Fact-checked by Grok 2 weeks ago

Wing loading

Wing loading is a key aerodynamic metric in and , defined as the total mass or weight of an or flying animal divided by the area of its wings, typically expressed in units such as kilograms per square meter (kg/m²) or pounds per (lb/ft²). This ratio quantifies the load borne by each unit of wing surface and is crucial for generating the lift needed to counteract during flight. In aircraft design, wing loading directly impacts operational performance; lower values, achieved through larger wing areas relative to weight, enable slower stalling speeds, shorter distances, and enhanced low-speed maneuverability, making them suitable for gliders and short-field operations. Conversely, higher wing loading—common in high-speed jets and large commercial airliners like the (approximately 730 kg/m²)—requires greater airspeeds to produce adequate , resulting in higher stall speeds, longer runways, and improved cruise efficiency but reduced sensitivity to . For example, during maneuvers involving load factors (e.g., turns), effective wing loading increases, potentially doubling stall speed from 50 knots to 100 knots under 4 Gs, which demands careful pilot management to avoid structural stress or loss of control. The parameter also extends to biological flight, where exhibit a wide range of wing loadings from about 1 kg/m² in lightweight soarers to over 20 kg/m² in heavier species, such as around 4.5 kg/m² for the , influencing gliding efficiency, takeoff requirements, and energy expenditure. In both contexts, optimizing wing loading balances trade-offs between speed, agility, and efficiency, guiding advancements in aircraft and evolutionary adaptations in .

Definition and Measurement

Basic Concept

Wing loading is a fundamental aerodynamic parameter defined as the ratio of an aircraft's or flying animal's total (or ) to its area, commonly expressed as W/S, where W represents and S the area. This measure quantifies the load supported per unit area of the , serving as a key indicator of how efficiently the generates relative to the vehicle's . For , the reference wing area is the gross planform area, which encompasses the projected surface of the wing as seen from above, including any areas covered by the but excluding control surfaces unless specified otherwise. In biological systems, such as bird wings, the reference area is similarly the planform area, calculated from the outline of the fully extended wings viewed from above or below, encompassing both wings and the intervening body section. While average wing loading provides an overall assessment for design purposes, local variations occur across the wing span due to spanwise lift distribution, resulting in higher loading near the root and lower toward the tips in typical elliptical or tapered wings.

Formulas and Units

Wing loading is fundamentally calculated as the ratio of an aircraft's total weight to its wing reference area, expressed in imperial units as pounds per square foot (lb/ft²) or in SI units as newtons per square meter (N/m²), though mass per unit area (kg/m²) is also commonly used in metric contexts. In steady level flight, wing loading relates directly to the aerodynamic lift equation, where lift L equals weight W, given by L = W = \frac{1}{2} \rho V^2 S C_L, with \rho as air density, V as , S as wing area, and C_L as the ; rearranging yields wing loading W/S = \frac{1}{2} \rho V^2 C_L. The reference wing area S is defined by authorities as the gross planform area of the wing, including all fixed surfaces but excluding movable control surfaces like ailerons, with the (FAA) specifying this in terms of the projected area for lift calculations and the (EASA) aligning with similar standards under Certification Specifications for large aeroplanes (CS-25). Unit conversions between and systems follow standard factors, such as 1 /ft² ≈ 47.88 /m² or ≈ 4.88 kg/m² when approximating weight as mass under . Calculations often adjust for operational weights, using empty weight for baseline structural assessments or (MTOW) for performance limits, as MTOW incorporates full , , and reserves, resulting in higher wing loading compared to empty configurations.

Typical Values and Variations

In Aviation

In aviation, wing loading varies significantly across aircraft categories, reflecting design priorities such as maneuverability, speed, and efficiency. Ultralight aircraft typically exhibit low wing loadings in the range of 10-30 kg/m² to facilitate short takeoffs and landings in constrained environments. General aviation aircraft, including single-engine piston models, generally operate with wing loadings between 50-150 kg/m², balancing ease of handling with practical payload capacities. Commercial jet airliners feature higher wing loadings of 300-800 kg/m², optimized for fuel-efficient cruise at high speeds over long distances. Military fighters often push this further, with wing loadings from 400-800 kg/m² to support supersonic performance and rapid acceleration. Representative examples illustrate these ranges: the wide-body airliner has a wing loading of approximately 750 kg/m², enabling efficient transoceanic flights while maintaining structural integrity under heavy loads. The , a staple of , achieves about 70 kg/m², contributing to its forgiving stall characteristics and suitability for . In contrast, the F-16 fighter jet operates at around 450 kg/m², allowing for agile dogfighting maneuvers at high dynamic pressures. These values are typically calculated at to represent operational extremes. Over time, wing loading in has trended upward, from 50-100 kg/m² in 1920s biplanes like the , which prioritized low-speed stability for early aerial combat, to over 600 kg/m² in modern supersonic jets. This evolution stems from advancing and aerodynamic requirements for higher speeds, reducing sensitivity to atmospheric turbulence. Wing aspect ratio, defined as the square of the divided by wing area, indirectly influences perceived wing loading by affecting distribution and induced for a given loading; higher aspect ratios enhance at lower loadings, common in gliders and early designs, while lower ratios suit high-loading fighters for better roll rates. These loadings fundamentally shape performance traits like stall speed and cruise , as explored in subsequent sections.

In Biological Systems

In biological systems, wing loading refers to the ratio of an animal's body mass to the of its wings, influencing flight , speed, and maneuverability in flying such as , , and extinct reptiles like pterosaurs. Soaring , such as the wandering , exhibit low wing loadings typically ranging from 10 to 20 kg/m², enabling efficient gliding over long distances by minimizing the energy required to stay aloft. In contrast, agile fliers like the common have higher wing loadings around 26 kg/m², which support rapid acceleration and precise turns at the cost of increased power demands during sustained flight. Hummingbirds, despite their small size, display wing loadings of approximately 3 to 4 kg/m², allowing for hovering and quick maneuvers through high wingbeat frequencies. , such as dragonflies, operate at even lower equivalent loadings of about 0.4 kg/m² (or 400 g/m²), facilitating agile predation and evasion in cluttered environments. Biological adaptations to wing loading reflect evolutionary pressures for diverse flight styles. Glider-like , including eagles and albatrosses, have evolved relatively large areas relative to , resulting in low wing loadings that favor endurance soaring in updrafts or over oceans, reducing metabolic costs during . Agile species like swifts and hummingbirds, adapted for insectivory in dynamic , possess proportionally smaller s and higher loadings, enabling bursts of speed and tight maneuvers essential for capturing prey mid-air. These adaptations parallel engineered designs in prioritizing trade-offs between and . In , s feature lightweight, corrugated structures that maintain low loading while providing structural rigidity against aerodynamic forces during hovering and forward flight. Measuring wing loading in biological systems presents challenges due to variations in wing conformation during flight and the difficulty of accurately quantifying projected wing area from static specimens. Researchers rely on morphological studies, such as photographing spread wings or using scans, but traditional methods like estimating from folded wings often underestimate total area by 10-20%, particularly in with slotted or high-aspect-ratio wings. Early ornithological efforts, exemplified by Otto Lilienthal's 19th-century observations of bird wings, highlighted the need for precise area measurements; he advocated for supporting surfaces of about 0.11 per of body mass, drawing directly from studies of large soaring to inform human gliding designs. Modern techniques, including the folded-wing method, improve accuracy across diverse morphologies by accounting for feather overlap and body projection. Evolutionary trade-offs in wing loading are evident across flying taxa, balancing endurance against speed and agility. Low wing loadings, as in soaring birds and small pterosaurs like (around 6 kg/m²), promote efficient long-distance flight but constrain maximum speeds due to reduced lift at higher velocities. Higher loadings, seen in larger pterosaurs such as (up to 23 kg/m²) and agile birds like swifts, enable faster travel and better penetration of headwinds but limit soaring capability and increase energy costs, as reflected in fossil records showing size-related shifts in flight strategies over eras. These patterns underscore how optimizes loading for ecological niches, from oceanic foraging to aerial insect hunting.

Performance Effects

Takeoff and Landing

Wing loading plays a critical role in determining the minimum airspeeds required for safe takeoff and landing, primarily through its influence on the aircraft's stall speed. The stall speed V_s, the lowest speed at which the wing can generate sufficient lift to support the aircraft's weight, is derived from the steady-state lift equation where lift equals weight at the onset of stall: W = \frac{1}{2} \rho V_s^2 S C_{L,\max}. Rearranging yields V_s = \sqrt{\frac{2 (W/S)}{\rho C_{L,\max}}}, with W/S as wing loading, \rho as air density, and C_{L,\max} as the maximum lift coefficient. This relationship demonstrates that stall speed scales proportionally with the square root of wing loading, meaning a doubling of W/S increases V_s by approximately 41%. Higher wing loading elevates speed, necessitating greater speeds and thus longer distances to accelerate to or decelerate from those speeds. Fighter aircraft, often designed with wing loadings exceeding 400 kg/m², typically require takeoff lengths of 800–1,500 meters due to their elevated minimum speeds, whereas low-wing-loading trainers around 100–150 kg/m² can manage with as little as 300 meters for ground roll under standard conditions. Conversely, low wing loading facilitates short (STOL) operations by permitting lower speeds, enabling operations from unprepared or confined sites; extreme cases approach vertical takeoff capabilities when combined with . Real-world applications highlight these effects. The AV-8B Harrier II, a VTOL-capable fighter, operates with a nominal wing loading of approximately 460 kg/m² but achieves vertical or short takeoffs by adjusting effective loading through reduced fuel and , often to around 500 kg/m² equivalent under operational constraints. In contrast, gliders optimized for short-field performance maintain wing loadings under 40 kg/m², allowing minimal approach speeds and landings in fields as short as 100–200 meters. Environmental conditions, particularly density altitude, exacerbate these dynamics. As altitude or temperature rises, air density \rho decreases, further increasing stall speed via the inverse square root relationship in the formula; this penalty is more pronounced for high-wing-loading aircraft, potentially extending required runway lengths by 20–50% or more at hot, high-elevation airports.

Maneuverability and Turning

Wing loading plays a critical role in determining an aircraft's ability to perform agile maneuvers, particularly in turns, where the load factor n (the ratio of lift to weight) directly influences the centripetal force required to sustain curved flight paths. The maximum load factor achievable at a given speed is constrained by the wing loading W/S, as n = \frac{C_L \cdot q}{W/S}, where C_L is the lift coefficient (limited by C_{L_{\max}}) and q is the dynamic pressure (\frac{1}{2} \rho V^2). Thus, higher wing loading reduces the maximum n for a fixed speed and C_{L_{\max}}, limiting the tightness of turns unless compensated by higher speeds or advanced aerodynamic features. The sustained turn rate \omega, which represents the of a steady turn without loss of speed or altitude, is given by: \omega = \frac{g}{V} \sqrt{n^2 - 1} where g is and V is . Here, n is bounded by structural limits and the aerodynamic ceiling imposed by W/S and C_{L_{\max}}; aircraft with higher W/S must operate at faster speeds to achieve comparable n, often trading off turn tightness for retention during prolonged engagements. This relationship underscores why low wing loading facilitates superior sustained turning performance in scenarios requiring continuous maneuvering, such as aerial combat. In practice, low wing loading enables tighter turns by allowing higher n at lower speeds, as seen in gliders with W/S typically below 50 kg/m², which are structurally limited to load factors of around 4-6 for utility operations, emphasizing gentle coordinated turns to avoid stall. Conversely, high-performance fighters like the , with a wing loading of approximately 377 kg/m², prioritize burst maneuvers up to +9 for instantaneous turns, where energy is temporarily sacrificed, but sustain lower rates in prolonged turns to preserve speed and altitude advantages. This design favors rapid repositioning over sustained circling, aligning with modern dogfighting tactics that emphasize over pure . Historical examples illustrate these trade-offs vividly. During , the Mk I, with a wing loading of about 130 kg/m², excelled in turning dogfights due to its ability to sustain higher load factors at combat speeds compared to heavy bombers like the at roughly 186 kg/m², which prioritized straight-line stability over agility and could manage only modest turns under load. In dogfights, wing loading often acts as the binding constraint for sustained turns, where drag buildup limits n, while instantaneous turns—relying on peak C_L and structural g-limits—allow brief advantages regardless of W/S, though prolonged use depletes rapidly.

Stability and Control

Wing loading significantly influences an aircraft's , particularly through its effects on the and short-period modes. Higher wing loading (W/S) tends to reduce the damping ratio of the mode, making this long-period less stable and more challenging to control, especially under where low becomes objectionable. Conversely, increased W/S raises the natural frequency of the short-period mode, resulting in a shorter period and quicker response to disturbances, though this can demand precise pilot inputs to avoid overcorrection. Historical examples illustrate these effects: early 1920s monoplanes, often with W/S around 100 kg/m², exhibited proneness to lateral instability, necessitating the addition of angles to restore roll without compromising structural integrity. In contrast, modern jets, featuring high W/S values up to approximately 600 kg/m², rely on electronic control systems to actively compensate for reduced inherent , enabling agile flight envelopes while mitigating and short-period divergences. Low wing loading also amplifies an aircraft's response to gusts and , as the lower inertial resistance to lift variations results in larger load factor excursions from vertical . This heightened sensitivity often necessitates structural reinforcements in the wing and fuselage to withstand repeated dynamic loads, particularly in high-aspect-ratio designs like gliders that prioritize low W/S for .

Design and Optimization Strategies

High-Lift Devices

High-lift devices, primarily trailing-edge flaps, enhance the wing's maximum lift coefficient (C_{L,\max}) to reduce effective wing loading during low-speed operations like takeoff and landing. By increasing C_{L,\max} through modifications to the airfoil camber, area, or airflow energization, these devices allow the aircraft to produce required lift at lower airspeeds, effectively lowering the impact of wing loading (W/S) in the lift equation L = \frac{1}{2} \rho V^2 S C_L. Typical increases in C_{L,\max} range from 50% to 100%, depending on the design; for instance, slotted flaps on commercial airliners can elevate C_L from about 1.5 in the clean configuration to 2.5 or higher when deployed. Various flap types achieve these gains through distinct mechanisms, each influencing drag and stall behavior differently. Plain flaps hinge downward from the trailing edge, increasing camber with moderate lift augmentation (e.g., C_{L,\max} to 1.7–2.0 for landing) and relatively low induced drag, though they promote earlier flow separation and a sharper stall. Split flaps deflect only the lower surface, generating substantial drag that aids deceleration but results in abrupt stalls due to upper-surface separation at lower angles of attack. Fowler flaps, by contrast, slide rearward on tracks before deflecting, expanding wing area by up to 25% while boosting camber, yielding the highest C_{L,\max} (e.g., 2.5–2.9 for landing) but with elevated drag from the extended geometry. A representative example is the , which utilizes triple-slotted Fowler flaps to achieve significant low-speed performance despite a cruise wing loading of approximately 550 kg/m². These flaps, combining multiple slots for energized airflow, enable a speed reduction of about 20% relative to wing configuration by leveraging the elevated C_{L,\max}. Despite their benefits, high-lift devices introduce substantial parasitic and induced at low speeds, which enhances deceleration during approach but renders them impractical for where drag minimization is critical for . Additionally, their deployment alters characteristics, often requiring complementary leading-edge devices to maintain control margins.

Variable Geometry

Variable geometry in refers to wings capable of altering their shape, primarily through sweep angle adjustments or folding mechanisms, to dynamically optimize wing loading across diverse flight regimes and operational needs. This approach addresses the trade-offs inherent in fixed-wing configurations, where low wing loading (high area relative to weight) benefits low-speed performance like , while higher effective loading (via increased sweep) minimizes during high-speed cruise. By varying geometry, can achieve versatile performance without compromising core structural integrity. The predominant form of variable geometry is the , also known as a swing wing, which pivots at a root-mounted to change the sweep angle in flight. A notable example is the , where wings sweep from 20° (fully extended) to 68° (fully swept), effectively modulating wing loading from approximately 230 kg/m² in the low-sweep configuration—enhancing for carrier operations—to around 470 kg/m² when swept back, reducing and supersonic drag. Another type, folding wings, primarily serves storage purposes rather than in-flight adjustments; seen in like the F/A-18 Hornet, these mechanisms fold the outer wing sections upward or inward to minimize deck footprint, effectively halving the for stowage without altering or loading once extended. Historical development traces to the , with (then NACA) pioneering concepts through the experimental aircraft, which demonstrated in-flight sweep variation starting in 1951, building on earlier German research. The first operational variable-sweep fighter, the Soviet , entered service in 1970, featuring sweep angles of 16°, 45°, and 72° to balance subsonic maneuverability and supersonic dash capabilities. Benefits of variable-sweep designs are pronounced in multi-role missions: at low sweep angles, the increased effective and lower wing loading for shorter takeoff distances and improved low-speed handling, while high sweep angles raise effective loading by streamlining airflow, cutting by up to 50% at speeds above 1.0 and enabling efficient supersonic cruise. These adaptations proved critical for like the F-14, allowing seamless transitions from carrier launches to high-altitude intercepts. However, the technology incurs significant drawbacks, including mechanical complexity from pivot systems, actuators, and fairings, which demand rigorous maintenance and reduce reliability in combat. Weight penalties are substantial, with studies indicating 17-28% increases in wing structural mass due to pivoting mechanisms, translating to roughly 5-10% of the total empty weight—limiting fuel or capacity and elevating overall costs. Despite these challenges, variable geometry remains a hallmark of advanced tactical for regime-spanning performance.

Loading Adjustments

Loading adjustments refer to operational techniques that alter an aircraft's wing loading by redistributing or varying without modifying the structure. These methods allow pilots and operators to optimize for specific conditions, such as adjusting for expected or requirements. Primary approaches include the use of dumpable in gliders, strategic loading in powered aircraft, and payload management in cargo planes. In gliders, water ballast is a widely adopted technique to increase wing loading for enhanced speed in strong soaring conditions, while enabling reduction for better climb performance in weaker . Dumpable water ballast systems were first introduced in the Gö 3 Minimoa sailplane in 1935, marking the initial use of such provisions to improve high-speed performance without permanent weight additions. Modern gliders typically carry 100 to 300 kg of water in wing tanks, raising wing loading from around 30-40 kg/m² in a clean configuration to 50-60 kg/m² when fully ballasted, depending on the model and total gross weight. For instance, the Alexander Schleicher ASG 29 sailplane features wing tanks with a capacity of 170 liters (170 kg), increasing its wing loading from approximately 37 kg/m² (including pilot) to a maximum of 57 kg/m², allowing pilots to optimize for cross-country flights by dumping ballast as needed to improve low-speed handling. In , fuel management influences wing loading by varying the initial fuel load or through in-flight consumption, which progressively decreases overall and thus wing loading during extended missions. Operators may load less for shorter flights to reduce takeoff wing loading and improve field performance, or carry excess for at the cost of higher initial loading. However, excess from full fuel tanks can reduce overall range efficiency due to increased and fuel burn. Cargo aircraft employ payload shifts and total load adjustments to balance wing loading within certification limits, ensuring safe takeoff and landing distances. By positioning cargo to maintain center of gravity while varying total payload, operators can fine-tune wing loading for operational constraints like runway length, though overloading reduces range and increases fuel consumption. These adjustments carry performance penalties, such as elevated stall speeds and reduced climb rates with higher loading, which can limit options in marginal conditions. Aviation regulations, including FAA certification under 14 CFR Part 23, impose maximum gross weight limits that effectively cap wing loading based on the fixed wing area, ensuring structural integrity and safe operation.

References

  1. [1]
    Wing loading - Science Learning Hub
    Sep 13, 2011 · Wing loading is a measurement that relates the mass of an aircraft or bird to the total wing area. The relationship between wing area and body weight is given ...
  2. [2]
    What is Wing Loading? - | How Things Fly
    Jan 8, 2018 · In aerodynamics, wing loading is the total mass of an aircraft divided by the area of its wing.
  3. [3]
    [PDF] Chapter 5: Aerodynamics of Flight - Federal Aviation Administration
    Lift is the upward force on the wing acting perpendicular to the relative wind and perpendicular to the aircraft's lateral axis. Lift is required to counteract ...<|control11|><|separator|>
  4. [4]
    [PDF] THE INFLUENCE OF WING LOADING ON TURBOFAN POWERED ...
    The effects of wing loading on the design of short takeoff and landing (STOL) transports using. (1) mechanical flap systems, and (2) externally blown flap ...
  5. [5]
    Geometry Definitions
    This slide gives technical definitions of a wing's geometry, which is one of the chief factors affecting airplane lift and drag.Missing: origin | Show results with:origin
  6. [6]
    [PDF] Wing area, wing growth and wing loading of Common Sandpipers ...
    A “wing planform” is a 1:1 drawing of the outline of a bird from above or below with its wings fully extended; “wing area” is the area of both wings and the ...
  7. [7]
    The Angle of Incidence - Wright Brothers Aeroplane Company
    The angle of incidence is fixed by area, weight, and speed alone. It varies directly as the weight, and inversely as the area and speed, though not in exact ...
  8. [8]
    [PDF] On Wings of the Minimum Induced Drag: Spanload Implications for ...
    The load distribution over a bird's wing is far more gradual than an elliptical spanload provides: consider a birds' wing. Page 17. 13 structure—both skeletal ...
  9. [9]
    Lift Formula
    L = Lift, which must equal the airplane's weight in pounds ; d = density of the air. This will change due to altitude. These values can be found in a I.C.A.O. ...
  10. [10]
    [PDF] Chapter 10: Weight and Balance - Federal Aviation Administration
    To assure that the lift generated is sufficient to counteract weight, loading an aircraft beyond the manufacturer's recommended weight must be avoided. If the ...
  11. [11]
    Wing And Power Loading - Aviation Safety Magazine
    Wing loading, or the ratio of an airplane's weight to its surface area, is the average load each unit of the wing must carry.
  12. [12]
    Design Process: Wing Size and Stall Speed - Kitplanes Magazine
    Sep 21, 2018 · Even so, we can see that the upper limit on wing loading for a truly legal Part 103 ultralight is only about 4 pounds per square foot. This is ...<|separator|>
  13. [13]
    Airplane math that matters - AOPA
    Jun 1, 2020 · Wing loading is an airplane's gross weight divided by its wing area, and it's usually expressed in terms of pounds per square foot. (A 1,000 ...
  14. [14]
    Wing loading definition, effects and design - Orizair
    Jul 18, 2025 · Higher wing loadings enable aircraft to fly faster during cruise. With a greater weight relative to wing area, the wings generate more lift at a ...
  15. [15]
    Wing Loading (W/S) - an overview | ScienceDirect Topics
    Wing loading (W/S) is defined as the ratio of the weight of an aircraft to its wing planform area, which influences its landing and take-off performance.
  16. [16]
    Boeing 747-100 performance | passenger aircraft
    wing loading (MTOW & flaps retracted) : 630 [kg/m2]. wing stress (2 g) during operation : 176 [N/kg] at 2g emergency manoeuvre. calculation : *6* (angles of ...
  17. [17]
    Most Successful Aircraft In History: A Look At The Cessna 172
    Jun 1, 2024 · Rate of climb: 721 ft/min (3.66 m/s); Wing loading: 14.1 lb/sq ft (68.6 kg/m2). Cessna Skyhawk cockpit avionics ...
  18. [18]
    General Dynamics F-16 Fighting Falcon - Wikipedia
    Wing loading: 88.3 lb/sq ft (431 kg/m2); Thrust/weight: 1.095 (1.24 with loaded weight & 50% internal fuel). Armament. Guns: 1 × 20 mm (0.787 in) M61A1 ...A/AM · Pakistani F-16s · General Dynamics F-16XL · Vought Model 1600
  19. [19]
    [PDF] Aircraft Design --- Chapter 5: Preliminary Sizing - HAW Hamburg
    The ratio from thrust-to-weight ratio and wing loading pursuant to equation 5.10 must not be undershot if the aircraft is to meet requirements. Page 11. 5 - 11.
  20. [20]
    Review of evolving trends in blended wing body aircraft design
    This paper reviews emerging trends in BWB aircraft design highlighting design challenges that have hindered the development of a BWB passenger transport ...
  21. [21]
    Effect of wing loading, aspect ratio, and span loading of flight ...
    An investigation is made of the possible improvements in maximum, cruising, and climbing speeds attainable through increase in the wing loading.
  22. [22]
    Wing Loading a Critical Aircraft Design Parameter - Engineer's Vault
    May 21, 2023 · A lower wing loading also provides a better climb performance and increases the service ceiling of the aircraft. However, a lower wing loading ...
  23. [23]
    [PDF] From Insects to Jumbo Jets - The Simple Science of Flight - MIT
    Looking at table 1, we find that wing loading and cruising speed generally increase as birds become heavier. But the rate at which this hap- pens is not ...
  24. [24]
    Aerodynamics of gliding flight in common swifts
    Feb 1, 2011 · where W/S (weight/area) is the wing loading and AR is the aspect ratio of the wing. The wing loading for the swift was 26 kg m–2 and for the ...
  25. [25]
    [PDF] Take-off Mechanics in Hummingbirds (Trochilidae)
    Single wing area (mm2). 599.2±46.4. Area of both wings and root box area of body (mm2) 1364.4±93.7. Wing loading (N·m–2). 36.7±3.0. Disc loading (N·m–2). 3.7± ...
  26. [26]
    None
    ### Summary of Wing Loading for Dragonflies
  27. [27]
    [PDF] Anatomical and Physiological Adaptations for Flight
    Aspect ratio of a wing is the ratio of its length to its breadth. A high aspect ratio indicates long, narrow wings (swift, albatross), whereas a low aspect.
  28. [28]
    New methods for estimating the total wing area of birds
    Sep 2, 2023 · We demonstrate that the new folded-wing method estimates total wing area with high precision across a variety of avian groups and wing shapes.
  29. [29]
    Bird Flight As A Basis of Aviation - Otto-Lilienthal-Museum
    The wing must show a curvature on the underside. The camber of the curvature should be about 1/12 of the width of the wing, in accordance with the construction ...Missing: loading studies
  30. [30]
    On the Size and Flight Diversity of Giant Pterosaurs, the Use of Birds ...
    A 22 kg pterosaur would equate to a 4.2 m wingspan ... Dimorphodon has been found to be a particularly heavyset pterosaur with relatively high wing loading ...
  31. [31]
    [PDF] Soaring styles of extinct giant birds and pterosaurs - bioRxiv
    Dec 24, 2020 · This poor thermal soaring performance was due to the large wing loading associated with the large body size. As shown in the Materials and.<|separator|>
  32. [32]
    https://www.globalsecurity.org/military/systems/aircraft/av-8-specs.htm
  33. [33]
    AV-8B Harrier - GlobalSecurity.org
    Jul 7, 2011 · Weights and Loadings (Single-Seaters, Except Where Indicated) ; AV-8B/Pegasus 11-61. 9,342 kg ; GR. Mk 7. 8,700 kg ; S/L VTO, 32°C · 8,142 kg.
  34. [34]
    [PDF] No. 439 - NASA Technical Reports Server (NTRS)
    wing loading of gliders varies therefore between 5 and 8 kg 02. (1.02 and 1.64 lb./sqft..), while it lies between 8 and 12 kg/m2. *Translation from Chapter IV ...
  35. [35]
    Chapter 8. Accelerated Performance: Turns
    The Wright brothers designed a complex mechanism involving coordinated ... High wing loading (W/S) will also allow a tighter turn. The rate of turn in ...Introduction · 8.1 The Mechanics Of A Turn · 8.6 The V‐n Or V‐g...<|control11|><|separator|>
  36. [36]
    [PDF] Turning Flight
    A turn rate can be sustained if we can maintain the airspeed at which it occurs. For this we require thrust to equal the drag.
  37. [37]
    [PDF] Chapter 5: Glider Performance
    The stall speed increases with the square root of any load on the glider. For example, if the weight or load factor on the glider doubles, the stall speed ...
  38. [38]
    F-22 Raptor > Air Force > Fact Sheet Display - AF.mil
    The F-22 has a significant capability to attack surface targets. In the air-to-ground configuration the aircraft can carry two 1,000-pound GBU-32 Joint Direct ...
  39. [39]
    Supermarine Spitfire - fighter - Aviastar.org
    Take-off weight, 2911 kg, 6418 lb. Empty weight, 2267 kg, 4998 lb. DIMENSIONS. Wingspan, 11.23 m, 37 ft 10 in. Length, 9.12 m, 30 ft 11 in. Height, 3.02 m, 10 ...
  40. [40]
    Boeing B-17 Flying Fortress - Army Air Corps Museum
    Wing Area: 1,420 sq ft (131.92 m²); Empty Weight: 36,135 lb (16,391 kg); Loaded Weight: 54,000 lb (24,500 kg); Max Takeoff Weight: 65,000 lb (29,500 kg).<|separator|>
  41. [41]
    [PDF] Flight Stability and Automatic Control - Iowa State University
    This book covers aircraft stability, flight control, autopilot design, static and dynamic stability, aircraft equations of motion, and automatic control theory.<|control11|><|separator|>
  42. [42]
    [PDF] A Theoretical Analysis Dynamic Stability in o( : Longitudinal Gliding ...
    The effects of wing loading and altitude appear only in o), while the tail ... The period of the short period oscillation. (Table 6) decreases with increasing ...<|separator|>
  43. [43]
    [PDF] Pilot Evaluation of Sailplane Handling Qualities
    Wing Loading. Root Chord. Tip Chord. Fuselage Length. Fuselage Width. Hor. Tail ... Stick Force Gradient, Stick Fixed Stability, and Stick Free Stability ...
  44. [44]
    Aircraft Stability & Control – Introduction to Aerospace Flight Vehicles
    Most swept-wing jet aircraft require a yaw damper to prevent excessive Dutch roll. The Dutch-roll dynamic mode is a coupled roll-yaw behavior usually well ...
  45. [45]
    II. THE DEVELOPMENT OF THE AEROPLANE - jstor
    dihedral and wing stagger to provide inherent stability. Later came the Handley. Page slot (1920), differential (de Havilland) or Frise ailerons, and wash-out ...
  46. [46]
    The aerodynamic principles of modern fighter jets
    May 19, 2025 · The F-15 Eagle's wing (56.5 m² for 30,800 kg) has a higher wing loading of 545 kg/m², which promotes greater stability but slightly less ...
  47. [47]
    [PDF] THE EFFECTS OF ATMOSPHERIC TURBULENCE UPON ... - DTIC
    It is common knowledge that aspect ratio and wing loading greatly influence the sensitivity of an aircraft to gusts. This sensitivity can be represented as the ...
  48. [48]
    [PDF] Robust gust load alleviation of flexible aircraft equipped with lidar
    May 4, 2022 · In this work, priority is put on the alleviation of the bending moment at the wing root, as it could avoid strong structural reinforcements ...
  49. [49]
    [PDF] High-Lift Systems on Commercial Subsonic Airliners
    flaps it is desirable to have only one slot on takeoff, even if the flap is double- or triple-slotted for landing. A flap mechanism that develops most of ...
  50. [50]
    https://aviation.stackexchange.com/questions/1726/why-do-some-military-aircraft-use-variable-sweep-wings
  51. [51]
    [PDF] 8 High Lift Systems and Maximum Lift Coefficients - HAW Hamburg
    A movable slat (slotted leading edge flap) increases the lift through a combination of increased wing area and increased camber and through the influence of the ...
  52. [52]
    Boeing 737 Detailed Technical Data
    Technical Specifications ; Thrust Loading (kg/kN), 343.17, 367.91 ; Wing Loading (kg/m²), 433.33, 513.63 ; Thrust/Weight Ratio, 0.297, 0.2771 ; Take-off (m):.Missing: m2 | Show results with:m2
  53. [53]
    Why do some military aircraft use variable-sweep wings?
    Feb 13, 2014 · Variable-sweep wings reduce drag at high speeds, and the swept configuration provides more lift at lower speeds, allowing for both high and low ...What are the advantages and disadvantages of an oblique wing ...What is the optimal wing sweep angle for a passenger airliner?More results from aviation.stackexchange.com
  54. [54]
    Summary of NACA/NASA Variable-Sweep Research and ...
    Late in 1958 a research breakthrough at Langley provided the technology for designing a variable-sweep wing having satisfactory stability through a wide sweep ...
  55. [55]
    Mikoyan-Gurevich MiG-23 (Flogger) Swing-Wing Fighter-Interceptor ...
    Tests were started with a first flight on April 3rd, 1967, and proved the design sound. The aircraft was unveiled at the 1967 Domododevo Air Show three months ...
  56. [56]
    [PDF] NJ\S/\ - NASA Technical Reports Server (NTRS)
    duced by the unconventional variable-sweep wing through a limited wing-design exercise WhlCh revealed a 28-percent penalty in wing weight due to the pivoting.
  57. [57]
    [PDF] NASA Contractor Report 172321
    The variable-sweep-wing concept has the same payload accommodations as those ... resulting penalty of 17.5 percent for the pivot was applied to the wing weight.
  58. [58]
    Pre-WWII (1935-1945) - Schempp-Hirth
    The "Wolf" was the company's first glider and was designed by Wolf Hirth and Reinhold Seeger. ... It was the first glider that allowed the adding of water ballast ...
  59. [59]
    ASG 29 Es - Alexander Schleicher
    Still, a minimum wing loading of 33 kg/m2 (6.75 lb/sqft) is possible, which can be increased to 57,1 kg/m2 (11.69 lb/sqft). For an optimum wing lay-out in ...
  60. [60]
    [PDF] Parametric study of variation in cargo-airplane performance related ...
    When the payload is restricted to volume available only in the fuselage, decreases in wing loading have a slightly adverse effect on the payload ratio; however, ...