F-35 and F-15EX fighter jets could get drone wingmen in the coming years as part of the Skyborg programme

The technology for the Skyborg program, which would see drones like the Valkyrie (bottom right) support jets like the F-35

• The US Air Force is exploring how AI-controlled jets could support fighter pilots
• Drones could enable the US Air Force to reduce the number of jets per mission
• Such would reduce the risk to pilots while economical drones cut overall costs
• XQ-58 Valkyrie stealth drones are among those marked for transfer to AI control

Unmanned drones, powered by artificial intelligence, may soon accompany US Air Force Pilots on missions as autonomous wingmen. 

Both Boeing's F-15 and Lockheed Martin's F-35 fighter jets are being considered for the 'Skyborg' drone support program.

The scheme would cut down on the amount of people in the jets and could both reduce the risk to pilots and be more economical. 

Drones can be manufactured for a fortieth of the cost of a new fighter jet and may be guided by the sole pilot inside the nearby fighter plane.  

To safely manage any such drones, however, AI will need to be sufficiently developed to make it immune to attacks that could exploit its operating features.

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Artificial intelligence could soon be up there with the best of the best as the US Air Force explores how fighter jets (such as the F-35, pictured) could be supported by AI wingmen

The technology for the Skyborg program is being developed by the US Air Force Research Laboratory, in collaboration with aircraft manufacturers Boeing and Lockheed Martin.

Teaming up fighter jets with autonomous drones would 'open up the door for an entirely different way to do aerial combat,' US Air Force Service Acquisition Executive Will Roper told Defense News.

According to Dr Roper, a standard flight formation of four jets could be replaced with one jet and three drones. 

'I'm very passionate about doing it, and the F-35 has a wonderful opportunity to do this as part of Block 4,' Dr Roper said, referring to the F-35's upcoming upgrade program. 

'We might also have an opportunity to do this as part of F-15EX.' Skyborg had previously been characterised by Dr Roper as an artificial intelligence based wingman that would be trained alongside human pilots and potentially incorporated in manned jet cockpits to assist them.

Dr Roper had also informed US lawmakers earlier in May that Skyborg would be moving to incorporate the XQ-58 Valkyrie drone programme.

This switch would see the stealth drones outfitted with new sensors, new payloads and the capacity to be networked with manned fighter craft. 

The Valkyrie is well suited to the latter task, having been designed to operate like a fighter jet.

The drone is capable of flying at Mach 0.85, can travel at least 1,500 nautical miles (around 1726 miles/2778 kilometres) while carrying a 500 pound (227 kilogram) payload, and is capable of taking off without a runway.

The first test flight of a Valkyrie was successfully undertaken at the Yuma Proving Ground in Arizona on March 5, 2019, following two-and-a-half years of development.

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Teaming up fighters with autonomous drones would open up the door for an entirely different way to do aerial combat. For example, a formation of four jets could be replaced with one jet and three drones (as pictured) — which would be more economical and risk less human life

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The scheme could both reduce the risk to human pilots and prove more economical — drones (like the XQ-58 Valkyrie, pictured) can be built for a fortieth of the cost of a new fighter jet

The Air Force is also investigating the potential of integrating other unmanned aerial platforms into the Skyborg program.

Characteristics sought after in any such vehicle would be the capacity to both take off and land autonomously, as well as avoid any obstacles and bad weather.

Also being explored is an autonomous, modular aircraft with open systems that could be upgraded with new AI software or hardware, Defense News reported.

'We can take risks with some systems to keep others safer,' Dr Roper said, explaining that the Skyborg program will enable the Air Force to separate sensors and shooters across different craft.

'Right now they're collocated on a single platform with a person in it,' he said. 

'In the future, we can separate them out, put sensors ahead of shooters, put our manned systems behind the unmanned.'

'There's a whole playbook,' he added.

WHAT IS THE F-15 EAGLE?

The F-15 Eagle is an American twin-engine, all-weather tactical fighter aircraft designed by McDonnell Douglas, now Boeing, in 1972. 

It entered service in 1976 and is among the most successful fighter jets in production today, with no losses in aerial combat.

The aircraft is predominantly used by the US Air Force as well as the air forces of Saudi Arabia, Israel and Japan.

Each model costs around £21 million ($28 million) and the aircraft has been modified and improved over the years with different variants now used around the world, including the faster F-15E Strike Eagle. 

As of 2017, the aircraft is being produced in different variants with production set to end in 2022.

AT A GLANCE:

Crew: One pilot

Length: 63 ft 9 ins (19.43 m)

Wingspan: 42 ft 10 ins (13.05 m)

Height: 18ft 6ins (5.63m)  

Max takeoff weight: 68,000 lbs (30,845 kg) 

Engines: 2 Pratt & Whitney F100-PW-100 or −220 afterburning turbofans 

Max speed: Mach 2.5+ (1,650 mph) 

Max altitude: 65,000 ft (20,000 m) 

Armament: One 20 mm (0.787 in) M61A1 Vulcan 6-barrel Rotary cannon, four AIM-7 Sparrow missiles, four AIM-9 Sidewinder missiles, eight AIM-120 AMRAAM missiles

Alongside reducing the risk to human life, each drone will also be more economical to manufacture than the fighter jets it will supplant.

When built in bulk, each Valkyrie will cost around 'a couple [of] million bucks', Dr Roper predicted, compared to the $80 million (£63 million) price tag of the F-35A and F-15EX jets.

Autonomous craft are expected to begin testing in the next year, with the ambition of having a workable Skyborg setup by 2023.

At this time, the F-35 will be undergoing its third key technology upgrade — with newly built models to feature improved processing power, higher levels of memory and more advanced cockpit displays.

At the same time, the fighter's operating system will be transitioned onto a government-owned open mission architecture, which will support the development and deployment of custom software application in to the jet.

It this capacity that would allow the F-35 fighters to be integrated alongside the AI-controlled drone craft. 

The F-35 is 'ideally suited' to team up with unmanned craft in applications like Skyborg, Lockheed Martin spokesperson Mike Friedman said in a statement.

'The F-35 is a force multiplier able to share its operational picture with ground, sea and air assets in the battlespace,' Mr Friedman said.

'Lockheed Martin has extensive experience in manned/unmanned teaming and are working closely with our customers to develop and field this critical capability,' Mr Friedman added.

Boeing, the manufacturer of the F-15 jet, is reportedly receptive to the proposed upgrades that would allow the fighter to be used in Skyborg.

'We are initiating early discussions with the US Air Force customer on how to insert contemporary technology such as this,' Boeing Vice President Prat Kumar told Defense News.

'The F-15EX is a uniquely suited platform for such tech insertions as it has available computing capacity and space.'

The US Congress must first decide whether they will approve funding for the development of the F-15EX.

With $986 million (£780 million) allocated in the draft House appropriations bill for the construction of eight jets, however, approval would seem a likely prospect.

'I don't think there's a barrier in terms of funding,' Dr Roper explains, who instead sees cultural and technological hurdles being more significant.

These may include, for example, integrating Skyborg into simulators, installing the artificial intelligence across the networked craft and deciding what actions the AI will be permitted to undertake.

'This is just different,' he said.

'We need to understand when the machine will be at its best and when the human will at its best,' he added.

'We will need to get the person trained to have an instinct for AI just like they have an instinct for stealth.' 

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Both Boeing's F-15 (pictured) and Lockheed Martin's F-35 fighter jets are being considered for the 'Skyborg' drone support program

Developing AI for military applications comes with inherent challenges above and beyond those found in current commercial uses. 

Not only will drone-flying AI need to be built in a way that addresses issues of trust and oversight — such as face applications like self-driving cars —  but will also need to be able to fend off attacks designed to exploit its fundamental capabilities.

Features such as data extraction, feature recognition and pattern recognition could be manipulated by feeding the AI false information, for example.

'The current generation of AI does not deal with a world that understands how AI works and intentionally trying to throw a wrench in its machine,' said Dr Roper.

'We will deal with that.' he added.

F-35 performs first public aerial demonstration at Paris Air Show

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F-35: How the planes serving HMS Elizabeth have been plagued with problems

The delivery of the RAF's new, US-built F-35B Lightning II Joint Strike Fighter in July marked a rare moment of celebration in what has been a troubled project.

The 'fifth generation' fighter aircraft is the world's most expensive weapons system, though costs have finally stabilised at an eye-watering $406billion.

Manufacturer Lockheed-Martin agreed to cap costs after US President Donald Trump critised the project and even tweeted support for a rival aircraft. 

Britain is currently embarked on a £9.1billion programme to purchase 48 of the F-35s, from American aviation giant Lockheed Martin, by 2025.

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One of the first four F-35B Lightning II aircraft arrives at RAF Marham in Norfolk on June 6, 2018

America enticed its Nato and other allies into sharing the cost of the aircraft by offering input into manufacture and 15 per cent of each one is comprised of parts from British companies while some of the jets will be made in Italy.

But the planes have been plagued by a catalogue of problems which have sent costs soaring.

There are fears about shortcomings in the technical systems underpinning the new generation of war planes will leave them unable to function properly.

The true cost of the British planes delivered this year is estimated to be over £150million each to cover 'extras' such as software upgrades and spare parts.

There are also concerns plane's software system is vulnerable to cyber-attack and cannot be tested independently by the UK.

The weak broadband on the Royal Navy's principal aircraft carrier HMS Queen Elizabeth is also hampering the jet's abilities.

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The problems are not helped by the department responsible for the computer networks essential to the aircraft's operation needs to find savings of £400 million this year.

The reports into the costs and other problems prompted the Defence Select Committee to launch an inquiry into the project.

It reprimanded the Ministry of Defence for keeping parliament and the public in the dark about the costs.

The MoD has so far refused to provide the estimated cost to the UK of buying the F-35, beyond referring to a National Audit Office which used the £9.1billion figure.

MPs said 'it is simply not acceptable for the MoD to refuse to disclose to parliament and the public its estimates for the total cost of the programme'.

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Though the cost of the F-35 has been the focus of attention, there have also been embarrassing reports of operational shortcomings emerging from the United States.

In a mock air battle in 2015, the cutting edge plane was defeated by an older generation F-16, a plane designed in the 1970s.

Last year Pentagon tests found 276 different faults in jet's combat system.

They included the 25mm cannon vibrating excessively and problems with the he aircraft's 'virtual reality' helmet

Overheating, premature wear of components in the vertical tails and vulnerability to fire were also found to be issues.

The US Air Force temporarily grounded dozens its F-35 stealth fighters while it investigated an oxygen supply issue.

The Marine Corps, who also operate the same F-35B model the UK has purchased, was forced to ground its planes after flaws were found in the  computer system.

Pentagon releases secret footage of swarm drones being launched from fighter jets - and is planning 'Avatar' self flying planes

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• Friday, April 12, 2019

  
  
  
  
  
  Strategy to Defeat China in The SCS
  

  
  
  

  The air campaign in Desert Storm was a watershed for air power. It demonstrated the effectiveness of precision munitions, marked a high water point for electronic warfare and introduced radar stealth in a decisive manner. It also established a template for the application of air power that has taken root in Air Force culture and remains firmly established a quarter century later.

  
  

  
  

  
  

  At the outset of the war sink all  surface Chinese ships and submarine, after radar and SAM coastal batteries have been neutralized using our airforce stealth bombers and jet fighters.

  
  

  
  

  
  

  
  

  
  

  In the context of a Sino-American war, the United States could try to take China’s greatest national strength—its export-oriented, booming economic-growth model—and transform it into a major military weakness. To do so, the United States would implement a naval blockade of China that attempted to choke off most of China’s maritime trade. Under the right conditions, the United States might be able to secure victory by debilitating China’s economy severely enough to bring it to the negotiating table.

  
  

  
  

  
  

  
  

  Yet until recently, a blockade strategy was largely overlooked, perhaps because economic warfare strategies seem inherently misguided given the close commercial ties between China and the United States. But if a serious conflict between the two nations erupted, then their immediate security interests would quickly override their trade interdependence and wreak enormous economic damage on both sides, regardless of whether a blockade were employed.

  
  

  
  

  
  

  
  

  Even if a blockade is never executed, its viability would still impact American and Chinese policies for deterrence reasons. The United States’ regional strategy is predicated on the belief that a favorable military balance deters attempts to change the status quo by force, thus reassuring allies and upholding strategic stability. The viability of a blockade influences this calculus, and can accordingly affect American and Chinese actions—both military and nonmilitary—that are based on perceptions of it. If a naval blockade is a feasible strategy, it strengthens the American system of deterrence and dilutes any potential attempts by China to coerce the United States or its allies. Moreover, if a blockade’s viability can be clearly enunciated, it would also enhance crisis stability and dampen the prospects of escalation due to misunderstandings—on either side—about the regional balance of power. In short, as Elbridge Colby put it: “the old saw remains true, that the best way to avoid war is to prepare for it.”

  
  

  
  

  
  

  
  

  While a blockade is not a priori impossible or irrelevant in any situation, it is also not a ready tool in the American arsenal and would be feasible mainly within certain boundaries. Most importantly, many commentators miss the fact that a blockade is a context-dependent strategy, one that crucially depends on the regional environment.

  
  

  
  

  
  

  
  

  

  
  

  
  

  
  

  
  

  Earlier this year, a Chinese frigate locked weapon-targeting radar on a Japanese destroyer near the Senkaku Islands. Both Japan and China lay territorial claims to these uninhabited islands, which are close to both Okinawa and Taiwan. This is one of many territorial disputes that China has in the South and East China Seas.

  
  

  
  

  
  

  
  

  Needless to say, there was no escalation in this particular instance: the Japanese destroyer did not respond, and the only volleys fired were of a diplomatic nature. But what if things shake out differently next time? It is not hard to imagine such a scenario spinning out of control and leading to a shooting war. What would the U.S. do if this led to a larger regional war?

  
  

  
  

  
  

  
  

  Under this and many other scenarios, the U.S. would be obligated to defend its allies. One way in which it might do this would be through a blockade of Chinese maritime traffic by U.S. forces, with the explicit support of nations that control key international straits, including Indonesia and Malaysia. Though it would be costly and risky, a blockade could prove decisive. T.X. Hammes and Sean Mirski contend that in the right circumstances, particularly a limited war of long duration, blockade could be a war winning strategy.

  
  

  
  

  
  

  
  

  At the same time, however, a blockade would not be without its pitfalls. It would take a long time to enact. It would have to balance interdiction of oil imports against economic exports. And a blockading nation would also need to consider how to “hold the line” to prevent China from achieving its goal (in the above example, securing sea control of the Senkaku Island) while a blockade was taking effect.

  
  

  
  

  
  

  
  

  Given its potential utility and also its possible downsides, decision makers and theater commanders must understand how a blockade of China would actually work and the precise conditions under which it holds promise.

  
  

  
  

  
  

  
  

  What Should Be Blockaded?

  
  

  
  

  
  

  
  

  When considering a blockade, the first question is: what commodity is to be targeted? One obvious option is to target everything. NWP 1-14, the Commander’s Handbook on the Law of Naval Operations, states that the belligerent right of blockade allows interdiction of all vessels and aircraft, regardless of cargo, crossing an exclusion zone. Blockades established to starve a civilian populace are illegal, but a reasonable case could be made that China’s agricultural resources and medical capabilities can provide for the civil population even during a blockade.

  
  

  
  

  
  

  
  

  But just because an option is legal, it is not necessarily wise. Total blockades, such as the Union blockade of the Confederacy or the German U-Boat campaign against Great Britain, are difficult and expensive. It is more efficient to target specific commodities. For instance, during World War II, the United States used both the strategic air campaign in Europe and the submarine campaign in the Pacific to effectively target Germany’s and Japan’s oil infrastructures. Such a strategy would prove effective in a long term conflict with China.

  
  

  
  

  
  

  
  

  Indeed, much as it was for Nazi Germany and Imperial Japan, oil is China’s Achilles’ heel. Chinese domestic oil production supplies only 40% of peacetime consumption and demand continues to increase, even during periods of zero or negative growth in exports (see 2001 and 2009). Another advantage of targeting oil is the ease of discrimination. An oil tanker is a unique vessel, easing the blockaders’ burden when identifying and prioritizing targets. Significant smuggling of oil in other types of ships is impractical. In addition, China would have a hard time importing enough oil over land due to difficult terrain, underdeveloped pipelines and competition for Russian oil.

  
  

  
  

  
  

  
  

  However, China recognizes its reliance on foreign oil and has taken steps to reduce its vulnerability to supply disruptions. Specifically, China has established a robust strategic oil reserve. China’s 2011 strategic oil reserve was sufficient to supply 100% of domestic consumption (factoring in domestic production) for 25 days without rationing. Improvements to this reserve are planned to more than double its duration by 2020, even factoring in an increase in Chinese oil demand.

  
  

  
  

  
  

  
  

  The effect of a war on China’s demand for oil must also be considered. China uses oil mostly for transportation, so given that a war would reduce Chinese exports (it would not, after all, continue trading with the United States and Japan), the demand for oil to transport goods would go down. Overland transport mitigates China’s reliance on maritime oil, even though it provides only a small share of China’s total need. A blockader also must be wary of resale of neutral oil that is allowed past the blockade, requiring a strong coalition to surround China. Rationing, while it would be unpopular with the Chinese people, would further reduce demand for oil.

  
  

  
  

  
  

  China’s export income of $2 trillion would be hard hit simply by declaring such a blockade (in addition to the immediate loss of revenue from U.S. ports closing their doors to China). This immediate loss to China could provide the catalyst to end hostilities, and if China made a poor transition to a wartime economy, a disgruntled middle class could cost the Chinese Communist Party dearly, thus reducing the perceived value of a war.

  
  

  
  

  
  

  Still, the Chinese economy has proven resilient in times of reduced trade by replacing export income with internal investment and stimulus. If China determined that the war objectives were worth the loss of exports, effectively managed nationalism could,in the short term buoy popular will during the immediate economic hardship. As enthusiasm for the war effort faded, governmental control over the economy could then be leveraged to spur domestic development for long term maintenance of the economy (investment in fixed capital contributes 75% more to China’s economy than exports and government stimulus could increase this more).

  
  

  
  

  
  

  
  

  But because the shift to domestic development would still require oil, the operational emphasis of a blockade should be on stopping oil while interdicting targets of opportunity when practicable. Periodically interdicting a container ship gives credence to the export blockade and drives away customers, while the main effort still focuses on compromising China’s oil situation. After all, WWII submariners still sank troop ships; they just sank the tankers first.

  
  

  
  

  
  

  
  

  How Should a Blockade Be Conducted?

  
  

  
  

  
  

  
  

  An ideal blockade of China would use multiple layers, with each layer having a different purpose. These layers should include (1) a distant conventional blockade focused on chokepoints of sea lines of communications to China; (2) a close, unconventional maritime engagement zone, and (3) diplomatic engagement to embargo points of embarkation.

  
  

  
  

  
  

  
  

  The most critical part of the blockade is the first: control of key chokepoints using conventional forces. The focal point of this blockade would be the Strait of Malacca and nearby archipelagic straits through Indonesia. These locations derive the protection of international law and the UN Convention of the Law of the Sea, which states that that belligerents cannot operate in neutral waters. Consequently, to make the blockade legal, the countries bordering the Strait of Malacca must explicitly support a blockade, becoming belligerents themselves. While failing to gain Malaysia’s support would be a surmountable challenge – it might simply move the blockade 12 miles outside the straits into international waters – Indonesia’s support will make or break a blockade. Its archipelagic sea lanes (at least four basic routes) provide several corridors for blockade runners exploiting innocent passage. Without Indonesian support, only a United Nations Security Council Resolution allows closure of these sea lanes, and China’s Security Council veto would never allow that.

  
  

  
  

  
  

  
  

  Even setting legalities aside, a blockade of the Strait of Malacca would be a complicated undertaking. Given the vast quantity of traffic that transits these chokepoints—much of it bound for allied or neutral countries—traditional methods of visit and search are challenging. Approximately 165 ships of all types transit the Strait of Malacca each day, of which 52 are oil tankers. A blockader would need to investigate all appropriate ships, evaluate whether they were blockade runners, and seize those that were. As many as thirteen warships would be required to enforce an oil blockade using traditional methods of visit and search . This number does not allow for force protection, replacements for material failures or prize crews. Additional ships would have to guard other passages such as the Lombok/Makassar straits. Increased insurance rates and risk-averse shippers would reduce that number of tankers destined for China; however, China’s large national fleet and other Chinese owned merchants would still sail, and China’s significant cash reserves could supplant traditional insurers. As such, the operational commander would still need to dedicate a squadron of significant size to blockade, revealing a major opportunity cost.

  
  

  
  

  
  

  
  

  It is possible to reduce this footprint if some measures are taken during peacetime (there is no time like the present). Specific examples include development of procedures, relationships and technologies to establish a Navicert system for shipping and stand up land-based Visit, Board, Search and Seizure (VBSS) teams from the Coast Guard and land forces. A Navicert process is a prescreening of traffic at the port of embarkation previously used by the British during their blockades of Germany, which could make blockade inspections more efficient. Combining a Navicert process with an electronic system such as the Automatic Identification System (an automated data system installed on all ships 300 tons or larger that reports a wealth of information) increases the potential for success.  A commander can use land based VBSS teams augmented with drones, helicopters and small boats to supplement warships in critical chokepoints, allowing precious destroyers and cruisers to assist in other efforts. These capabilities would be difficult to develop “on the fly” in wartime, so capabilities and relationships should be fostered now to improve their effectiveness at the onset of hostilities.

  
  

  
  
  Pentagon's micro-drones can be launched from F-16 and F A/18 fighter jets 
• Can also be launched by hurling from ground, or with slingshot-like device
• The drones gain situational awareness to find each other and create swarm
• Avatar project would turn older jets into autonomous planes  

A highly secretive Pentagon organization is experimenting with 'micro-drones' which could one day take to the sky like a like a swarm of robotic locusts.

The experiments led by the Strategic Capabilities Office were conducted in Alaska last summer, according to The Washington Post, during which the tiny drones were launched from fighter jets.

After launch, the 3-D printed micro-drones break free of a canister and seek each other out to create a swarm. Pentagon releases video showing micro-drones dropping from F-15

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SWARMING MICRO-DRONES 

The micro-drones have inch-wide propellers, and can be launched from the flare dispensers of F-16 and F/A-18 fighter jets.

After launch, they descend in a parachute-equipped canister and then break free.

Once free, the drones gain situational awareness and locate other drones to create a swarm.

The program costs roughly $20 million, and is named after Perdix, a character in Greek mythology who was turned into a partridge by Athena.

The Alaska exercise put the drones through 150 tests, 72 of which were from fighter jets.

These micro-drones can also be launched from the ground by hand, or using a sling-shot like device.

It's been said they can be used for surveillance and as a way of confusing enemy forces.

While the SCO can't release specific details on the drones, it's been said they can be used for surveillance and as a way of confusing enemy forces.

The micro-drones have inch-wide propellers, and can be launched from the flare dispensers of F-16 and F/A-18 fighter jets.

In the footage reviewed by The Washington Post, a micro-UAV (unmanned aerial vehicle) is shot out from an F-16 moving 430 mph.

This happens at 2,000 feet above the surface Earth, and the drone descends inside a parachute-equipped canister.

After a moment, the small drone which weighs roughly a pound bursts free and its swings spread out to catch the wind. 

According to The Washington Post, these tiny craft have situational awareness, allowing them to move together in swarms after they've been released from the canister.

The program costs roughly $20 million, and is named after Perdix, a character in Greek mythology who was turned into a partridge by Athena.

The Alaska exercise put the drones through 150 tests, 72 of which were from fighter jets.These micro-drones can also be launched from the ground by hand, or using a sling-shot like device.

In an interview with The Washington Post, physicist and director of SCO William Roper said last summer's tests proved the swarming capabilities of the micro-drones.

Roper also revealed the Pentagon's plans for a project called Avatar, which aims to pair 'fifth-generation' fighter jets with unmanned versions of older jets.

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A highly secretive Pentagon organization is experimenting with 'micro-drones' which could one day take to the sky like a like a swarm of robotic locusts. The experiments led by the Strategic Capabilities Office were conducted in Alaska last summer, during which the tiny drones were launched from fighter jets

This would couple high-tech jets like the F-22 Raptor and F-35 Joint Strike Fighter with jets like the F-16 Fighting Falcon or F/A-18 Hornet in a concept known as the 'Loyal Wingman' in the Air Force.

In the program, which was previously called 'Skyborg,' older jets would be flown autonomously for the first time, allowing them to act with less direction from the pilot in the manned jet. 

In a speech this past February, Secretary of Defense Ash Carter discussed some of the proposed 2017 budget, including a call for $902 million for the SCO.

Carter described the many ways the SCO is exploring autonomous technologies, hinting at the capabilities of the swarming micro-drones.

'In the air, they develop micro-drones that are really fast, really resistant,' Carter said.

'They can fly through heavy winds and be kicked out the back of a fighter jet moving at Mach 0.9, like they did during an operational exercise in Alaska last year, or they can be thrown into the air by a soldier in the middle of the Iraqi desert.'

While the SCO can't release specific details on the drones, it's been said they can be used for surveillance and as a way of confusing enemy forces. The micro-drones have inch-wide propellers, and can be launched from the flare dispensers of F-16 and F/A-18 fighter jets

He also went on to say that this technology, along with a similar fleet of autonomous boats and other projects are just a few of the many systems the SCO is now working on.

'For example, the micro-drones, I mentioned a moment ago, use a lot of commercial components and are actually 3-D printed and the boats build on some of the same artificial intelligence algorithms that long-ago and in a much more primitive form were on the Mars lander.'  

These types of UAVs have been tested since 2014, but the Alaska experiment during the military exercise Northern Edge, they reached a new milestone.

Physicist and director of SCO William Roper, pictured above, said last summer's tests proved swarming capabilities of the micro-drones. These types of UAVs have been tested since 2014, but the Alaska experiment during the military exercise Northern Edge, they reached a new milestone

SELF-LEARNING ROBOT SWARM BOATS 

The robotic swarms work like a school of fish, or flock of birds.

Using a neural network as a 'living brain,' the robots can interact with each other, working from a set of simple instructions.

Each boat only acknowledges its neighbour, and will work together for monitoring, navigation, aggregation, and dispersion.

After tests in a simulate environment, the 'fittest' robots, those who have the most successful behaviours, are tested in a real world setting.