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Grumman X-29

The Grumman X-29 was an American experimental aircraft developed in the 1980s to demonstrate advanced aerodynamic technologies, including forward-swept wings, canard control surfaces, and digital fly-by-wire flight controls, aimed at improving fighter aircraft maneuverability and efficiency.^[1]^[2] The program, a joint effort by NASA, the U.S. Air Force, the Defense Advanced Research Projects Agency (DARPA), and Grumman Aerospace Corporation, began with a $87 million contract awarded to Grumman in December 1981 and resulted in the construction of two prototypes based on modified Northrop F-5A fuselages.^[1]^[3] The first X-29A made its maiden flight on December 14, 1984, from Edwards Air Force Base, California, with subsequent testing conducted at NASA's Dryden (now Armstrong) Flight Research Center in California.^[2]^[1]^[4] Over the course of the program, which ran until 1992, the two aircraft completed 422 research flights, achieving a maximum speed of Mach 1.6, an altitude of 50,000 feet, and controlled flight at angles of attack up to 67 degrees, validating concepts like aeroelastic tailoring and vortex flow control for enhanced high-alpha performance.^[1]^[3] The X-29's highly unstable design, which required constant corrections from its triple-redundant digital flight control system operating 40 times per second, represented a significant advancement in unstable aircraft control, though the technology influenced later designs indirectly as stealth and thrust-vectoring priorities shifted in subsequent fighter development.^[2]^[3]

Development

Program Origins

The Grumman X-29 program originated in the mid-1970s as part of broader efforts to advance forward-swept wing (FSW) technology, drawing on historical research from World War II German experiments with the Junkers Ju 287 jet bomber and early U.S. glider designs like the Cornelius XFG-1, as well as post-war NASA studies on aeroelasticity and wing divergence. In 1975, Air Force Colonel Norris J. Krone Jr.'s dissertation at the Air Force Institute of Technology highlighted the potential of composite materials to enable rigid FSW structures, overcoming past issues with structural twisting at high speeds. This work, conducted under DARPA auspices, secured initial funding of $300,000 in 1976 to explore FSW feasibility through wind tunnel tests and simulations at NASA Langley Research Center and Grumman Aerospace Corporation. By 1977, DARPA and the U.S. Air Force Flight Dynamics Laboratory issued requests for proposals to industry, aiming to develop a demonstrator aircraft that integrated FSW with emerging technologies.^[4]^[2]^[1] Grumman was selected as the prime contractor in December 1981 following competitive evaluations against proposals from General Dynamics and others, receiving an $87 million cost-plus contract primarily funded by DARPA to design and build two aircraft, with additional support from NASA for technical oversight and the U.S. Air Force for flight testing at Edwards Air Force Base. The program, valued at approximately $100 million initially including options for a second airframe, represented a collaborative effort among DARPA (advanced concepts), NASA (research integration), and the USAF (operational validation), building on prior joint ventures like the HiMAT remotely piloted vehicle. This tri-agency partnership formalized through a 1981 DARPA-NASA memorandum of agreement emphasized risk-sharing to accelerate technology maturation for future fighters.^[1]^[4]^[5] The core objectives focused on validating FSW advantages, such as improved maneuverability through higher lift-to-drag ratios at high angles of attack, reduced transonic drag for enhanced efficiency, and better stall resistance compared to aft-swept wings. The program also aimed to flight-test relaxed static stability—intentionally reducing natural aerodynamic damping—for agile handling, paired with a triple-redundant digital fly-by-wire system to maintain control in this unstable configuration. To ensure cost efficiency and rapid development, the X-29 baseline utilized the forward fuselage and nose landing gear from surplus Northrop F-5A Freedom Fighter airframes (serial numbers 82-0003 and 82-0049), supplemented by off-the-shelf components like F-16 landing gear struts and an F404 engine from the F/A-18, allowing Grumman to concentrate resources on innovative elements like composite wings and canards.^[4]^[1]^[2]

Design Evolution

In December 1981, the Defense Advanced Research Projects Agency (DARPA), with the U.S. Air Force as the contracting agent, awarded Grumman Corporation an $87 million contract to design and build two X-29A prototypes (serial numbers 82-0003 and 82-0049), marking the formal start of hardware development for the forward-swept wing demonstrator program.^[4] Construction began in mid-1982 following funding agreements, incorporating off-the-shelf components to accelerate assembly and control costs, with the first prototype completed by August 1984 ahead of its rollout ceremony on August 27 (sources vary as August 15 or 27). The second prototype followed later, arriving at Edwards Air Force Base in November 1988.^[4] Ship 1 was assigned to NASA's Dryden (now Armstrong) Flight Research Center for initial aerodynamic validation, while Ship 2 was designated for the U.S. Air Force Flight Test Center at Edwards Air Force Base to support advanced maneuvers.^[4] The total program cost was approximately $150 million for major phases, though estimates varied up to $200 million including all contributions through 1992, balancing innovative features with fiscal constraints through subscale testing and component reuse.^[4]^[6] The fuselage drew from the forward section of surplus Northrop F-5A Freedom Fighter airframes, while retaining the F-5A's nose landing gear for compatibility.^[4] Main landing gear came from the F-16 Fighting Falcon, providing robust retraction and servo-actuation suited to the X-29's high-performance envelope, and the aircraft was powered by a single General Electric F404-GE-400 afterburning turbofan engine delivering 16,000 lbf of thrust.^[7] These integrations minimized custom fabrication, allowing focus on novel aerodynamic elements, though early assembly in 1983 required adjustments to fit the F-16 gear to Ship 1's frame.^[4] Wing development centered on a 33-degree forward sweep across a 27-foot-2.5-inch span, using thin supercritical airfoils to enhance transonic performance, complemented by 33-degree swept canard foreplanes for pitch authority.^[7] The vertical stabilizers were canted forward to improve yaw control, with all control surfaces designed for rapid deflection via hydraulic actuators.^[4] Initial validation occurred through 1982 wind tunnel tests at NASA Langley's Transonic Dynamics Tunnel and 30-by-60-foot Full-Scale Tunnel, employing 22-percent and 1/16-scale models to confirm stability, control effectiveness, and divergence boundaries under subsonic and transonic flows.^[4] The two prototypes differed in configuration to support phased testing: Ship 1 emphasized basic aerodynamic and stability evaluation without high-angle-of-attack modifications, completing 242 flights by late 1988.^[4] Ship 2 incorporated nose strakes to enhance vortex flow at elevated angles of attack and a conical ribbon spin recovery parachute mounted above the exhaust, enabling safer exploration of post-stall regimes up to 66 degrees AoA during its 85 flights starting in 1989.^[4] Early challenges included reconciling the aircraft's inherent longitudinal instability—requiring a digital fly-by-wire system for control—with budget limits, addressed via extensive subscale model predictions of handling qualities that aligned closely with later flight data.^[4] Flight control software verification delays pushed the first flight from April to December 1984, but iterative ground simulations ensured safe envelope expansion.^[4]

Design Features

Aerodynamic Configuration

The Grumman X-29 featured a distinctive three-surface aerodynamic configuration, consisting of forward-swept main wings, close-coupled canards, and twin canted vertical tails, which eliminated the need for conventional horizontal stabilizers and allowed for optimized lift distribution across the aircraft.^[1] The main wings had an aspect ratio of 3.9 and an exposed area of 188.84 square feet, enabling efficient aerodynamic loading by shifting more lift outward along the span compared to traditional designs.^[8] The forward-swept wings, with a 33-degree sweep angle, were designed to enhance transonic maneuverability by promoting inward spanwise airflow that delayed tip stall and increased outboard lift generation.^[9] This geometry addressed key limitations of aft-swept wings, potentially achieving up to a 20% improvement in lift-to-drag ratio through reduced induced drag and better stall resistance at high angles of attack.^[8] The close-coupled canards, swept at 33 degrees and spanning 16 feet 6 inches, served primarily for pitch control while generating positive lift to unload the main wing, thereby improving overall trim efficiency.^[1] At high angles of attack, the canards also facilitated vortex management by creating leading-edge vortices that augmented lift and stability without excessive trim drag.^[8] The twin vertical tails, each 6 feet 6 inches high and canted forward at 30 degrees, provided yaw stability and directional control while enhancing roll authority through differential rudder inputs, avoiding the need for dihedral effects on the wings.^[9] This configuration contributed to the aircraft's relaxed static stability, which was a deliberate design choice to maximize performance.^[1] Overall, the X-29's geometry offered potential reductions in radar cross-section due to the aligned surfaces and improved short takeoff and landing characteristics via enhanced high-alpha vortex lift, demonstrating advanced aerodynamic integration for future fighter concepts.^[8]

Flight Control System

The Grumman X-29 featured a highly relaxed longitudinal static stability design, with the center of gravity positioned to achieve up to a 35% negative static margin, rendering the aircraft aerodynamically unstable without active control.^[10] This deliberate instability required continuous computer inputs from the flight control system to maintain controllability, as the aircraft could not be flown manually.^[9] The configuration increased the short-period pitch mode frequency compared to stable designs, enhancing responsiveness but demanding precise augmentation. The core of the X-29's flight control was a triple-redundant digital fly-by-wire (FBW) system, which provided artificial stability through electronic linkages rather than mechanical ones.^[1] The system utilized three identical digital computers processing up to 40 commands per second to adjust control surfaces in real time.^[1] An analog backup mode activated if two digital channels failed, ensuring envelope protection and equivalent reliability to conventional systems.^[1] Pilots interfaced via a side-stick controller and head-up display, with no direct mechanical connections to the surfaces implemented from the program's 1984 start.^[9] Control laws employed gain scheduling tailored to flight regimes, including a high-angle-of-attack mode using angle-of-attack and sideslip feedback to prevent departure.^[11] Feedback loops incorporated pitch rate, normal acceleration, and canard position for longitudinal control, with breakpoints at specific angles of attack to adapt gains dynamically.^[11] The system integrated with engine controls for coordinated response, though full authority digital engine control was not explicitly part of the primary FBW architecture.^[9] Actuation relied on hydraulic servoactuators for the canards, ailerons, rudders, and flaperons, driven solely by electronic signals.^[1] Canards deflected up to +30 degrees leading edge up and -60 degrees leading edge down (equivalent to trailing edge deflections for pitch authority), while flaperons ranged from 10 degrees trailing edge up to 25 degrees down, and rudders up to ±30 degrees.^[4] These surfaces, including strake flaps, enabled the three-surface layout's precise trim and maneuverability.^[9] Safety was prioritized through fault-tolerant voting logic in the triplex redundancy, allowing continued operation with a single failure.^[11] Extensive ground simulations, exceeding 1,000 hours across nonlinear and real-time models, validated handling qualities prior to flight, incorporating air data sensors and attitude references for comprehensive testing.^[12] This rigorous validation ensured the system's stability margins met requirements of at least 3 dB gain and 22.5 degrees phase across the envelope.^[11]

Structural and Materials Innovations

The forward-swept wing design of the Grumman X-29 presented significant aeroelastic challenges, particularly the risk of structural divergence, where aerodynamic loads could induce a self-reinforcing twisting motion leading to failure. To counter this, the aircraft employed graphite-epoxy composite spars engineered with aeroelastic tailoring, incorporating a built-in washout twist through ply orientation to provide favorable bend-twist coupling that limited outboard twisting under load.^[4] This approach, combined with variable stiffness—achieved by aligning fibers to make the inboard sections stiffer and the outboard more flexible—effectively prevented divergence within the flight envelope, as validated by finite element analysis predicting flutter modes up to Mach 1.2.^[13]^[14] The main wing was constructed primarily from advanced composites, including graphite-epoxy for the skins and spars, which allowed for a lightweight, thin supercritical airfoil with a 35-degree leading-edge sweep. The laminate configuration featured 0°/90° and ±45° plies, with the latter oriented to enhance torsion resistance, enabling the wing to achieve an 8-9% weight reduction compared to equivalent metallic structures while maintaining structural integrity.^[4]^[14] Static load tests at Grumman's Bethpage facility confirmed the design's robustness at 100% of limit loads, with no evidence of flutter or divergence.^[4] The canards and vertical tail surfaces also utilized composite materials, such as graphite-epoxy and Kevlar, contributing to overall weight savings and an empty weight of approximately 13,600 pounds for the aircraft.^[1] These components were designed to integrate seamlessly with the forward-swept wing, supporting high-angle-of-attack maneuvers without compromising aeroelastic stability.^[15] The fuselage was based on an aluminum Northrop F-5A forward section, reinforced with composite elements around the engine bay to accommodate the General Electric F404-GE-400 turbofan engine, while the overall airframe was optimized for maneuver loads up to +9g.^[4] This hybrid construction balanced the proven durability of aluminum with the lightness of composites, facilitating the integration of the fly-by-wire system for enhanced stability.^[13] The X-29 program marked the first operational application of tailored composites for active aeroelastic control in a high-performance aircraft, demonstrating their potential to mitigate inherent instabilities of forward-swept designs and influencing subsequent NASA research on adaptive structures for advanced fighters.^[4]^[15]

Flight Testing

Initial Flights and Envelope Expansion

The first Grumman X-29A prototype, designated Ship 1, underwent rollout at the company's Calverton facility on August 27, 1984, marking the public unveiling of the forward-swept-wing demonstrator.^[4] Prior to flight operations, extensive ground testing included vibration surveys to assess structural dynamics and ensure flutter margins exceeded predicted operational frequencies by at least 20 percent, correlating accelerometer data with analytical models for safe envelope progression.^[9] Taxi tests commenced in early December 1984 at Edwards Air Force Base, with high-speed runs along Runway 04-22 reaching 140 knots indicated airspeed under the control of Grumman pilot Chuck Sewell, confirming nosewheel steering responsiveness and canard surface behavior over surface irregularities.^[4] Ship 1's maiden flight lifted off from Edwards on December 14, 1984, piloted by Grumman Chief Test Pilot Chuck Sewell, lasting approximately 30 minutes and climbing to 15,000 feet while gear and flaps remained extended to validate low-speed handling and flight control system integrity.^[16]^[4] The sortie encountered no anomalies, with the digital fly-by-wire system demonstrating stable response and handling qualities rated highly by the pilot, smoother than simulator predictions.^[17] This initial flight was followed by three additional contractor acceptance sorties through late December 1984, transitioning control to Air Force and NASA teams by early 1985. The second prototype, Ship 2, achieved its maiden flight on May 23, 1989, from Edwards, piloted by NASA test pilot Steve Ishmael in a 52-minute profile reaching Mach 0.6 at 29,100 feet mean sea level.^[2]^[4] Envelope expansion for Ship 1 proceeded methodically, prioritizing 1-g and maneuver limits below Mach 0.6 and 30,000 feet initially to monitor wing divergence and flutter via onboard excitation systems.^[18] By September 1985, after roughly 40 flights, the operational envelope extended to Mach 0.75, 35,000 feet, and normal load factors up to 4.5 g, with flutter clearance verified to 1.28 Mach through real-time structural response analysis.^[19] The program's first supersonic milestone occurred on December 13, 1985, when Ship 1 achieved level flight at Mach 1.03, marking the inaugural supersonic operation of a forward-swept-wing aircraft and confirming aeroelastic stability without pilot-induced oscillations.^[4] Early testing validated the fly-by-wire system's real-world performance in managing the aircraft's inherent instability, with no divergence or control issues observed during subsonic buildup.^[17] By the end of 1986, Ship 1 had logged 104 flights, encompassing envelope clearance to 50,000 feet and maximum tested Mach numbers, alongside preliminary carrier compatibility simulations through approach and landing pattern evaluations.^[17] Minor challenges arose, including higher-than-predicted canard torsion loads at transonic speeds and the need for flight control software gain adjustments to enhance pitch damping at low altitudes, resolved via iterative updates without compromising safety margins.^[17] Overall, Ship 1 accumulated 242 flights by the program's midpoint in 1988, fully establishing the baseline envelope for subsequent research.^[20]

Advanced Research Missions

Following the initial envelope expansion, the second X-29 aircraft (designated Ship 2) focused on high-angle-of-attack (AoA) research, commencing after its maiden flight on May 23, 1989. This phase involved modifications such as the addition of nose strakes to the forebody, which helped generate and control leading-edge vortices for enhanced stability and maneuverability at extreme attitudes. The aircraft achieved a maximum AoA of 67 degrees during momentary pitch-up maneuvers, while maintaining controlled flight up to 45 degrees in all axes, demonstrating precise pitch control within 1 degree and reduced wing rock compared to predictions. Over 120 flights in this Phase 2 effort validated post-stall maneuverability without aerodynamic departure, showcasing the effectiveness of the digital fly-by-wire system in managing the aircraft's inherent instability.^[21]^[1]^[12] Supersonic and agility trials further highlighted the forward-swept wing's benefits, with the X-29 confirming Mach 1.6 capability in level flight—the first such achievement for a forward-swept wing aircraft. These tests revealed improved turn rates attributable to the wing design's delayed stall characteristics and enhanced lift distribution, outperforming conventional swept-wing baselines like the F-16 in high-AoA regimes. Vortex flow visualization was achieved using smoke generators in the nose to entrain smoke within the forebody vortex system, providing in-flight data on airflow behavior at angles up to 45 degrees and aiding validation of wind-tunnel models. Pilots, including those from the U.S. Air Force Test Pilot School, conducted these maneuvers from 1989 to 1991, logging sustained turns at elevated AoA that exceeded expectations for unstable configurations.^[1]^[22]^[23] The advanced missions encompassed 422 total research flights across both aircraft by program completion in 1992, integrating digital engine control systems for optimized thrust response and collecting extensive sensor data to refine computational fluid dynamics (CFD) models of vortex-dominated flows. Peak altitudes reached 50,000 feet during these evaluations, enabling tests of handling qualities in thin-air conditions relevant to fighter operations. Each flight recorded over 1,000 aerodynamic and structural parameters, which were archived in NASA databases to advance understanding of highly unstable aircraft dynamics and inform future designs. These efforts, conducted primarily at NASA's Dryden Flight Research Center (now Armstrong), emphasized military utility assessments, including vortex control techniques that mitigated sideslip-induced asymmetries.^[1]^[2]^[22]

Program Legacy

Retirement and Preservation

The Grumman X-29 flight research program concluded in 1992 after completing its objectives, with the final phase of testing ending in August of that year.^[1] The two aircraft together accumulated 422 research missions, including 242 flights in Phase 1 with the first prototype and 180 flights (120 in Phase 2 plus 60 in vortex flow control testing) with the second.^[1] Following the end of operations, both prototypes were decommissioned and placed into storage before being allocated for public display.^[2] The first X-29A (NASA designation No. 1, USAF serial 82-003) was transferred from NASA to the U.S. Air Force and retired to the National Museum of the United States Air Force at Wright-Patterson Air Force Base in Dayton, Ohio, in late 1994.^[2] It has been on static display in the museum's Research & Development Gallery, where it remains in preserved condition for educational purposes.^[2] The second X-29A (NASA No. 2) was retained by NASA and is on static display at the agency's Armstrong Flight Research Center at Edwards Air Force Base, California.^[1] Preservation efforts for both airframes have focused on static exhibition rather than restoration to flightworthy status, with no plans for reactivation noted as of 2025.^[1] The aircraft are maintained intact and contribute to STEM outreach programs at their respective sites, highlighting advancements in aerodynamics and flight controls.^[2] Additionally, a full-scale replica fuselage of the X-29, originally displayed at the Smithsonian National Air and Space Museum, was relocated to the Cradle of Aviation Museum in Garden City, New York, in 2011 for educational exhibits tied to Grumman's Long Island heritage.^[24] As of November 2025, all three displays—no recent modifications or relocations reported—continue to serve as key artifacts in aviation history collections.^[1]

Technological Impact and Lessons Learned

The Grumman X-29 program validated the use of digital fly-by-wire (FBW) systems for controlling highly unstable aircraft, demonstrating that such configurations could achieve stable flight with up to 35% static margin instability at subsonic speeds.^[4] This integration reduced trim drag by approximately 15-20% in transonic regimes through forward-swept wings (FSW), canards, and automatic camber control, confirming theoretical benefits for maneuverability while highlighting flutter suppression challenges via aeroelastic tailoring.^[4] The aircraft's forward-swept design also enhanced high-angle-of-attack (high-alpha) performance, with airflow remaining attached at the wingtips up to 45 degrees, though manufacturing complexities with composite materials increased costs and structural risks. Despite these advancements, the X-29's technologies were not adopted into production fighters due to the high expense and complexity of graphite-epoxy composites, which outweighed marginal gains in drag reduction and agility compared to aft-swept wing alternatives.^[4] Emerging priorities for stealth in fifth-generation aircraft, such as the F-22, rendered FSW less viable, as conventional designs proved sufficient for transonic performance without the added flutter and divergence risks.^[4] Program data informed subsequent developments but did not directly translate to operational platforms, as the overall system integration demands exceeded practical benefits for cost-constrained military programs. The X-29 contributed to relaxed static stability concepts in aircraft like the Eurofighter Typhoon and F-35, providing empirical validation for FBW-enabled instability that improved agility without full FSW adoption.^[4] Its flight data advanced computational fluid dynamics (CFD) modeling for unstable configurations, with archived results supporting modern simulations for high-alpha aerodynamics. NASA Technical Memorandum 4598 details FBW lessons that influenced fault-tolerant control systems in subsequent designs.^[25] As a benchmark for 1980s integrated flight controls, the X-29 inspired follow-on programs like the X-31 and F/A-18 High Alpha Research Vehicle (HARV), emphasizing real-time data analysis and simulation validation.^[4] Quantitatively, handling qualities achieved Level 1 ratings (1-3 on the Cooper-Harper scale) in most regimes post-modifications, with Level 2 in lateral axes.

Specifications

General Characteristics

The Grumman X-29A was a single-seat experimental aircraft crewed by one pilot.^[6] Its primary dimensions comprised a length of 48.1 ft (14.66 m), a wingspan of 27.2 ft (8.29 m).^[1] The aircraft's weights included an empty weight of 13,600 lb (6,165 kg), a gross weight of 17,600 lb (7,983 kg), and a maximum takeoff weight of 17,800 lb (8,074 kg).^[1]^[18] Propulsion was provided by a single General Electric F404-GE-400 afterburning turbofan engine, delivering approximately 11,000 lbf (49 kN) of dry thrust and 16,000 lbf (71 kN) with afterburner.^[6] As an experimental platform, the X-29A carried no armament but included provisions for test equipment bays to support research instrumentation.^[2] The avionics suite featured a triple-redundant digital fly-by-wire flight control system, a head-up display (HUD), and an inertial navigation system tailored for research operations.^[4] The extensive use of composite materials in the wing structure offered benefits in reduced weight and precise aeroelastic tailoring to mitigate divergence risks.^[4]

Performance

The Grumman X-29 demonstrated a maximum speed of Mach 1.6 (approximately 737 mph or 1,186 km/h) at high altitudes during its flight test program, marking the first instance of a forward-swept wing aircraft achieving supersonic flight in level conditions.^[1] Typical cruise speeds ranged from Mach 0.8 to 0.9 during subsonic research missions, allowing for efficient envelope exploration without excessive fuel consumption.^[4] The aircraft's service ceiling reached 50,000 feet (15,240 meters), enabling high-altitude testing of aerodynamic stability and control.^[2] Flight endurance was typically around 1 hour for standard missions, with the longest recorded subsonic flight lasting 1.5 hours, constrained by its internal fuel capacity of approximately 3,977 pounds.^[4] Maneuverability testing revealed exceptional high-angle-of-attack (AoA) performance, with the X-29 maintaining control up to a maximum AoA of 67 degrees during 1-g flight, far exceeding conventional aircraft limits and validating the forward-swept wing's potential for enhanced lift at extreme attitudes.^[21] The fly-by-wire system enabled these capabilities by providing precise stability augmentation. Structural load factors were tested up to +6.7 g, with design limits set at approximately +8 g based on 80% proof loading during early flights.^[26] Sustained turn rates exceeded 20 degrees per second at Mach 0.9 in the 30–40 degree AoA regime, contributing to tight turn radii and agile handling.^[23] Additional metrics included a peak roll rate of 180 degrees per second at 200 knots calibrated airspeed and 20,000 feet, supporting rapid lateral maneuvering without reversal.^[21] Test data confirmed a high-alpha lift coefficient of up to 1.6 at 16 degrees AoA, with further increases at higher angles due to the wing-canard interaction, enhancing overall aerodynamic efficiency.^[8] The configuration also verified supersonic dash capability across multiple regimes, achieving Mach 1.48 at 50,200 feet.^[4]

References

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During Phase 2 flights, NASA, Air Force and Grumman project pilots reported the X-29 aircraft had excellent control response to 45 degrees angle of attack and ...Missing: experimental | Show results with:experimental
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Grumman X-29A - Air Force Museum
The X-29A program explored cutting-edge aircraft design features, including forward-swept wings, advanced materials, a forward-mounted elevator (or canard)Missing: experimental | Show results with:experimental
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Grumman X-29: The impossible fighter jet with inverted wings | CNN
Jul 13, 2019 · The X-29, an experimental plane flown by NASA in the 1980s, sports one of the most unusual designs in the history of aviation.
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The X-29 program involved contributions from many extremely talented individuals in both industry and Government. It was a privilege to be a member of the team ...Missing: conceptualization | Show results with:conceptualization
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X-29: The Most Aerodynamically Unstable Aircraft Ever Built - DARPA
Dec 14, 1984 · DARPA, NASA, and the U.S. Air Force jointly developed two X-29 technology demonstration aircraft, which the Air Force acquired in March 1985 ...Missing: Grumman funding 1981 $150
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The Grumman Corporation was chosen in December 1981 to receive an $87 million contract to build two X-29 aircraft. They were to become the first new X-series ...Missing: funding $150
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This high degree of instability necessitates high levels of artificial stability augmentation provided by the triplex digital fly-by-wire flight control system.
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The purpose of this paper is to report these results. Because the X-29A was a technology demonstrator, it did not undergo thorough aerodynamic design.
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The broad program objective is to demonstrate, through flight, the feasibility of the forward-swept wing design, and to develop confidence in the design and in ...
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The X-29A aircraft is a recent example of a control configured vehicle that was designed with a high degree of longitudinal static instability (up to 35 percent ...
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Mar 9, 1984 · by using the aeroelastic tailoring technology, that forward swept wings could be constructed with composites resulting in an increase in the.
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Because the vertical tail does not incorporate any new technologies, and the load levels reached within the military utility envelope were modest compared to ...
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Dec 24, 2012 · X-29A Ship No. 1 (S/N 82-0003) made its first flight on Friday, 14 December 1984 with Grumman Chief Test Pilot doing the honors. This flight ...
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Sep 13, 1987 · The initial flight test program objec- tive was to expand the aircraft 1-g and maneuver flight envelopes prior to more detailed research.Missing: Grumman rollout taxi
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Flaperon deflection ranye is from 10' trailiny edge up to 25" trailing edge down. The winy aerodynamics are coupled with a full-authority, high-rate canard ...
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Jan 1, 1985 · The X-29 advanced technology demonstrator began flight testing on Dec. 14, 1984; by Sept. 26, 1985, its envelope had been expanded to 0.75 Mach, ...
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Feb 10, 2016 · Grumman manufactured two airframes. They flew a total of 437 flights between 1984-1992. On Dec. 13, 1985, the X-29 became the first ...<|control11|><|separator|>
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Specification ; DIMENSIONS ; Wingspan, 8.3 m, 27 ft 3 in ; Length, 16.4 m, 54 ft 10 in ; Height, 4.4 m, 14 ft 5 in ; Wing area, 17.5 m · 188.37 sq ft.Missing: tail | Show results with:tail
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A digital-analog triplex fly-by-wire flight control system (FCS) has a 40-Hz update rate in each flight axis to artificially stabilize the large negative static ...