government's decision to deploy the RAF Reaper fleet against the Islamic State (ISIS). This decision was announced after the Report was completed but is entirely consistent with its conclusions. The Report examines the distinctive and unavoidable choices for the United Kingdom over a crucial emerging technology and sets out the under-appreciated distinction between legally constrained British practice and the US Government's cross-border counter-terrorism strikes which dominate and distort UK public debate. The Commission considers various moral arguments and concludes that the current and emerging generation of RPA pose no greater ethical challenges than those already involved in decisions to use any other type of UK military asset. The Report shows clearly that the UK has operated its armed Reapers in Afghanistan according to the same exceptionally strict Rules of Engagement (no weapon should be discharged unless there is 'zero expectation of civilian casualties') that it applies to manned aircraft. Key findings There are three main obstacles affecting the UK Government's use of drones that must be overcome: gaining public understanding and acceptance of the legal and ethical soundness of the practice; allaying fears over the potential development of LAWS; and safeguarding British airspace and the privacy of British citizens if drones are to be increasingly used for domestic surveillance and security. (PDF format) Report’s download page
11/07/2014

UK, France to Launch FCAS Demo Phase

PARIS --- Four years after they first agreed to jointly develop an unmanned combat aircraft, France and Britain will finally launch the demonstration phase of the Future Combat Air System (FCAS) on July 15 at the Farnborough air show, the French defense ministry announced July 10. The two countries’ defense ministers will sign a Memorandum of Understanding (MoU) authorizing a 24-month, €150 million definition phase of the FCAS program, known as FCAS-Demonstration Phase, the French defense ministry announced July 10. Contracts will be awarded to industry in the autumn, and the project will officially begin in January 2015. Participating companies are Dassault Aviation and BAE Systems for airframe and systems integration; Thales and Selex ES (UK) for sensors and electronics; and Snecma and Rolls-Royce for engine and power systems. “There is agreement on a two-year concept phase…[and]….a contract could be awarded shortly,” UK Defence Procurement Minister Philip Dunne told reporters at the Eurosatory show here June 19, adding however that “data-sharing agreements have to be competed.” Physics and aerodynamics being what they are, it is not surprising that Dassault’s Neuron demonstrator (above) and BAE System’s Taranis demonstrator (below) should look the same at first glance. The FCAS will build on knowledge gained on both programs. (photos Dassault and BAE). BAE and Dassault have been working together for about 18 months to investigate the feasibility of joint development of FCAS, based on their separate but complementary experience in developing unmanned combat air vehicle (UCAV) demonstrators, either alone (BAE with its Taranis) or jointly – Dassault’s Neuron project also included Italy’s Alenia Aermacchi, Sweden’s Saab as well as smaller Greek and Spanish firms. A major question mark concerns the work-sharing arrangements, as both companies are obviously keen to advance and maintain their technological know-how. This is complicated, again, by their previous work on Taranis and Neuron, which sometimes led them in different directions and which may be difficult to reconcile. “We have already shared some data, but we haven’t shown everything yet,” Benoît Dussaugey, Dassault Executive Vice-President, International, told Defense-Aerospace.com June 18, adding that full disclosure will not take place before contract award. However, having successfully managed Neuron on time and on schedule with an international team of partners, Dassault does not believe this aspect will be a show-stopper. "We are confident we will find an agreement with our partners on work-share, subject to sovereign decisions by governments," Dussaugey said. The program could be opened to additional foreign partners, he adds, on two conditions: "that everyone accepts and respects our common rules, and that the respective governments finance [their share] of the entire phase." Nonetheless, BAE’s surprise and high-profile unveiling of its Taranis UCAV demonstrator in January, which it had jealously kept under wraps until then, was clearly intended to show its credentials in the lead-up to the FCAS MoU. It is probable that, as in the previous phase, BAE will remain FCAS prime contractor, while France’s defense procurement agency, Direction Générale pour l’Armement (DGA), will act as program executive on behalf of both nations. Having successive definition and demonstration phases is considered essential for governments to define and harmonize their operational requirements, and for industry to weigh their technical feasibility and cost implications. For example, will in-flight refueling be required, and if yes using a receptacle or a boom? Where and how should radar antennas be integrated into the airframe? Will FCAS be designed to follow a pre-programmed flight path (which the French favor, as it is impervious to jamming, interception and loss of data-link), or on the contrary be remotely-piloted, as the Royal Air Force favors so as to keep a man permanently in the loop? Should the aircraft be totally silent in terms of radar, radio and IR emissions, or could it resort to jamming? Should it be single- or twin-engined? Once these basic questions are answered, processed and priced by industry, the logical follow-up would be a demonstration phase, during which the project would be further developed and prototypes or flight test aircraft built, but a decision would not be required before late 2017, which makes it very unlikely that a FCAS could fly before the end of the decade. -ends-
30/04/2014

USAF Vision & Plans for UAVs 2013-2038

Source: US Air Force Ref: no reference Issued April 04, 2014) 101 PDF pages Air Force leaders outlined what the next 25 years for remotely piloted aircraft will look like in the RPA Vector, published April 4. “The RPA Vector is the Air Force’s vision for the next 25 years for remotely-piloted aircraft,” said Col. Kenneth Callahan, the RPA capabilities division director. “It shows the current state of the program, the great advances of where we have been and the vision of where we are going.” The goal for the vector on the operational side is to continue the legacy Airmen created in the RPA field. The vector is also designed to expand upon leaps in technology and changes the Airmen have made through the early years of the program. “The Airmen have made it all about supporting the men and women on the ground,” Callahan said. “I couldn’t be more proud of them for their own advances in technology to expand the program, making it a top platform.” The document gives private corporations an outlook on the capabilities the Air Force wants to have in the future, ranging from creation of new RPAs to possibilities of automated refueling systems. “There is so much more that can be done with RPAs,” said Col. Sean Harrington, an intelligence, surveillance, and reconnaissance command and control requirements chief. “Their roles (RPAs) within the Air Force are evolving. We have been able to modify RPAs as a plug-and-play capability while looking to expand those opportunities.” In recent years, RPAs not only supported the warfighter on the ground, they also played a vital role in humanitarian missions around the world. They provided real time imagery and video after the earthquake that led to a tsunami in Japan in 2011 and the earthquake in Haiti in 2010, according to Callahan. Then, most recently, during the California Rim Fire in August 2013, more than 160,000 acres of land were destroyed. Though this loss was significant, it was substantially decreased by the support of the California Air National Guard’s 163rd Reconnaissance Wing, with support from an MQ-1 Predator, a remotely piloted aircraft. With this vector, technologies may be created to improve those capabilities while supporting different humanitarian efforts, allowing the Air Force to support natural disaster events more effectively and timely. The future of the Air Force’s RPA programs will be continuously evolving, to allow the Air Force to be the leader in Air, Space, and Cyberspace. “We already combine our air, space and cyber forces to maximize these enduring contributions, but the way we execute must continually evolve as we strive to increase our asymmetric advantage,” said Gen. Mark Welsh, the Air Force chief of staff. “Our Airmen's ability to rethink the battle while incorporating new technologies will improve the varied ways our Air Force accomplishes its missions.” (PDF format) Full text