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Radio control (often abbreviated to RC) is the use of
The idea of controlling unmanned vehicles (for the most part in an attempt to improve the accuracy of torpedoes for military purposes) predates the invention of radio. The latter half of the 1800s saw development of many such devices, connected to an operator by wires, including the first practical application invented by German engineer Werner von Siemens in 1870.
Getting rid of the wires via using a new wireless technology, radio, appeared in the late 1890s. In 1897 British engineer Ernest Wilson and C. J. Evans patented a radio controlled torpedo or demonstrated remote radio control boats on the Thames river (accounts of what they did vary). At an 1898 exhibition at Madison Square Garden, Nikola Tesla demonstrated a small unmanned boat that used a coherer based radio control. With an eye towards selling the idea to the US government as a torpedo, Tesla's 1898 patent included a clockwork frequency changer so an enemy couldn't take control of the device.
In 1903, the Spanish engineer Leonardo Torres y Quevedo introduced a radio based control system called the "''Telekino''" at the Paris Academy of Science. In the same year, he obtained a patent in France, Spain, Great Britain, and the United States. It was intended as a way of testing a Astra-Torres airship, dirigible of his own design without risking human lives. To avoid the expense of conceivably crashing his airship prototype he built his demonstration device into a boat. Unlike the previous systems, which carried out actions of the 'on/off' type, Torres device was able to memorize the signals received to execute the operations on its own and could carry out to 19 different orders. In 1906, in the presence of an audience which included the King of Spain, Torres demonstrated the invention in the Port of Bilbao, guiding a boat from the shore with people on board. Later, he would try to apply the Telekino to projectiles and torpedoes but had to abandon the project for lack of financing.
In 1904, ''Bat'', a Windermere steam launch, was controlled using experimental radio control by its inventor, [Jack Kitchen]. In 1909 the French inventor Gabet demonstrated what he called his "''Torpille Radio-Automatique''", a radio-controlled torpedo.
In 1917, Archibald Low as head of the secret Royal Flying Corps, RFC experimental works at Feltham, was the first person to use radio control successfully on an aircraft, an British unmanned aerial vehicles of World War I#1917 Aerial Target, "Aerial Target". It was "piloted" from the ground by future world aerial speed record holder Henry Segrave. Low's systems encoded the command transmissions as a countermeasure to prevent enemy intervention. By 1918 the secret British unmanned aerial vehicles of World War I#The Royal Navy's D.C.B. Section, D.C.B. Section of the Royal Navy's Signals School, Portsmouth under the command of Eric Gascoigne Robinson, Eric Robinson V.C. used a variant of the Aerial Target’s radio control system to control from ‘mother’ aircraft different types of naval vessels including a submarine.UK National Archives ADM 1/8539/253 Capabilities of distantly controlled boats. Reports of trials at Dover 28 - 31 May 1918
During World War I American inventor John Hays Hammond, Jr. developed many techniques used in subsequent radio control including developing remote controlled torpedoes, ships, anti-jamming systems and even a system allowing his remote-controlled ship targeting an enemy ship's searchlights. In 1922 he installed radio control gear on the obsolete US Navy battleship USS Iowa (BB-4), USS ''Iowa'' so it could be used as a target ship (sunk in gunnery exercise in March 1923).
The Soviet Red Army used remotely controlled teletanks during the 1930s in the Winter War against Finland and fielded at least two teletank battalions at the beginning of the Great Patriotic War. A teletank is controlled by radio from a control tank at a distance of 500–1,500 m, the two constituting a ''telemechanical group''. There were also remotely controlled cutters and experimental remotely controlled planes in the Red Army.
The United Kingdom's World War One development of their radio-controlled 1917 'Aerial Target' (AT) and 1918 'Distant Control Boat' (DCB) using Low's control systems led eventually to their 1930s fleet of de Havilland Tiger Moth, "Queen Bee". This was a remotely controlled unmanned version of the de Havilland "Tiger Moth" aircraft for Naval fleet, Navy fleet gunnery firing practice. The "Queen Bee" was superseded by the similarly named ''Airspeed Queen Wasp, Queen Wasp'', a purpose-built, target aircraft of higher performance.
The first general use of radio control systems in models started in the early 1950s with single-channel self-built equipment; commercial equipment came later. The advent of transistors greatly reduced the battery requirements, since the current requirements at low voltage were greatly reduced and the high voltage battery was eliminated. In both tube and early transistor sets the model's control surfaces were usually operated by an electromagnetic 'Servo (radio control)#Escapements, escapement' controlling the stored energy in a rubber-band loop, allowing simple on/off rudder control (right, left, and neutral) and sometimes other functions such as motor speed.
Crystal oscillator, Crystal-controlled superheterodyne receivers with better selectivity and stability made control equipment more capable and at lower cost. Multi-channel developments were of particular use to aircraft, which really needed a minimum of three control dimensions (yaw, pitch and motor speed), as opposed to boats, which required only two or one.
As the electronics revolution took off, single-signal channel circuit design became redundant, and instead radios provided proportionally coded signal streams which a servomechanism could interpret, using pulse-width modulation (PWM).
More recently, high-end hobby systems using pulse-code modulation (PCM) features have come on the market that provide a computerized Digital data, digital bit-stream signal to the receiving device, instead of the earlier PWM encoding type. However, even with this coding, loss of transmission during flight has become more common, in part because of the ever more wireless society. Some more modern FM-signal receivers that still use "PWM" encoding instead can, thanks to the use of more advanced computer chips in them, be made to lock onto and use the individual signal characteristics of a particular PWM-type RC transmitter's emissions alone, ''without'' needing a special "code" transmitted along with the control information as PCM encoding has always required.
In the early 21st century, 2.4 gigahertz spread spectrum RC control systems have become increasingly utilized in control of model vehicles and aircraft. Now, these 2.4 GHz systems are being made by most radio manufacturers. These radio systems range in price from a couple thousand dollars, all the way down to under US$30 for some. Some manufacturers even offer conversion kits for older digital 72 MHz or 35 MHz receivers and radios. As the emerging multitude of 2.4 GHz band spread spectrum RC systems usually use a Frequency agility, "frequency-agile" mode of operations, like Frequency-hopping spread spectrum, FHSS that do not stay on one set frequency any longer while in use, the older "exclusive use" provisions at model flying sites needed for VHF-band RC control systems' frequency control, for VHF-band RC systems that only used one set frequency unless serviced to change it, are not as mandatory as before.
Remote control military applications are typically not radio control in the direct sense, directly operating flight control surfaces and propulsion power settings, but instead take the form of instructions sent to a completely Wiktionary:autonomy, autonomous, computerized autopilot, automatic pilot. Instead of a "turn left" signal that is applied until the aircraft is flying in the right direction, the system sends a single instruction that says "fly to this point".
Some of the most outstanding examples of remote radio control of a vehicle are the Mars Exploration Rovers such as Mars Pathfinder, Sojourner.
control signal
In telecommunication, signaling is the use of signals for controlling communications. This may constitute an information exchange concerning the establishment and control of a telecommunication circuit and the management of the network.
Classif ...
s transmitted by radio
Radio is the technology of signaling and communicating using radio waves. Radio waves are electromagnetic waves of frequency between 30 hertz (Hz) and 300 gigahertz (GHz). They are generated by an electronic device called a transmit ...
to remotely control a device. Examples of simple radio control systems are garage door opener
A garage door opener is a motorized device that opens and closes a garage door controlled by switches on the garage wall. Most also include a handheld radio remote control carried by the owner, which can be used to open and close the door from a ...
s and keyless entry system
A remote keyless system (RKS), also known as keyless entry or remote central locking, is an electronic lock that controls access to a building or vehicle by using an electronic remote control (activated by a handheld device or automatically by ...
s for vehicles, in which a small handheld radio transmitter unlocks or opens doors. Radio control is also used for control of model vehicles from a hand-held radio transmitter
In electronics and telecommunications, a radio transmitter or just transmitter is an electronic device which produces radio waves with an antenna. The transmitter itself generates a radio frequency alternating current, which is applied to the ...
. Industrial
Industrial may refer to:
Industry
* Industrial archaeology, the study of the history of the industry
* Industrial engineering, engineering dealing with the optimization of complex industrial processes or systems
* Industrial city, a city dominate ...
, military
A military, also known collectively as armed forces, is a heavily armed, highly organized force primarily intended for warfare. It is typically authorized and maintained by a sovereign state, with its members identifiable by their distinct ...
, and scientific research
The scientific method is an empirical method for acquiring knowledge that has characterized the development of science since at least the 17th century (with notable practitioners in previous centuries; see the article history of scientific m ...
organizations make use of radio-controlled vehicles as well. A rapidly growing application is control of unmanned aerial vehicles (UAVs or drones) for both civilian and military uses, although these have more sophisticated control systems than traditional applications.
History
The idea of controlling unmanned vehicles (for the most part in an attempt to improve the accuracy of torpedoes for military purposes) predates the invention of radio. The latter half of the 1800s saw development of many such devices, connected to an operator by wires, including the first practical application invented by German engineer Werner von Siemens in 1870.
Getting rid of the wires via using a new wireless technology, radio, appeared in the late 1890s. In 1897 British engineer Ernest Wilson and C. J. Evans patented a radio controlled torpedo or demonstrated remote radio control boats on the Thames river (accounts of what they did vary). At an 1898 exhibition at Madison Square Garden, Nikola Tesla demonstrated a small unmanned boat that used a coherer based radio control. With an eye towards selling the idea to the US government as a torpedo, Tesla's 1898 patent included a clockwork frequency changer so an enemy couldn't take control of the device.
In 1903, the Spanish engineer Leonardo Torres y Quevedo introduced a radio based control system called the "''Telekino''" at the Paris Academy of Science. In the same year, he obtained a patent in France, Spain, Great Britain, and the United States. It was intended as a way of testing a Astra-Torres airship, dirigible of his own design without risking human lives. To avoid the expense of conceivably crashing his airship prototype he built his demonstration device into a boat. Unlike the previous systems, which carried out actions of the 'on/off' type, Torres device was able to memorize the signals received to execute the operations on its own and could carry out to 19 different orders. In 1906, in the presence of an audience which included the King of Spain, Torres demonstrated the invention in the Port of Bilbao, guiding a boat from the shore with people on board. Later, he would try to apply the Telekino to projectiles and torpedoes but had to abandon the project for lack of financing.
In 1904, ''Bat'', a Windermere steam launch, was controlled using experimental radio control by its inventor, [Jack Kitchen]. In 1909 the French inventor Gabet demonstrated what he called his "''Torpille Radio-Automatique''", a radio-controlled torpedo.
In 1917, Archibald Low as head of the secret Royal Flying Corps, RFC experimental works at Feltham, was the first person to use radio control successfully on an aircraft, an British unmanned aerial vehicles of World War I#1917 Aerial Target, "Aerial Target". It was "piloted" from the ground by future world aerial speed record holder Henry Segrave. Low's systems encoded the command transmissions as a countermeasure to prevent enemy intervention. By 1918 the secret British unmanned aerial vehicles of World War I#The Royal Navy's D.C.B. Section, D.C.B. Section of the Royal Navy's Signals School, Portsmouth under the command of Eric Gascoigne Robinson, Eric Robinson V.C. used a variant of the Aerial Target’s radio control system to control from ‘mother’ aircraft different types of naval vessels including a submarine.UK National Archives ADM 1/8539/253 Capabilities of distantly controlled boats. Reports of trials at Dover 28 - 31 May 1918
During World War I American inventor John Hays Hammond, Jr. developed many techniques used in subsequent radio control including developing remote controlled torpedoes, ships, anti-jamming systems and even a system allowing his remote-controlled ship targeting an enemy ship's searchlights. In 1922 he installed radio control gear on the obsolete US Navy battleship USS Iowa (BB-4), USS ''Iowa'' so it could be used as a target ship (sunk in gunnery exercise in March 1923).
The Soviet Red Army used remotely controlled teletanks during the 1930s in the Winter War against Finland and fielded at least two teletank battalions at the beginning of the Great Patriotic War. A teletank is controlled by radio from a control tank at a distance of 500–1,500 m, the two constituting a ''telemechanical group''. There were also remotely controlled cutters and experimental remotely controlled planes in the Red Army.
The United Kingdom's World War One development of their radio-controlled 1917 'Aerial Target' (AT) and 1918 'Distant Control Boat' (DCB) using Low's control systems led eventually to their 1930s fleet of de Havilland Tiger Moth, "Queen Bee". This was a remotely controlled unmanned version of the de Havilland "Tiger Moth" aircraft for Naval fleet, Navy fleet gunnery firing practice. The "Queen Bee" was superseded by the similarly named ''Airspeed Queen Wasp, Queen Wasp'', a purpose-built, target aircraft of higher performance.
Second World War
Radio control was further developed during World War II, primarily by the Germany, Germans who used it in a number of missile projects. Their main effort was the development of radio-controlled missiles and glide bombs for use against shipping, a target otherwise both difficult and dangerous to attack. However, by the end of the war, the ''Luftwaffe'' was having similar problems attacking Allied bombers and developed a number of radio command guided Surface-to-air missile, anti-aircraft missiles, none of which saw service. The effectiveness of the Luftwaffe's systems, primarily comprising the series of Telefunken ''Funk-Gerät'' (or FuG) 203 ''Kehl'' twin-axis, single joystick-equipped transmitters mounted in the deploying aircraft, and Telefunken's companion FuG 230 ''Straßburg'' receiver placed in the ordnance to be controlled during deployment and used by both the Fritz X unpowered, armored anti-ship bomb, and the powered Henschel Hs 293 guided bomb, was greatly reduced by United Kingdom, British efforts to jam their radio signals, eventually with American assistance. After initial successes, the British launched a number of commando raids to collect the missile radio sets. Jammers were then installed on British ships, and the weapons basically "stopped working". The German development teams then turned to Wire-guided missile, wire guidance once they realized what was going on, but the systems were not ready for deployment until the war had already moved to France. The German ''Kriegsmarine'' operated ''FL-Boote'' (''ferngelenkte Sprengboote'') which were radio controlled motor boats filled with explosives to attack enemy shipping from 1944. Both the British and US also developed radio control systems for similar tasks, to avoid the huge anti-aircraft batteries set up around German targets. However, no system proved usable in practice, and the one major US effort, ''Operation Aphrodite'', proved to be far more dangerous to its users than to the target. The American Azon guided free-fall ordnance, however, proved useful in both the European Theater of World War II, European and CBI Theaters of World War II. Radio control systems of this era were generally electromechanical in nature, using small metal "fingers" or "reed receiver, reeds" with different resonance, resonant frequencies each of which would operate one of a number of different relays when a particular frequency was received. The relays would in turn then activate various actuators acting on the control surfaces of the missile. The controller's radio transmitter would transmit the different frequencies in response to the movements of a control stick; these were typically on/off signals. The radio gear used to control the rudder function on the American-developed Azon guided ordnance, however, was a fully proportional control, with the "ailerons", solely under the control of an on-board gyroscope, serving merely to keep the ordnance from rolling. These systems were widely used until the 1960s, when the increasing use of solid state (electronics), solid state systems greatly simplified radio control. The electromechanical systems using reed relays were replaced by similar electronic ones, and the continued miniaturization of electronics allowed more signals, referred to as ''control channels'', to be packed into the same package. While early control systems might have two or three channels using amplitude modulation, modern systems include 20 or more using frequency modulation.Radio-controlled models
The first general use of radio control systems in models started in the early 1950s with single-channel self-built equipment; commercial equipment came later. The advent of transistors greatly reduced the battery requirements, since the current requirements at low voltage were greatly reduced and the high voltage battery was eliminated. In both tube and early transistor sets the model's control surfaces were usually operated by an electromagnetic 'Servo (radio control)#Escapements, escapement' controlling the stored energy in a rubber-band loop, allowing simple on/off rudder control (right, left, and neutral) and sometimes other functions such as motor speed.
Crystal oscillator, Crystal-controlled superheterodyne receivers with better selectivity and stability made control equipment more capable and at lower cost. Multi-channel developments were of particular use to aircraft, which really needed a minimum of three control dimensions (yaw, pitch and motor speed), as opposed to boats, which required only two or one.
As the electronics revolution took off, single-signal channel circuit design became redundant, and instead radios provided proportionally coded signal streams which a servomechanism could interpret, using pulse-width modulation (PWM).
More recently, high-end hobby systems using pulse-code modulation (PCM) features have come on the market that provide a computerized Digital data, digital bit-stream signal to the receiving device, instead of the earlier PWM encoding type. However, even with this coding, loss of transmission during flight has become more common, in part because of the ever more wireless society. Some more modern FM-signal receivers that still use "PWM" encoding instead can, thanks to the use of more advanced computer chips in them, be made to lock onto and use the individual signal characteristics of a particular PWM-type RC transmitter's emissions alone, ''without'' needing a special "code" transmitted along with the control information as PCM encoding has always required.
In the early 21st century, 2.4 gigahertz spread spectrum RC control systems have become increasingly utilized in control of model vehicles and aircraft. Now, these 2.4 GHz systems are being made by most radio manufacturers. These radio systems range in price from a couple thousand dollars, all the way down to under US$30 for some. Some manufacturers even offer conversion kits for older digital 72 MHz or 35 MHz receivers and radios. As the emerging multitude of 2.4 GHz band spread spectrum RC systems usually use a Frequency agility, "frequency-agile" mode of operations, like Frequency-hopping spread spectrum, FHSS that do not stay on one set frequency any longer while in use, the older "exclusive use" provisions at model flying sites needed for VHF-band RC control systems' frequency control, for VHF-band RC systems that only used one set frequency unless serviced to change it, are not as mandatory as before.
Modern military and aerospace applications
Remote control military applications are typically not radio control in the direct sense, directly operating flight control surfaces and propulsion power settings, but instead take the form of instructions sent to a completely Wiktionary:autonomy, autonomous, computerized autopilot, automatic pilot. Instead of a "turn left" signal that is applied until the aircraft is flying in the right direction, the system sends a single instruction that says "fly to this point".
Some of the most outstanding examples of remote radio control of a vehicle are the Mars Exploration Rovers such as Mars Pathfinder, Sojourner.
Industrial radio remote control
Today radio control is used in industry for such devices as overhead Crane (machine), cranes and switchyard locomotives. Radio-controlled Remote operation, teleoperators are used for such purposes as inspections, and special vehicles for disarming of bombs. Some remotely controlled devices are loosely called robots, but are more properly categorized as teleoperators since they do not operate autonomously, but only under control of a human operator. An industrial radio remote control can either be operated by a person, or by a computer control system in a machine to machine (M2M) mode. For example, an automated warehouse may use a radio-controlled crane that is operated by a computer to retrieve a particular item. Industrial radio controls for some applications, such as lifting machinery, are required to be of a fail-safe design in many jurisdictions. Industrial remote controls work differently from most consumer products. When the receiver receives the radio signal which the transmitter sent, it checks it so that it is the correct frequency and that any security codes match. Once the verification is complete, the receiver sends an instruction to a relay which is activated. The relay activates a function in the application corresponding to the transmitters button. This could be to engage an electrical directional motor in an overhead crane. In a receiver there are usually several relays, and in something as complex as an overhead crane, perhaps up to 12 or more relays are required to control all directions. In a receiver which opens a gate, two relays are often sufficient. Industrial remote controls are getting more and higher safety requirements. For example: a remote control may not lose the safety functionality in case of malfunction. This can be avoided by using redundant relays with forced contacts.See also
* Precision-guided munition * Radio-controlled airplane * Radio-controlled boat * Radio-controlled car * Radio-controlled helicopter * Remote control * Remote control vehicle * Telecommand * TeletankNotes and references
Further reading
* Bill Yenne, ''Attack of the drones: a history of unmanned aerial combat'', Zenith Imprint, 2004, * Laurence R. Newcome ''Unmanned aviation: a brief history of unmanned aerial vehicles'', AIAA, 2004, , {{DEFAULTSORT:Radio Control Radio control, pl:Zdalne sterowanie