Cruise control

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Common cruise control icon on dashboards specified by ISO-7000-2047, ISO 2575:2010, and ISO 6727. Another icon exists for the more modern adaptive cruise control, but some cars also use the cruise control icon for the speed limiter function, which has no standard icon. Cruise Control.svg
Common cruise control icon on dashboards specified by ISO-7000-2047, ISO 2575:2010, and ISO 6727. Another icon exists for the more modern adaptive cruise control, but some cars also use the cruise control icon for the speed limiter function, which has no standard icon.

Cruise control (also known as speed control, cruise command, autocruise, or tempomat) is a system that automatically controls the speed of an automobile. The system is a servomechanism that takes over the car's throttle to maintain a steady speed set by the driver.

Contents

History

Cruise command push button on the left of the dashboard of a 1967 AMC Ambassador 1967 Ambassador 990 4-d yellow Miami 15.jpg
Cruise command push button on the left of the dashboard of a 1967 AMC Ambassador
Cruise control on a Citroen Xsara Cruise control Citroen Xsara.jpg
Cruise control on a Citroën Xsara
Cruise control on a 2000 Jeep Grand Cherokee steering wheel 2000 Jeep Steering Wheel.jpg
Cruise control on a 2000 Jeep Grand Cherokee steering wheel

Speed control existed in early automobiles such as the Wilson-Pilcher in the early 1900s. They had a lever on the steering column that could be used to set the speed to be maintained by the engine. [1] In 1908, the Peerless included a governor to keep the speed of the engine through an extra throttle lever on the steering wheel. [2] Peerless successfully used a flyball governor. [3] They advertised their system as being able to "maintain speed whether uphill or down."

A governor was used by James Watt and Matthew Boulton in 1788 to control steam engines, but the use of governors dates at least back to the 17th century. On an engine, the governor uses centrifugal force to adjust the throttle position to adapt the engine's speed to different loads (e.g., when going up a hill).

Modern cruise control (also known as a speedostat or tempomat) was invented in 1948 by the blind inventor and mechanical engineer Ralph Teetor. [4] [5] He came up with the idea due to being frustrated by his driver's habit of speeding up and slowing down as he talked.

A more significant factor in developing cruise control was the 35 mph (56 km/h) speed limit imposed in the United States during World War II to reduce gasoline use and tire wear. [5] A mechanism controlled by the driver provided resistance to further pressure on the accelerator pedal when the vehicle reached the desired speed. [5] Teetor's idea of a dashboard speed selector with a mechanism connected to the driveshaft and a device able to push against the gas pedal was patented in 1950. [5] He added a speed lock capability that maintained the car's speed until the driver tapped the brake pedal or turned off the system. [5]

A 1955 U.S. patent for a "constant speed regulator" was filed in 1950 by M-Sgt Frank J. Riley. [6] He conceived the device while driving on the Pennsylvania Turnpike and installed his invention in his car in 1948. [7]

Another inventor named Harold Exline, working independently of Riley, also invented a type of cruise control that he first installed on his car and friends' cars. Exline filed a U.S. patent for a "vacuum powered throttle control with electrically controlled air valve" in 1951, which was granted in 1956. [8] Despite these patents, Riley, Exline, and subsequent patent holders were not able to collect royalties for any cruise control inventions.

The first car with Teetor's "speedostat" system was the 1958 Chrysler Imperial (called "auto-pilot"), using a speed control dial on the dashboard. [9] This system calculated ground speed from the rotating speedometer cable and used a bi-directional screw-drive electric motor to vary the throttle position as needed. Cadillac soon renamed and marketed the device as "cruise control." [5]

In 1965, American Motors Corporation (AMC) introduced a low-priced automatic speed control for its large-sized cars with automatic transmissions. [10] The AMC "cruise command" unit was actuated through a push-button on the dashboard once the car's desired speed was reached. The throttle position was automatically adjusted by a vacuum control that opened and closed the throttle based on input from the speedometer cable rather than through an adjustable control on the dashboard. [10] [11] The unit would shut off anytime the brakes were applied.

Daniel Aaron Wisner invented an "automotive electronic cruise control" in 1968 as an engineer for RCA's Industrial and Automation Systems Division in Plymouth, Michigan. His invention is described in two patents filed that year (US patents 3570622 and 3511329), with the second introducing digital memory, and was the first electronic device that controlled a car. [12]

Due to the 1973 oil crisis and rising fuel prices, the device became more popular in the U.S. [13] "Cruise control can save gas by avoiding surges that expel fuel" while driving at steady speeds. [13] In 1974, AMC, GM, and Chrysler priced the option at $60 to $70, while Ford charged $103. [13]

In the late 1980s, an integrated circuit for Wisner's design for electronic cruise control was finally commercially developed by Motorola as the MC14460 Automotive Speed Control Processor in CMOS. [14] The advantage of electronic speed control over its mechanical predecessor was that it could be integrated with electronic accident avoidance and engine management systems.

Operation

Cruise control unit in the speedometer-cable and vacuum valve Tempomat Cruise Control IMG 20170712 182317674.jpg
Cruise control unit in the speedometer-cable and vacuum valve
Cruise control throttle servo Tempomat Cruise Control IMG 20170712 182537172.jpg
Cruise control throttle servo

The driver must manually bring the vehicle up to speed and use a button to set the cruise control to the current speed.

The cruise control takes its speed signal from a rotating driveshaft, speedometer cable, wheel speed sensor from the engine's RPM, or internal speed pulses produced electronically by the vehicle. Most systems do not allow the use of the cruise control below a certain speed - typically around 25 or 30 mph (40 or 48 km/h). The vehicle will maintain the desired speed by pulling the throttle cable with a solenoid, a vacuum-driven servomechanism, or by using the electronic systems built into the vehicle (fully electronic) if it uses a 'drive-by-wire' system.

All cruise control systems must have the capability to be turned off explicitly and automatically when the driver depresses the brake pedal and often also the clutch. Cruise control systems frequently include a memory feature to resume the set speed after braking and a coast feature to reduce the set speed without braking. When the cruise control is engaged, the throttle can still accelerate the car, but once the pedal is released, it will slow down the vehicle until it reaches the previously set speed.

On the latest vehicles fitted with electronic throttle control, cruise control can be integrated into the vehicle's engine management system. Modern "adaptive" systems include the ability to automatically reduce speed when the distance to a car in front, or the speed limit, decreases.

The cruise control systems of some vehicles incorporate a "speed limiter" function, which will not allow the vehicle to accelerate beyond a preset maximum; this can usually be overridden by fully depressing the accelerator pedal. Most systems will prevent the vehicle from increasing engine speed to accelerate beyond the chosen speed. However, they will not apply the brakes in the event of overspeeding downhill, nor stop the car from going faster than the selected speed even with the engine just idling.

Cruise control is less flexible on vehicles with a manual transmission because depressing the clutch pedal and shifting gears usually disengages the cruise control. The "resume" feature has to be used each time after selecting the new gear and releasing the clutch. Therefore, cruise control is most beneficial at motorway/highway speeds when top gear is used virtually all the time. The speed limiter function, however, does not have this problem.

Advantages and disadvantages

Some advantages of cruise control include: [15]

However, when misused, cruise control can lead to accidents due to several factors, such as: [15]

Adaptive cruise control

Adaptive cruise control (ACC) steering wheel switch on Nissan Note e-Power. The bottom-left button is the adaptive cruise control symbol defined in ISO 2575:2010 and ISO 7000-2580 standards and used in various vehicles. NOTE e-POWER SteeringSwitch.png
Adaptive cruise control (ACC) steering wheel switch on Nissan Note e-Power. The bottom-left button is the adaptive cruise control symbol defined in ISO 2575:2010 and ISO 7000-2580 standards and used in various vehicles.

Some modern vehicles have adaptive cruise control (ACC) systems, a general term meaning improved cruise control. Dynamic set speed systems use the GPS position of speed limit signs from a database. Many systems also incorporate cameras, lasers, and millimeter-wave radar equipment to determine how close a vehicle is to others or other objects on the roadway. [20]

The technologies can be set to maintain a distance from vehicles in front of the car; the system will automatically slow down based on the vehicles in front or continue to keep the set speed. [20] Some systems cannot detect completely stationary cars or pedestrians, so the driver must always pay attention. Automatic braking systems use either a single or a combination of sensors (radar, lidar, and camera) to allow the vehicle to keep pace with the car it is following, slow when closing in on the vehicle in front, and accelerate to the preset speed when traffic allows. Some systems also feature forward collision warning systems, which warn the driver if a vehicle in frontgiven the speed of both vehiclesgets too close within the preset headway or braking distance.

Vehicles with adaptive cruise control are considered a Level 1 autonomous car, as defined by SAE International. [21]

See also

Related Research Articles

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References

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  6. Constant Speed Regulator. Frank J. Riley. United States Patent US2714880
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  8. Vacuum powered throttle control with electrically controlled air valve. Harold Exline. US Patent 2742123
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