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Future Vertical Lift

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Future Vertical Lift
The Bell V-280 Valor, an FVL concept developed as a Joint Multi-Role Technology Demonstrator
General information
Issued byUnited States Department of Defense
History
RelatedFuture Attack Reconnaissance Aircraft (FARA) – cancelled
Future Long-Range Assault Aircraft (FLRAA) – in development
PredecessorsJoint Multi-Role (JMR)

Future Vertical Lift (FVL) is a plan[1] to develop a family of military helicopters for the United States Armed Forces. Five different sizes of aircraft are to be developed, sharing common hardware such as sensors, avionics, engines, and countermeasures.[2] The U.S. Army has been considering the program since 2004.[3] FVL is meant to develop replacements for the Army's UH-60 Black Hawk, AH-64 Apache, CH-47 Chinook, and OH-58 Kiowa helicopters.[4][5] The precursor for FVL is the Joint Multi-Role (JMR) helicopter program.[6]

Overview

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Summary

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After a decade of combat from Operation Iraqi Freedom and Operation Enduring Freedom, the U.S. Department of Defense found that the U.S. Army's rotorcraft fleet was wearing out. Combat operations made the helicopters fly five times more often than in peacetime. Manufacturers have been remanufacturing and upgrading existing families of aircraft without creating original platforms. The Future Vertical Lift (FVL) concept is to create a new rotorcraft that uses new technology, materials, and designs that are quicker, have longer range and higher payload capacity, are more reliable, easier to maintain and operate, have lower operating costs, and can reduce logistical footprints. FVL is to create a family of systems to replace most Army helicopters. The Joint Multi-Role (JMR) phases will provide technology demonstrations. JMR-TD will develop the aerial platform; JMR Phase I will develop the air vehicle; JMR Phase II will develop mission systems. The Army plans to acquire as many as 4,000 aircraft from the FVL program.[7] The Army started an FVL engine program in 2016.[8]

Future Vertical Lift was established in 2009 as an initiative, not yet a solution,[9] by the Secretary of Defense to focus all DoD vertical lift capabilities and technology development, as well as retaining long-term engineering capabilities.[10] In October 2011, the Deputy Secretary of Defense issued the FVL Strategic Plan to outline a joint approach for the next generation vertical lift aircraft for all military services. The Strategic Plan provided a foundation for replacing the current fleet with advanced capability by shaping the development of vertical lift aircraft for the next 25 to 40 years. It indicates 80 percent of decision points for the DoD vertical lift fleet to either extend the life, retire, or replace with a new solution occurring in the next eight to ten years. Implementation of the FVL Strategic Plan will impact vertical lift aviation operations for the next 50+ years.[11] The United States Navy is a partner to the Army on the effort, so a derivative of FVL may be used in the Navy's MH-XX program to replace the service's MH-60S/R helicopters.[12]

Configurations

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Three sizes were planned in 2009, then four and five (which may or may not be of the same design) are envisioned to replace 25 current rotorcraft types:[13][14]

According to the U.S. House Armed Services Committee, three different configurations of JMR aircraft – a conventional helicopter, a large-wing slowed rotor compound helicopter, and a tiltrotor – were being studied as of April 2013.[20]

Design requirements

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Although requirements are still being refined, the notional concept for a new aircraft must reach speeds of 230 kn (260 mph; 430 km/h), carry up to 12 troops, operate in "high-hot" conditions at altitudes of 6,000 ft (1,800 m) and temperatures of 95 °F (35 °C), and have a combat radius of 263 mi (424 km) with an overall unrefueled range of 527 mi (848 km). Mission sets are to include cargo transport, utility, armed scout, attack, humanitarian assistance, medical evacuation, anti-submarine warfare, anti-surface warfare, land/sea search and rescue, special warfare support, vertical replenishment, airborne mine countermeasures, and others.[21] The FVL family of aircraft will be required to have either optionally piloted or autonomous flight capabilities.[22]

In March 2013, the Army asked the industry to submit proposals for an effort called the Alternative Engine Conceptual Design and Analysis. Although formal requirements for the FVL family of systems had not yet been set, they will need to have hover, speed, range, payload, and fuel efficiency characteristics "beyond any current rotorcraft". This may require an aircraft that can hover at 10,000 feet (3,000 m) and cruise at 30,000 feet (9,100 m). Capabilities include good hover maneuverability at high altitude.[23][24]

The engine will require alternative, advanced engine/power system configurations that enable enhanced mission capability, such as improved time on station, increased mission radius, and quieter operation. Due to the different configurations of the airframe, power outputs from 40 shp (30 kW) to 10,000 shp (7,500 kW) are being studied. One to four companies can be awarded a contract with work completed in 18 months.[25]

Lockheed Martin is developing a single "common missions system" that could be integrated into FVL light, medium, heavy, and ultra-heavy aircraft. The system could save the Army billions of dollars over the course procurement and sustainment, eliminating the need to train maintenance staff, trainers, and personnel in multiple systems. One component is a helmet derived from the one used on the F-35 Lightning II using distributed aperture technology that uses integrated sensors to enable pilots to view "through" the aircraft.[26]

JMR competitors

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Bell

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Bell Helicopter proposed a third-generation tiltrotor design for the FVL program, which was ultimately selected for the FLRAA contract award.[27] Bell sought partners for financial and technological support, although the company did not require assistance.[28] In April 2013, Bell revealed its tiltrotor design, named the Bell V-280 Valor. It is designed to have a cruise speed of 280 knots (320 mph; 520 km/h), range of 2,100 nautical miles (2,400 mi; 3,900 km), and a combat range of 500 to 800 nmi (580–920 mi; 930–1,480 km).[29][30][31][32]

It features a V-tail, a large cell carbon core wing with a composite fuselage, triple redundant fly-by-wire flight control system, retractable landing gear, and two six-foot-wide (1.8 m) side doors for ease of access. The V-280 is unusual in that only the rotor system tilts, but not the engines. The planned demonstrator is medium-size and carries four crew members and 14 troops. It is to be built at 92 percent scale or larger.[29][33][34][35] Bell says they are investing four times the government's amount.[36]

Bell has suggested that their design could be ready for other services' helicopter replacement programs before the Army is ready to award a bid.[37] On December 5, 2022, the Army selected Bell Textron for the FLRAA contract award,[38][39] with GAO overriding a program dispute from the Sikorsky-Boeing team.[40]

Sikorsky/Boeing

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The SB-1 Defiant

The SB-1 Defiant (or "SB>1") is the Sikorsky Aircraft and Boeing entry for the program. It is a compound helicopter with rigid coaxial rotors and two Honeywell T55 engines. Its first flight took place in March 2019.

Defiant X variant

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In January 2021, Sikorsky-Boeing announced the Defiant X variant, specifically designed for the Future Long-Range Assault Aircraft program.[41] In February 2022, Sikorsky-Boeing picked Honeywell's new HTS7500 turboshaft engine, which will replace the Honeywell T55 engine that powered the SB-1 Defiant technology demonstrator platform informing the Defiant X offering.[42] The HTS7500 is rated at 7,500 horsepower and is 42% more powerful with an 18% reduction in specific fuel consumption and weighs less than the T55 engine.[43]

Former competitors

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AVX

AVX Aircraft proposed an aircraft with their coaxial rotor and twin ducted fan design that provides better steering and some additional forward power.[44] Their JMR-TD is to be built at 75% scale.[29] It is capable of flying at 230 kn (260 mph; 430 km/h), with 40% lift from the small forward wings and 60% from the 56-foot (17 m) rotors. Half the drag of the design comes from the fuselage and half from the rotor system, so wind tunnel tests are aiming to reduce drag by a third. The rotor system has two composite-flexbeam hubs with drag-reducing aerodynamic fairings on the blade cuffs and the mast between the hubs.[45] The medium-sized version is proposed to weigh 27,000 lb (12,000 kg), carry four crew and 12 troops, and have a 13,000-pound (5,900 kg) external lifting capacity.[6]

It has a six-by-six-foot (1.8 m × 1.8 m) cabin, which is twice the interior size of the UH-60 Black Hawk, and has an 8,000-pound (3,600 kg) internal lifting capacity. The aircraft can carry 12 NATO litters, have an auxiliary fuel system for self-deployment over distances, and is planned to be capable of being optionally manned. The utility and attack versions will have 90% commonality and fly at the same speed. Test aircraft will be equipped with current GE T706 engines, but AVX is looking to equip their design with the Advanced Affordable Turbine Engine with its higher 4,800 hp (3,600 kW) output. AVX has teamed with Rockwell Collins, General Electric, and BAE Systems.[7] It features entry doors on both sides of the fuselage with a large rear ramp for easy cargo handling. Both versions have retractable landing gear, and the attack variant carries all armaments stored inside until needed to provide a clean aerodynamic design.[11]

The company refers to the unnamed concept as an "innovative compound coaxial helicopter" capable of achieving 80 percent of the speed of the V-22 Osprey at half the cost. It will be able to hover at 6,000 feet (1,800 m) in temperatures of 95 °F (35 °C) and fly unrefueled from Travis Air Force Base in California to Hawaii, a distance of 2,100 nmi (2,400 mi; 3,900 km). AVX considers its position as a smaller company (with 25 employees, some of which worked on the V-22)[36] to its advantage without a legacy or burden of overhead attributes like larger defense corporations; if selected to supply an aircraft, AVX will likely have a teaming arrangement with another company that can handle assembly, integration, and production support.[46] Like Sikorsky, AVX considers coaxials as unsuitable for heavy-lift, and suggests their tiltrotor instead for Capability Set 4 (Chinook replacement).[47]

Karem

Karem Aircraft proposed to design an optimum-speed tiltrotor (OSTR), designated the TR36TD demonstrator. It would have had twin 36-foot-diameter (11 m) variable-speed rotors powered by existing turboshaft engines. The production version of the TR36D would have had a level flight speed of 360 kn (410 mph; 670 km/h). Karem says its variable-speed OSTR configuration offers advantages in weight, drive train, and aerodynamic and propulsive efficiency. It has high speed, "robust" hover performance at altitude, higher climb rate and sustained maneuverability, and longer range than other vertical-takeoff-and-landing configurations. They also say it offers reduced complexity, inherent safety advantages, simplified maintenance, and low total ownership cost.[48] As of 2016, Karem continues to work on versions of the TR36, intending to start testing rotors around 2018.[49]

Other entries

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EADS was planning to submit a proposal for the JMR Phase I demonstration, expected to have been based on the Eurocopter X³,[44][50] but withdrew in late May 2013 because Eurocopter might have to transfer X³ intellectual property to the US,[51] and to focus on its bids for the Armed Aerial Scout program (later cancelled).[52][53] The company also said the cost of developing a high-speed rotorcraft was far greater than the $75 million funding that would have been awarded. The EADS proposal was not totally based on the X3 design, but did leverage aspects of its technology. EADS may re-submit its proposal for FVL when the Army creates specific requirements.[54]

Piasecki Aircraft was bidding its PA61-4 Advanced Winged Compound (AWC). The full-compound version was planned to fly at 233 kn (268 mph; 432 km/h) and used their vectored-thrust ducted propeller (VTDP), flown previously on the Piasecki X-49. It propelled the aircraft and had a long-span wing for lift and anti-torque. The wing pivoted in pitch for addition flight control and to reduce rotor download in the hover. Removing the wing but retaining the VTDP produced the 180 kn (210 mph; 330 km/h) thrust compound version, which could be used for shipboard operations. Replacing the VTDP with a conventional tail rotor produced the 160 kn (180 mph; 300 km/h) version, which was slower but was lighter, cheaper, and could better handle external-lift or vertical-replenishment missions.[45] The Piasecki entry was not selected for the Joint Multi-Role phase of the program.[55] As of 2016, Piasecki has other funding to update the X-49, and intends to offer a winged compound helicopter design for FVL.[56]

Development

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Joint Multi-Role

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On 5 June 2013, Bell announced that its V-280 Valor design had been selected by the Army for the Joint Multi-Role (JMR) Technology Demonstrator (TD) phase. The Army classified the offering as a Category I proposal, meaning it is a well-conceived, scientifically or technically sound proposal pertinent to program goals and objectives with applicability to Army mission needs, offered by a responsible contractor with the competent scientific and technical staff supporting resources required to achieve results.[57][58]

The Boeing-Sikorsky team, pitching the high-speed compound helicopter design based on the X2 prototype, also reported they were invited to negotiate a technology investment agreement for the JMR-TD Phase I program. JMR-TD contracts were expected to be awarded in September 2013, with flights scheduled for 2017.[59][58]

AVX Aircraft also confirmed that it had been selected for the JMR Phase I as a Category I participant. Their entry is a coaxial-rotor compound helicopter with ducted fans for propulsion and small wings to offload the rotors at high speed. The company plans to build a 70% scale demonstrator using existing General Electric T700 engines.[60]

EADS withdrew from the program before designs had been selected, and Piasecki Aircraft was not chosen to continue in the effort.[55]

On 31 July 2013, Boeing and Sikorsky pledged they will invest more than double the amount money the government is spending on JMR if the team is chosen to build and demonstrate a rotorcraft for the program.[61]

On 6 August 2013, Lockheed Martin said it will offer a new mission equipment package to meet the requirements for the JMR/FVL program. Lockheed Martin will incorporate future airborne capability environment software standards into the aircraft's cockpit and mission systems to use their avionics, weapons, and sensors like the F-35 helmet.[62] Boeing and other companies are expected to offer rival sets of avionics.[63] On 9 September 2013, Bell announced Lockheed would be teaming with them on the V-280.[64]

On 2 October 2013, the U.S. Army awarded technology investment agreements (IIA) to AVX Aircraft, Bell Helicopters, Karem Aircraft and Sikorsky Aircraft under the Joint Multi-Role Technology Demonstrator Phase I program. There are two general types of proposals: tiltrotors with rotors that serve as both rotors and conventional propellers, and compound helicopters that use vertical rotors and separate rear-mounted propellers. AVX and Sikorsky are offering compound designs with two counter-rotating rotors to provide vertical lift. For forward movement, AVX uses two ducted fans and Sikorsky uses a single propeller on the back. Bell is offering the V-280 Valor tiltrotor. Karem Aircraft is offering a tiltrotor with optimum-speed rotors, allowing the aircraft to speed or slow the propellers depending on speed or efficiency demands. Similar technology was used on the A160 Hummingbird. JMR-TD is to develop and demonstrate an operationally representative mix of capabilities, technologies, and interfaces to investigate realistic design trades and enabling technologies.[11][48]

The TIAs give the four teams nine months to complete preliminary design of their rotorcraft, which the Army will then review and authorize the construction of two competing demonstrators to fly in 2017. While there was a potential for an early downselect, the four teams are focused on the 2017 flight demonstrations. Emerging results from JMR TD Phase 1 will be used to inform the FVL effort regarding vehicle configurations, the maturity of enabling technologies, attainable performance and capabilities, and will highlight affordable technical solutions required to achieve those capabilities.[65][66] Each of the four teams received $6.5 million from the Army for this phase of the program.[67] On 21 October 2013, defense executives bidding for the program stated that the Army plans to downselect to two companies in 2014, who will then develop prototypes for flight tests in 2017. JMR-TD phase I is focused on creating a medium utility rotorcraft airframe, while phase II will develop mission systems and software[68] although integration with airframes is not planned and thus will not be flying.[69]

Submissions for JMR evaluations were to be entered by the four competitors by June 2014, with the Army selecting two to build demonstrators to fly between 2017 and 2019, but the Army may choose a non-JMR vehicle for FVL, and may pursue different types for different FVL classes. Commonality of systems across vehicles and across military units is desired.[70][71] Specifications are for a design capable of performing both medium utility and attack missions, with a 230 kn (260 mph; 430 km/h) cruising speed, and of hovering at 6,000 ft (1,800 m) in 95 °F (35 °C) temperatures.

After the flight tests and technology development, JMR will end and a Request for Proposals (RFP) will be issued open to all companies to begin the projected $100 billion FVL effort. Demonstrators developed under JMR will be "X-planes" to demonstrate some key technologies, but they won't have production-representative engines or real mission systems architecture; JMR will show off technologies to enable Army rotary-wing aviation to make the next leap in speed, lift, protection, and interoperability under FVL for the 2030s.

The program is intentionally slow-paced partly due to the challenges seen in the Joint Strike Fighter program[70][71] and failures of past programs like Future Combat Systems, which was cancelled after complex requirements could not be met within established budgets and timelines. A contract for a joint common architecture standard was to be awarded in July 2014 for lab-based testing, and the FVL RFP is to be issued in 2019.[72] The Sikorsky-Boeing team submitted the SB-1 Defiant design and risk report to the Army in mid-June for JMR.[73]

The Army is looking at five criteria to downselect JMR-TD entries: how much the design advances the services' science and technology goals; whether the design meets performance specifications; how well the demonstrator validates specifications; whether the competitor has kept to their schedule; and whether the company has the skills and competency to carry out a flight demonstration. Even with the prospect of sequestration returning in FY 2016, the JMR program will likely be spared from cuts or cancellation due to the Army's support of research and development programs.[74] The demonstrator aircraft will have a lifespan of 200 flight hours, and the Army's budget is $240 million.[69] In July 2014 the Army decided which two competitors would proceed to Phase One, but will hold program discussions with all four parties to determine a reasonable path forward before announcing the winners,[75] which is expected to occur in late August or early September 2014. Earlier in July, the Army selected the Boeing-Sikorsky team to develop the Joint Common Architecture (JCA) standard "digital backbone" through which mission systems will be integrated into the FVL system's design.[76]

Down selection

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On 11 August 2014, the Army informed the Sikorsky-Boeing and Bell-Lockheed teams that they had chosen the SB-1 Defiant and V-280 Valor to continue with the JMR demonstration program. The aircraft designs show the Army is pursuing both coaxial and tilt-rotor designs, and preferring larger and established contractors over the smaller entries. AVX Aircraft says it is still in negotiations with the Army and believes they can still continue with some level of work on the program. Official word of the downselect was to be announced in late August once negotiations had been finalized.[77] The Army formally announced the selection of the Sikorsky-Boeing SB-1 and Bell-Lockheed V-280 on 3 October 2014. Both teams will now build technology demonstration aircraft with flight tests starting in 2017. Though AVX and Karem Aircraft were not selected, the Army is still interested in technologies they have offered.[78]

In early September 2014, a panel of aviation experts advised personnel from the FVL initiative how to avoid mistakes made by previous acquisition efforts, namely the F-35 Joint Strike Fighter. The panel had three suggestions: split the program into different manageable pieces; use the expertise of the commercial helicopter industry; and secure early support from the U.S. Congress. FVL is seeking to develop four separate lift classes, which may even become five if the program includes medium lift aircraft for the Navy and U.S. Marine Corps, so the sheer diversity of requirements casts doubt that a single program can successfully produce different versions of a given design.[79]

One main problem the F-35 program encountered was having a single program to try to meet different needs with variants of one design. It is possible for FVL to avoid this and still meet it primary goals of using common drive trains, engines, and communications across different helicopters in different services; although the Army's Apache and Black Hawk designs are entirely different, the Marines' UH-1Y Venom utility and AH-1Z Viper attack helicopters have 85 percent parts commonality despite using different airframes. Money and time could be saved by using available technologies from commercial helicopter manufacturers, which was impossible to do with the high-performance F-35.[80]

Even though the JSF has secured international partners and FVL has none, partners would be welcomed once the program officially starts, and pre-acquisition industry-to-industry cooperation was advised before government-to-government agreements occur. Congressional support was also advised to be secured early on, as keeping lawmakers in the dark caused lack of trust and imposition of reporting requirements for funding with the F-35.[81] As Army Aviation purchase budgets has decreased 40% in 3 years, FVL funding could be conflicting with modernization of the current rotorcraft fleet.[82][83]

In January 2015, the Army confirmed that the FVL-medium category would be split into two different versions, one for attack/reconnaissance and one for utility and troop carrying. Though the program seeks component commonality across the fleet, service leaders identified that different sized aircraft are needed for attack and troop-carrying, so the same airframe may not be used for both missions; other services may also tailor their own FVL-medium variants for specific needs. The versions may even use different forms of propulsion (one tiltrotor and one pusher propeller with coaxial blades), but nothing would be certain until the results of the 2018 TD test flights.[84]

Text split from the Futures command article

Future Vertical Lift had planned to use the DoD modular open systems approach (MOSA), an integrated business and technical strategy in FARA, and in FLRAA[85][86][87][88][89][90][91][92][93][94] FLRAA is anticipated to enter service by Fiscal Year 2030.[95] By abstracting its requirements, the Army was able to request prototypes which used new technologies.

Joint Multi-Role Technology Demonstrator (JMR-TD) prototypes are to be built by two teams to replace Sikorsky UH-60 Blackhawks with Future Long-Range Assault Aircraft (FLRAA).[96] The tilt-rotor FLRAA demonstrator by Bell is flying unmanned (October 2019); it logged 100 hours of flight testing by April 2019.[97] Both Bell and Sikorsky-Boeing received contract awards to compete in a risk reduction effort (CDRRE) for FLRAA in March 2020.[98][97][99] The risk reduction effort will be a 2-phase, 2-year competition. The competition will transition technologies (powertrain, drivetrain and control laws) from the previous demonstrators (JMR-TDs) of 2018–2019 to requirements, conceptual designs, and acquisition approach for the weapon system.[98][100] The Army wants flight testing of FLRAA prototypes[101] beginning in 2025, with fielding to the first units in 2030.[102]

The Future Attack Reconnaissance Aircraft (FARA) was to be smaller than FLRAA. The Army's requests for proposals (RFPs) for FARA were due in December 2018;[103][104]

A long range precision munition for the Army's aircraft will begin its program of design and development. In the interim, the Army is evaluating the Spike 18–mile range non-line of sight missile on its Boeing AH-64E Apache attack helicopters.[105]

On 5 December 2022, the Army announced that the V-280 Valor was selected by the program.[106] The Sikorsky-Boeing team formally disputed the contract award later that month.[39] On 6 April 2023, Government Accountability Office denied the protest.[107]

In February 2024 the FARA program was cancelled; after expending $2 billion on its development, the 41st Chief of Staff of the Army announced that the $5 billion that had been allocated for FARA's future development for the next five years would be spent on Black Hawks, on the CH-47F Block II Chinook cargo helicopter, on the Future Long-Range Assault Aircraft (FLRAA), and on research and development for unmanned aerial reconnaissance capability.[108][109][100] The effective use of drones in Ukraine was a factor in the decision.[108][110]

Unmanned UH-60

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An unmanned UH-60 Black Hawk flew pilotless in July 2022.[111] An FVL FLRAA (JMR-TD) flew unmanned in 2019.[97]

See also

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References

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  1. ^ Graham Warwick. "Industry: FVL Needs To Move Faster To Survive". Aviation Week & Space Technology. Archived from the original on 28 May 2016. Retrieved 29 May 2016. FVL is complicated. It is not a program but a plan to replace all of the U.S. military's rotorcraft
  2. ^ Reed, John (5 October 2010). "Pentagon plans 4 new helos". Army Times. Retrieved 25 October 2010.
  3. ^ Brannen, Kate. "U.S. Army Eyes Joint Multirole Helo". Defense News, 19 July 2010.
  4. ^ Hoffman, Michael (2 October 2011). "At 50, the Chinook remains the Army's workhorse". Gannett Government Media. Archived from the original on 17 September 2021. Retrieved 2 October 2011.
  5. ^ "Superfast Helicopters". Defense media network. 25 October 2011. Archived from the original on 31 March 2013. Retrieved 22 May 2013.
  6. ^ a b "AVX Presses Case For Coaxial-Rotor JMR Demonstrator". Aviation week. 6 May 2013. Archived from the original on 12 October 2013. Retrieved 17 September 2021.
  7. ^ a b "Future Vertical Lift: An Overview", Aviation today, 1 May 2013, archived from the original on 13 September 2016, retrieved 17 September 2021.
  8. ^ "Adaptive Vertical Lift Engine Conceptual Design and Analysis Program – Federal Business Opportunities: Opportunities". fbo.gov. Archived from the original on 17 February 2017. Retrieved 27 May 2017.
  9. ^ Drwiega, Andrew. "Proceed with Caution: JMR Tech Demo Phase 1 Archived 6 October 2014 at the Wayback Machine" Aviation Today, 1 November 2013. Accessed: 18 October 2014.
  10. ^ Majumdar, Dave. "Mixed reaction over US plans for new prototype attack helicopter" Flightglobal, 21 January 2013. Accessed: 21 June 2014. Archived on 21 June 2014.
  11. ^ a b c "Joint Multi-Role (JMR): The Technology Demonstrator Phase Contenders", Defense media network, 8 October 2013, archived from the original on 12 October 2013, retrieved 13 October 2013.
  12. ^ "Sikorsky and Boeing Team Submit New Army Helicopter Design". USNI. 17 June 2014. Archived from the original on 19 June 2014. Retrieved 18 June 2014.
  13. ^ a b US Army reveals details of Joint Multi-Role fleet vision, Flight global, 16 August 2011, archived from the original on 29 December 2018, retrieved 2 June 2013
  14. ^ Turnbull, Grant. "FVL milestone on horizon" Archived 28 September 2015 at the Wayback Machine 15 September 2015
  15. ^ "U.S. Army Cancels FARA In Overhaul Of Aviation Plans". Aviation Week Network (aviationweek.com). Retrieved 16 February 2024.
  16. ^ Judson, Jen (12 February 2024). "Army was right to kill multibillion-dollar helo program, analysts say". Defense News. Retrieved 16 February 2024.
  17. ^ "Army Chooses Bell Textron's V-280 Valor Tiltrotor to Replace Black Hawk". National Defense Magazine. Retrieved 27 January 2023.
  18. ^ Drwiega, Andrew. "Boeing Plans for Additional Apache and Chinook Versions Before Future Vertical Lift Arrives" Aviation Today, 1 July 2014. Accessed: 4 July 2014. Archived on 3 July 2014.
  19. ^ Trimble, Stephen (16 August 2011). "US Army reveals details of Joint Multi-Role fleet vision". Flight Global. Archived from the original on 9 July 2021. Retrieved 7 July 2021.
  20. ^ Miller, Mary J. (16 April 2013). "US Army's Science and Technology (S&T) Program for Fiscal Year 2014" (PDF). p. 13. Archived (PDF) from the original on 19 September 2014. Retrieved 22 April 2013.
  21. ^ Army Propels Next Generation Helicopter Program Forward Archived 11 October 2014 at the Wayback Machine – Defensetech.org, 8 October 2014
  22. ^ Army matures autonomous flight technologies Archived 19 November 2014 at the Wayback Machine – Armytechnology.Armylive.DoDlive.mil, 31 October 2014
  23. ^ "Archived copy". Archived from the original on 17 February 2017. Retrieved 6 March 2016.{{cite web}}: CS1 maint: archived copy as title (link)
  24. ^ "Archived copy". Archived from the original on 17 February 2017. Retrieved 6 March 2016.{{cite web}}: CS1 maint: archived copy as title (link)
  25. ^ US Army seeks advanced engine for future rotorcraft Archived 29 July 2013 at the Wayback Machine – Flightglobal.com, 20 March 2013
  26. ^ Lockheed pitches F-35 technology for US Army’s future vertical lifter Archived 8 May 2014 at the Wayback Machine – Flightglobal.com, 7 May 2014
  27. ^ "Army announces Future Long Range Assault Aircraft contract award". United States Army. 5 December 2022. Retrieved 5 December 2022.
  28. ^ "Bell will pitch third-gen tilt-rotor for JMR/FVL" Archived 19 April 2013 at the Wayback Machine. Flightglobal.com, 4 March 2013
  29. ^ a b c "Sikorsky Moves X2 Technology Up A Size For JMR" Aviation Week & Space Technology, 4 November 2013. Accessed: 22 June 2014. Archived on 22 June 2014.
  30. ^ "PICTURES: Bell unveils V-280 Valor" Archived 14 April 2013 at the Wayback Machine. Flight International, 10 April 2013.
  31. ^ Bell Helicopter Introduces the Bell V-280 Valor Tiltrotor at AAAA Archived 30 May 2013 at the Wayback Machine – Bell press release, 10 April 2013
  32. ^ V-280 fact sheet Archived 10 August 2015 at the Wayback Machine. Bell
  33. ^ "PICTURES: Bell unveils V-280 Valor" Archived 14 April 2013 at the Wayback Machine. Flight International, 10 April 2013.
  34. ^ Bell Helicopter Introduces the Bell V-280 Valor Tiltrotor at AAAA Archived 30 May 2013 at the Wayback Machine – Bell press release, 10 April 2013
  35. ^ V-280 fact sheet Archived 10 August 2015 at the Wayback Machine. Bell
  36. ^ a b Drwiega, Andrew. "Gorillas Versus The Underdog" Aviation Today, 1 July 2014. Accessed: 4 July 2014.Archived on 3 July 2014.
  37. ^ Seligman, Lara (11 November 2015). "Bell Could Have FVL Ready For US Navy, Air Force By 2025". defensenews.com. TEGNA. Archived from the original on 17 September 2021. Retrieved 11 November 2015.
  38. ^ "Army announces Future Long Range Assault Aircraft contract award". United States Army. 5 December 2022. Retrieved 5 December 2022.
  39. ^ a b Sharma, Soumya (29 December 2022). "Sikorsky files protest against US Army's FLRAA contract decision". Army Technology. Retrieved 2 April 2023.
  40. ^ Ashley Rocque "GAO denies Sikorsky-Boeing FLRAA protest; Bell, Army clear to proceed". breakingdefense.com, 6 Apr 2023.
  41. ^ O'Connor, Kate (26 January 2021). "Sikorsky-Boeing Team Unveils Defiant X". AVweb. Retrieved 15 April 2022.
  42. ^ Beinart, Matthew (10 February 2022). "Sikorsky-Boeing Select New Honeywell Engine To Power FLRAA Offering". Defense Daily. Retrieved 15 April 2022.
  43. ^ Neumann, Norbert (21 February 2022). "Honeywell to power DEFIANT X". Airforce Technology. Retrieved 15 April 2022.[permanent dead link]
  44. ^ a b "Future Vertical Lift Takes Step Forward" Archived 3 July 2020 at the Wayback Machine. Nationaldefensemagazine.com, April 2013
  45. ^ a b The Other JMR/FVL Contenders Archived 2 May 2013 at the Wayback Machine – Aviationweek.com, 12 April 2013
  46. ^ AVX expects work to continue on its future vertical lift design Archived 6 May 2014 at the Wayback Machine – Flightglobal.com, 6 May 2014
  47. ^ "AVX would replace heavy-lift Chinook with tiltrotor". Flightglobal. Archived from the original on 1 May 2016. Retrieved 1 May 2016.
  48. ^ a b Karem Unveils Variable-Speed Tiltrotor For U.S. Army JMR Demo Archived 5 October 2013 at the Wayback Machine – Aviationweek.com, 2 October 2013
  49. ^ "Karem readies optimum-speed tiltrotor for FVL". Flightglobal. Archived from the original on 2 May 2016. Retrieved 1 May 2016.
  50. ^ Warwick, Graham. "Eurocopter's X3 – Would You Go to War in One?" Aviation Week & Space Technology, 27 July 2012. Accessed: 10 May 2014. Archive
  51. ^ "Intellectual Property Concerns Swayed EADS JMR Pullout Archived 1 February 2016 at the Wayback Machine" Aviation Week & Space Technology, 24 June 2013. Accessed: 17 June 2014. Quote: "Guillaume Faury said the company made the "strategic decision" because it was concerned that it would have to transfer the intellectual property rights of the company’s self-developed X3 technology to the U.S."
  52. ^ Warwick, Graham. "EADS Withdraws JMR Bid To Focus On AAS" Aviation Week & Space Technology, 4 June 2013. Accessed: 17 June 2014. Archive
  53. ^ "EADS Quits Helo Competition To Pursue Uncertain AAS" Aviation Week & Space Technology, 10 June 2013. Accessed: 17 June 2014. Archive
  54. ^ Majumdar, Dave. "Cost drove EADS from US Army rotorcraft demonstration" 13 June 2013. Accessed: 17 June 2014. Archived on 12 May 2014
  55. ^ a b AVX joins Bell, Sikorsky/Boeing for Army's JMR-TD development Archived 11 June 2013 at the Wayback Machine – Flightglobal.com, 6 June 2013
  56. ^ "Piasecki touts winged compound helicopters for Future Vertical Lift". Flightglobal. Archived from the original on 2 May 2016. Retrieved 1 May 2016.
  57. ^ Bell V-280 Valor Selected for Army’s JMR-TD Program Archived 18 July 2013 at the Wayback Machine – Bell press release, 5 June 2013.
  58. ^ a b US Army selects Bell, Sikorsky/Boeing team for JMR demonstration Archived 14 June 2013 at the Wayback Machine – Flightglobal.com, 5 June 2013.
  59. ^ Carey, Bill (25 January 2013). "Boeing, Sikorsky Team for Army's Joint Multi-Role Demonstration". AIN Online. Archived from the original on 23 July 2013. Retrieved 11 June 2013.
  60. ^ AVX Aircraft Wins Place On U.S. Army’s JMR Demo Archived 4 October 2013 at the Wayback Machine – Aviationweek.com, 7 June 2013
  61. ^ Boeing-Sikorsky pledge to more than double US Army's initial JMR investment Archived 5 August 2013 at the Wayback Machine – Janes.com, 31 July 2013
  62. ^ McGarry, Brendan. "Lockheed Pitches F-35 Helmet for Future Helos" DefenseTech, 7 May 2014. Accessed: 22 June 2014. Archived on 8 May 2014.
  63. ^ Lockheed to offer JMR/FVL avionics package Archived 24 August 2013 at the Wayback Machine – Flightglobal.com, 6 August 2013
  64. ^ "Bell Helicopter and Lockheed Martin team on V-280 Valor Archived 16 November 2020 at the Wayback Machine". AirFramer, 9 September 2013. Accessed: 9 September 2013.
  65. ^ Army selects four companies for advanced rotorcraft concepts Archived 5 October 2013 at the Wayback Machine – Flightglobal.com, 3 October 2013
  66. ^ McLeary, Paul (2 October 2013). "Four Companies Get US Army's Nod to Begin Critical Helicopter Designs". DefenseNews. Archived from the original on 4 October 2013. Retrieved 4 October 2013.
  67. ^ Doubts Swirl around Army’s Next Generation Helicopter Fleet Archived 27 October 2013 at the Wayback Machine – Defensetech.org, 25 October 2013
  68. ^ "Army to downselect to two JMR-TD bidders in 2014" Archived 23 October 2013 at the Wayback Machine – Janes.com, 21 October 2013.
  69. ^ a b Trimble, Stephen (22 July 2014). "Looming FVL demonstrator awards plot uncertain path for US rotorcraft industry". FlightGlobal. Archived from the original on 24 July 2014. Retrieved 24 July 2014.
  70. ^ a b Sydney J. Freedberg Jr. "Future Vertical Lift: One Program Or Many?" Breaking Defense, 5 June 2014. Accessed: 22 June 2014. Archived on 6 June 2014.
  71. ^ a b Erwin, Sandra I. "Bumpy Ride Ahead for Military's Future Helicopter Program" National Defense Magazine, 4 June 2014. Accessed: 22 June 2014. Archived on 22 June 2014.
  72. ^ Step by Step: US Army Slowly Nears Apache, Black Hawk Replacements – Defensenews.com, 5 May 2014
  73. ^ "Sikorsky and Boeing Team Submit New Army Helicopter Design Archived 19 June 2014 at the Wayback Machine" – News.USNI.org, 17 June 2014.
  74. ^ Companies Await Decision on Joint Multi-Role Helicopter Program[permanent dead link] – Nationaldefensemagazine.org, 1 July 2014
  75. ^ Insinna, Valerie. "Army narrows playing field for Joint-Multi Role Helicopter, but few public details announced" National Defense Magazine, 1 August 2014. Accessed: 1 August 2014.
  76. ^ US Army's JMR Helo Selection Slips – Defensenews.com, 1 August 2014
  77. ^ "Army Picks Firms to Build Future Helicopter", DoD Buzz, 12 August 2014, archived from the original on 22 October 2017, retrieved 13 August 2014.
  78. ^ U.S. Army Selects Bell and Sikorsky/Boeing to Build Prototypes for Next Generation Helicopter Program, USNI, 3 October 2014, archived from the original on 5 October 2014, retrieved 4 October 2014.
  79. ^ "FVL Helicopters: How To Avoid F-35 Snafu", Breaking defense, 8 September 2014, archived from the original on 14 September 2014, retrieved 14 September 2014.
  80. ^ "FVL Helicopters: How To Avoid F-35 Snafu", Breaking defense, 8 September 2014, archived from the original on 14 September 2014, retrieved 14 September 2014.
  81. ^ "FVL Helicopters: How To Avoid F-35 Snafu", Breaking defense, 8 September 2014, archived from the original on 14 September 2014, retrieved 14 September 2014.
  82. ^ "Why US Army aviation plans are in a spin", Flightglobal, Reed Business Information, 8 April 2015, archived from the original on 9 April 2015, retrieved 9 April 2015
  83. ^ Trimble, Stephen (31 March 2015), "Cash-strapped US Army aviation focuses on immediate needs", Flightglobal, Reed Business Information, archived from the original on 9 April 2015, retrieved 9 April 2015
  84. ^ "Army Looks To Build Two Forms of Medium Future Vertical Lift", Breaking defense, 29 January 2015, archived from the original on 3 February 2015, retrieved 1 February 2015
  85. ^ New Army aircraft will be durable, lethal, unmanned for modern conflicts
  86. ^ Sydney J. Freedberg, Jr. (3 October 2018) Army Wants Revolutionary Scout Aircraft For $30 Million, Same As Apache E FARA Solicitation
  87. ^ Eric Adams (5 July 2019) The Pirouetting S-97 Raider Makes Your Helicopter Look Lazy
  88. ^ Sydney J. Freedberg Jr. and Richard Whittle (23 October 2019) Tilting Wings, Tilting Tailprop, But Not A Tiltrotor: Karem's FARA Design
  89. ^ Sydney J. Freedberg Jr. and Richard Whittle (23 October 2019) Bell 360: Will Slower & Steadier Win The Race For FARA?
  90. ^ Freedberg Jr., Sydney J. "MOSA: The Invisible, Digital Backbone Of FVL". Modular Open System Architecture, 13 March 2020.
  91. ^ "DoD Modular Open Systems Architecture (MOSA)". Archived from the original on 28 March 2019. Retrieved 31 August 2018.
  92. ^ Sydney J. Freedberg Jr. (28 March 2019) FVL: Next Steps For UH-60 & Shadow Replacements In ‘Weeks’. breakingdefense.com
  93. ^ Sean Kimmons (24 October 2018) Future Vertical Lift projects to build on recent progress FVL Deliverables—1: Joint Multi-Role Technology Demonstration (JMR). 2: Analysis of alternatives (AoA). Phase II award—2020–2023
  94. ^ Judson, Jen.(4 April 2019) US Army plans to field a future long-range assault helicopter by 2030 FLRAA
    • RFI posted on the Federal Business Opportunities, 4 April
    • Contract award: fourth quarter of FY21
    • preliminary design review (PDR) second quarter of FY23
    • first flight in the third quarter of FY24
    • critical design review (CDR) in the fourth quarter of FY24
    • fielding to first unit in second quarter of FY30
  95. ^ Trimble, Steve. (24 July 2020) "U.S. Army Upgrades Vision For Future Vertical Lift Programs". aviationweek.com
  96. ^ FLRAA, JMR-TD: Flight test
  97. ^ a b c Sydney J. Freedberg Jr. (15 October 2019) 4 Flights, 3 Hours, 20 Knots: Defiant Inches Ahead
  98. ^ a b Jen Judson (16 Mar 2020) Army selects companies to continue in long-range assault aircraft competition
  99. ^ Sydney J. Freedberg Jr. (20 February 2020) We’ve Got Enough Data On Defiant: Sikorsky & Boeing
  100. ^ a b Sydney J. Freedberg Jr. (26 February 2020) FVL: Can Army Break The Comanche Curse?
  101. ^ Jen Judson (13 Oct 2022) US Army nearly ready to make future long-range assault aircraft award
  102. ^ Jen Judson (12 Jul 2021) US Army triggers competition for future long-range assault aircraft
  103. ^ "Army Pushing Forward with Major Future Helicopter Projects". nationaldefensemagazine.org. Retrieved 22 December 2021.
  104. ^ Andrew Eversden (8 Jul 2022) Army’s FARA-destined future helicopter engine passes first test ITEP engine
  105. ^ Judson, Jen. (14 Jun 2021) "US Army sets timeline to design new long-range weapon". Defensenews.com
  106. ^ Judson, Jen. "US Army makes largest helicopter award in 40 years". Defense News, 5 December 2022.
  107. ^ "GAO Statement on Protest of Sikorsky Aircraft Corporation, B-421359, B-421359.2". gao.gov. Retrieved 16 April 2023.
  108. ^ a b Jen Judson (8 Feb 2024) US Army spent billions on a new helicopter that now will never fly
  109. ^ Valerie Insinna (6 Mar 2024) Lawmakers press Army aviation leadership on FARA cancelation
  110. ^ Jen Judson (26 Apr 2024) Army officials question plan for future attack reconnaissance
  111. ^ Osborn, Kris. (28 Jul 2022) "UH-60 Black Hawk Helicopter Achieves Pilotless Flight" Sikorsky, DARPA's ALIAS program "... includes the ability to operate aircraft at all times of the day or night, with and without pilots, and in a variety of difficult conditions, such as contested, congested, and degraded visual environments".— Stuart Young, DARPA
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