Quadcopter

A quadcopter or quadrotor[1] is a type of helicopter with four rotors.[2]

A DJI Phantom quadcopter drone in flight

Although quadrotor helicopters and convertiplanes have long been flown experimentally, the configuration remained a curiosity until the arrival of the modern UAV or drone. The small size and low inertia of drones allows use of a particularly simple flight control system, which has greatly increased the practicality of the small quadrotor in this application.

Design principles

Each rotor produces both lift and torque about its center of rotation, as well as drag opposite to the vehicle's direction of flight.

Quadcopters generally have two rotors spinning clockwise (CW) and two counterclockwise (CCW). Flight control is provided by independent variation of the speed and hence lift and torque of each rotor. Pitch and roll are controlled by varying the net centre of thrust, with yaw controlled by varying the net torque.[3]

Unlike conventional helicopters, quadcopters do not usually have cyclic pitch control, in which the angle of the blades varies dynamically as they turn around the rotor hub. In the early days of flight, quadcopters (then referred to either as 'quadrotors' or simply as 'helicopters') were seen as a possible solution to some of the persistent problems in vertical flight. Torque-induced control issues (as well as efficiency issues originating from the tail rotor, which generates no useful lift) can be eliminated by counter-rotation, and the relatively short blades are much easier to construct. A number of manned designs appeared in the 1920s and 1930s. These vehicles were among the first successful heavier-than-air vertical take off and landing (VTOL) vehicles.[4] However, early prototypes suffered from poor performance,[4] and latter prototypes required too much pilot work load, due to poor stability augmentation[5] and limited control authority.

Torque

If all four rotors are spinning at the same angular velocity, with two rotating clockwise and two counterclockwise, the net torque about the yaw axis is zero, which means there is no need for a tail rotor as on conventional helicopters. Yaw is induced by mismatching the balance in aerodynamic torques (i.e., by offsetting the cumulative thrust commands between the counter-rotating blade pairs).[6][7]

Vortex ring state

All quadcopters are subject to normal rotorcraft aerodynamics, including the vortex ring state.

Mechanical structure

The main mechanical components are a fuselage or frame, the four rotors (either fixed-pitch or variable-pitch), and motors. For best performance and simplest control algorithms, the motors and propellers are equidistant.[8]

Coaxial rotors

Quadcopter coaxial  OnyxStar FOX-C8 XT Observer from AltiGator

In order to allow more power and stability at reduced weight, a quadcopter, like any other multirotor can employ a coaxial rotor configuration. In this case, each arm has two motors running in opposite directions (one facing up and one facing down).

Operations

Autonomous flight

The quadcopter configuration is relatively simple to program for autonomous flight. This has allowed experiments with complex swarming behaviour based on basic sensing of the adjacent drones.

Endurance

The longest flight time achieved by a battery-powered quadcopter was 2 hours, 31 minutes and 30 seconds. The record was set by Ferdinand Kickinger of Germany in 2016.[9] In setting the record, Kickinger used low-discharge rate, high capacity Lithium Ion batteries and stripped the airframe of non-essential weight to reduce power draw and extend endurance.[10]

Alternative power sources like hydrogen fuel cells and hybrid gas-electric generators have been used to dramatically extend endurance because of the increased energy density of both hydrogen and gasoline, respectively.[11]

History

Pioneers

The first heavier-than-air aerodyne to take off vertically was a four-rotor helicopter designed by Louis Breguet. If was tested only in tethered flight and to an altitude of a few feet. In 1908 it was reported as having flown 'several times', although details are sparse.[12]

Etienne Oehmichen experimented with rotorcraft designs in the 1920s. Among the designs he tried, his helicopter No.2 had four rotors and eight propellers, all driven by a single engine. The Oehmichen No.2 used a steel-tube frame, with two-bladed rotors at the ends of the four arms. The angle of these blades could be varied by warping. Five of the propellers, spinning in the horizontal plane, stabilized the machine laterally. Another propeller was mounted at the nose for steering. The remaining pair of propellers functioned as its forward propulsion. The aircraft exhibited a considerable degree of stability and increase in control-accuracy for its time, and made over a thousand test flights during the middle 1920s. By 1923 it was able to remain airborne for several minutes at a time, and on April 14, 1924 it established the first-ever FAI distance record for helicopters of 360 m (390 yd). It demonstrated the ability to complete a circular course[13] and later, it completed the first 1 kilometre (0.62 mi) closed-circuit flight by a rotorcraft.

Dr. George de Bothezat and Ivan Jerome developed the de Bothezat helicopter, with six-bladed rotors at the end of an X-shaped structure. Two small propellers with variable pitch were used for thrust and yaw control. The vehicle used collective pitch control. Built by the US Air Service, it made its first flight in October 1922. About 100 flights were made by the end of 1923. The highest it ever reached was about 5 m (16 ft 5 in). Although demonstrating feasibility, it was underpowered, unresponsive, mechanically complex and susceptible to reliability problems. Pilot workload was too high during hover to attempt lateral motion.

Postwar era

The Convertawings Model A Quadrotor was intended to be the prototype for a line of much larger civil and military helicopters. The design featured two engines driving four rotors through a system of v belts. No tail rotor was needed and control was obtained by varying the thrust between rotors.[14] Flown many times from 1956, this helicopter proved the quadrotor design and it was also the first four-rotor helicopter to demonstrate successful forward flight. Due to a lack of orders for commercial or military versions however, the project was terminated. Convertawings proposed a Model E that would have a maximum weight of 42,000 lb (19 t) with a payload of 10,900 lb (4.9 t) over 300 miles and at up to 173 mph (278 km/h). The Hanson Elastic Articulated (EA) bearingless rotor grew out of work done in the early 1960s at Lockheed California by Thomas F. Hanson, who had previously worked at Convertawings on the quadrotor's rotor design and control system.[15][16]

Curtiss-Wright VZ-7

The Curtiss-Wright VZ-7 of 1958 was a VTOL aircraft designed by Curtiss-Wright in competition for the US Army Transport and Research Command "flying jeep". The VZ-7 was controlled by changing the thrust of each of the four ducted fan rotors.

The Piasecki PA-97 was a propsal for a large hybrid aircraft in which four helicopter fuselages were combined with a lighter-than-air airship in the 1980s.

Current developments

The Bell Boeing Quad TiltRotor concept takes the fixed quadcopter concept further by combining it with the tilt rotor concept for a proposed C-130 sized military transport.

Flying prototype of the Parrot AR.Drone
Parrot AR.Drone 2.0 take-off, Nevada, 2012

Airbus is developing a battery-powered quadcopter to act as an urban air taxi, at first with a pilot but potentially autonomous in the future.[17]

Drones

In the last few decades, the quadcopter layout has become popular for small-scale unmanned aerial vehicles or drones. The need for aircraft with greater maneuverability and hovering ability has led to a rise in quadcopter research. The four-rotor design allows quadcopters to be relatively simple in design yet highly reliable and maneuverable. Research is continuing to increase the abilities of quadcopters by making advances in multi-craft communication, environment exploration, and maneuverability. If these developing qualities can be combined, quadcopters would be capable of advanced autonomous missions that are currently not possible with other vehicles.[18]

Around 2005 to 2010, advances in electronics allowed the production of cheap lightweight flight controllers, accelerometers (IMU), global positioning system and cameras. This resulted in the quadcopter configuration becoming popular for small unmanned aerial vehicles. With their small size and maneuverability, these quadcopters can be flown indoors as well as outdoors.[1][19]

For small drones, quadcopters are cheaper and more durable than conventional helicopters due to their mechanical simplicity.[20] Their smaller blades are also advantageous because they possess less kinetic energy, reducing their ability to cause damage. For small-scale quadcopters, this makes the vehicles safer for close interaction. It is also possible to fit quadcopters with guards that enclose the rotors, further reducing the potential for damage.[2] However, as size increases, fixed propeller quadcopters develop disadvantages relative to conventional helicopters. Increasing blade size increases their momentum. This means that changes in blade speed take longer, which negatively impacts control. Helicopters do not experience this problem as increasing the size of the rotor disk does not significantly impact the ability to control blade pitch.

Due to their ease of construction and control, quadcopters are popular as amateur model aircraft projects.[21][22]

gollark: This is not optimal.
gollark: It's a weird and very problematic optical effect.
gollark: #bee500
gollark: Ugh, these style sheets are not cascading desirably.
gollark: A minor disadvantage, yes.

See also

References

  1. Hoffmann, G.M.; Rajnarayan, D.G.; Waslander, S.L.; Dostal, D.; Jang, J.S.; Tomlin, C.J. (November 2004). "The Stanford Testbed of Autonomous Rotorcraft for Multi Agent Control (STARMAC)". In the Proceedings of the 23rd Digital Avionics System Conference. Salt Lake City, UT. pp. 12.E.4/1–10. doi:10.1109/DASC.2004.1390847.
  2. Hoffman, G.; Huang, H.; Waslander, S.L.; Tomlin, C.J. (20–23 August 2007). "Quadrotor Helicopter Flight Dynamics and Control: Theory and Experiment" (PDF). In the Conference of the American Institute of Aeronautics and Astronautics. Hilton Head, South Carolina. Archived from the original (PDF) on 13 August 2010.
  3. Stafford, Jesse (Spring 2014). "How a Quadcopter works | Clay Allen". University of Alaska, Fairbanks. Retrieved 2015-01-20.
  4. Leishman, J.G. (2000). Principles of Helicopter Aerodynamics. New York, NY: Cambridge University Press. ISBN 9780521858601.
  5. Anderson, S.B. (1997). "Historical Overview of V/STOL Aircraft Technology". NASA Technical Memorandum 81280.
  6. "Quadrotor". Archived from the original on 27 December 2014. Retrieved 29 December 2014.
  7. Andrew Hobden. "Quadcopters: Yaw". hoverbear.org. Retrieved 3 April 2017.
  8. Uriah (2010-04-13). "Wyvern Quadrotor Helicopter". Retrieved 29 December 2014.
  9. Ferdinand Kickinger (2016-04-30), 151min30s FPV with Copter, retrieved 2018-08-26
  10. SPK Drones. How Quadcopters Fly.
  11. McNabb, Miriam (February 2018). US Manufacturer Harris Aerial Launches New Hybrid Gas Electric Drone. Dronelife
  12. Young, Warren R. (1982). The Helicopters. The Epic of Flight. Chicago: Time-Life Books. p. 28. ISBN 978-0-8094-3350-6.
  13. "A Successful French Helicopter" Flight 24 January 1924 p47
  14. "1956 - 1564 - Flight Archive". flightglobal.com. Retrieved 13 March 2015.
  15. "Patent US3261407 - Helicopter rotor system". google.com. Retrieved 13 March 2015.
  16. Inan, Esin; Kiris, Ahmet (2007-01-20). The Seventh International Conference on Vibration Problems ICOVP 2005. ISBN 9781402054013. Retrieved 13 March 2015.
  17. "Airbus on track to fly its electric aerial taxi in 2018".
  18. "Illumin - The Quadrotor's Coming of Age". Retrieved 29 December 2014.
  19. Büchi, Roland (2011). Fascination Quadrocopter. ISBN 978-3-8423-6731-9.
  20. Pounds, P.; Mahony, R.; Corke, P. (December 2006). "Modelling and Control of a Quad-Rotor Robot" (PDF). In the Proceedings of the Australasian Conference on Robotics and Automation. Auckland, New Zealand.
  21. "How-To: Quadrocopter based on Arduino". MAKE. Archived from the original on 11 December 2011. Retrieved 29 December 2014.
  22. "FrontPage - UAVP-NG - The Open Source Next Generation Multicopter". Retrieved 29 December 2014.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.