Adaptive cruise control

Adaptive cruise control is a type of advanced driver-assistance system for road vehicles that automatically adjusts the vehicle speed to maintain a safe distance from vehicles ahead. As of 2019, it is also called by 20 unique names that describe that basic functionality. This is also known as Dynamic cruise control.
Control is based on sensor information from sensors. Such systems may use a radar, laser sensor or a camera setup allowing the vehicle to brake when it detects the car is approaching another vehicle ahead, then accelerate when traffic allows it to.
ACC technology is regarded as a key component of future generations of intelligent cars. The technology enhances passenger safety and convenience as well as increasing road capacity by maintaining optimal separation between vehicles and reducing driver errors. Vehicles with autonomous cruise control are considered a Level 1 autonomous car, as defined by SAE International. When combined with another driver assist feature such as lane centering, the vehicle is considered a Level 2 autonomous car.

Consumer use

Adaptive cruise control does not provide full autonomy: the system only provides some help to the driver, but does not drive the car by itself. For example, the driver is able to set the cruise control to 55 mph, if the car while traveling that speed catches up to another vehicle going only 45 mph, the ACC will cause the car to automatically brake and maintain a safe distance behind the vehicle in front, and will maintain that distance until the road opens up again and the car can safely return to the initially set speed of 55 mph.

Pricing

Given the fact that ACC is considered a key component of future generations of intelligent cars, and the fact that it can increase comfort and safety on longer drives, ACC systems cost anywhere between $500 and $2500, depending on the type of ACC, as well as the model of the car.

History

1992: Mitsubishi Motors was the first to offer a lidar-based distance detection system on the Japanese market Debonair. Marketed as "distance warning", this system warns the driver, without influencing throttle, brakes, or gearshifting.
1995: Mitsubishi Diamante introduced laser "Preview Distance Control". This system controlled speed through throttle control and downshifting, but could not apply the brakes.
1997: Toyota offered a "laser adaptive cruise control" system on the Japanese market Celsior. It controlled speed through throttle control and downshifting, but could not apply the brakes.
1999: Mercedes introduced "Distronic", the first radar-assisted ACC, on the Mercedes-Benz S-Class and the CL-Class.
1999: Jaguar began offering a radar-based ACC system on the Jaguar XK.
1999: Nissan introduced laser ACC on the Japanese market Nissan Cima.
1999: Subaru introduced world's first camera-based ACC on the Japanese-market Subaru Legacy Lancaster.
2000: BMW introduced radar "Active Cruise Control" in Europe on the BMW 7 Series - E38.
2000: Toyota was the first to bring laser ACC to the US market in late 2000, with the LS 430 Dynamic Laser Cruise Control system.
2000: Toyota's laser ACC system added "brake control", that also applies brakes.
2001: Infiniti introduced laser "Intelligent Cruise Control" on the 2002 Infiniti Q45 Third generation F50 and 2002 Infiniti QX4.
2001: Renault introduced ACC on the Renault Vel Satis
2002: Lancia introduced radar ACC on the Lancia Thesis
2002: Volkswagen introduced radar ACC, manufactured by Autocruise, on the Volkswagen Phaeton.
2002: Audi introduced radar ACC on the Audi A8 in late 2002
2003: Cadillac introduced radar ACC on the Cadillac XLR.
2003: Toyota shifted from laser to radar ACC on the Celsior. The first Lexus Dynamic Radar Cruise Control and a radar-guided pre-collision system appeared on the Lexus LS US market facelift.
2004: Toyota added "low-speed tracking mode" to the radar ACC on the Crown Majesta. The low-speed tracking mode was a second mode that would warn the driver and provide braking if the car ahead stopped; it could stop the car, but would then deactivate.
2005: In the United States, Acura introduced radar ACC integrated with a Collision avoidance system in the model year 2006 Acura RL.
2005: Mercedes-Benz S-Class upgraded ACC to completely halt the car if necessary.
2008: Lincoln introduced radar ACC on the 2009 Lincoln MKS.
2008: SsangYong Motor Company introduced radar "Active Cruise Control" on the SsangYong Chairman
2008: Volkswagen Passat CC, B6 and Touareg GP. The ACC system was updated to support a full auto stop and added Front Assist function to prevent collisions working separately of ACC. Front Assist cannot brake automatically, it only increases the pressure in the brake system and warns the driver.
2008: Volkswagen Golf 6 introduced ACC with lidar.
2009: Hyundai introduced radar ACC on Hyundai Equus in Korean market.
2009: ACC and CMBS also became available as optional feature for the 2010 Acura MDX Mid Model Change and the newly introduced model year 2010 Acura ZDX.
2010: Ford debuted its first ACC on the sixth generation Ford Taurus
2010: Audi introduced a GPS-guided radar ACC on Audi A8#D4
2010: Volkswagen Passat B7, CC. Update of ACC and updated Front Assist. Introduced emergency braking, named "City". The car could brake automatically to prevent a collision.
2010: Jeep introduced ACC on the 2011 Jeep Grand Cherokee
2012: Volkswagen made ACC standard on the Volkswagen Golf MK7 SE and above.
2013: Mercedes introduced "Distronic Plus with Steering Assist" on the Mercedes-Benz S-Class
2013: BMW introduced Active Cruise Control with Traffic Jam Assistant.
2014: Chrysler introduced full speed range radar "Adaptive Cruise Control with Stop+" on the 2015 Chrysler 200.
2014: Tesla Motors introduced autopilot feature to Model S cars, enabling semi-autonomous cruise control.
2015: Ford introduced the first pickup truck with ACC on the 2015 Ford F150.
2015: Honda introduced its European CR-V 2015 with predictive cruise control.
2015: Volvo began offering ACC on all its models.
2017: Cadillac introduced its Super Cruise semi-autonomous feature in the model year 2018 CT6. The system used onboard radar and cameras along with lidar mapping data, allowing the driver to go hands-free on limited-access highways.
2017: Toyota introduced its safety sense on all models as a standard feature. Toyota Safety Sense P includes DRCC that uses a front-grille-mounted radar and a forward-facing camera that is designed to detect a vehicle in front and automatically adjust the vehicle's speed to help maintain a pre-set distance behind a vehicle ahead.
Types

-based systems work using LIDAR, allowing laser-based ACC to provide the largest detection distance as well as the best accuracy of all ACC systems. However, laser-based systems do not detect and track vehicles as reliably in adverse weather conditions due to the fact that fog, or water particles in the air may absorb and or redirect the light emitted from the laser, through absorption, scattering, and reflection. Laser based ACC systems also have a more difficult time tracking dirty vehicles. Laser-based sensors must be exposed, the sensor is typically found in the lower grille, offset to one side.
Radar-based sensors work by emitting a radio wave at a frequency of either 24GHz or 77GHz. As these signals are emitted, the car computes how long it takes for the signal to return, thus finding out how far away a vehicle may be in front of it. Due to the widely distributed beam, radar ACC systems allow for a much wider field of view while still being able to provide accurate measurements of 160+ meters. These radar systems can be hidden behind plastic fascias; however, the fascias may look different from a vehicle without the feature. For example, Mercedes-Benz packages the radar behind the upper grille in the center and behind a solid plastic panel that has painted slats to simulate the look of the rest of the grille.
Single radar systems are the most common. Systems involving multiple sensors use either two similar hardware sensors like the 2010 Audi A8 or the 2010 Volkswagen Touareg, or one central long range radar coupled with two short radar sensors placed on the corners of the vehicle like the BMW 5 and 6 series.
A more recent development is the binocular computer vision system, such as that introduced to the US market in model year 2013 by Subaru. These systems have front-facing video cameras mounted on either side of the rearview mirror and use digital processing to extract depth information from the parallax between the two cameras' views. Due to the fact that there are video cameras, this type of ACC is able to reliably determine shape and classification of objects in front of the vehicle, and are also able to specifically detect when a vehicle in front is braking. As of now, this type of ACC is more widely used for lane centering.

Assisting systems

Radar-based ACC is often sold together with a precrash system, which warns the driver and/or provides brake support if there is a high risk of a collision. Also in certain cars, it is incorporated with a lane maintaining system which provides a power steering assist to reduce steering input burden on corners when the cruise control system is activated.

Multi-sensor systems

Systems with multiple sensors can practice sensor fusion to integrate the data to improve safety and/or driving experience. GPS data can inform the system of geographic features such as a freeway offramp. A camera system could notice driver behavior such as brake lights and/or a turn signal. This could allow the following car to interpret a turn signal by an exit as not requiring the following car to slow down, as the leading car will exit. Multi-sensor systems could also take note of traffic signs/signals and not, e.g., violate a red light while following a vehicle that crossed before the signal changed.