Collision avoidance system

A collision avoidance system (CAS), also known as a pre-crash system, forward collision warning system, or collision mitigation system, is a motorcar safety system designed to prevent or reduce the severity of a collision.[2] In its basic form, a forward collision warning system monitors a vehicle's speed, the speed of the vehicle in front of it, and the distance between the vehicles, so that it can provide a warning to the driver if the vehicles get too close, potentially helping to avoid a crash.[3] Various technologies and sensors that are used include radar (all-weather) and sometimes laser (LIDAR) and cameras (employing image recognition) to detect an imminent crash. GPS sensors can detect fixed dangers such as approaching stop signs through a location database.[2][4][5][6] Pedestrian detection can also be a feature of these types of systems.

Schematic of a collision avoidance system
Nissan Leaf approaching a movable target performing an Autonomous Emergency Braking (AEB) test. The vehicle has AEB Pedestrian, AEB Cyclist, AEB City and AEB Interurban as standard in 2018. Euro NCAP comments AEB interurban has good performance in most of the test scenarios.[1].

Collision avoidance systems scope and definition

Collision avoidance systems range from widespread systems mandatory in some countries, such as autonomous emergency braking (AEB) in the EU, agreements between car makers and safety officials to make crash avoidance systems eventually standard, such as in the United States,[7] to research projects including some manufacturer specific devices.

Advanced emergency braking system

Advanced emergency braking system (AEBS) as defined by UN ECE regulation 131 is considered as: a system which can automatically detect a potential forward collision and activate the vehicle braking system to decelerate the vehicle with the purpose of avoiding or mitigating a collision.[8] UN ECE regulation 152 says deceleration can be 5 metres per second squared.[9]

Once an impending collision is detected, these systems provide a warning to the driver. When the collision becomes imminent, they can take action autonomously without any driver input (by braking or steering or both). Collision avoidance by braking is appropriate at low vehicle speeds (e.g. below 50 km/h (31 mph)), while collision avoidance by steering may be more appropriate at higher vehicle speeds if lanes are clear.[10] Cars with collision avoidance may also be equipped with adaptive cruise control, using the same forward-looking sensors.

AEB differs from forward collision warning: FCW alerts the driver with a warning but does not by itself brake the vehicle.[11]

According to Euro NCAP, AEB has three characteristics:[12]

  • Autonomous: the system acts independently of the driver to avoid or mitigate the accident.
  • Emergency: the system will intervene only in a critical situation.
  • Braking: the system tries to avoid the accident by applying the brakes.

Time-to-collision could be a way to choose which avoidance method (braking or steering) is most appropriate.[13]

Collision avoidance system by steering is a new concept. It is considered by some research projects.[13] Collision avoidance system by steering has some limitations: over-dependence on lane markings, sensor limitations, and interaction between driver and system.[14]

Early approaches and forward collision avoidance system

Early warning systems were attempted as early as the late 1950s. An example is Cadillac, which developed a prototype vehicle named the Cadillac Cyclone which used the new radar technology to detect objects in front of the car with the radar sensors mounted inside "nose cones". It was deemed too costly to manufacture.

The first modern forward collision avoidance system was demonstrated in 1995 by a team of scientists and engineers at Hughes Research Laboratories in Malibu, California. The project was funded by Delco Electronics, and was led by HRL physicist Ross D. Olney. The technology was marketed as Forewarn. The system was radar based  a technology that was readily available at Hughes Electronics, but not commercially elsewhere. A small custom fabricated radar antenna was developed specifically for this automotive application at 77 GHz.[15] In August 1997, the first production laser adaptive cruise control on a Toyota vehicle was introduced on the Celsior model (Japan only).

AEB Commercial and regulatory development

In 2008, AEB was introduced in the British market.[16]

Between 2010 and 2014, Euro-ncap rewarded various constructors whose system had AEB features.

EuroNCAP rewards
Maker Year System
BMW 2014BMW Pedestrian Warning with City Brake Activation
FIAT 2013FIAT City Brake Control
Mitsubishi 2013Mitsubishi Forward Collision Mitigation
Skoda 2013Skoda Front Assistant
Audi 2012Audi Pre Sense Front
Audi 2012Audi Pre Sense Front Plus
VW 2012Volkswagen Front Assist
Ford 2011Ford Active City Stop
Ford 2011Ford Forward Alert
Mercedes-Benz 2011Mercedes-Benz Collision Prevention Assist
VW 2011Volkswagen City Emergency Brake
Honda 2010Honda Collision Mitigation Brake System
Mercedes-Benz 2010Mercedes-Benz PRE-SAFE® Brake
Volvo 2010Volvo City Safety

In the early-2000s, the U.S. National Highway Traffic Safety Administration (NHTSA) studied whether to make frontal collision warning systems and lane departure warning systems mandatory.[17] In 2011, the European Commission investigated the stimulation of "collision mitigation by braking" systems.[18] Mandatory fitting (extra cost option) of Advanced Emergency Braking Systems in commercial vehicles was scheduled to be implemented on 1 November 2013 for new vehicle types and on 1 November 2015 for all new vehicles in the European Union.[19] According to the "impact assessment",[20] this could prevent around 5,000 fatalities and 50,000 serious injuries per year across the EU.

In March 2016, the National Highway Traffic Safety Administration (NHTSA) and the Insurance Institute for Highway Safety announced the manufacturers of 99% of U.S. automobiles had agreed to include automatic emergency braking systems as standard on virtually all new cars sold in the U.S. by 2022.[21] In Europe, there was a related agreement about an AEBS or AEB in 2012.[22] United Nations Economic Commission for Europe (UNECE) has announced that this kind of system will become mandatory for new heavy vehicles starting in 2015.[23] AEBS is regulated by UNECE regulation 131.[24] NHTSA projected that the ensuing accelerated rollout of automatic emergency braking would prevent an estimated 28,000 collisions and 12,000 injuries.[21]

In 2016, 40% of US car model have AEB as an option.[25]

As of January 2017, in the United Kingdom, an estimated 1,586,103 vehicles had AEB. This makes AEB available in 4.3% of the British vehicle fleet.[16]

Australia
AEB shares in Australia (first 100 car models)[26]

In April 2020 AEB is:

  • standard on 66% of new light vehicle models (passenger cars, SUVs and light commercial vehicles) sold in Australia,
  • 10% on higher grade variants only (AEB not available on base variant)
  • 6% as option
  • 16% have no form of AEB[27]
United States
Percent of US vehicles with AEB produced 1 September 2017 to 31 August 2018
(2018 model year)[28]
Percent of US vehicles with standard AEB
(2019 model year)[28]
As reported by manufacturer for light-duty vehicles 3,850 kg (8,500 lb) or less gross vehicle weight As compiled by consumer reports
Tesla100100
Mercedes-Benz9689
Volvo93100
Toyota/Lexus9090
Audi8787
Nissan/Infiniti7854
Volkswagen6950
Honda/Acura6159
Mazda6167
Subaru5750
BMW4982
Maserati/Alfa Romeo270
General Motors240
Hyundai/Genesis1862
Kia1327
Fiat Chrysler100
Porsche817
Ford/Lincoln636
Mitsubishi60
Jaguar Land Rover062

In 2019, 66% of autobrake systems evaluate by the IIHS in 2019 models earn the highest rating of superior for front crash prevention.[29]

Japan

In 2018, 84.6 percent of cars had a kind of AEB in Japan, but certification goal was not meet by each of them.[30]

AEBS as a mandatory feature

From fiscal year 2021, in Japan, all new cars should have an automatic braking systems to prevent accidents, including with a car or pedestrian but not with cyclist, at speeds defined by three international regulations.[30]

From May 2022, in the European Union, by law, new vehicles will have advanced emergency-braking system.[31]

In India, autonomous emergency braking system (AEB) could become mandatory on new cars by 2022.[32]

In the United States, automakers voluntary committed to release automatic emergency braking as a standard feature on all new cars and trucks starting in 2022, in order to provide AEB three years earlier than through a regulatory process.[33]

In Australia where AEB is not yet mandatory, the federal government has suggested in a Regulation Impact Statement (RIS) that car-to-car and pedestrian AEB should be standard on all new models launched from July 2022 and all new vehicles sold from July 2024 like in the European Union.[34]

AEB Benefits

A 2012 study[35] by the Insurance Institute for Highway Safety examined how particular features of crash-avoidance systems affected the number of claims under various forms of insurance coverage. The findings indicate that two crash-avoidance features provide the biggest benefits: (a) autonomous braking that would brake on its own, if the driver does not, to avoid a forward collision, and (b) adaptive headlights that would shift the headlights in the direction the driver steers. They found lane departure systems to be not helpful, and perhaps harmful, at the circa 2012 stage of development. A 2015 Insurance Institute for Highway Safety study found forward collision warning and automatic braking systems reduced rear collisions.[36]

A 2015 study based on European and Australasian data suggests the AEB can decrease rear-end collisions by 38%.[37]

In the 2016 Berlin truck attack, the vehicle used was brought to a stop by its automatic braking system.[38] Collision avoidance features are rapidly making their way into the new vehicle fleet. In a study of police-reported crashes, automatic emergency braking was found to reduce the incidence of rear-end crashes by 39 percent.[39] A 2012 study suggests that if all cars feature the system, it will reduce accidents by up to 27 percent and save up to 8,000 lives per year on European roads.[40][41]

A 2016 US study on trucks, considering 6,000 CAS activations from over 3 million miles and 110,000 hours driving performed with year 2013 technology, find that CAS activations were the result of lead vehicle actions, such as braking, turning, switching lanes, or merging.[42]

In the UK and in the US, third party damages and costs have decreased by 10% and 40% according to some insurances.[11]

Efficiency varies depending on analysis, according to the European Commission:[43]

  • 38% drop in accidents according to Fildes, 2015
  • 9%-20% drop in collision according to Volvo
  • 44% drop according to Ciccino

In April 2019, IIHS/HLDI considered real-world benefits of crash avoidance technologies, based on rates of police-reported crashes and insurance claims. Forward collision warning plus autobrake is associated to a 50% decrease in front to rear crashes and a 56% decrease in front to rear crashes with injuries, while forward collision warning alone is associated with only a 27% decrease in front to rear crashes and an only 20% decrease in front to rear crashes with injuries. The rear automatic braking is considered to have generated a 78% decrease on backing crashes (when combined with rear view camera and parking sensor). However, repair costs with this equipment are an average of US$109 higher due to the sensors being in areas prone to damage.[44]

In Australia, AEB has been found to reduce police-reported crashes by 55 per cent, rear-end crashes by 40 per cent and vehicle occupant trauma by 28 per cent.[45]

A 2020 Italian study suggests AEB reduces rear-end collision by 45% based on data from event data recorders in a sample of 1.5 million vehicles in 2017 and 1.8 million in 2018, for recent vehicles.[46]

It has been estimated that ALKS could help to avoid 47,000 serious accidents and save 3,900 lives over the first decade in the United Kingdom.[47]

AEB Limitations and safety issues

A NTSB communication suggests that some vehicle collision avoidance assist systems are not able to detect damaged crash attenuators. Therefore the vehicle may drive into the crash attenuator. The NTSB considers such a feature would be a must have for safety with partial automated vehicles to detect potential hazards and warn of potential hazards to drivers.[48]

AEB features

AEB systems aim to detect possible collisions with the car in front.[49] This is performed using sensors to detect and classify things in front of the vehicle, a system to interpret the data from the sensors, and a braking system which can work autonomously.[50]

Some cars may implement lane departure warning systems.[51]

Pedestrian detection

Since 2004, Honda has developed a night vision system that highlights pedestrians in front of the vehicle by alerting the driver with an audible chime and visually displaying them via HUD. Honda's system only works in temperatures below 30 degrees Celsius (86 Fahrenheit). This system first appeared on the Honda Legend.[52]

To assist in pedestrian safety as well as driver safety, Volvo implemented a pedestrian airbag in the Volvo V40, introduced in 2012. Many more manufacturers are developing Pedestrian crash avoidance mitigation (PCAM) systems.

ANCAP reports

Since 2018, the ANCAP provides AEB rating and tests AEB features.[53]

The ANCAP report in its adult occupant protection section contains AEB rating taking into account AEB City from 10 to 50 km/h.

The ANCAP report in its vulnerable user protection section contains AEB rating taking into account both AEB and FCW for pedestrian and cyclists, with various speeds named "Operational from" (for instance 10 to 80 km/h) in the reports:

  • For pedestrians in day and night: adult crossing, child running, and adult walking along.
  • For cyclists in day only: cyclist crossing, cyclist traveling along.

The ANCAP report in its safety assist section contains AEB rating taking into account the AEB interurban with various speeds named "Operational from" (for instance 10 to 180 km/h):

  • HMI performance
  • FCW (stationary and slower moving car)
  • AEB interurban (car braking lightly, car braking heavily, driving toward slower moving car)

Reverse automatic braking

In the US by 2017, 5% of cars were capable of reverse automatic braking. This feature allows autonomous braking of the vehicle while working in reverse direction, to avoid a reverse collision. Those systems are assessed by IIHS.[54]

Automated lane keeping systems

The automated lane keeping system, known as ALKS, is UN-ECE regulation 157 which provide level 3 driving up to 60 km/h on dedicated roads. It deals with avoiding some cases of collisions.

ALKS features

It defines some concepts:

Imminent collision risk describes a situation or an event which leads to a collision of the vehicle with another road user or an obstacle which cannot be avoided by a braking demand with lower than 5 m/s

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

Emergency Manoeuvre (EM) is a manoeuvre performed by the system in case of an event in which the vehicle is at imminent collision risk and has the purpose of avoiding or mitigating a collision.

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

The activated system shall not cause any collisions that are reasonably foreseeable and preventable. If a collision can be safely avoided without causing another one, it shall be avoided. When the vehicle is involved in a detectable collision, the vehicle shall be brought to a standstill.

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

The activated system shall detect the distance to the next vehicle in front as defined in paragraph 7.1.1. and shall adapt the vehicle speed in order to avoid collision.

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

The activated system shall be able to bring the vehicle to a complete stop behind a stationary vehicle, a stationary road user or a blocked lane of travel to avoid a collision. This shall be ensured up to the maximum operational speed of the system.

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

The activated system shall avoid a collision with a leading vehicle (...)

The activated system shall avoid a collision with a cutting in vehicle (...)

The activated system shall avoid a collision with an unobstructed crossing pedestrian in front of the vehicle.

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems

This document clarifies derivation process to define conditions under which automated lane keeping systems (ALKS) shall avoid a collision

Uniform provisions concerning the approval of vehicles with regard to automated lane keeping systems, Guidance on traffic disturbance critical scenarios for ALKS

ALKS regulation

In all contracting countries, the date of entry into force of UNECE regulation 157 is 22 January 2021.[55]

Within the period of six months from the date of depositary notification C.N.297.2020.TREATIES-XI.B.16 of 22 July 2020 by which the Secretary-General transmitted to the Governments of the Contracting Parties the text of draft United Nations Regulation No. 157, none of the Contracting Parties to the Agreement notified the Secretary-General of their intention not to apply the said United Nations Regulation on the date of its entry into force, pursuant to paragraphs 3 and 4 of article 1 of the Agreement.


Therefore, in accordance with article 1 (3) of the Agreement, the draft United Nations Regulation is adopted as United Nations Regulation No. 157. In accordance with paragraphs 3 and 4 of article 1 of the Agreement, the date of entry into force of United Nations Regulation No. 157 for all Contracting Parties is 22 January 2021.

The Secretary-General of the United Nations, 1 February 2021[55]

Regulations

AEB and ALKS are each defined by one or several UN-ECE regulations.

Japan requires AEB since 2020 and ALKS since 2021. The European Union requires AEB since 2022 but did not defined a date for ALKS.


Automobile manufacturers

Various vendors provide AEB components to automakers.[56] The global automotive AEB system market consists of a few established companies that are manufacturers or suppliers of specialized AEB components or systems.[57] For example, the main vendors for radar systems include Bosch, Delphi, Denso, TRW, and Continental.[58] Automobile manufactures may describe the systems installed on their vehicles using different names to differentiate their marketing efforts.[11] A particular automaker may have systems and sensors sourced from a variety of suppliers.[59] Therefore, even a single car brand may offer various levels of technology sophistication and the: frequency of false alerts can be different from model to model and trim level to trim level, depending on the types of camera and/or laser-based systems installed.[59]

In countries, such as the UK, one quarter of new vehicles might have some kind of AEB system; but only 1% of previously sold cars might have AEB.[11]

Audi

"Pre sense" autonomous emergency braking system uses twin radar and monocular camera sensors[60] and was introduced in 2010 on the 2011 Audi A8.[61] "Pre sense plus" works in four phases. The system first provides warning of an impending accident, activating hazard warning lights, closing windows and sunroof, and pretensioning front seat belts. The warning is followed by light braking to get the driver's attention. The third phase initiates autonomous partial braking at a rate of 3 m/s2 (9.8 ft/s2). The fourth phase increases braking to 5 m/s2 (16.4 ft/s2) followed by automatic full braking power, roughly half a second before projected impact. "Pre sense rear", is designed to reduce the consequences of rear-end collisions. The sunroof and windows are closed and seat belts are prepared for impact. The seats are moved forward to protect the car's occupants. 2015 introduced the "avoidance assistant" system that intervenes in the steering to help the driver avoid an obstacle. If an accident occurs, the "turning assistant" monitors opposing traffic when turning left at low speeds. In critical situation, it brakes the car. "Multicollision brake assist" uses controlled braking maneuvers during the accident to aid the driver. Both systems were introduced on the Second generation Q7.[62]

BMW

In 2012 BMW introduced two systems on the 7 Series. "Active Protection" detects imminent accidents to pretension safety belts, close windows and moonroof, bring backrest of the front passenger seat to an upright position, and activate post-crash braking. A driver drowsiness detection includes an advice to take a break from driving. An "Active Driving Assistant" combines lane departure warning, pedestrian protection, and city collision mitigation.[63]

In 2013, "Driving Assistant Plus" was introduced on most models combining the front-facing camera, lane-departure warning, and in some cases front radar sensors to detect vehicles ahead. Should the driver not react to the warning of a potential collision, the system would gradually prime brake pressure and apply  with maximum deceleration power  if necessary. In the case of a crash, the system can bring the vehicle to a standstill. Later iterations of the system on cars equipped with Automatic Cruise Control system are improved by combining radar and camera detection during fog, rain, and other situations where normal camera operations may be compromised.[64]

Ford

Collision warning and brake support on the 2009 Lincoln MKS

Beginning on the 2012 Ford Focus, Active City Stop was offered on the range topping Titanium model, under the optional Sports Executive Pack. The system used windscreen mounted cameras, radars, and lidars to monitor the road ahead. The system doesn't provide a warning, rather, it can prevent a crash occurring at speeds between 3.6 and 30 km/h (2.2 and 18.6 mph). This speed was later raised to 50 km/h (31 mph), and was available on all models, the Trend, Sport, Titanium, ST, and RS (Limited Edition only).

General Motors

General Motors' collision alert system was introduced in GMC Terrain SUVs in 2012. It uses a camera to provide warning when there is a vehicle ahead or there is a lane departure.[65] The 2014 Chevrolet Impala received the radar- and camera-based crash imminent braking (radar technology detects a possible crash threat and alerts the driver. If the driver does not appear to react quickly enough or doesn’t react at all, this feature intervenes to apply the brakes in an effort to avoid the crash. Forward collision alert, lane departure warning, side blind zone alert (using radar sensors on both sides of the vehicle, the system “looks” for other vehicles in the blind zone areas of the Impala and indicates their presence with LED-lit symbols in the outside mirrors. Rear cross traffic alert features.[66]

Honda

2003: Honda introduced an autonomous braking (Collision Mitigation Brake System CMBS, originally CMS) front collision avoidance system on the Inspire[67] and later in Acura, using a radar-based system to monitor the situation ahead and provide brake assistance if the driver reacts with insufficient force on the brake pedal after a warning in the instrument cluster and a tightening of the seat belts.[68][69] The Honda system was the first production system to provide automatic braking.[69] The 2003 Honda system also incorporated an "E-Pretensioner", which worked in conjunction with the CMBS system with electric motors on the seat belts. When activated, the CMBS has three warning stages. The first warning stage includes audible and visual warnings to brake. If ignored, the second stage would include the E-Pretensioner's tugging on the shoulder portion of the seat belt two to three times as an additional tactile warning to the driver to take action. The third stage, in which the CMBS predicts that a collision is unavoidable, includes full seat belt slack takeup by the E-Pretensioner for more effective seat belt protection and automatic application of the brakes to lessen the severity of the predicted crash. The E-Pretensioner would also work to reduce seat belt slack whenever the brakes are applied and the brake assist system is activated.[69]

Mercedes-Benz

2002: Mercedes' "Pre-Safe" system was exhibited at the Paris Motor Show on the 2003 S-Class. Using electronic stability control sensors to measure steering angle, vehicle yaw, and lateral acceleration and brake assist (BAS) sensors to detect emergency braking, the system can tighten the seat belts, adjust seat positions, including rear seats (if installed), raise folded rear headrests (if installed), and close the sunroof if it detects a possible collision (including rollover).[70] A later version of the Pre-Safe system was supplemented by an additional function that can close any open windows if necessary.

2006: Mercedes-Benz's "Brake Assist BAS Plus" was their first forward warning collision system introduced on the W221 S-Class, it incorporates the autonomous cruise control system and adds a radar-based collision warning.

2006: the "Pre-Safe Brake" on the CL-Class C216[71] was their first to offer partial autonomous braking (40%, or up to 0.4g deceleration) if the driver does not react to the BAS Plus warnings and the system detects a severe danger of an accident.[72][73]

2009: Mercedes introduced the first Pre-Safe Brake with full (100%) autonomous braking with maximum braking force approximately 0.6 seconds before impact, on the Mercedes-Benz E-Class (W212).[74][75]

2013: Mercedes updated Pre-Safe on the W222 S-Class as plus with cross-traffic assist.[76] Pre-Safe with pedestrian detection and City Brake function is a combination of stereo camera and radar sensors to detect pedestrians in front of the vehicle. Visual and acoustic warnings are triggered when a hazard is spotted. If the driver then reacts by braking, the braking power will be boosted as the situation requires, up to a full brake application. Should the driver fail to react, Pre-Safe Brake triggers autonomous vehicle braking. Pedestrian detection is active up to about 72 km/h (45 mph) , and is able to reduce collisions with pedestrians autonomously from an initial speed of up to 50 km/h (31 mph).[76] A radar sensor in the rear bumper monitors the traffic behind the vehicle. If the risk of an impact from the rear is detected, the rear hazard warning lights are activated to alert the driver of the vehicle behind (not on vehicles with USA/Canada coding). Anticipatory occupant protection measures, such as the reversible belt tensioners, are deployed. If the vehicle is stopped and the driver indicates a wish to remain stationary  by depressing the brake pedal, activating the hold function, or moving the selector lever to "P"  the system increases the brake pressure to keep the vehicle firmly braked during a possible rear-end collision.[76] Pre-Safe Impulse works an early phase of the crash, before the resulting deceleration starts to increase, the front occupants are pulled away from the direction of impact and deeper into their seats by their seat belts. By the time the accident enters the phase when loads peak, the extra distance they are retracted by can be used while dissipating energy in a controlled fashion. Pre-acceleration and force limitation allow the occupants to be temporarily isolated from the effects of the crash, significantly reducing the risk and severity of injuries in a frontal collision.[76]

Nissan

Nissan's Infiniti brand offers both laser-based and radar-based systems. Brake assist with preview function anticipates the need to apply emergency braking and pre-pressurize the brake system to help improve brake response. Intelligent brake assist (IBA) with forward emergency braking (FEB) (on QX80) uses radar to monitor approaching speed to the vehicle ahead, helping detect an imminent collision. It provides a two-stage warning to alert the driver, and if the driver takes no action, the system automatically engages the brakes to mitigate the collision speed and impact. Predictive forward collision warning system warns the driver of risks that may be obscured from the driver's view. It senses the relative velocity and distance of a vehicle directly ahead, as well as a vehicle travelling in front of the preceding one. The forward emergency braking system judges that deceleration is required, it alerts the driver using both a screen display and sound, then generates a force that pushes the accelerator pedal up and applies partial braking to assist the driver in slowing the vehicle down. When the system judges that there is the possibility of a collision, it will automatically apply harder braking to help avoid one.

Nissan has been under investigation for collision avoidance systems on late-model Rogue models that allegedly brake the vehicles for no reason, according to the US National Highway Traffic Safety Administration (NHTSA).[77] As of September 2019, Nissan considered the issue strictly as a "performance update" by issuing technical service bulletins—at least three since January 2019—that pertain to reprogramming the radar control unit, according to the agency.[77] At least 553,860 cars are potentially affected[77] from the 2017 and 2018 model years.[78]

Subaru

Subaru's system, branded "EyeSight", was announced in May 2008 using stereo camera technology to detect pedestrians and bicyclists. As initially announced, EyeSight enabled pre-collision braking control and adaptive cruise control at all speeds.[79] It was rolled out in Japan to selected models in 2010; in Australia in 2011; and in North America in 2012 for the 2013 model year Legacy and Outback models.[80] An alarm is used to warn the driver of a potential collision hazard in the pre-collision system.

The pre-collision braking control was upgraded in 2010 to allow the vehicle to stop automatically if the speed difference between the EyeSight-equipped vehicle and the object in front is less than 30 km/h (19 mph) and the driver takes no action to slow down or stop. Above 30 km/h (19 mph), the vehicle will reduce its speed automatically.[79] It also allows the vehicle to engage braking assist, if there is a risk of a frontal collision and the driver suddenly applies the brakes.[79] The speed difference to allow an automatic stop was raised to 50 km/h (31 mph) in 2013 with improved cameras.[81] The adaptive cruise control was also upgraded in 2010 to allow automatic emergency braking in traffic, fully stopping the EyeSight vehicle when the car in front has come to a complete stop.[79]

In 2013, color was added to the cameras, allowing the system to recognize brake lights and red stoplights ahead.[81] Subaru also added an active lane-keeping (keeping the vehicle in the middle of the lane, and applying steering force to keep the vehicle in the lane when unintentionally crossing lane markers) and throttle management (to prevent sudden unintended acceleration in forward and reverse) systems in 2013 with the improved cameras.[81] EyeSight has been very popular, equipped on approximately 90% of all Legacy and Outbacks sold in Japan at the beginning of 2012,[80] and the engineers responsible for its development won a prize from the Japanese government that year.[82]

As of 2021, EyeSight is standard on the Ascent, Forester, Legacy, and Outback. It is also standard on all CVT equipped Crosstrek, Impreza and WRX. It is not available on the BRZ.

Toyota

2008 LS 600h forward PCS diagram, with radar (blue) and stereo camera (red) coverage

Toyota's pre-collision system (PCS) is a radar-based system that uses a forward-facing millimeter-wave radar. When the system determines that a frontal collision is unavoidable, it preemptively tightens the seat belts, removing any slack, and pre-charges the brakes using brake assist to give the driver maximum stopping power when the driver depresses the brake pedal.

2003 February: Toyota launched PCS in the redesigned Japanese domestic market Harrier.

2003 August: added an automatic partial pre-crash braking system to the Celsior.[83]

2003 September: PCS made available in North America on the Lexus LS 430, becoming the first radar-guided forward collision warning system offered in the US.

2004: In July 2004, the Crown Majesta radar PCS added a single digital camera to improve the accuracy of collision forecast and warning and control levels[84][85][86]

2006: Pre-collision system with Driver Monitoring System introduced in March 2006 on the Lexus GS 450h[84] using a CCD camera on the steering column. This system monitors the driver's face to determine where the driver is looking. If the driver's head turns away from the road and a frontal obstacle is detected, the system will alert the driver using a buzzer, and if necessary, pre-charge the brakes and tighten the safety belts.

2006: the Lexus LS introduced an advanced pre-collision system (APCS), added a twin-lens stereo camera located on the windshield and a more sensitive radar to detect smaller "soft" objects such as animals and pedestrians. A near-infrared projector located in the headlights allows the system to work at night. With the adaptive variable suspension (AVS) and electric power steering, the system can change the shock absorber firmness, steering gear ratios, and torque assist to aid the driver's evasive steering measures. The lane departure warning system will make automatic steering adjustments to help ensure that the vehicle maintains its lane in case the driver fails to react. Driver Monitoring System was introduced on the Lexus LS. Rear-end pre-collision system includes a rearward-facing millimeter-wave radar mounted in the rear bumper.[87] The system adjusts the active head restraints by moving them upward and forward to reduce the risk of whiplash injuries if an imminent rear collision is detected.[88]

2008: Improved driver monitoring system added on the Crown for detecting whether the driver's eyes are properly open.[89] It monitors the driver's eyes to detect the driver's level of wakefulness. This system is designed to work even if the driver is wearing sunglasses, and at night.

2008: PCS with GPS-navigation linked brake assist function on the Crown. The system is designed to determine if the driver is late in decelerating at an approaching stop sign, will then sound an alert and can also pre-charge the brakes to provide braking force if deemed necessary. This system works in certain Japanese cities and requires Japan specific road markings that are detected by a camera.

2009: Crown[90] added a front-side millimeter-wave radar to detect potential side collisions primarily at intersections or when another vehicle crosses the center line. The latest version tilts the rear seat upward, placing the passenger in a more ideal crash position if it detects a front or rear impact.[91]

2012: Higher speed APCS on the Lexus LS enables deceleration from up to 37 mph (60 km/h), compared to the previous of 25 mph (40 km/h). The higher speed APCS uses the same technologies as then current APCS. This system increases the braking force up to twice that applied by average drivers. It was not then available in U.S. markets.

2013: Pre-collision system with pedestrian-avoidance steer assist and steering bypass assist[92] can help prevent collisions in cases where automatic braking alone is not sufficient, such as when the vehicle is travelling too fast or a pedestrian suddenly steps into the vehicle’s path. An on-board sensor detects pedestrians and issues a visual alert on the dashboard immediately in front of the driver if the system determines that there is a risk of collision. If the likelihood of a collision increases, the system issues an audio and visual alarm to encourage the driver to take evasive action, and the increased pre-collision braking force and automatic braking functions are activated.[93] If the system determines that a collision cannot be avoided by braking alone and there is sufficient room for avoidance, steer assist is activated to steer the vehicle away from the pedestrian.[94]

2016: Toyota announced it would make Toyota Safety Sense (TSS) and Lexus Safety System+ standard on nearly all Japan, Europe, and US models by the end of 2017.[95][96]

2017: Lexus introduced the updated Lexus Safety System+ 2.0 on the fifth generation LS. In the US 2017 model year, Toyota sold more vehicles equipped with collision warning than any other single brand with a total 1.4 million sold or 56% of their fleet.[97]

2018: Toyota released its updated Toyota Safety Sense 2.0 (TSS 2.0) to include Lane Tracing Assist, Road Sign Assist, and Low Light Pedestrian Detection with Daytime Bicyclist Detection which improves the Pre-Collision System. The first Japanese car model to receive (TSS 2.0) is the executive Crown in its 15th generation.

Volkswagen

Laser sensor of VW Up

2010: "Front Assist" on the 2011 Volkswagen Touareg can brake the car to a stop in case of an emergency and tension the seat belts as a precautionary measure.[98]

2012: Volkswagen Golf Mk7 introduced a "Proactive Occupant Protection" that will close the windows and retract the safety belts to remove excess slack if the potential for a forward crash is detected. Multi-collision brake system (automatic post-collision braking system) to automatically brake the car after an accident in order to avoid a second collision. City emergency braking automatically activates brakes at low speeds in urban situations.

2014: Volkswagen Passat (B8) introduces pedestrian recognition a part of the system. It uses a sensor fusion between a camera and the radar sensor. There is an "emergency assist" in case of a non-reacting driver, the car takes the control of the brakes and the steering until a complete stop. This is also found on the Volkswagen Golf Mk8.

Volvo

Volvo City Safety multiple camera

2006: Volvo's "Collision Warning with Auto Brake", developed in cooperation with Mobileye, was introduced on the 2007 S80. This system is powered by a radar/camera sensor fusion and provides a warning through a head up display that visually resembles brake lamps. If the driver does not react, the system pre-charges the brakes and increases the brake assist sensitivity to maximize driver braking performance. Later versions will automatically apply the brakes to minimize pedestrian impacts. In some models of Volvos, the automatic braking system can be manually turned off. The V40 also included the first pedestrian airbag, when it was introduced in 2012.

2013: Volvo introduced the first cyclist detection system. All Volvo automobiles now come standard with a lidar laser sensor that monitors the front of the roadway, and if a potential collision is detected, the safety belts will retract to reduce excess slack. Volvo now includes this safety device as an option in FH series trucks.[99]

2015: "IntelliSafe" with auto brake at intersection. The Volvo XC90 features automatic braking, if the driver turns in front of an oncoming car. This is a common scenario at busy city crossings as well as on highways, where the speed limits are higher.

March 2020: Volvo recalled 121,000 cars over auto emergency braking failure.[100] The system may not detect an object and so may not work as intended, increasing the risk of a crash.[100]

List of cars with available collision avoidance features

New car assessment program

EuroNCAP and C-NCAP and ANCAP are involved in taking into account the Autonomous Emergency Braking (AEB) in their respective New Car Assessment Program.[102]

Since 2016, EuroNCAP takes into account pedestrian in AEB rating.[102]

In 2018, EuroNCAP provides assessments for AEB city (since 2014), AEB interurban (since 2014), AEB pedestrian (since 2018), and AEB cyclist (since 2018). Since 2018, ANCAP also provides assessments for AEB city, AEB interurban, AEB pedestrian and cyclist.

Cost

Many vehicles have AEB fitted as standard. The AEB is not available for every car. When AEB is available as an option, its cost can be in the £180 (AEB city only)  £1300 (regular AEB) range.[11]

However, due to various reason, the cost of AEB is linked to the cost of ACC and FCW.[103]

See also

References

  1. Nissan Leaf 2018 Euro NCAP rating
  2. Lim, Hazel Si Min; Taeihagh, Araz (2019). "Algorithmic Decision-Making in AVs: Understanding Ethical and Technical Concerns for Smart Cities". Sustainability. 11 (20): 5791. doi:10.3390/su11205791.
  3. "What is a forward collision warning system?". www.safercar.gov. Retrieved 21 February 2020.
  4. Wong, S.Y. (13 February 2008). "Toyota Develops Automatic Brake System Assisted by GPS Technology for Safety Driving". My Digital Life. Retrieved 10 April 2020.
  5. "Volvo Collision Warning with Auto Brake". The Volvo Owners Club. 29 August 2007. Retrieved 11 April 2020.
  6. Fuller, John (22 April 2009). "How Pre-Collision Systems Work". HowStuffWorks.com. Retrieved 21 February 2020.
  7. "Automakers, Safety Officials Make Crash Avoidance Systems Standard by 2022". cars.com. 17 March 2016. Retrieved 21 February 2020.
  8. "Uniform provisions concerning the approval of motor vehicles with regard to the Advanced Emergency Braking Systems (AEBS) - Addendum: 130 - Regulation: 131" (PDF). United Nations. 27 February 2014. Retrieved 3 November 2019.
  9. "Uniform provisions concerning the approval of motor vehicles with regard to the Advanced Emergency Braking System (AEBS) for M1 and N1 vehicles" (PDF). United Nations Economic Commission for Europe. 4 February 2020. p. 8. Retrieved 31 July 2020.
  10. Kanarachos, Stratis (2009). "A new method for computing optimum obstacle avoidance steering manoeuvres of vehicles". International Journal of Vehicle Autonomous Systems. 7 (1): 73–95. doi:10.1504/IJVAS.2009.027968. Retrieved 29 July 2015.
  11. "Autonomous Emergency Braking (AEB) Frequently Asked Questions" (PDF). UK: Thatcham Research. Archived from the original (PDF) on 1 May 2018.
  12. "Autonomous Emergency Braking". Euro NCAP. Retrieved 8 June 2019.
  13. Hayashi, Ryuzo; Chatporntanadul, Puwadech; Nagai, Masao (4 September 2013). Improvement of Trajectory Tracking Performance in Autonomous Collision Avoidance by Steering. 7th IFAC Symposium on Advances in Automotive Control. Tokyo. doi:10.3182/20130904-4-JP-2042.00104.
  14. "Improved Impact of Collision Avoidance by Steering Technology on Real Life Safety". Vinnova. Stockholm, Sweden. Retrieved 3 November 2019.
  15. Olney, R.D.; et al. (November 1995), "Collision Warning System Technology", Intelligent Transport Systems World Congress, Yokohama, Japan
  16. Sari, Zahra; Brookes, David; Avery, Matthew (5 June 2017). AEB Performance in the UK; A Decade of Development. 25th International Technical Conference on the Enhanced Safety of Vehicles. US: Transportation Research Board. Retrieved 8 June 2019.
  17. "Forward Collision Warning Requirements Project Final Report - Task 1" (PDF). National Highway Traffic Safety Administration. January 2003. Retrieved 29 July 2015.
  18. "Written question  Rear-end traffic collisions in the European Union - E-011477/2011". europa.eu. Retrieved 25 January 2015.
  19. "Answer to a written question - Rear-end traffic collisions in the European Union - E-011477/2011". europa.eu. Retrieved 25 January 2015.
  20. "Annex to the proposal for a regulation of the European Parliament and of the Council concerning type-approval requirements for the general safety of motor vehicles - Impact Assessment" (PDF). Commission of the European Communities. 23 May 2008. Archived from the original (PDF) on 23 June 2015. Retrieved 31 March 2016.
  21. "U.S. DOT and IIHS announce historic commitment of 20 automakers to make automatic emergency braking standard on new vehicles". U.S. Department of Transportation National Highway Traffic Safety Administration. 17 March 2016. Retrieved 17 March 2016.
  22. "Automakers agree to make auto braking a standard by 2022".
  23. "UNECE works on new standards to increase the safety of trucks and coaches".
  24. "Uniform provisions concerning the approval of motor vehicles with regard to the Advanced Emergency Braking Systems (AEBS)" (PDF). United Nations. 27 February 2014. Retrieved 21 October 2019.
  25. Golson, Jordan (27 January 2016). "Rear-end crashes go way down when cars can brake themselves". The Verge. Retrieved 26 May 2018.
  26. "Standard inclusion of autonomous emergency braking increases ten-fold". Australia: ANCAP. 13 June 2018. Retrieved 24 March 2019.
  27. https://www.motoring.com.au/government-proposes-mandatory-aeb-126859/
  28. "10 automakers equipped most of their 2018 vehicles with automatic emergency braking". US: NHTSA. 13 March 2019. Retrieved 28 March 2019.
  29. "Autobrake is good, but it could be better". US: Insurance Institute for Highway Safety. 21 February 2019. Retrieved 15 June 2019.
  30. "AEB to be Required on New Cars in Japan". 2 December 2019.
  31. "Parliament approves EU rules requiring life-saving technologies in vehicles | News | European Parliament". Europarl.europa.eu. 16 April 2019. Retrieved 31 August 2020.
  32. Dash, Dipak K (7 September 2018). "Soon, all vehicles to have 'brakes with brains'". Times of India. Retrieved 8 June 2019.
  33. "North America Publishes Report on recent Automaker Automatic Emergency Braking Commitment". JATO. 9 June 2016. Retrieved 31 August 2020.
  34. https://www.motoring.com.au/government-proposes-mandatory-aeb-126859/
  35. "Crash avoidance features cut insurance claims". US: Insurance Institute for Highway Safety. Retrieved 4 April 2015.
  36. Beene, Ryan (28 January 2016). "Automatic braking reduces rear-end crashes, IIHS study finds". Automotive News. Retrieved 10 March 2016.
  37. "New study confirms real-world safety benefits of autonomous emergency braking". European Transport Safety Council. 11 July 2015. Retrieved 8 June 2019.
  38. "Automatic brakes stopped Berlin truck during Christmas market attack". Deutsche Welle. 28 December 2016.
  39. Cicchino, Jessica (2016). "Effectiveness of Forward Collision Warning Systems with and without Autonomous Emergency Braking in Reducing Police-Reported Crash Rates". Insurance Institute for Highway Safety. Archived from the original on 30 April 2016.
  40. euroncapcom (13 June 2012). "Euro NCAP - Autonomous Emergency Braking AEB" via YouTube.
  41. "New EU legislation requires cars to include autonomous braking system".
  42. Kilcarr, Sean (16 June 2016). "NHTSA study: Collision avoidance systems can reduce crashes". Fleet Owner. Retrieved 11 April 2020.
  43. "Advanced driver assistance systems 2018" (PDF). European Road Safety Observatory. Retrieved 8 June 2019.
  44. "Real-word benefits of crash avoidance technologies" (PDF). US: Insurance Institute for Highway Safety. April 2019. Retrieved 15 June 2019.
  45. https://www.motoring.com.au/government-proposes-mandatory-aeb-126859/
  46. https://etsc.eu/aeb-systems-cut-rear-end-collisions-by-45/
  47. Campion, Alice (26 August 2020). "Automated system introduced to keep your car in lane". Confused. Retrieved 4 October 2020.
  48. "Collision Between a Sport Utility Vehicle Operating With Partial Driving Automationand a Crash Attenuator" (PDF). California, US: NTSB. 23 March 2018. HWY18FH011. Retrieved 10 April 2020.
  49. "Car Safety Feature - Auto Emergency Braking (AEB)". Howsafeisyourcar.com.au. Australia. Retrieved 8 June 2019.
  50. Anderson, Robert; Doecke, Samuel; Macken, James. "Potential Benefits of Autonomous Emergency Braking Based on In-depth Crash Reconstruction and Simulation". Australia: Centre for Automotive Safety Research, The University of Adelaide. S2CID 8767744. Paper Number 13-0152. Cite journal requires |journal= (help)
  51. Umar Zakir Abdul, Hamid; et al. (2016). "Current Collision Mitigation Technologies for Advanced Driver Assistance Systems–A Survey". PERINTIS eJournal. 6 (2). Retrieved 14 June 2017.
  52. "Safety - Honda's Intelligent Night Vision system". Automotive Engineer PLUS. October 2004. Archived from the original on 8 August 2008.
  53. White, Tom (26 February 2018). "AEB or auto emergency braking: Not all systems are created equal". CarsGuide. Australia. Retrieved 8 June 2019.
  54. Krok, Andrew (22 February 2018). "IIHS begins testing reverse automatic braking". Roadshow. US: CNN. Retrieved 8 June 2019.
  55. https://treaties.un.org/doc/Publication/CN/2021/CN.53.2021-Eng.pdf
  56. Francis, Sam (19 April 2019). "ADAS: Top 40 advanced driver assistance systems companies". Robotics and Automation News. Retrieved 10 February 2020.
  57. "Top 6 Vendors in the Global Automotive Advanced Emergency Braking System Market from 2016 to 2020: Technavio" (Press release). Business Wire. 21 September 2016. Retrieved 10 February 2020.
  58. Sedgwick, David (13 October 2014). "Demand skyrockets for collision-avoidance sensors". Automotive News. Retrieved 10 February 2020.
  59. Naranjo, Michelle (25 February 2016). "Forward-Collision Warning Systems Are Not All Created Equal". Consumer Reports. Retrieved 21 February 2020.
  60. "Extensive safety in the new Audi A8" (Press release). Bosch Media Services. 27 April 2010. Archived from the original on 21 September 2010. Retrieved 29 July 2015.
  61. "The new Audi A8" (PDF) (Press release). Archived from the original (PDF) on 3 August 2017. Retrieved 17 February 2010.
  62. "The new Audi Q7 – Sportiness, efficiency, premium comfort" (Press release). Audi Media Center. 12 December 2014. Archived from the original on 19 May 2019.
  63. "The new BMW 7 Series" (Press release). BMW Group. 25 May 2012.
  64. Russel, Matthew (16 October 2013). "Model Year 2014 Update Information". BMW USA News.
  65. "New Camera-Based Collision Alert Debuts on GMC Terrain". media.gm.com (Press release). Retrieved 25 January 2015.
  66. "Chevrolet News - United States  Impala" (Press release). Media.gm.com. 15 December 2014. Retrieved 10 March 2016.
  67. "Honda Announces a Full Model Change for the Inspire" (Press release). Honda. 18 June 2003. Archived from the original on 24 June 2003. Retrieved 19 January 2015.
  68. "Honda Worldwide". honda.com (Press release). Archived from the original on 30 December 2014. Retrieved 25 January 2015.
  69. "Honda Worldwide - World News - News Releases". honda.com (Press release). 20 May 2003. Archived from the original on 29 December 2014. Retrieved 25 January 2015.
  70. "MERCEDES-BENZ LAUNCHES FIRST-EVER CAR WITH "REFLEXES" - New Pre-Safe System Anticipates Collisions to Protect Occupants" (Press release). 15 October 2002. Archived from the original on 8 October 2007. Retrieved 14 March 2013.
  71. "Innovation as a tradition" (Press release). Daimler. 29 December 2014. Archived from the original on 29 December 2014.
  72. Breuer, Joerg J.; Faulhaber, Andreas; Gleissner, Stefan. "Real world Safety benefits of brake assistance systems" (PDF). DaimlerChrysler. Archived from the original (PDF) on 4 March 2016. Retrieved 10 March 2016.
  73. "Impact: Real Drivers. Life Changing Stories - Mercedes-Benz". Impact. Retrieved 25 January 2015.
  74. "Mercedes-Benz TecDay Special Feature: PRE-SAFE And PRE-SAFE Brake". emercedesbenz.com (Press release). Archived from the original on 12 January 2015. Retrieved 25 January 2015.
  75. Umar Zakir Abdul, Hamid; et al. (2017). "Autonomous Emergency Braking System with Potential Field Risk Assessment for Frontal Collision Mitigation". 2017 IEEE Conference on Systems, Process and Control (ICSPC). Retrieved 14 March 2018.
  76. "Extended PRE-SAFE protection: Prevention is better than cure". daimler.com (Press release). May 2013. Archived from the original on 3 January 2015. Retrieved 25 January 2015.
  77. Atiyeh, Clifford (12 September 2019). "Owners Accuse Nissan Rogue of Braking for No Reason; NHTSA Investigating". Car and Driver. US. Retrieved 6 June 2020.
  78. "Nissan Rogue under investigation after claims emergency brakes turned on for no reason". USA Today. US. 15 December 2019. Retrieved 6 June 2020.
  79. "FHI to Introduce the "New EyeSight" Subaru's Unique Driving Assist System with Advanced Safety Functions" (PDF) (Press release). Subaru Corporation. 22 April 2010. Retrieved 1 June 2017.
  80. "FHI to Introduce the "EyeSight" to North America - The Second Overseas Launch of Subarufs [sic] Unique Driving Assist System" (Press release). Subaru Corporation. 16 March 2012. Retrieved 1 June 2017.
  81. "FHI Reveals the Next Generation "EyeSight"" (Press release). Subaru Corporation. 22 April 2010. Retrieved 1 June 2017.
  82. "Subaru's Unique Driving Assist System "EyeSight" Received the Commendation for Science and Technology 2012 from the Minister of Education, Culture, Sports, Science and Technology" (Press release). Subaru Corporation. 17 April 2012. Retrieved 1 June 2017.
  83. "Safety matters: advanced crash avoidance technology finds its way into production vehicles in Japan". Automotive Industries. 2004.
  84. "Toyota - Technical Development - Electronics Parts". toyota-global.com (Press release). Retrieved 4 April 2015.
  85. "Toyota Crown Majesta undergoes complete redesign". theautochannel.com. Retrieved 4 April 2015.
  86. "(Really Playing it Safe)". Designnews.com. Archived from the original on 27 October 2008. Retrieved 10 March 2016.
  87. "Toyota: News Releases". toyota.co.jp (Press release). Retrieved 25 January 2015.
  88. Matsubayashi, Kiyoka; Yamada, Yukinori; Iyoda, Motomi; Koike, Shin; Kawasaki, Tomoya; Tokuda, Masanori. "Development of Rear Pre-Crash Safety System For Rear-End Collisions" (PDF). Toyota Motor. Archived from the original (PDF) on 4 March 2016. Retrieved 10 March 2016.
  89. "Toyota Enhances Pre-crash Safety System with Eye Monitor" (Press release). Toyota.co.jp. 22 January 2008. Archived from the original on 4 March 2016. Retrieved 10 March 2016.
  90. "Toyota Launches Redesigned Crown Majesta in Japan". Worldcarfans. Retrieved 25 January 2015.
  91. "Toyota Adds to Pre-crash Safety Technologies" (Press release). Toyota.co.jp. 26 February 2009. Archived from the original on 27 October 2016. Retrieved 10 March 2016.
  92. "Toyota Global Site - Technology File". toyota-global.com (Press release). Retrieved 25 January 2015.
  93. "Different driveway alert systems". www.drivewayalertsystems.net. Archived from the original on 18 February 2017. Retrieved 17 February 2017.
  94. Crowe, Phillipe. "oyota Develops New Pedestrian Safety Technology". HybridCars.
  95. "Lexus and Toyota Will Make Automated Braking Standard on Nearly Every Model and Trim Level by End of 2017". Toyota Press Room (Press release). 21 March 2016. Archived from the original on 4 April 2016. Retrieved 31 March 2016.
  96. "Nearly Every Toyota to Have Automatic Emergency Braking by 2017 » AutoGuide.com News". 21 March 2016.
  97. Charniga, Kackie (21 December 2017). "NHTSA, IIHS document increase in emergency braking systems in 2017 vehicles". Automotive news. US. Retrieved 8 June 2019.
  98. "To the Point: The New Touareg. Volkswagen SUV is one of the safest automobiles of all times" (Press release). Archived from the original on 20 July 2011. Retrieved 2 June 2010.
  99. "Volvo Trucks - Emergency braking at its best!". YouTube. Retrieved 25 January 2015.
  100. Szymkowski, Sean (18 March 2020). "Volvo recalls 121,000 cars over auto emergency braking failure". CNET. US. Retrieved 6 June 2020.
  101. "Der neue Nissan X-Ttrail Fahrzeuge". nissan.ch (Press release). Retrieved 25 January 2015.
  102. "Creating a Global Market for Vehicle Safety" (PDF). Global New Car Assessment Programme. Retrieved 8 June 2019.
  103. Grover, C.; Knight, I.; Okoro, F.; Simmons, I.; Couper, G.; Massie, P.; Smith, B. (April 2008). "Automated Emergency Brake Systems: Technical requirements, costs and benefits" (PDF). European Commission. Retrieved 8 June 2019.
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