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Military UAV Designs

Not on my watch!!! ;)

IDK why people dont thank informative posts especially if they have no political, religious or other implications. People should thank posts based on the information being helpful.
and people should give more +ve ratings as well! ;)
 
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Fotros (UCAV)
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Is an Iranian reconnaissance, surveillance, and combat drone built by IAIO and unveiled in November 2013. It is considered the largest in Iran's arsenal of unmanned aerial vehicles, and depending on armament, has an operational range of 1,700 km to 2,000 km with flight endurance of 16 to 30 hours.
http://en.wikipedia.org/wiki/Fotros_(UCAV)
Fotros (UCAV) - Wikipedia, the free encyclopedia
 
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Hamaseh UCAV
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Teherans’ Drone Fever

Last week Iran unveiled its latest drone dubbed “Hamaseh”. This unmanned aerial vehicle follows a classic twin-boom tail design, pioneered by IAI’s Scout and Tadiran Mastiff in the 1980s. On the My 9, 2013 unveiling ceremony the drone was shown carrying two 107mm rockets and what seems to be an electronic payload – probably a radar. The Iranians say it can ‘avoid detection by the enemy thanks to its stealth features’, but based on visual impression of the aircraft shown in flight, the overall shape and non-stealth features such as the non retractable landing gear, wing strakes (beefing up the hard-points) would negate signature reduction to a level considered ‘stealthy’ by western standards. According to the Iranians, Hamaseh is designed for reconnaissance and combat missions.


Regardless of the maturity of the current Hamaseh, the design represents a new level of maturity for Iran’s drone program, which currently includes about 40 different types of drones. Of these, about 30 are in different phases of production.

In recent months the Iranians have released a number of drones.

Another drone unveiled in 2012 was Shahed 129 followed another Israeli design – the Hermes 450. In April 2013 Tehran unveiled four new drone programs – Azem-2, Mohajer B, Hazem 3 and Sarir H110, dubbed as a ‘long-endurance drone’. Sharir 110 was first shown on a march in Tehran, on April 10, 2013. As other recently unveiled Iranian designs, this drone follows the design of the Israeli Hunter (Developed by IAI), which has seen operational use with the US Army in Iraq and Afghanistan over the past decade. Sharir 110 is also configured with a twin-boom tail, and is powered by two propellers used in tractor-pusher configuration. This drone was also displayed carrying external weapons on wing pylons (it was displayed with two SA-7 class air/air missiles). Iran also claims this drone is stealthy, but its design does not indicate any such attributes.
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Tehran is developing the operational techniques, tactics and procedures (TTP) for these unmanned systems in parallel to the continuous development of systems. Unmanned systems are integrated in all exercises, on both sides. Iran regularly trains its forces and air defenses in counter-surveillance measures, and specific counter-UAV techniques. These have culminated in the ‘abduction’ of an RQ-170 Sentinel, the top-secret CIA drone operated from Afghanistan in 2011. The Sentinel was said to be on surveillance missions over east-central Iran when Tehran’s electronic warfare units claimed to have managed to deceive its navigation and command links, landing the drone undamaged in Iran. It is assumed that by reverse engineering some of the RQ-170 design features the Iranians could implement signature reduction capabilities, particularly in electromagnetic shielding, use of materials and the topology of elements, achieving a level of low observability in their newer drones. Nevertheless, the adaptation of overall stealth design, that requires complex manufacturing techniques, exotic materials and use of advanced aerodynamic control are probably beyond the scope of Iran’s current achievements, hence the lack of visible ‘stealth shaped’ drones.
Teherans’ Drone Fever | Defense Update:
Shahed 129 UCAV





globalmilitaryreview.blogspot.ca/2013/09/iranian-shahed-129-unmanned-combat-air_28.html
 
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DARPA unveils hack-proof drone
By Kris Osborn - May22, 2014

The Pentagon’s research arm unveiled a new drone built with secure software that prevents the control and navigation of the aircraft from being hacked.

The program, called High Assurance Cyber Military Systems, or HACMS, uses software designed to thwart cyber attacks. It has been underway with the Defense Advance Research Project Agency for several years after originating at the University of California, San Diego and the University of Washington, said Kathleen Fischer, HACMS program manager for DARPA.

“The software is designed to make sure a hacker cannot take over control of a UAS. The software is mathematically proven to be invulnerable to large classes of attack,” Fisher said.

The mini drone is engineered with mathematically assured software making it invulnerable to cyber attack. Citing the success of mock-enemy or “red-team” exercises wherein cyber experts tried to hack into the quadcopter and failed, Fisher indicated that DARPA experts have referred to the prototype quadcopter as the most secure UAS in the world.

“We started out with the observation that many vehicles are easy for malicious hackers to tamper with the software and take control remotely. We’ve replaced all the software with our high assurance software that was developed using the tools and techniques that were invented in the program,” Fisher said.

The drone prototype was among more than 100 projects and 29 advanced research programs on display in the Pentagon’s courtyard Wednesday in what was billed as DARPA Demo Day.

The HACMS program develops system architecture models, software components and operating system software, DARPA officials said.

Vulnerabilities or security issues can arise when drones or other military aircraft are “networked” to one another such that they can share information in real time. Security risks can emerge through network protocols, software bugs or unintended interactions between otherwise correct components, DARPA officials explained.

“Many things have computers inside and those computers are networked to talk to other things. Whenever you have that situation, you have the possibility for remote vulnerabilities where somebody can use the network connection to take over and get the device to do what the attacker wants instead of what the owner wants,” Fisher explained.

The software tools used for the HACMS program can be adjusted to larger platforms. In fact, DARPA plans to transition the secure software to Boeing’s Unmanned Little Bird helicopter, DARPA officials said.

“The software is foundational so it could be used for a large number of systems,” Fisher added.

DARPA unveils hack-proof drone | Fox News
 
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Why aren't we using these. More than a thousand should be operating (flying) over NW and the afghan border at all times.
 
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AeroVironment launches overland Puma flights for BP
By:BETH STEVENSON
18 Jun 2014



getasset.aspx

The US Federal Aviation Administration has granted the first authorisation for overland unmanned air system (UAS) operations in the USA to BP and AeroVironment, with the latter’s Puma AE aircraft.

This Certificate of Waiver or Authorization (COA) was utilised for the first time on 8 June, when energy company BP flew the Puma AE to survey the largest oilfield in the USA, at Prudhoe Bay, Alaska.The move is an extension of an FAA decision last year, when it issued restricted category type certificates to the Puma AE and Insitu Scan Eagle UAS, allowing them to be flown in surveillance roles over Arctic waters.

The approval was then revised for the Puma AE, allowing overland operation after AeroVironment demonstrated the type's capability to carry out these additional flights, the FAA says.

Under the FAA’s 2012 Reauthorisation Bill, the administration mandated that the process by which UAS were granted COAs to fly in national airspace be streamlined. This move came alongside a declaration that Arctic operations and small UAS flights would be the first to be integrated.

In parallel with being granted the COA, on 10 June BP announced it had contracted AeroVironment to provide routine UAS services over the site in Prudhoe Bay.This includes the provision of mapping and geographic information data, as well as other commercial information services, to monitor BP’s pipelines, roads and equipment.

The company will deploy the Puma AE equipped with either a light detection and ranging sensor or its standard electro-optical/infrared sensor payload. This data will then be used for 3D computerised models of roads, pads and pipelines.

The Puma AE is approximately 1.4m (4.6ft) long with a 3.5h endurance and wingspan of 2.7m. The UAS’s ability to fly low and slow – at 2,400ft above ground level and at speeds of less than 40kt (74km/h) – will help provide BP with accurate information to help manage the site, AeroVironment notes.

"Using the information generated by the Puma’s sensors, BP hopes to target maintenance activities on specific roads and infrastructure, which will save time and support safety and operational reliability goals, while helping to protect the sensitive North Slope environment," the FAA says.

BP has previously trialled a number of unmanned technologies, including the Aeryon Scout vertical take-off and landing UAS and unmanned maritime platforms.

http://www.flightglobal.com/news/ar...FGUAV-2014-0623-GLOBnews&sfid=70120000000taAj
 
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Northrop demonstrates broad area search radar on MQ-8B
By:STEPHEN TRIMBLE 19 Jun 2014

getasset.aspx


The NorthropGrumman MQ-8B Fire Scout will deploy next year with a new maritime surveillance radar that can track up to 200 targets beyond 15nm (27.8km).

The Telephonics RDR-1700B – redesignated by the US Navy as the ZPY-4(V)1 – provides a broad area search and track on the Fire Scout for the first time.

The new radar “complements Fire Scout's other sensors and systems to provide the Navy with increased visibility far beyond the horizon”, says GeorgeVardoulakis, Northrop’s vice-president for medium range tactical systems.

The MQ-8B will deploy with the ZPY-4(V)1 on the next deployment of the Freedom-class littoral combat ship USS Fort Worth in early 2015, according to Telephonics.

The demonstration on 7 May comes more than 17 months after Northrop selected Telephonics to supply the new radar in January 2013.

Telephonics, a Griffon subsidiary, describes the radar as an X-Band radar with a 15nm detection range of a 1-square-meter detection range in up to sea state 3 conditions.

The radar can operate in four different modes: surface search, terrain mapping, emergency beacon detection and weather avoidance, according to Telephonics. It can operate in both inverse and normal synthetic aperture modes.

Though highly capable, the radar is relatively lightweight at 34kg (75lb).


http://www.flightglobal.com/news/ar...FGUAV-2014-0623-GLOBnews&sfid=70120000000taAj
 
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June 26/14: N-UCAS support.Northrop Grumman Systems Corp. in San Diego, CA receives a $63.1 million to a previously awarded cost-plus-fixed-fee contract modification for Phase II of N-UCAS post-demonstration activities. $45.9 million is committed immediately, using US Navy FY 2013 and 2014 RDT&E budgets.

Phase II activities will include continued flights, test bed and flight test support at both shore-based locations and associated carrier detachments, continued development of Fleet Concepts of Operations, X-47B maintenance support, lab and test bed operational support and continued flight test opportunities.

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X-47B UCAS-D

The idea of UAVs with full stealth and combat capabilities has come a long way, quickly. Air forces around the world are pursuing R&D programs, but in the USA, progress is being led by the US Navy.

Their interest is well-founded. A May 2007 non-partisan report discussed the lengthening reach of ship-killers. Meanwhile, the US Navy’s carrier fleet sees its strike range shrinking to 1950s distances, and prepares for a future with fewer carrier air wings than operational carriers. Could UCAV/UCAS vehicles with longer ranges, and indefinite flight time limits via aerial refueling, solve these problems? Some people in the Navy seem to think that they might. Hence UCAS-D/ N-UCAS, which received a major push in the FY 2010 defense review. Now, Northrop Grumman is improving its X-47 UCAS-D under contract, even as emerging privately-developed options expand the Navy’s future choices as it works on its new RFP.


Naval Air, Unmanned: US Navy Flying Toward N-UCAS
 
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The IAI Super Heron HF(Heavy Fuel)

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weight ---------------1450 kg
wingspan -----------17 m
power ---------------200 hp diesel
max speed -------- 278 km/h
max ceiling --------10,000 m
max payload ------ 450 kg
endurance ----------24 - 45 h
 
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Lycoming: Use Aircraft Engines To Improve UAV Reliability
Jul. 14, 2014 -By TOM KINGTON

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Lycoming Engines supplies engines for the Aerosonde Mk. 4.7 UAV. (Aerosonde)


FARNBOROUGH, ENGLAND— As concerns grow over UAV reliability rates, US firm Lycoming Engines has claimed it is time for manufacturers to stop using snowmobile and chainsaw engines on their unmanned platforms and switch to general aviation aircraft engines.

“You will not successfully integrate UAVs in US civil airspace until reliability improves, and the FAA is saying the equipment should be no different to that used by manned aircraft,” said Michael Kraft, senior vice president and general manager at Lycoming Engines, a unit of Textron. “UAVs need piston engines which are safe.”

Lycoming has been manufacturing general aviation engines for decades and is now a presence in the UAV market, Kraft said, and has all the right credentials to save the industry from regular crashes.

“We use the same manufacturing techniques and materials used in manned aircraft that no chainsaw manufacturer would use,” Kraft said at the Farnborough International Airshow. “For example, we use an alloy on our DEL 120 which was deemed too expensive for Formula One racing.”

The DEL 120, built for general aviation aircraft, has been used on the General Atomics Improved Grey Eagle UAV as well as on its Block Zero retrofit after a previous supplier, Thielert, became insolvent.

“Some 152 Grey Eagle UAVs will be produced, while we would supply twice that number of engines for a successful general aviation aircraft in one year,” said Kraft, “so it is also a question of the support we can provide.”

Kraft said Lycoming was also able to leverage its return on investment from selling 3,000 general aviation engines last year to boost its research into UAV applications.

The firm currently supplies engines to the Aerosonde Mk. 4.7G UAV used by the US in Afghanistan, the Northrop Grumman Firebird and is seeking to power the pending Shadow M2.

Kraft said the Firebird, at 350 horsepower, was about the largest UAV that would benefit from a general aviation piston engine.

“When our engine was put on the Aerosonde, replacing a non-general aviation engine, reliability improved five fold,” Kraft said.


Lycoming: Use Aircraft Engines To Improve UAV Reliability | Defense News | defensenews.com
 
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FLIGHT OF THE DRONES

Anwar al-Awlaki and several of his al-Qaeda colleagues stopped their pickup truck on a remote, dusty road deep inside Yemen’s interior. He can have had only a split second to realise what was about to happen. But the missile strike that killed al-Qaeda’s most effective propagandist was no real surprise. It was just the latest example of the way America’s armed Predator and Reaper drones are changing the terms of combat with the country’s enemies, leaving them able to run but with nowhere to hide.

American officers, with their passion for acronyms, prefer not to call the machine that killed al-Awlaki a drone. They have a point. In nature, drone bees are poor, useless things that produce no honey and have no sting. That hardly describes the remotely-piloted Predator MQ-1 or Reaper MQ-9 aircraft. Laden with sophisticated sensors and carrying Hellfire missiles and laser-guided bombs, they patrol the skies above Afghanistan, launch lethally accurate strikes against terrorists in the tribal areas of Pakistan, Yemen and Somalia and have helped NATO turn the tide against Muammar Qaddafi’s forces in Libya. Even calling them Unmanned Aerial Vehicles (UAVs) or Unmanned Aerial Systems (UAS) is slightly misleading. There may not be a man in the cockpit, but each Reaper, a bigger, deadlier version of the Predator, requires more than 180 people to keep it flying. A pilot is always at the controls (albeit from a base that might be 7,500 miles, or 12,000km, away); and another officer operates its sensors and cameras.

Over the past decade UAS have become the counter-terrorism weapon of choice. Since 2005 there has been a 1,200% increase in combat air patrols by UAVs. Hardly a month passes without claims that another al-Qaeda or Taliban leader has been taken out by drone-launched missiles. There are now more hours flown by America’s UAS than by its manned strike aircraft and more pilots are being trained to fly them than their manned equivalents. While taking a knife to other cherished defence programmes last year, the defence secretary, Robert Gates, went out of his way to exempt drones from future cuts.

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Under Barack Obama, the frequency of drone strikes on terrorists in Pakistan’s tribal areas has risen tenfold, from one every 40 days during George Bush’s presidency to one every four. John Brennan, Mr Obama’s counter-terrorism chief, has made it clear that as America draws down its forces in Afghanistan over the next three years, there will be no let up in drone strikes, which, he claims, are partly responsible for al-Qaeda being “on the ropes”. The grim Reaper’s ability to loiter for up to 24 hours, minutely observe human activity from five miles above while transmitting “full motion video” to its controllers and strike with pinpoint accuracy has made it the essential weapon in America’s “long war”.But does this mean that the future belongs to UAS? As military thoughts turn to the threat posed by more powerful potential adversaries than jihadist militants—a fast-emerging China, say, or a nuclear-tipped Iran—will their enthusiasm for unmanned aircraft continue unabated? Or will having a pilot in the cockpit making life and death decisions remain the least risky option for the majority of missions, as proponents of the late and wildly over-budget F-35 Joint Strike Fighter, due to enter service in 2016, claim? If the answer favours the drones, then the world may be just at the beginning of a genuine revolution in warfare. It would be a revolution dominated, at least at the start, by America, which accounts for the overwhelming majority of UAS. Other countries, though, such as Britain and Italy, have also been quick to deploy armed drones and Israel, in particular, has a thriving UAS industry, using drones in a wide variety of roles.Drones come in many shapes and sizes. Although Predators and Reapers get most of the attention, they are only part of a large, diverse fleet of unmanned vehicles. What they have in common is that they offer a new dimension in intelligence, reconnaissance and surveillance—knowing where the enemy is and what he is doing.Some are big aircraft, such as the RQ-4A Global Hawk, a jet-engined, all-weather spy plane, equipped with advanced synthetic aperture radar, that costs more than an F-18 fighter, can survey 53,000 square miles of ground in a day and has flown from America to Australia without refuelling. Some are micro- or even (in the near future) nano-sized devices, which may imitate a bird or an insect, crawling inside a house or perching on a window ledge, to send back information. In between are a plethora of planes, ranging from hand-launched aircraft looking like big model aeroplanes designed to tell soldiers what is happening over the next hill to medium-size catapult-launched aircraft, such as the RQ-7B Shadow that has probably covered more ground and spotted more combat targets than any other drone.

Inside the hive
Two years ago, the US Air Force published its thinking on UAS development, “Unmanned Aircraft Systems Flight Plan 2009-2047”. The most striking thing about this document was its vision of a networked family of UAS. Drones would be built around common airframes of differing size incorporating a modular, “open-architecture” approach so they could be as flexible as possible. The medium-sized successors to today’s Reaper would be able to do more things, from defending airspace against enemy intrusion to attacking enemy air defences—all tasks that the F-35 has been designed to undertake. The largest UAS would operate as airborne warning and control aircraft (AWACs), aerial refuelling tankers, strategic lift transports and long-range bombers. Controversially, the UAS Flight Plan assumes that the next generation of drones will have artificial intelligence giving them a high degree of operational autonomy including—if legal and ethical questions can be resolved—the ability to shoot to kill.

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Some question whether artificial intelligence, which always seems just a few years away, will ever work well enough. But if the Air Force’s Flight Plan is right, it should be possible to overcome the technical problems. In 30 years it should be technically feasible to imbue drones with all the capabilities of manned aircraft as well as some extra powers of their own.But just because something is possible does not necessarily make it desirable. When UAS first emerged, the accepted wisdom was that they would be most useful doing tasks deemed “dull, dirty, dangerous, difficult or different”.Included in the “dull” and the “difficult” categories were surveillance missions requiring time and a degree of persistence that crews of manned aircraft could not provide. By maintaining what a former director of the Central Intelligence Agency described as an “unblinking stare” over a target for 18 hours the pilot (or pilots in shifts) can monitor patterns of activity on the ground and choose the best moment to fire missiles.

A typical “dirty” task for a UAS would be flying in to observe or take samples after a chemical or biological attack. Missions too dangerous for manned aircraft include everything from probing enemy air defences to carrying out surveillance over territory where a shot-down pilot could be used as a hostage. In the “different” category is the multitude of tactical reconnaissance missions that small drones can carry out which would be beyond the scope of manned aircraft.Along with persistence, UAS have other potential advantages over manned aircraft. Because they provide more detailed information about targets, their strikes are usually more accurate and cause fewer civilian casualties (the idea that drones are constantly blowing up Afghan weddings is wrong). They can be cheaper because, without the systems and space needed to keep aircrews safe, they are smaller. This is certainly true of the kind of UAS operated by the army to improve situational awareness, although there is a trend towards bigger, costlier aircraft. By freeing up space for fuel and by dispensing with a human crew subject to fatigue, UAS can also fly for much longer than conventional aircraft. For counter-insurgency or anti-terrorism missions, drones are easier to use discretely than manned aircraft because most of the team required to support them is far from the conflict zone. Nor do UAS have to be rotated in and out of a war zone like manned aircraft. Training UAS controllers, even those with no previous flying experience, costs less than a tenth as much as turning out a fast-jet pilot.As China and other countries develop more accurate ballistic and cruise missiles, able to hit moving targets 1,000 miles away, America and its allies have become worried about the aircraft-carriers they have relied upon as a principal means of projecting power since 1945.

Those worries are not much helped by the carrier version of the F-35 which, without external fuel tanks, has a combat radius of only 680 miles. The US Navy’s response has been to propose what it calls the Unmanned Carrier-Launched Airborne Surveillance and Strike aircraft. It has already asked for financing and hopes—somewhat optimistically—that it will enter service by 2018. If a big, long-range UAS can operate safely from a congested carrier flight deck at sea, that would go some way to allaying fears for the future of aircraft-carriers.Another potential advantage for UAS is that future designs may be better able to survive in contested airspace than manned aircraft are. Without the need to accommodate crew, drones can be given strange radar-cheating stealthy shapes. They may also acquire “hyper-manoeuvrability”. Composite materials and advances in avionics allow the latest aircraft designs to pull g-forces, especially extreme lateral acceleration, that would be too much for a pilot to stand.Not all the arguments favour UAS, though. Advocates of continuing investment in manned aircraft point out that current drones depend on two-way satellite communications. If the datalink is broken the remote pilot will lose direct control of the aircraft, which then has to rely on pre-loaded software and GPS guidance. For routine missions that may be all right, but for missions requiring constant oversight, the vulnerability to electronic jamming or a direct attack on a communications satellite is an Achilles heel. Datalinks can also go down without help from an enemy.A related problem afflicting today’s drones is the slight delay between the remote pilot sending an instruction to the aircraft and its response (known as latency).

In contrast, a pilot in the cockpit can react instantly to a threat and take evasive action. Drones operating over Iraq, Afghanistan, Yemen and Somalia are fairly safe: the enemy is powerless to hurt them. But when Predators were first introduced in Bosnia, there was high rate of attrition because the Serbs had a large number of Soviet-era surface-to-air-missiles.Another problem is that UAS have not been cleared to share civil airspace over America and Europe by air-traffic controllers. The Federal Aviation Authority began trials in 2010, but it will not be easy to dispel fears that if a pilot were temporarily to lose control of a UAS, it might smash into a passenger airliner in shared airspace.There are fixes for most of these weaknesses. To reduce latency, small, solar- or laser-powered ultra-long-endurance drones can form a chain in the sky along which satellite signals can be bounced. But real resilience—and with it the huge growth in what drones could possibly do—would require UAS to work with a lot more autonomy from their human operators. And that is controversial.To reduce the workload on pilots, big UAS can already take off and land automatically. They can fly unaided to the target area and monitor much of what is happening on the ground without help from their controllers. At present, each drone has its own pilot. But the US Air Force plans to have a single pilot operating up to four drones at a time. And the aim is to go much further, with largely autonomous UAS programmed to make mission-critical decisions when flying in swarms to overwhelm enemy air defences. It may even be possible, according to military visionaries, to give drones a form of ethical reasoning, using artificial intelligence.

Civil-liberty advocacy groups have raised concerns about targeted killings by drones of suspected terrorists, especially in the case of al-Awlaki who was an American citizen. But so far, the use of drones has not fundamentally challenged the Geneva Convention-based Law of Armed Conflict. This requires that before an attack, any weapons system (whether manned or unmanned) must be able to verify that targets are legitimate military ones, take all reasonable precautions to minimise civilian harm and avoid disproportionate collateral damage.As long as a UAS pilot can trust the data from remote sensors and networked information, he or she should be able to make a proper assessment based on the rules of engagement in the same way as the pilot of a manned aircraft. Indeed, because of the unique characteristics of UAS, he may be in a better position to do so. He should have more time to assess the situation accurately, will not be exhausted by the physical battering of flying a jet and will be less affected by the adrenalin rush of combat.

Automatic enemy deletion in progressBut what about the next step? Does it follow that an unmanned aircraft should be allowed to fire a weapon based entirely on its own data analysis?The British Ministry of Defence suggests the answer is: perhaps. In a thoughtful document on the British approach to UAS earlier this year, the ministry’s Development, Concepts and Doctrine Centre argued that if the controlling system addressed the principles of the law on armed conflicts (military necessity, humanity, proportionality and the ability to distinguish between military targets and civilians) and if the rules of engagement were satisfied, then an armed strike would meet legal norms. However, it goes on to say that the software testing and certification of such a system would be expensive and difficult. And decisions about what is proportionate often require fine distinctions and sophisticated judgment. The authors conclude: “As technology matures and new capabilities appear, policymakers will need to be aware of the potential legal issues and take advice at a very early stage of any new system’s procurement cycle.”David Deptula, a retired general who was until recently in charge of the US Air Force’s intelligence and surveillance operations agrees. He recently told Jane’s Defence Weekly: “Technologically, we can take [autonomy] pretty far, but it won’t be technology that is the limiting factor, it will be policy.” The Air Force’s chief scientist, Mark Maybury, points out that there will be an almost infinite combination of contingencies facing drones. Designing systems that ensure they respond in a safe and effective way may take a decade or more. Evangelists for drones concur that even when there is no longer “a man in the loop” piloting a UAS directly, it will still probably be necessary to have humans “on the loop” monitoring and intervening.The ethical problems do not end there. There may be nothing in the laws of war saying combatants must be willing to put themselves in harm’s way, but some find creepy the idea of a UAS pilot stationed in Nevada driving home for supper with the family a few hours after surgically killing dozens of people in Pakistan. The peculiar detachment of drone warfare has given people close to the receiving end of drone attacks some success in depicting America’s use of them as the cowardly action of a bully sheltering behind superior technology. Looking farther ahead, there are fears that UAS and other robotised killing machines will so lower the political threshold for fighting that an essential element of restraint will be removed. Robert E. Lee said “it is well that war is so terrible, otherwise we would grow too fond of it.” Drones might make leaders fonder of war.More mundane obstacles may also slow the rise of UAS. Peter Singer, director of the 21st Century Defence Initiative at the Brookings Institution, a think-tank in Washington, DC, says that at a time of falling defence spending, UAS procurement and development may lack allies against powerful and conservative constituencies. These include sceptical military bureaucrats, fast-jet pilots, and members of Congress fighting to preserve traditional weapons programmes and the jobs that go with them. But as Mr Singer concluded in a recent article in the Armed Forces Journal: “Tough budgetary environments, first generation limits and reliance on the ‘proven’ are often crucial barriers to change, but history also shows they can’t prevent the future from happening.” Two years ago, Mr Gates conceded that the F-35 would probably be the last manned strike fighter. It may take longer than the visionaries think, but the pilot in the cockpit is already an endangered species.

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EITAN-HERON TP

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RQ-4A GLOBAL HAWK

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MQ-9 REAPER

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MQ-1B PREDATOR

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X47-B

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RQ-7B SHADOW
 
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This photo of X-47B combat drone taking fuel from tanker proves we are one step closer to unmanned aerial refueling
Apr 16 2015 By David Cenciotti

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Image credit: Northrop Grumman

X-47B has completed first contact with an aerial refueling hose.

On Apr. 16, “Salty Dog 502″, one of the two Unmanned Carrier Air Vehicle demonstrator (UCAS-D) aircraft of the X-47B program performed autonomous aerial refueling (AAR) test, plugging the in-flight refueling (IFR) probe into the hose of a Omega Air tanker off the coast of Maryland.

The AAR in set to be the last for the two X-47B stealth killer drone technology demonstrators (the other being “Salty Dog 501″): with the end of this testing phase the two unmanned aircraft will be retired and probably donated to a museum or stored at the “boneyard”, the Aerospace Maintenance and Regeneration Group (AMARG) at Davis Monthan Air Force Base, Arizona.

In fact the X-47B is “just” a technology demonstrator and, as such, it’s till quite different from the planned Navy’s Unmanned Carrier Launched Surveillance and Strike (UCLASS).

In spite of calls to extend testing on the Northrop platforms, the costs to reconfigure the two X-47B in such a way to let them behave more like the Navy’s preferred option for UCLASS would be prohibitive.


The Aviationist » This photo of X-47B combat drone taking fuel from tanker proves we are one step closer to unmanned aerial refueling
 
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Northrop Grumman to test U-2 sensors on Global Hawk
2015-05-02


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Northrop Grumman is planning November test flights of the Global Hawk UAV with key U-2 sensors. Source: USAF




Key Points
  • A universal payload adaptor would allow the RQ-4 to carry approximately 3,000-4,000 lbs (1360-1814 kg) of sensors
  • Critical U-2 sensors weigh approximately 1,500 lbs (680 kg)

Northrop Grumman has nearly completed integration of key sensors carried by the US Air Force's (USAF's) Lockheed Martin U-2 manned reconnaissance aircraft onto its RQ-4B Global Hawk unmanned aerial vehicle (UAV), the defence technology company's manager for the effort told IHS Jane's on 29 April.

The company is self-funding the construction of a "universal payload adaptor", a metal grid that will be attached to the underside of the Global Hawk to allow it to carry the Senior Year Electro-Optical Reconnaissance System-2B/C and the Optical Bar Camera, said Mick Jaggers, Northrop Grumman's Global Hawk director and programme manager.

"That grid allows you to bolt on any of these sensors without restructuring the aircraft," said Jaggers. He said the universal payload adaptor (UPA) can carry approximately 3,000-4,000 lbs (1360-1814 kg) of payload. The U-2's SYERS and Optical Bar Camera weigh about 1,500 lbs (680 kg) combined.

The USAF is providing two Global Hawks and sensors to allow Northrop Grumman to perform flight tests of the UPA in November. Successful tests would allow for UPA integration onto the entire fleet. "Then you can put any sensor on any Global Hawk," Jaggers said.

The Pentagon wants to retire the U-2 and other ageing manned platforms in favour of UAVs to save money. Service officials have argued that they can afford only one high-altitude reconnaissance aircraft. They have wavered over which aircraft to keep, but are currently pursuing the U-2 divestment and RQ-4 upgrades.

The USAF recently told Congress that integration of U-2 sensors aboard Global Hawk was technically possible but that it was still determining the cost of such a project. Senior air force officials have previously said that Global Hawk still needed nearly USD2 billion in upgrades to reach parity with U-2 capabilities.

However, Jaggers said Northrop Grumman would likely be able to provide the UPA retrofit to the fleet, as well as upgrades to ground and communications systems for less than USD1 billion. "Once we prove this out in November ... it's just a matter of making more UPAs," he said.

COMMENT

Global Hawk still has a great deal of untapped potential. Jaggers noted that Northrop Grumman had not made significant upgrades to the system in nearly three decades due to the air force's wavering on which ISR aircraft it planned to keep.

"We really haven't touched the system much since 1998," he said. The UPA will allow the UAV to host almost any sensor payload, so the USAF could expand the aircraft's capability once it is integrated into the fleet.

Recent Global Hawk humanitarian missions, such as post-tsunami flights over Japan and the Philippines with aircraft stationed in Guam, as well as flights over Nigeria to search for schoolgirls kidnapped by Boko Haram with aircraft out of Sigonella, Italy, have shown that rapid deployment of RQ-4s is far more efficient than scrambling manned aircraft for reconnaissance.

Credit: Marina Malenic Washington, DC

Northrop Grumman to test U-2 sensors on Global Hawk - Intelligent Aerospace

Northrop Grumman to test U-2 sensors on Global Hawk - IHS Jane's 360
 
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