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Northrop Grumman X-47B

"
X-47B UCAS-D
An X-47B demonstrator receiving fuel from an Omega Boeing 707 tanker while airborne over the U.S. Navy's Atlantic Test Range on 22 April 2015
Role Unmanned combat air vehicle
Technology demonstrator
National origin United States
Manufacturer Northrop Grumman
First flight 4 February 2011
Primary user United States Navy
Number built 2
Program cost US$813 million (2012 estimate)[1]
Developed from X-47A Pegasus
Developed into X-47C UCLASS (planned)

The Northrop Grumman X-47B is a demonstration unmanned combat air vehicle (UCAV) designed for aircraft carrier-based operations. Developed by the American defense technology company Northrop Grumman, the X-47 project began as part of DARPA's J-UCAS program, and subsequently became part of the United States Navy's Unmanned Combat Air System Demonstration (UCAS-D) program. The X-47B is a tailless jet-powered blended-wing-body aircraft capable of semi-autonomous operation and aerial refuelling.[2]

The X-47B first flew in 2011, and as of 2015, its two active demonstrators have undergone extensive flight and operational integration testing, having successfully performed a series of land- and carrier-based demonstrations.[3][4][5] In August 2014, the US Navy announced that it had integrated the X-47B into carrier operations alongside manned aircraft,[6] and by May 2015 the aircraft's primary test program was declared complete.[7] Northrop Grumman intends to develop the prototype X-47B into a battlefield-ready aircraft, the Unmanned Carrier-Launched Airborne Surveillance and Strike (UCLASS) system, which will enter service in the 2020s.[8][9][10] The X-47B demonstrators themselves were intended to become museum exhibits after the completion of their flight testing, but the Navy later decided to maintain them in flying condition pending further development.[11][12]

Design and development

Origins

Video of aerial refueling of an X-47B in April 2015

The US Navy did not commit to practical UCAS efforts until 2000, when the service awarded contracts of US$2 million each to Boeing and Northrop Grumman for a 15-month concept-exploration program.[13] Design considerations for a naval UCAV included dealing with the corrosive saltwater environment, deck handling for launch and recovery, integration with command and control systems, and operation in an aircraft carrier's high-electromagnetic-interference environment. The Navy was also interested in procuring UCAVs for reconnaissance missions, penetrating protected airspace to identify targets for following attack waves.[14] Northrop Grumman's proof-of-concept X-47A Pegasus, which provided the basis for the X-47B's development, first flew in 2003.[15]

The J-UCAS program was terminated in February 2006 following the US military's Quadrennial Defense Review. The US Air Force and Navy proceeded with their own UAV programs. The Navy selected Northrop Grumman's X-47B as its unmanned combat air system demonstrator (UCAS-D) program.[16] To provide realistic testing, the company built the demonstration vehicle to be the same size and weight as the projected operational craft, with a full-sized weapons bay capable of carrying existing missile systems.[17][18][19][20]

The X-47B prototype rolled out from Air Force Plant 42 in Palmdale, California, on 16 December 2008. Its first flight was planned for November 2009, but the flight was delayed as the project fell behind schedule. On 29 December 2009, Northrop Grumman oversaw towed taxi tests of the aircraft at the Palmdale facility,[16] with the aircraft taxiing under its own power for the first time in January 2010.

Flight testing

The X-47B's first takeoff at Edwards Air Force Base, California, on 4 February 2011

An X-47B demonstrator with folded wings on the aircraft elevator of  (CVN-77)George H.W. BushUSS  on 14 May 2013
An X-47B launches from the Bush on 14 May 2013
An X-47B in flight near the Bush on 14 May 2013
An X-47B makes a successful arrested landing on the Bush on 10 July 2013

The first flight of the X-47B demonstrator, designated Air Vehicle 1 (AV-1), took place at Edwards Air Force Base, California, on 4 February 2011.[21][22] The aircraft first flew in cruise configuration with its landing gear retracted on 30 September 2011.[23] A second X-47B demonstrator, designated AV-2, conducted its maiden flight at Edwards Air Force Base on 22 November 2011.[24]

The two X-47B demonstrators were initially planned to have a three-year test program with 50 tests at Edwards AFB and NAS Patuxent River, Maryland, culminating in sea trials in 2013.[24][25] However, the aircraft performed so consistently that the preliminary tests stopped after 16 flights.[26] Thereafter, the Navy decided to use the aircraft to demonstrate carrier launches and recoveries, as well as autonomous inflight refueling with a probe and drogue. In November 2011, the Navy announced that aerial refuelling equipment and software would be added to one of the prototype aircraft in 2014 for testing.[27] The Navy also affirmed that the demonstrator aircraft would never be armed.[26] In 2012, Northrop Grumman tested a wearable remote control system, designed to allow ground crews to steer the X-47B while on the carrier deck.[28]

In May 2012, AV-1 began high-intensity electromagnetic interference testing at Patuxent River, to test its compatibility with planned electronic warfare systems.[29] In June 2012, AV-2 arrived at Patuxent River to begin a series of tests, including arrested landings and catapult launches, to validate the ability of the aircraft to conduct precision approaches to an aircraft carrier.[30] The drone‍ '​s first land-based catapult launch was conducted successfully on 29 November 2012.[31][32]

On 26 November 2012, the X-47B began its carrier-based evaluation aboard the

  • X-47B UCAS page and media gallery on NorthropGrumman.com
  • "X-47B – First Navy Stealth UAV Ready". The Future of Things. 20 January 2009.
  • "Could we trust killer robots?". Wall Street Journal. 19 May 2012.
  • "I Am Warplane: How the first autonomous strike plane will land on aircraft carriers, navigate hostile airspace and change the future of flight". Popular Science. 5 July 2012.
  • "X-47B stealth drone targets new frontiers". BBC Future. 19 December 2012.

External links

References

Related lists
Aircraft of comparable role, configuration and era

See also


Plan diagram of the Northrop Grumman X-47B, with a human to scale

Specifications (X-47B)

Proposed larger version intended for the Navy's UCLASS project.

X-47C

Demonstrator aircraft with a wingspan, first flown in 2011.

X-47B

Original proof-of-concept prototype with a wingspan, first flown in 2003.

X-47A

Variants

The Navy used software from the X-47B to demonstrate unmanned aerial refueling capabilities. On 28 August 2013, a contractor-flown Learjet 25 refueled from a Boeing 707 tanker while flying autonomously as a surrogate aircraft uploaded with the X-47B's technology.[57] The test was to demonstrate that unmanned and optionally manned aircraft can have an automated aerial refueling capability, significantly increasing their range, persistence, and flexibility.[57] Plans to further demonstrate autonomous aerial refueling were reportedly cut in the Navy’s fiscal 2014 budget,[58] but the X-47B nonetheless conducted a successful autonomous refuelling demonstration in April 2015.[2]

Derivative development

In March 2014, the X-47B won the 57th Annual Laureate Award for “extraordinary achievements” in aeronautics and propulsion hosted by Aviation Week.[55] On 9 April 2014, the National Aeronautic Association selected Northrop Grumman, the United States Navy, and the X-47B's development team as the joint recipients of the 2013 Collier Trophy for excellence in aeronautic technology.[56]

Awards

In February 2015, the Navy stated that the competition for private tenders for constructing the UCLASS fleet would begin in 2016, with the aircraft expected to enter service in the early 2020s.[10] Reportedly, despite the X-47B's success in test flights, Navy officials were concerned that it would be too costly and insufficiently stealthy for the needs of the UCLASS project.[10] In April 2015, it was reported that the X-47B demonstrators would become museum exhibits upon the completion of their flight testing.[11][53] In June 2015, United States Secretary of the Navy Ray Mabus stated that the X-47B test program should continue but that Northrop-Grumman should not gain an unfair advantage in the competition for the UCLASS contract.[54] In July 2015, the Navy stated that the X-47B demonstrators would remain in flying condition rather than being converted to museum exhibits, allowing for a variety of follow-on evaluations.[12]

End of program

The project was initially funded under a US$635.8-million contract awarded by the Navy in 2007. By January 2012, the X-47B's total program cost had grown to an estimated $813 million.[1] Government funding for the X-47B UCAS-D program was to run out at the end of September 2013, with the close of the fiscal year.[42] However, in June 2014 the Navy provided an additional $63 million for "post-demonstration" development of the X-47B.[52]

Costs

[11] This marked the effective completion of the X-47B's development, as it had completed all the primary demonstration tasks required of it.[51][2].Maryland tanker over the coast of KC-707 Omega Air In April 2015, the X-47B successfully conducted the world's first fully autonomous aerial refuelling, rendezvousing with an [50] The testing was successfully completed on 24 August 2014, with the X-47B completing five catapult launches, four arrestments, and nine touch-and-go landings. Nighttime taxi and deckhandling operations on the flight deck were also performed for the first time. The X-47B met its objective of performing launches and recoveries at 90-second intervals with manned Hornet planes.[49] alongside an Theodore Roosevelt On 17 August 2014, the X-47B took off and landed on the USS

Sea trials on the USS Theodore Roosevelt in 2014 were intended to test the X-47B's ability to swiftly take off, land, and hold in a pattern among manned aircraft without disruption to carrier operations. The X-47B also operated with a jet-blast deflector on deck for the first time, allowing it to conduct takeoffs without disrupting operations taking place behind it.[47] On 10 April 2014, the X-47B performed its first night flight.[48]

On 18 September 2013, the X-47B flew the 100th flight for the UCAS-D program. The objectives of the program were finally completed in July, which included a total of 16 precision approaches to the carrier flight deck, including five tests of X-47B wave-off functions, nine touch-and-go landings, two arrested landings, and three catapult launches.[45] On 10 November 2013, flight testing for the X-47B continued on board the USS Theodore Roosevelt (CVN-71). During this phase, the X-47B's digitized carrier-controlled environment was tested; this involved the interface between the unmanned aircraft and carrier personnel during launching, recovering, and flight operations.[46]

On 15 July 2013, the second X-47B demonstrator, designated 501, was forced to abort another planned landing on the Bush due to technical issues.[41][42] Officials asserted that only one successful at-sea landing was required for the program, though testers were aiming for three, and only two out of four were achieved.[42] The Navy continued flying the two X-47B demonstrators through 2014, after the service was criticised for prematurely retiring the testbeds.[43] The Navy subsequently deployed the aircraft to carriers for three further test phases between 2013 and 2015, with the intent of demonstrating that unmanned aircraft could seamlessly work with a 70-plane carrier air wing.[44]

On 10 July 2013, the X-47B launched from Patuxent River and landed on the deck of the George H.W. Bush, conducting the first ever arrested landing of a UAV on an aircraft carrier at sea.[5] The drone subsequently completed a second successful arrested landing on the Bush, but a third attempt was diverted to the Wallops Flight Facility in Virginia after a technical problem was detected, aborting the planned carrier landing.[39] One of the drone's three navigational sub-systems failed, which was identified by the other two sub-systems. The anomaly was indicated to the mission operator, who followed test plan procedures to abort the landing. The Navy stated that the aircraft's detection of a problem demonstrated its reliability and ability to operate autonomously.[40]

[38]

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