Jump to content

Self-driving car

From Wikipedia, the free encyclopedia
(Redirected from Semi-autonomous driving)

A self-driving car, also known as a autonomous car (AC), driverless car, robotaxi, robotic car or robo-car,[1][2][3] is a car that is capable of operating with reduced or no human input.[4][5] Self-driving cars are responsible for all driving activities, such as perceiving the environment, monitoring important systems, and controlling the vehicle, which includes navigating from origin to destination.[6]

As of late 2024, no system has achieved full autonomy (SAE Level 5). In December 2020, Waymo was the first to offer rides in self-driving taxis to the public in limited geographic areas (SAE Level 4),[7] and as of April 2024 offers services in Arizona (Phoenix) and California (San Francisco and Los Angeles). In June 2024, after a Waymo self-driving taxi crashed into a utility pole in Phoenix, Arizona, all 672 of its Jaguar I-Pace were recalled after they were found to have susceptibility to crashing into pole like items and had their software updated.[8][9][10] In July 2021, DeepRoute.ai started offering self-driving taxi rides in Shenzhen, China. Starting in February 2022, Cruise offered self-driving taxi service in San Francisco,[11] but suspended service in 2023. In 2021, Honda was the first manufacturer to sell an SAE Level 3 car,[12][13][14] followed by Mercedes-Benz in 2023.[15]

A Waymo-operated Jaguar I-Pace in San Francisco, 2023. This model was recalled after a crash into a pole.[9]
Roborace autonomous racing car on display at the 2017 New York City ePrix
Baidu self-driving car

History

[edit]

Experiments have been conducted on advanced driver assistance systems (ADAS) since at least the 1920s.[16] The first ADAS system was cruise control, which was invented in 1948 by Ralph Teetor.

Trials began in the 1950s. The first semi-autonomous car was developed in 1977, by Japan's Tsukuba Mechanical Engineering Laboratory.[17] It required specially marked streets that were interpreted by two cameras on the vehicle and an analog computer. The vehicle reached speeds of 30 km/h (19 mph) with the support of an elevated rail.[18][19]

Carnegie Mellon University's Navlab[20] and ALV[21][22] semi-autonomous projects launched in the 1980s, funded by the United States' Defense Advanced Research Projects Agency (DARPA) starting in 1984 and Mercedes-Benz and Bundeswehr University Munich's EUREKA Prometheus Project in 1987.[23] By 1985, ALV had reached 31 km/h (19 mph), on two-lane roads. Obstacle avoidance came in 1986, and day and night off-road driving by 1987.[24] In 1995 Navlab 5 completed the first autonomous US coast-to-coast journey. Traveling from Pittsburgh, Pennsylvania and San Diego, California, 98.2% of the trip was autonomous. It completed the trip at an average speed of 63.8 mph (102.7 km/h).[25][26][27][28] Until the second DARPA Grand Challenge in 2005, automated vehicle research in the United States was primarily funded by DARPA, the US Army, and the US Navy, yielding incremental advances in speeds, driving competence, controls, and sensor systems.[29]

The US allocated US$650 million in 1991 for research on the National Automated Highway System,[30] which demonstrated automated driving, combining highway-embedded automation with vehicle technology, and cooperative networking between the vehicles and highway infrastructure. The programme concluded with a successful demonstration in 1997.[31] Partly funded by the National Automated Highway System and DARPA, Navlab drove 4,584 km (2,848 mi) across the US in 1995, 4,501 km (2,797 mi) or 98% autonomously.[32] In 2015, Delphi piloted a Delphi technology-based Audi, over 5,472 km (3,400 mi) through 15 states, 99% autonomously.[33] In 2015, Nevada, Florida, California, Virginia, Michigan, and Washington DC allowed autonomous car testing on public roads.[34]

From 2016 to 2018, the European Commission funded development for connected and automated driving through Coordination Actions CARTRE and SCOUT programs.[35] The Strategic Transport Research and Innovation Agenda (STRIA) Roadmap for Connected and Automated Transport was published in 2019.[36]

In November 2017, Waymo announced testing of autonomous cars without a safety driver.[37] However, an employee was in the car to handle emergencies.[38]

In March 2018, Elaine Herzberg became the first reported pedestrian killed by a self-driving car, an Uber test vehicle with a human backup driver; prosecutors did not charge Uber, while the human driver was sentenced to probation.[39]

In December 2018, Waymo was the first to commercialize a robotaxi service, in Phoenix, Arizona.[40] In October 2020, Waymo launched a robotaxi service in a (geofenced) part of the area.[41][42] The cars were monitored in real-time, and remote engineers intervened to handle exceptional conditions.[43][42]

In March 2019, ahead of Roborace, Robocar set the Guinness World Record as the world's fastest autonomous car. Robocar reached 282.42 km/h (175.49 mph).[44]

In March 2021, Honda began leasing in Japan a limited edition of 100 Legend Hybrid EX sedans equipped with Level 3 "Traffic Jam Pilot" driving technology, which legally allowed drivers to take their eyes off the road when the car was travelling under 30 kilometres per hour (19 mph).[12][13][45][14]

In December 2020, Waymo became the first service provider to offer driverless taxi rides to the general public, in a part of Phoenix, Arizona. Nuro began autonomous commercial delivery operations in California in 2021.[46] DeepRoute.ai launched robotaxi service in Shenzhen in July 2021.[47] In December 2021, Mercedes-Benz received approval for a Level 3 car.[48] In February 2022, Cruise became the second service provider to offer driverless taxi rides to the general public, in San Francisco.[11] In December 2022, several manufacturers scaled back plans for self-driving technology, including Ford and Volkswagen.[49] In 2023, Cruise suspended its robotaxi service.[50] Nuro was approved for Level 4 in Palo Alto in August, 2023.[51]

As of August 2023, vehicles operating at Level 3 and above were an insignificant market factor;[citation needed] as of early 2024, Honda leases a Level 3 car in Japan, and Mercedes sells two Level 3 cars in Germany, California and Nevada.[52][53]

Definitions

[edit]

Organizations such as SAE have proposed terminology standards. However, most terms have no standard definition and are employed variously by vendors and others. Proposals to adopt aviation automation terminology for cars have not prevailed.[54]

Names such as AutonoDrive, PilotAssist, Full-Self Driving or DrivePilot are used even though the products offer an assortment of features that may not match the names.[55] Despite offering a system it called Full Self-Driving, Tesla stated that its system did not autonomously handle all driving tasks.[56] In the United Kingdom, a fully self-driving car is defined as a car so registered, rather than one that supports a specific feature set.[57] The Association of British Insurers claimed that the usage of the word autonomous in marketing was dangerous because car ads make motorists think "autonomous" and "autopilot" imply that the driver can rely on the car to control itself, even though they do not.

Automated driving system

[edit]

SAE identified 6 levels for driving automation from level 0 to level 5.[58] An ADS is an SAE J3016 level 3 or higher system.

Advanced driver assistance system

[edit]

An ADAS is a system that automates specific driving features, such as Forward Collision Warning (FCW), Automatic Emergency Braking (AEB), Lane Departure Warning (LDW), Lane Keeping Assistance (LKA) or Blind Spot Warning (BSW).[59] An ADAS requires a human driver to handle tasks that the ADAS does not support.

Autonomy versus automation

[edit]

Autonomy implies that an automation system is under the control of the vehicle rather than a driver. Automation is function-specific, handling issues such as speed control, but leaves broader decision-making to the driver.[60]

Euro NCAP defined autonomous as "the system acts independently of the driver to avoid or mitigate the accident".[61]

In Europe, the words automated and autonomous can be used together. For instance, Regulation (EU) 2019/2144 supplied:[62]

  • "automated vehicle" means a vehicle that can move without continuous driver supervision, but that driver intervention is still expected or required in the operational design domains (ODD);[62]
  • "fully automated vehicle" means a vehicle that can move entirely without driver supervision;[62]

Cooperative system

[edit]

A remote driver is a driver that operates a vehicle at a distance, using a video and data connection.[63]

According to SAE J3016,

Some driving automation systems may indeed be autonomous if they perform all of their functions independently and self-sufficiently, but if they depend on communication and/or cooperation with outside entities, they should be considered cooperative rather than autonomous.

Operational design domain

[edit]

Operational design domain (ODD) is a term for a particular operating context for an automated system, often used in the field of autonomous vehicles. The context is defined by a set of conditions, including environmental, geographical, time of day, and other conditions. For vehicles, traffic and roadway characteristics are included. Manufacturers use ODD to indicate where/how their product operates safely. A given system may operate differently according to the immediate ODD.[64]

The concept presumes that automated systems have limitations.[65] Relating system function to the ODD it supports is important for developers and regulators to establish and communicate safe operating conditions. Systems should operate within those limitations. Some systems recognize the ODD and modify their behavior accordingly. For example, an autonomous car might recognize that traffic is heavy and disable its automated lane change feature. [65]

Vendors have taken a variety of approaches to the self-driving problem. Tesla's approach is to allow their "full self-driving" (FSD) system to be used in all ODDs as a Level 2 (hands/on, eyes/on) ADAS.[66] Waymo picked specific ODDs (city streets in Phoenix and San Francisco) for their Level 5 robotaxi service.[67] Mercedes Benz offers Level 3 service in Las Vegas in highway traffic jams at speeds up to 40 miles per hour (64 km/h).[68] Mobileye's SuperVision system offers hands-off/eyes-on driving on all road types at speeds up to 130 kilometres per hour (81 mph).[69] GM's hands-free Super Cruise operates on specific roads in specific conditions, stopping or returning control to the driver when ODD changes. In 2024 the company announced plans to expand road coverage from 400,000 miles to 750,000 miles.[70] Ford's BlueCruise hands-off system operates on 130,000 miles of US divided highways.[71]

Self-driving

[edit]

The Union of Concerned Scientists defined self-driving as "cars or trucks in which human drivers are never required to take control to safely operate the vehicle. Also known as autonomous or 'driverless' cars, they combine sensors and software to control, navigate, and drive the vehicle."[72]

The British Automated and Electric Vehicles Act 2018 law defines a vehicle as "driving itself" if the vehicle is "not being controlled, and does not need to be monitored, by an individual".[73]

Another British government definition stated, "Self-driving vehicles are vehicles that can safely and lawfully drive themselves".[74]

British definitions

[edit]

In British English, the word automated alone has several meanings, such as in the sentence: "Thatcham also found that the automated lane keeping systems could only meet two out of the twelve principles required to guarantee safety, going on to say they cannot, therefore, be classed as 'automated driving', preferring 'assisted driving'".[75] The first occurrence of the "automated" word refers to an Unece automated system, while the second refers to the British legal definition of an automated vehicle. British law interprets the meaning of "automated vehicle" based on the interpretation section related to a vehicle "driving itself" and an insured vehicle.[76]

In November 2023 the British Government introduced the Automated Vehicles Bill. It proposed definitions for related terms:[77]

  • Self-driving: "A vehicle “satisfies the self-driving test” if it is designed or adapted with the intention that a feature of the vehicle will allow it to travel autonomously, and it is capable of doing so, by means of that feature, safely and legally."
  • Autonomy: A vehicle travels “autonomously” if it is controlled by the vehicle, and neither the vehicle nor its surroundings are monitored by a person who can intervene.
  • Control: control of vehicle motion.
  • Safe: a vehicle that conforms to an acceptably safe standard.
  • Legal: a vehicle that offers an acceptably low risk of committing a traffic infraction.

SAE classification

[edit]
Tesla Autopilot is classified as an SAE Level 2 system.[78][79]

A six-level classification system – ranging from fully manual to fully automated – was published in 2014 by SAE International as J3016, Taxonomy and Definitions for Terms Related to On-Road Motor Vehicle Automated Driving Systems; the details are revised occasionally.[80] This classification is based on the role of the driver, rather than the vehicle's capabilities, although these are related. After SAE updated its classification in 2016, (J3016_201609),[81] the National Highway Traffic Safety Administration (NHTSA) adopted the SAE standard.[82][83] The classification is a topic of debate, with various revisions proposed.[84][85]

Classifications

[edit]

A "driving mode", aka driving scenario, combines an ODD with matched driving requirements (e.g., expressway merging, traffic jam).[1][86] Cars may switch levels in accord with the driving mode.

Above Level 1, level differences are related to how responsibility for safe movement is divided/shared between ADAS and driver rather than specific driving features.

J3016 Automation Levels[86]
Level Name Narrative Direction and
speed control
Monitoring Fallback responsibility Mode coverage
0 No Automation Full-time performance by the driver of all aspects of driving, even when "enhanced by warning or intervention systems" Driver Driver Driver n/a
1 Driver Assistance Driving mode-specific control by an ADAS of either steering or speed Uses information about the driving environment and with the expectation that the driver performs all other driving tasks. Driver and system Some
2 Partial Automation Driving mode-specific execution by one or more driver assistance systems of both steering and speed System
3 Conditional Automation Driving mode-specific control by an ADAS of all aspects of driving Driver must appropriately respond to a request to intervene. System
4 High Automation If a driver does not respond appropriately to a request to intervene, the car can stop safely. System Many
5 Full Automation System controls the vehicle under all conditions. All

SAE Automation Levels have been criticized[by whom?] for their technological focus. It has been argued that the structure of the levels suggests that automation increases linearly and that more automation is better, which may not be the case.[87] SAE Levels also do not account for changes that may be required to infrastructure[88] and road user behavior.[89][90]

Mobileye System

[edit]

Mobileye CEO Amnon Shashua and CTO Shai Shalev-Shwartz proposed an alternative taxonomy for autonomous driving systems, claiming that a more consumer-friendly approach was needed. Its categories reflect the amount of driver engagement that is required.[91][92] Some vehicle makers have informally adopted some of the terminology involved, while not formally committing to it.[93][94][95][96]

Eyes-on/hands-on

[edit]

The first level, hands-on/eyes-on, implies that the driver is fully engaged in operating the vehicle, but is supervised by the system, which intervenes according to the features it supports (e.g., adaptive cruise control, automatic emergency braking). The driver is entirely responsible, with hands on the wheel, and eyes on the road.[92]

Eyes-on/hands-off

[edit]

Eyes-on/hands-off allows the driver to let go of the wheel. The system drives, the driver monitors and remains prepared to resume control as needed.[92]

Eyes-off/hands-off

[edit]

Eyes-off/hands-off means that the driver can stop monitoring the system, leaving the system in full control. Eyes-off requires that no errors be reproducible (not triggered by exotic transitory conditions) or frequent, that speeds are contextually appropriate (e.g., 80 mph on limited-access roads), and that the system handle typical maneuvers (e.g., getting cut off by another vehicle). The automation level could vary according to the road (e.g., eyes-off on freeways, eyes-on on side streets).[92]

No driver

[edit]

The highest level does not require a human driver in the car: monitoring is done either remotely (telepresence) or not at all.[92]

Safety

[edit]

A critical requirement for the higher two levels is that the vehicle be able to conduct a Minimum Risk Maneuver and stop safely out of traffic without driver intervention.[92]

Technology

[edit]

Architecture

[edit]

The perception system processes visual and audio data from outside and inside the car to create a local model of the vehicle, the road, traffic, traffic controls and other observable objects, and their relative motion. The control system then takes actions to move the vehicle, considering the local model, road map, and driving regulations.[97][98][99][100]

Several classifications have been proposed to describe ADAS technology. One proposal is to adopt these categories: navigation, path planning, perception, and car control.[101]

[edit]

Navigation involves the use of maps to define a path between origin and destination. Hybrid navigation is the use of multiple navigation systems. Some systems use basic maps, relying on perception to deal with anomalies. Such a map understands which roads lead to which others, whether a road is a freeway, a highway, are one-way, etc. Other systems require highly detailed maps, including lane maps, obstacles, traffic controls, etc.

Perception

[edit]

ACs need to be able to perceive the world around them. Supporting technologies include combinations of cameras, LiDAR, radar, audio, and ultrasound,[102] GPS, and inertial measurement.[103][104][105] Deep neural networks are used to analyse inputs from these sensors to detect and identify objects and their trajectories.[106] Some systems use Bayesian simultaneous localization and mapping (SLAM) algorithms. Another technique is detection and tracking of other moving objects (DATMO), used to handle potential obstacles.[107][108] Other systems use roadside real-time locating system (RTLS) technologies to aid localization. Tesla's "vision only" system uses eight cameras, without LIDAR or radar, to create its bird's-eye view of the environment.[109]

Path planning

[edit]

Path planning finds a sequence of segments that a vehicle can use to move from origin to destination. Techniques used for path planning include graph-based search and variational-based optimization techniques. Graph-based techniques can make harder decisions such as how to pass another vehicle/obstacle. Variational-based optimization techniques require more stringent restrictions on the vehicle's path to prevent collisions.[110] The large scale path of the vehicle can be determined by using a voronoi diagram, an occupancy grid mapping, or a driving corridor algorithm. The latter allows the vehicle to locate and drive within open space that is bounded by lanes or barriers.[111]

Maps

[edit]

Maps are necessary for navigation. Map sophistication varies from simple graphs that show which roads connect to each other, with details such as one-way vs two-way, to those that are highly detailed, with information about lanes, traffic controls, roadworks, and more.[102] Researchers at the MITComputer Science and Artificial Intelligence Laboratory (CSAIL) developed a system called MapLite, which allows self-driving cars to drive with simple maps. The system combines the GPS position of the vehicle, a "sparse topological map" such as OpenStreetMap (which has only 2D road features), with sensors that observe road conditions.[112] One issue with highly-detailed maps is updating them as the world changes. Vehicles that can operate with less-detailed maps do not require frequent updates or geo-fencing.

Sensors

[edit]

Sensors are necessary for the vehicle to properly respond to the driving environment. Sensor types include cameras, LiDAR, ultrasound, and radar. Control systems typically combine data from multiple sensors.[113] Multiple sensors can provide a more complete view of the surroundings and can be used to cross-check each other to correct errors.[114] For example, radar can image a scene in, e.g., a nighttime snowstorm, that defeats cameras and LiDAR, albeit at reduced precision. After experimenting with radar and ultrasound, Tesla adopted a vision-only approach, asserting that humans drive using only vision, and that cars should be able to do the same, while citing the lower cost of cameras versus other sensor types.[115] By contrast, Waymo makes use of the higher resolution of LiDAR sensors and cites the declining cost of that technology.[116]

Drive by wire

[edit]

Drive by wire is the use of electrical or electro-mechanical systems for performing vehicle functions such as steering or speed control that are traditionally achieved by mechanical linkages.

Driver monitoring

[edit]

Driver monitoring is used to assess the driver's attention and alertness. Techniques in use include eye monitoring, and requiring the driver to maintain torque on the steering wheel.[117] It attempts to understand driver status and identify dangerous driving behaviors.[118]

Vehicle communication

[edit]

Vehicles can potentially benefit from communicating with others to share information about traffic, road obstacles, to receive map and software updates, etc.[119][120][102]

ISO/TC 22 specifies in-vehicle transport information and control systems,[121] while ISO/TC 204 specifies information, communication and control systems in surface transport.[122] International standards have been developed for ADAS functions, connectivity, human interaction, in-vehicle systems, management/engineering, dynamic map and positioning, privacy and security.[123]

Rather than communicating among vehicles, they can communicate with road-based systems to receive similar information.

Software update

[edit]

Software controls the vehicle, and can provide entertainment and other services. Over-the-air updates can deliver bug fixes and additional features over the internet. Software updates are one way to accomplish recalls that in the past required a visit to a service center. In March 2021, the UNECE regulation on software update and software update management systems was published.[124]

Safety model

[edit]

A safety model is software that attempts to formalize rules that ensure that ACs operate safely.[125]

IEEE is attempting to forge a standard for safety models as "IEEE P2846: A Formal Model for Safety Considerations in Automated Vehicle Decision Making".[126] In 2022, a research group at National Institute of Informatics (NII, Japan) enhanced Mobileye's Reliable Safety System as "Goal-Aware RSS" to enable RSS rules to deal with complex scenarios via program logic.[127]

Notification

[edit]

The US has standardized the use of turquoise lights to inform other drivers that a vehicle is driving autonomously. It will be used in the 2026 Mercedes-Benz EQS and S-Class sedans with Drive Pilot, an SAE Level 3 driving system.[citation needed]

As of 2023, the Turquoise light had not been standardized by the P.R.C or the UN-ECE.[128]

Artificial Intelligence

[edit]

Artificial intelligence (AI) plays a pivotal role in the development and operation of autonomous vehicles (AVs), enabling them to perceive their surroundings, make decisions, and navigate safely without human intervention. AI algorithms empower AVs to interpret sensory data from various onboard sensors, such as cameras, LiDAR, radar, and GPS, to understand their environment and improve its technological ability and overall safety over time.[129]

Challenges

[edit]
Autonomous delivery vehicles stuck in one place by attempting to avoid one another

Obstacles

[edit]

The primary obstacle to ACs is the advanced software and mapping required to make them work safely across the wide variety of conditions that drivers experience.[130] In addition to handling day/night driving in good and bad weather[131] on roads of arbitrary quality, ACs must cope with other vehicles, road obstacles, poor/missing traffic controls, flawed maps, and handle endless edge cases, such as following the instructions of a police officer managing traffic at a crash site.

Other obstacles include cost, liability,[132][133] consumer reluctance,[134] ethical dilemmas,[135][136] security,[137][138][139][140] privacy,[131] and legal/regulatory framework.[141] Further, AVs could automate the work of professional drivers, eliminating many jobs, which could slow acceptance.[142]

Concerns

[edit]

Deceptive marketing

[edit]

Tesla calls its Level 2 ADAS "Full Self-Driving (FSD) Beta".[143] US Senators Richard Blumenthal and Edward Markey called on the Federal Trade Commission (FTC) to investigate this marketing in 2021.[144] In December 2021 in Japan, Mercedes-Benz was punished by the Consumer Affairs Agency for misleading product descriptions.[145]

Mercedes-Benz was criticized for a misleading US commercial advertising E-Class models.[146] At that time, Mercedes-Benz rejected the claims and stopped its "self-driving car" ad campaign that had been running.[147][148] In August 2022, the California Department of Motor Vehicles (DMV) accused Tesla of deceptive marketing practices.[149]

With the Automated Vehicles Bill (AVB) self-driving car-makers could face prison for misleading adverts in the United-Kingdom.[150]

Security

[edit]

In the 2020s, concerns over ACs' vulnerability to cyberattacks and data theft emerged.[151]

Espionage

[edit]

In 2018 and 2019 former Apple engineers were charged with stealing information related to Apple's self-driving car project.[152][153][154] In 2021 the United States Department of Justice (DOJ) accused Chinese security officials of coordinating a hacking campaign to steal information from government entities, including research related to autonomous vehicles.[155][156] China has prepared "the Provisions on Management of Automotive Data Security (Trial) to protect its own data".[157][158]

Cellular Vehicle-to-Everything technologies are based on 5G wireless networks.[159] As of November 2022, the US Congress was considering the possibility that imported Chinese AC technology could facilitate espionage.[160]

Testing of Chinese automated cars in the US has raised concern over which US data are collected by Chinese vehicles to be stored in Chinese country and concern with any link with the Chinese communist party.[161]

Driver communications

[edit]

ACs complicate the need for drivers to communicate with each other, e.g., to decide which car enters an intersection first. In an AC without a driver, traditional means such as hand signals do not work (no driver, no hands).[162]

Behavior prediction

[edit]

ACs must be able to predict the behavior of possibly moving vehicles, pedestrians, etc in real time in order to proceed safely.[99] The task becomes more challenging the further into the future the prediction extends, requiring rapid revisions to the estimate to cope with unpredicted behavior. One approach is to wholly recompute the position and trajectory of each object many times per second. Another is to cache the results of an earlier prediction for use in the next one to reduce computational complexity.[163][164]

Handover

[edit]

The ADAS has to be able to safely accept control from and return control to the driver.[165]

Trust

[edit]

Consumers will avoid ACs unless they trust them as safe.[166][167] Robotaxis operating in San Francisco received pushback over perceived safety risks.[168] Automatic elevators were invented in 1900, but did not become common until operator strikes and trust was built with advertising and features such as an emergency stop button.[169][170] However, with repeated use of autonomous driving functions, drivers' behavior and trust in autonomous vehicles gradually improved and both entered a more stable state. At the same time this also improved the performance and reliability of the vehicle in complex conditions, thereby increasing public trust.[171]

Economics

[edit]

Autonomous also present various political and economic implications. The transportation sector holds significant sway in many the political and economic landscapes. For instance, many US states generates much annual revenue from transportation fees and taxes.[172] The advent of self-driving cars could profoundly affect the economy by potentially altering state tax revenue streams. Furthermore, the transition to autonomous vehicles might disrupt employment patterns and labor markets, particularly in industries heavily reliant on driving professions.[172] Data from the U.S. Bureau of Labor Statistics indicates that in 2019, the sector employed over two million individuals as tractor-trailer truck drivers.[173] Additionally, taxi and delivery drivers represented approximately 370,400 positions, and bus drivers constituted a workforce of over 680,000.[174][175][176] Collectively, this amounts to a conceivable displacement of nearly 2.9 million jobs, surpassing the job losses experienced in the 2008 Great Recession.[177]

Equity and Inclusion

[edit]

The prominence of certain demographic groups within the tech industry inevitably shapes the trajectory of autonomous vehicle (AV) development, potentially perpetuating existing inequalities. There are others in society without a political agenda who believe that the advancement of technology has nothing to do with promoting inequalities in certain groups and see this as a ridiculous presumption. [178]

Ethical issues

[edit]

Pedestrian Detection

[edit]

Research from Georgia Tech revealed that autonomous vehicle detection systems were generally five percent less effective at recognizing darker-skinned individuals. This accuracy gap persisted despite adjustments for environmental variables like lighting and visual obstructions.[179]

Rationale for liability

[edit]

Standards for liability have yet to be adopted to address crashes and other incidents. Liability could rest with the vehicle occupant, its owner, the vehicle manufacturer, or even the ADAS technology supplier, possibly depending on the circumstances of the crash.[180] Additionally, the infusion of ArtificiaI Intelligence technology in autonomous vehicles adds layers of complexity to ownership and ethical dynamics. Given that AI systems are inherently self-learning, a question arises of whether accountability should rest with the vehicle owner, the manufacturer, or the AI developer?[181]

Trolley problem

[edit]

The trolley problem is a thought experiment in ethics. Adapted for ACs, it considers an AC carrying one passenger confronts a pedestrian who steps in its way. The ADAS notionally has to choose between killing the pedestrian or swerving into a wall, killing the passenger.[182] Possible frameworks include deontology (formal rules) and utilitarianism (harm reduction).[99][183][184]

One public opinion survey reported that harm reduction was preferred, except that passengers wanted the vehicle to prefer them, while pedestrians took the opposite view. Utilitarian regulations were unpopular.[185] Additionally, cultural viewpoints exert substantial influence on shaping responses to these ethical quandaries. Another study found that cultural biases impact preferences in prioritizing the rescue of certain individuals over others in car accident scenarios.[181]

Privacy

[edit]

Some ACs require an internet connection to function, opening the possibility that a hacker might gain access to private information such as destinations, routes, camera recordings, media preferences, and/or behavioral patterns, although this is true of an internet-connected device.[186][187][188]

Road infrastructure

[edit]

ACs make use of road infrastructure (e.g., traffic signs, turn lanes) and may require modifications to that infrastructure to fully achieve their safety and other goals.[189] In March 2023, the Japanese government unveiled a plan to set up a dedicated highway lane for ACs.[190] In April 2023, JR East announced their challenge to raise their self-driving level of Kesennuma Line bus rapid transit (BRT) in rural area from the current Level 2 to Level 4 at 60 km/h.[191]

Testing

[edit]

Approaches

[edit]

ACs can be tested via digital simulations,[192][193] in a controlled test environment,[194] and/or on public roads. Road testing typically requires some form of permit[195] or a commitment to adhere to acceptable operating principles.[196] For example, New York requires a test driver to be in the vehicle, prepared to override the ADAS as necessary.[197]

2010s and disengagements

[edit]
A prototype of Waymo's self-driving car, navigating public streets in Mountain View, California in 2017

In California, self-driving car manufacturers are required to submit annual reports describing how often their vehicles autonomously disengaged from autonomous mode.[198] This is one measure of system robustness (ideally, the system should never disengage).[199]

In 2017, Waymo reported 63 disengagements over 352,545 mi (567,366 km) of testing, an average distance of 5,596 mi (9,006 km) between disengagements, the highest (best) among companies reporting such figures. Waymo also logged more autonomous miles than other companies. Their 2017 rate of 0.18 disengagements per 1,000 mi (1,600 km) was an improvement over the 0.2 disengagements per 1,000 mi (1,600 km) in 2016, and 0.8 in 2015. In March 2017, Uber reported an average of 0.67 mi (1.08 km) per disengagement. In the final three months of 2017, Cruise (owned by GM) averaged 5,224 mi (8,407 km) per disengagement over 62,689 mi (100,888 km).[200]

Disengagement data
Car maker California, 2016[200] California, 2018[citation needed] California, 2019[201]
Distance between
disengagements
Total distance traveled Distance between
disengagements
Total distance traveled Distance between
disengagements
Total distance traveled
Waymo 5,128 mi (8,253 km) 635,868 mi (1,023,330 km) 11,154 mi (17,951 km) 1,271,587 mi (2,046,421 km) 11,017 mi (17,730 km) 1,450,000 mi (2,330,000 km)
BMW 638 mi (1,027 km) 638 mi (1,027 km)
Nissan 263 mi (423 km) 6,056 mi (9,746 km) 210 mi (340 km) 5,473 mi (8,808 km)
Ford 197 mi (317 km) 590 mi (950 km)
General Motors 55 mi (89 km) 8,156 mi (13,126 km) 5,205 mi (8,377 km) 447,621 mi (720,376 km) 12,221 mi (19,668 km) 831,040 mi (1,337,430 km)
Aptiv 15 mi (24 km) 2,658 mi (4,278 km)
Tesla 3 mi (4.8 km) 550 mi (890 km)
Mercedes-Benz 2 mi (3.2 km) 673 mi (1,083 km) 1.5 mi (2.4 km) 1,749 mi (2,815 km)
Bosch 7 mi (11 km) 983 mi (1,582 km)
Zoox 1,923 mi (3,095 km) 30,764 mi (49,510 km) 1,595 mi (2,567 km) 67,015 mi (107,850 km)
Nuro 1,028 mi (1,654 km) 24,680 mi (39,720 km) 2,022 mi (3,254 km) 68,762 mi (110,662 km)
Pony.ai 1,022 mi (1,645 km) 16,356 mi (26,322 km) 6,476 mi (10,422 km) 174,845 mi (281,386 km)
Baidu (Apolong) 206 mi (332 km) 18,093 mi (29,118 km) 18,050 mi (29,050 km) 108,300 mi (174,300 km)
Aurora 100 mi (160 km) 32,858 mi (52,880 km) 280 mi (450 km) 39,729 mi (63,938 km)
Apple 1.1 mi (1.8 km) 79,745 mi (128,337 km) 118 mi (190 km) 7,544 mi (12,141 km)
Uber 0.4 mi (0.64 km) 26,899 mi (43,290 km) 0 mi (0 km)

2020s

[edit]

Disengagement definitions

[edit]

Reporting companies use varying definitions of what qualifies as a disengagement, and such definitions can change over time.[202][199] Executives of self-driving car companies have criticized disengagements as a deceptive metric, because it does not consider varying road conditions.[203]

Standards

[edit]

In April 2021, WP.29 GRVA proposed a "Test Method for Automated Driving (NATM)".[204]

In October 2021, Europe's pilot test, L3Pilot, demonstrated ADAS for cars in Hamburg, Germany, in conjunction with ITS World Congress 2021. SAE Level 3 and 4 functions were tested on ordinary roads.[205][206][207]

In November 2022, an International Standard ISO 34502 on "Scenario based safety evaluation framework" was published.[208][209]

Collision avoidance

[edit]

In April 2022, collision avoidance testing was demonstrated by Nissan.[210][211] Waymo published a document about collision avoidance testing in December 2022.[212]

Simulation and validation

[edit]

In September 2022, Biprogy released Driving Intelligence Validation Platform (DIVP) as part of Japanese national project "SIP-adus", which is interoperable with Open Simulation Interface (OSI) of ASAM.[213][214][215]

Toyota

[edit]

In November 2022, Toyota demonstrated one of its GR Yaris test cars, which had been trained using professional rally drivers.[216] Toyota used its collaboration with Microsoft in FIA World Rally Championship since the 2017 season.[217]

Pedestrian reactions

[edit]

In 2023 David R. Large, senior research fellow with the Human Factors Research Group at the University of Nottingham, disguised himself as a car seat in a study to test people's reactions to driverless cars. He said, "We wanted to explore how pedestrians would interact with a driverless car and developed this unique methodology to explore their reactions." The study found that, in the absence of someone in the driving seat, pedestrians trust certain visual prompts more than others when deciding whether to cross the road.[218]

Incidents

[edit]

Tesla

[edit]

As of 2023, Tesla's ADAS Autopilot/Full Self Driving (beta) was classified as Level 2 ADAS.[219]

On 20 January 2016, the first of five known fatal crashes of a Tesla with Autopilot occurred, in China's Hubei province.[220] Initially, Tesla stated that the vehicle was so badly damaged from the impact that their recorder was not able to determine whether the car had been on Autopilot at the time. However, the car failed to take evasive action.

Another fatal Autopilot crash occurred in May in Florida in a Tesla Model S[221][222] that crashed into a tractor-trailer. In a civil suit between the father of the driver killed and Tesla, Tesla documented that the car had been on Autopilot.[223] According to Tesla, "neither Autopilot nor the driver noticed the white side of the tractor-trailer against a brightly lit sky, so the brake was not applied." Tesla claimed that this was Tesla's first known Autopilot death in over 130 million miles (210 million kilometers) with Autopilot engaged. Tesla claimed that on average one fatality occurs every 94 million miles (151 million kilometers) across all vehicle types in the US.[224][225][226] However, this number also includes motorcycle/pedestrian fatalities.[227][228] The ultimate National Transportation Safety Board (NTSB) report concluded Tesla was not at fault; the investigation revealed that for Tesla cars, the crash rate dropped by 40 percent after Autopilot was installed.[229]

Google Waymo

[edit]
Google's in-house automated car

In June 2015, Google confirmed that 12 vehicles had suffered collisions as of that date. Eight involved rear-end collisions at a stop sign or traffic light, in two of which the vehicle was side-swiped by another driver, one in which another driver rolled a stop sign, and one where a driver was controlling the car manually.[230] In July 2015, three employees suffered minor injuries when their vehicle was rear-ended by a car whose driver failed to brake. This was the first collision that resulted in injuries.[231]

According to Google Waymo's accident reports as of early 2016, their test cars had been involved in 14 collisions, of which other drivers were at fault 13 times, although in 2016 the car's software caused a crash.[232] On 14 February 2016 a Google vehicle attempted to avoid sandbags blocking its path. During the maneuver it struck a bus. Google stated, "In this case, we clearly bear some responsibility, because if our car hadn't moved, there wouldn't have been a collision."[233][234] Google characterized the crash as a misunderstanding and a learning experience. No injuries were reported.[232]

Uber's Advanced Technologies Group (ATG)

[edit]

In March 2018, Elaine Herzberg died after she was hit by an AC tested by Uber's Advanced Technologies Group (ATG) in Arizona. A safety driver was in the car. Herzberg was crossing the road about 400 feet from an intersection.[235] Some experts said a human driver could have avoided the crash.[236] Arizona governor Doug Ducey suspended the company's ability to test its ACs citing an "unquestionable failure" of Uber to protect public safety.[237] Uber also stopped testing in California until receiving a new permit in 2020.[238][239]

NTSB's final report determined that the immediate cause of the accident was that safety driver Rafaela Vasquez failed to monitor the road, because she was distracted by her phone, but that Uber's "inadequate safety culture" contributed. The report noted that the victim had "a very high level" of methamphetamine in her body.[240] The board called on federal regulators to carry out a review before allowing automated test vehicles to operate on public roads.[241][242]

In September 2020, Vasquez pled guilty to endangerment and was sentenced to three years' probation.[243][39]

NIO Navigate on Pilot

[edit]

On 12 August 2021, a 31-year-old Chinese man was killed after his NIO ES8 collided with a construction vehicle.[citation needed] NIO's self-driving feature was in beta and could not deal with static obstacles.[244] The vehicle's manual clearly stated that the driver must take over near construction sites. Lawyers of the deceased's family questioned NIO's private access to the vehicle, which they argued did not guarantee the integrity of the data.[245]

Pony.ai

[edit]

In November 2021, the California Department of Motor Vehicles (DMV) notified Pony.ai that it was suspending its testing permit following a reported collision in Fremont on 28 October.[246] In May 2022, DMV revoked Pony.ai's permit for failing to monitor the driving records of its safety drivers.[247]

Cruise

[edit]

In April 2022, Cruise's testing vehicle was reported to have blocked a fire engine on emergency call, and sparked questions about its ability to handle unexpected circumstances.[248][249]

Ford

[edit]

In February 2024, a driver using the Ford BlueCruise hands-free driving feature struck and killed the driver of a stationary car with no lights on in the middle lane of a freeway in Texas.[250]

In March 2024, a drunk driver who was speeding, holding her cell phone, and using BlueCruise on a Pennsylvania freeway struck and killed two people who had been driving two cars.[251] The first car had become disabled and was on the left shoulder with part of the car in the left driving lane.[251] The second driver had parked his car behind the first car presumably to help the first driver.[251]

The NTSB is investigating both incidents.[252]

Total incidents

[edit]

The NHTSA began mandating incident reports from autonomous vehicle companies in June 2021. Some reports cite incidents from as early as August 2019, with current data available through June 17, 2024.[253]

There have been a total of 3,979 autonomous vehicle incidents (both ADS and ADAS) reported during this timeframe. 2,146 of those incidents (53.9%) involved Tesla vehicles.[254]

Public opinion surveys

[edit]

2010s

[edit]

In a 2011 online survey of 2,006 US and UK consumers, 49% said they would be comfortable using a "driverless car".[255]

A 2012 survey of 17,400 vehicle owners found 37% who initially said they would be interested in purchasing a "fully autonomous car". However, that figure dropped to 20% if told the technology would cost US$3,000 more.[256]

In a 2012 survey of about 1,000 German drivers, 22% had a positive attitude, 10% were undecided, 44% were skeptical and 24% were hostile.[257]

A 2013 survey of 1,500 consumers across 10 countries found 57% "stated they would be likely to ride in a car controlled entirely by technology that does not require a human driver", with Brazil, India and China the most willing to trust automated technology.[258]

In a 2014 US telephone survey, over three-quarters of licensed drivers said they would consider buying a self-driving car, rising to 86% if car insurance were cheaper. 31.7% said they would not continue to drive once an automated car was available.[259]

In 2015, a survey of 5,000 people from 109 countries reported that average respondents found manual driving the most enjoyable. 22% did not want to pay more money for autonomy. Respondents were found to be most concerned about hacking/misuse, and were also concerned about legal issues and safety. Finally, respondents from more developed countries were less comfortable with their vehicle sharing data.[260] The survey reported consumer interest in purchasing an AC, stating that 37% of surveyed current owners were either "definitely" or "probably" interested.[260]

In 2016, a survey of 1,603 people in Germany that controlled for age, gender, and education reported that men felt less anxiety and more enthusiasm, whereas women showed the opposite. The difference was pronounced between young men and women and decreased with age.[261]

In a 2016 US survey of 1,584 people, "66 percent of respondents said they think autonomous cars are probably smarter than the average human driver". People were worried about safety and hacking risk. Nevertheless, only 13% of the interviewees saw no advantages in this new kind of cars.[262]

In a 2017 survey of 4,135 US adults found that many Americans anticipated significant impacts from various automation technologies including the widespread adoption of automated vehicles.[263]

In 2019, results from two opinion surveys of 54 and 187 US adults respectively were published. The questionnaire was termed the autonomous vehicle acceptance model (AVAM), including additional description to help respondents better understand the implications of various automation levels. Users were less accepting of high autonomy levels and displayed significantly lower intention to use autonomous vehicles. Additionally, partial autonomy (regardless of level) was perceived as requiring uniformly higher driver engagement (usage of hands, feet and eyes) than full autonomy.[264]

In the 2020s

[edit]

In 2022, a survey reported that only a quarter (27%) of the world's population would feel safe in self-driving cars.[265]

In 2024, a study by Saravanos et al.[266] at New York University reported that 87% of their respondents (from a sample of 358) believed that conditionally automated cars (at Level 3) would be easy to use.

Opinion surveys may have little salience given that few respondents had any personal experience with ACs.

Regulation

[edit]

The regulation of autonomous cars concerns liability, approvals, and international conventions.

In the 2010s, researchers openly worried that delayed regulations could delay deployment.[267] In 2020, UNECE WP.29 GRVA was issued to address regulation of Level 3 automated driving.

Commercialization

[edit]

Vehicles operating below Level 5 still offer many advantages.[268]

As of 2023 most commercially available ADAS vehicles are SAE Level 2. A couple of companies reached higher levels, but only in restricted (geofenced) locations.[269]

Level 2 – Partial Automation

[edit]

SAE Level 2 features are available as part of the ADAS systems in many vehicles. In the US, 50% of new cars provide driver assistance for both steering and speed.[270]

Ford started offering BlueCruise service on certain vehicles in 2022; the system is named ActiveGlide in Lincoln vehicles. The system provided features such as lane centering, street sign recognition, and hands-free highway driving on more than 130,000 miles of divided highways. The 2022 1.2 version added features including hands-free lane changing, in-lane repositioning, and predictive speed assist.[271][272] In April 2023 BlueCruise was approved in the UK for use on certain motorways, starting with 2023 models of Ford's electric Mustang Mach-E SUV.[273]

Tesla's Autopilot and its Full Self-Driving (FSD) ADAS suites are available on all Tesla cars since 2016. FSD offers highway and street driving (without geofencing), navigation/turn management, steering, and dynamic cruise control, collision avoidance, lane-keeping/switching, emergency braking, obstacle avoidance, but still requires the driver to remain ready to control the vehicle at any moment. Its driver management system combines eye tracking with monitoring pressure on the steering wheel to ensure that drives are both eyes on and hands on.[274][275]

Tesla's FSD rewrite V12 (released in March 2024) uses a single deep learning transformer model for all aspects of perception, monitoring, and control.[276][277] It relies on its eight cameras for its vision-only perception system, without use of LiDAR, radar, or ultrasound.[277] As of April 2024, FSD has been deployed on two million Tesla cars.[278] As of January 2024, Tesla has not initiated requests for Level 3 status for its systems and has not disclosed its reason for not doing so.[275]

Development

[edit]

General Motors is developing the "Ultra Cruise" ADAS system, that will be a dramatic improvement over their current "Super Cruise" system. Ultra Cruise will cover "95 percent" of driving scenarios on 2 million miles of roads in the US, according to the company. The system hardware in and around the car includes multiple cameras, short- and long-range radar, and a LiDAR sensor, and will be powered by the Qualcomm Snapdragon Ride Platform. The luxury Cadillac Celestiq electric vehicle will be one of the first vehicles to feature Ultra Cruise.[279]

Europe is developing a new "Driver Control Assistance Systems" (DCAS) level 2 regulation to no longer limit the use of lane changing systems to roads with 2 lanes and a physical separation from traffic in the opposite direction.[280][281]

Level 3 – Conditional Automation

[edit]

As of April 2024, two car manufacturers have sold or leased Level 3 cars: Honda in Japan, and Mercedes in Germany, Nevada and California.[53]

Mercedes Drive Pilot has been available on the EQS and S-class sedan in Germany since 2022, and in California and Nevada since 2023.[68] A subscription costs between €5,000 and €7,000 for three years in Germany and $2,500 for one year in the United States.[282] Drive Pilot can only be used when the vehicle is traveling under 40 miles per hour (64 km/h), there is a vehicle in front, readable line markings, during the day, clear weather, and on freeways mapped by Mercedes down to the centimeter (100,000 miles in California).[282][68] As of April 2024, one Mercedes vehicle with this capability has been sold in California.[282]

Development

[edit]

Honda continued to enhance its Level 3 technology.[283][284] As of 2023, 80 vehicles with Level 3 support had been sold.[285]

Mercedes-Benz received authorization in early 2023 to pilot its Level 3 software in Las Vegas.[15] California also authorized Drive Pilot in 2023.[286]

BMW commercialized its AC in 2021.[287] In 2023 BMW stated that its Level-3 technology was nearing release. It would be the second manufacturer to deliver Level-3 technology, but the only one with a Level 3 technology which works in the dark.[288]

In 2023, in China, IM Motors, Mercedes, and BMW obtained authorization to test vehicles with Level 3 systems on motorways.[289][290]

In September 2021, Stellantis presented its findings from its Level 3 pilot testing on Italian highways. Stellantis's Highway Chauffeur claimed Level 3 capabilities, as tested on the Maserati Ghibli and Fiat 500X prototypes.[291]

Polestar, a Volvo Cars' brand, announced in January 2022 its plan to offer Level 3 autonomous driving system in the Polestar 3 SUV, a Volvo XC90 successor, with technologies from Luminar Technologies, Nvidia, and Zenseact.[292]

In January 2022, Bosch and the Volkswagen Group subsidiary CARIAD released a collaboration for autonomous driving up to Level 3. This joint development targets Level 4 capabilities.[293]

Hyundai Motor Company is enhancing cybersecurity of connected cars to offer a Level 3 self-driving Genesis G90.[294] Kia and Hyundai Korean car makers delayed their Level 3 plans, and will not deliver Level 3 vehicles in 2023.[295]

Level 4 – High Automation

[edit]

Waymo offers robotaxi services in parts of Arizona (Phoenix) and California (San Francisco and Los Angeles), as fully autonomous vehicles without safety drivers.[296]

In April 2023 in Japan, a Level 4 protocol became part of the amended Road Traffic Act.[297] ZEN drive Pilot Level 4 made by AIST operates there.[298]

Development

[edit]

In July 2020, Toyota started public demonstration rides on Lexus LS (fifth generation) based TRI-P4 with Level 4 capability.[299] In August 2021, Toyota operated a potentially Level 4 service using e-Palette around the Tokyo 2020 Olympic Village.[300]

In September 2020, Mercedes-Benz introduced world's first commercial Level 4 Automated Valet Parking (AVP) system named Intelligent Park Pilot for its new S-Class.[301][302] In November 2022, Germany’s Federal Motor Transport Authority (KBA) approved the system for use at Stuttgart Airport.[303]

In September 2021, Cruise, General Motors, and Honda started a joint testing programme, using Cruise AV.[304] In 2023, the Origin was put on indefinite hold following Cruise's loss of its operating permit.[305]

In January 2023, Holon announced an autonomous shuttle during the 2023 Consumer Electronics Show (CES). The company claimed the vehicle is the world's first Level 4 shuttle built to automotive standard.[306]

See also

[edit]

References

[edit]
  1. ^ a b Taeihagh, Araz; Lim, Hazel Si Min (2 January 2019). "Governing autonomous vehicles: emerging responses for safety, liability, privacy, cybersecurity, and people risk". Transport Reviews. 39 (1): 103–128. arXiv:1807.05720. doi:10.1080/01441647.2018.1494640. ISSN 0144-1647. S2CID 49862783.
  2. ^ Maki, Sydney; Sage, Alexandria (19 March 2018). "Self-driving Uber car kills Arizona woman crossing street". Reuters. Retrieved 14 April 2019.
  3. ^ Thrun, Sebastian (2010). "Toward Robotic Cars". Communications of the ACM. 53 (4): 99–106. doi:10.1145/1721654.1721679. S2CID 207177792.
  4. ^ Xie, S.; Hu, J.; Bhowmick, P.; Ding, Z.; Arvin, F. (2022). "Distributed Motion Planning for Safe Autonomous Vehicle Overtaking via Artificial Potential Field". IEEE Transactions on Intelligent Transportation Systems. 23 (11): 21531–21547. doi:10.1109/TITS.2022.3189741. S2CID 250588120. Retrieved 2 February 2024.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  5. ^ Gehrig, Stefan K.; Stein, Fridtjof J. (1999). Dead reckoning and cartography using stereo vision for an automated car. IEEE/RSJ International Conference on Intelligent Robots and Systems. Vol. 3. Kyongju. pp. 1507–1512. doi:10.1109/IROS.1999.811692. ISBN 0-7803-5184-3.
  6. ^ Xie, S.; Hu, J.; Ding, Z.; Arvin, F. (2023). "Cooperative Adaptive Cruise Control for Connected Autonomous Vehicles Using Spring Damping Energy Model". IEEE Transactions on Vehicular Technology. 72 (3): 2974–2987. doi:10.1109/TVT.2022.3218575. S2CID 253359200. Retrieved 1 February 2024.
  7. ^ "Waymo's Robotaxis are Hitting the Highway, A First For Self Driving Cars". Forbes.
  8. ^ Valdes-Dapena, Peter (13 June 2024). "Waymo recalls driverless cars to make them less likely to drive into poles | CNN Business". CNN. Retrieved 21 June 2024.
  9. ^ a b Bellan, Rebecca (12 June 2024). "Waymo issues second recall after robotaxi hit telephone pole". TechCrunch. Retrieved 18 June 2024.
  10. ^ "Waymo recalls software in all its cars after its robotaxi crashes into a pole". NBC News. 13 June 2024. Retrieved 18 June 2024.
  11. ^ a b Vijayenthiran, Viknesh (2 February 2022). "Cruise opens up driverless taxi service to public in San Francisco". Motor Authority. Retrieved 27 March 2022.
  12. ^ a b "Honda to Begin Sales of Legend with New Honda SENSING Elite". Honda. 4 March 2021. Retrieved 6 March 2021.
  13. ^ a b "Honda to start selling world's 1st level-3 autonomous car for $103K on Fri". Kyodo News. 4 March 2021. Archived from the original on 5 March 2021. Retrieved 6 March 2021.
  14. ^ a b Beresford, Colin (4 March 2021). "Honda Legend Sedan with Level 3 Autonomy Available for Lease in Japan". Car and Driver. Retrieved 6 March 2021.
  15. ^ a b "Mercedes-Benz Drive Pilot certified for use in Nevada – first L3 system approved for US highways". 27 January 2023.
  16. ^ "'Phantom Auto' will tour city". Milwaukee Sentinel. 1926. p. 4. Cited in Munir, Farzeen; Azam, Shoaib; Hussain, Muhammad Ishfaq; Sheri, Ahmed Muqeem; Jeon, Moongu (2018). Autonomous Vehicle: The Architecture Aspect of Self Driving Car. Proceedings of the 2018 International Conference on Sensors, Signal and Image Processing. Association for Computing Machinery. doi:10.1145/3290589.3290599. ISBN 9781450366205. S2CID 58534759.
  17. ^ Srinivas, Rao P; Rohan Gudla; Vijay Shankar Telidevulapalli; Jayasree Sarada Kota; Gayathri Mandha (2022). "Review on self-driving cars using neural network architectures". World Journal of Advanced Research and Reviews. 16 (2): 736–746. doi:10.30574/wjarr.2022.16.2.1240.
  18. ^ Vanderbilt, Tom (6 February 2012). "Autonomous Cars Through The Ages". Wired. Retrieved 26 July 2018.
  19. ^ Weber, Marc (8 May 2014). "Where to? A History of Autonomous Vehicles". Computer History Museum. Retrieved 26 July 2018.
  20. ^ "Carnegie Mellon". Navlab: The Carnegie Mellon University Navigation Laboratory. The Robotics Institute. Retrieved 20 December 2014.
  21. ^ Kanade, Takeo (February 1986). "Autonomous land vehicle project at CMU". Proceedings of the 1986 ACM fourteenth annual conference on Computer science - CSC '86. pp. 71–80. doi:10.1145/324634.325197. ISBN 9780897911771. S2CID 2308303.
  22. ^ Wallace, Richard (1985). First results in robot road-following (PDF). JCAI'85 Proceedings of the 9th International Joint Conference on Artificial Intelligence. Archived from the original (PDF) on 6 August 2014.
  23. ^ Schmidhuber, Jürgen (2009). "Prof. Schmidhuber's highlights of robot car history". Retrieved 15 July 2011.
  24. ^ Turk, M.A.; Morgenthaler, D.G.; Gremban, K.D.; Marra, M. (May 1988). "VITS-a vision system for automated land vehicle navigation". IEEE Transactions on Pattern Analysis and Machine Intelligence. 10 (3): 342–361. doi:10.1109/34.3899. ISSN 0162-8828.
  25. ^ "Look, Ma, No Hands". Carnegie Mellon University. Retrieved 2 March 2017.
  26. ^ "Navlab 5 Details". cs.cmu.edu. Retrieved 2 March 2017.
  27. ^ Crowe, Steve (3 April 2015). "Back to the Future: Autonomous Driving in 1995". Robotics Trends. Archived from the original on 29 December 2017. Retrieved 2 March 2017.
  28. ^ "NHAA Journal". cs.cmu.edu. Retrieved 5 March 2017.
  29. ^ Technology Development for Army Unmanned Ground Vehicles. National Research Council. 2002. doi:10.17226/10592. ISBN 9780309086202.
  30. ^ "The Automated Highway System: An Idea Whose Time Has Come | FHWA". highways.dot.gov. Retrieved 30 August 2023.
  31. ^ Novak, Matt. "The National Automated Highway System That Almost Was". Smithsonian. Retrieved 8 June 2018.
  32. ^ "Back to the Future: Autonomous Driving in 1995". Robotics Business Review. 3 April 2015. Archived from the original on 12 June 2018. Retrieved 8 June 2018.
  33. ^ "This Is Big: A Robo-Car Just Drove Across the Country". WIRED. Retrieved 8 June 2018.
  34. ^ Ramsey, John (1 June 2015). "Self-driving cars to be tested on Virginia highways". Richmond Times-Dispatch. Retrieved 4 June 2015.
  35. ^ Meyer, Gereon (2018). "European Roadmaps, Programs, and Projects for Innovation in Connected and Automated Road Transport". In G. Meyer; S. Beiker (eds.). Road Vehicle Automation. Lecture Notes in Mobility. Springer. pp. 27–39. doi:10.1007/978-3-319-94896-6_3. ISBN 978-3-319-94895-9. S2CID 169808153.
  36. ^ STRIA Roadmap Connected and Automated Transport: Road, Rail and Waterborne (PDF). European Commission. 2019. Archived from the original (PDF) on 16 October 2022. Retrieved 10 November 2019.
  37. ^ Hawkins, Andrew J. (7 November 2017). "Waymo is first to put fully self-driving cars on US roads without a safety driver". The Verge. Retrieved 7 November 2017.
  38. ^ "FAQ – Early Rider Program". Waymo. Retrieved 30 November 2018.
  39. ^ a b Billeaud, Jacques; Snow, Anita (28 July 2023). "The backup driver in the 1st death by a fully autonomous car pleads guilty to endangerment". Associated Press. Retrieved 1 September 2024.
  40. ^ "Waymo launches nation's first commercial self-driving taxi service in Arizona". The Washington Post. Retrieved 6 December 2018.
  41. ^ "Waymo's Self-Driving Future Looks Real Now That the Hype Is Fading". Bloomberg.com. 21 January 2021. Retrieved 5 March 2021.
  42. ^ a b Ackerman, Evan (4 March 2021). "What Full Autonomy Means for the Waymo Driver". IEEE Spectrum: Technology, Engineering, and Science News. Retrieved 8 March 2021.
  43. ^ Hawkins, Andrew J. (8 October 2020). "Waymo will allow more people to ride in its fully driverless vehicles in Phoenix". The Verge. Retrieved 5 March 2021.
  44. ^ Suggitt, Connie (17 October 2019). "Robocar: Watch the world's fastest autonomous car reach its record-breaking 282 km/h". Guinness World Records.
  45. ^ "世界初! 自動運転車(レベル3)の型式指定を行いました" [The world's first! approval of level-3 type designation for certification]. MLIT, Japan (in Japanese). 11 November 2020. Retrieved 6 March 2021.
  46. ^ "Nuro set to be California's first driverless delivery service". BBC News. 24 December 2020. Retrieved 27 December 2020.
  47. ^ Staff, The Robot Report (14 September 2021). "DeepRoute.ai closes $300M Series B funding round". The Robot Report.
  48. ^ "Mercedes-Benz self-driving car technology approved for use". Feet News. 9 December 2021. Archived from the original on 9 December 2021. Retrieved 10 December 2021.
  49. ^ "Slow Self-Driving Car Progress Tests Investors' Patience". The Wall Street Journal. 28 November 2022. Retrieved 14 December 2022.
  50. ^ Shepardson, David; Klayman, Ben (14 November 2023). "GM's Cruise suspends supervised and manual car trips, expands probes".
  51. ^ "https://twitter.com/nuro/status/1688965912165265408". Twitter. Retrieved 10 August 2023. {{cite web}}: External link in |title= (help)
  52. ^ AUTOCRYPT (13 January 2023). "The State of Level 3 Autonomous Driving in 2023". AUTOCRYPT. Retrieved 21 April 2024.
  53. ^ a b Tucker, Sean (9 January 2024). "Self-Driving Cars: Everything You Need To Know". Kelley Blue Book. Retrieved 21 April 2024.
  54. ^ Umar Zakir Abdul, Hamid; et al. (2021). "Adopting Aviation Safety Knowledge into the Discussions of Safe Implementation of Connected and Autonomous Road Vehicles". SAE Technical Papers (SAE WCX Digital Summit) (2021–01–0074). Retrieved 12 April 2021.
  55. ^ Morris, David (8 November 2020). "What's in a name? For Tesla's Full Self Driving, it may be danger". Fortune. Retrieved 8 March 2021.
  56. ^ Boudette, Neal E. (23 March 2021). "Tesla's Autopilot Technology Faces Fresh Scrutiny". The New York Times. Archived from the original on 28 December 2021. Retrieved 15 June 2021.
  57. ^ Cellan-Jones, Rory (12 June 2018). "Insurers warning on "autonomous" cars". BBC News.
  58. ^ "An Integrated Approach for Predicting Consumer Acceptance of Self-Driving Vehicles in the United States". Journal of Marketing Development and Competitiveness. 15 (2). 14 July 2021. doi:10.33423/jmdc.v15i2.4330. ISSN 2155-2843.
  59. ^ Aleksa, Michael; Schaub, Andrea; Erdelean, Isabela; Wittmann, Stephan; Soteropoulos, Aggelos; Fürdös, Alexander (27 June 2024). "Impact analysis of Advanced Driver Assistance Systems (ADAS) regarding road safety – computing reduction potentials". European Transport Research Review. 16 (1): 39. Bibcode:2024ETRR...16...39A. doi:10.1186/s12544-024-00654-0. ISSN 1866-8887.
  60. ^ Antsaklis, Panos J.; Passino, Kevin M.; Wang, S.J. (1991). "An Introduction to Autonomous Control Systems" (PDF). IEEE Control Systems Magazine. 11 (4): 5–13. CiteSeerX 10.1.1.840.976. doi:10.1109/37.88585. Archived from the original (PDF) on 16 May 2017. Retrieved 21 January 2019.
  61. ^ "Autonomous Emergency Braking – Euro NCAP". euroncap.com.
  62. ^ a b c Regulation (EU) 2019/2144
  63. ^ Yu, Yang; Lee, Sanghwan (16 June 2022). "Remote Driving Control With Real-Time Video Streaming Over Wireless Networks: Design and Evaluation". IEEE Access. 10: 64920–64932. Bibcode:2022IEEEA..1064920Y. doi:10.1109/ACCESS.2022.3183758.
  64. ^ Lee, Chung Won; Nayeer, Nasif; Garcia, Danson Evan; Agrawal, Ankur; Liu, Bingbing (October 2020). "Identifying the Operational Design Domain for an Automated Driving System through Assessed Risk". 2020 IEEE Intelligent Vehicles Symposium (IV). pp. 1317–1322. doi:10.1109/IV47402.2020.9304552. ISBN 978-1-7281-6673-5. S2CID 231599295.
  65. ^ a b Erz, Jannis; Schütt, Barbara; Braun, Thilo; Guissouma, Houssem; Sax, Eric (April 2022). "Towards an Ontology That Reconciles the Operational Design Domain, Scenario-based Testing, and Automated Vehicle Architectures". 2022 IEEE International Systems Conference (SysCon). pp. 1–8. doi:10.1109/SysCon53536.2022.9773840. ISBN 978-1-6654-3992-3. S2CID 248850678.
  66. ^ Lambert, Fred (8 March 2023). "Tesla pushes new Full Self-Driving Beta v11 update as it slowly expands rollout". electrek.co.
  67. ^ Ohnsman, Alan. "Waymo's Robotaxis Are Hitting The Highway, A First For Self-Driving Cars". Forbes. Retrieved 13 February 2024.
  68. ^ a b c Golson, Daniel (27 September 2023). "We put our blind faith in Mercedes-Benz's first-of-its-kind autonomous Drive Pilot feature". The Verge. Retrieved 13 February 2024.
  69. ^ "Mobileye SuperVision™ | The Bridge from ADAS to Consumer AVs". Mobileye. Retrieved 14 February 2024.
  70. ^ HUNT, RHIAN (15 February 2024). "GM Adding 350,000 Miles Of Super Cruise Road Coverage". GM Authority.
  71. ^ Wardlaw, Christian (20 April 2021). "What is Ford BlueCruise, and How Does It Work?". jdpower.com.
  72. ^ "Self-Driving Cars Explained". Union of Concerned Scientists.
  73. ^ "Automated and Electric Vehicles Act 2018 becomes law". penningtonslaw.com. Retrieved 24 March 2021.
  74. ^ "Self-driving vehicles listed for use in Great Britain". GOV.UK. 20 April 2022. Retrieved 19 July 2022.
  75. ^ Hancocks, Simon (26 October 2020). "The ABI and Thatcham warn against automated driving plans". Visordown.
  76. ^ Automated and Electric Vehicles Act 2018
  77. ^ "Automated Vehicle Bill".
  78. ^ "Support – Autopilot". Tesla. 13 February 2019. Archived from the original on 10 April 2019. Retrieved 6 September 2019.
  79. ^ Roberto Baldwin (9 March 2021). "Tesla Tells California DMV that FSD Is Not Capable of Autonomous Driving". Car and Driver.
  80. ^ SAE International (30 April 2021). "Taxonomy and Definitions for Terms Related to Driving Automation Systems for On-Road Motor Vehicles (SAE J3016)". Archived from the original on 20 December 2021. Retrieved 25 December 2021.
  81. ^ SAE International
  82. ^ "Federal Automated Vehicles Policy" (PDF). NHTSA, U.S. September 2016. p. 9. Retrieved 1 December 2021.
  83. ^ "JASO TP 18004: 自動車用運転自動化システムのレベル分類及び定義" [JASO TP 18004: Taxonomy and Definitions for Terms Related to Driving Automation Systems] (PDF). JASO, Japan. 1 February 2018. Archived from the original (PDF) on 1 December 2021. Retrieved 1 December 2021.
  84. ^ Steckhan, Lorenz; Spiessl, Wolfgang; Quetschlich, Nils; Bengler, Klaus (2022), Krömker, Heidi (ed.), "Beyond SAE J3016: New Design Spaces for Human-Centered Driving Automation", HCI in Mobility, Transport, and Automotive Systems, Lecture Notes in Computer Science, vol. 13335, Cham: Springer International Publishing, pp. 416–434, doi:10.1007/978-3-031-04987-3_28, ISBN 978-3-031-04986-6, retrieved 24 January 2023
  85. ^ Inagaki, Toshiyuki; Sheridan, Thomas B. (November 2019). "A critique of the SAE conditional driving automation definition, and analyses of options for improvement". Cognition, Technology & Work. 21 (4): 569–578. doi:10.1007/s10111-018-0471-5. hdl:1721.1/116231. ISSN 1435-5558. S2CID 254144879.
  86. ^ a b "Automated Driving – Levels of Driving Automation are Defined in New SAE International Standard J3016" (PDF). SAE International. 2014. Archived (PDF) from the original on 1 July 2018.
  87. ^ Stayton, E.; Stilgoe, J. (September 2020). "It's Time to Rethink Levels of Automation for Self-Driving Vehicles [Opinion]". IEEE Technology and Society Magazine. 39 (3): 13–19. doi:10.1109/MTS.2020.3012315. ISSN 1937-416X.
  88. ^ "Preparing the UK's motorways for self-driving vehicles: New £1m research project announced in partnership with Highways England". Loughborough University. 6 July 2020. Retrieved 13 April 2021.
  89. ^ Cavoli, Clemence; Phillips, Brian (2017). "Social and behavioural questions associated with Automated Vehicles A Literature Review" (PDF). UCL Transport Institute. Tom Cohen.
  90. ^ Parkin, John; Clark, Benjamin; Clayton, William; Ricci, Miriam; Parkhurst, Graham (27 October 2017). "Autonomous vehicle interactions in the urban street environment: a research agenda". Proceedings of the Institution of Civil Engineers - Municipal Engineer. 171 (1): 15–25. doi:10.1680/jmuen.16.00062. ISSN 0965-0903.
  91. ^ Hagman, Brian (16 February 2023). "Mobileye Proposes New Taxonomy and Requirements for Consumer Autonomous Vehicles to Ensure Clarity, Safety, and Scalability". Self Drive News. Retrieved 4 February 2024.
  92. ^ a b c d e f Shashua, Amnon; Shalev-Shwartz, Shai (5 February 2023). "Defining a New Taxonomy for Consumer Autonomous Vehicles".
  93. ^ "Ford BlueCruise | Consumer Reports Top-Rated Active Driving Assistance System | Ford.com". Ford Motor Company. Retrieved 8 February 2024.
  94. ^ "Hands-Free, Eyes On". www.gm.com. Retrieved 8 February 2024.
  95. ^ "Level 2 of autonomous driving - "EYES ON / HANDS OFF"". Valeo. Retrieved 8 February 2024.
  96. ^ Dow, Jameson (27 September 2023). "Hands-off with the first true hands-free car in the US, and it's not Tesla". Electrek.co. Retrieved 8 February 2024.
  97. ^ Hu, J.; Bhowmick, P.; Jang, I.; Arvin, F.; Lanzon, A. (2021). "A Decentralized Cluster Formation Containment Framework for Multirobot Systems". IEEE Transactions on Robotics. 37 (6): 1936–1955. doi:10.1109/TRO.2021.3071615. Retrieved 2 February 2024 – via ieeexplore.ieee.org.
  98. ^ "European Roadmap Smart Systems for Automated Driving" (PDF). EPoSS. 2015. Archived from the original (PDF) on 12 February 2015.
  99. ^ a b c Lim, THazel Si Min; Taeihagh, Araz (2019). "Algorithmic Decision-Making in AVs: Understanding Ethical and Technical Concerns for Smart Cities". Sustainability. 11 (20): 5791. arXiv:1910.13122. Bibcode:2019arXiv191013122L. doi:10.3390/su11205791. S2CID 204951009.
  100. ^ Matzliach, Barouch (2022). "Detection of Static and Mobile Targets by an Autonomous Agent with Deep Q-Learning Abilities". Entropy. 24 (8). Entropy, 2022, 24, 1168: 1168. Bibcode:2022Entrp..24.1168M. doi:10.3390/e24081168. PMC 9407070. PMID 36010832.
  101. ^ Zhao, Jianfeng; Liang, Bodong; Chen, Qiuxia (2 January 2018). "The key technology toward the self-driving car". International Journal of Intelligent Unmanned Systems. 6 (1): 2–20. doi:10.1108/IJIUS-08-2017-0008. ISSN 2049-6427.
  102. ^ a b c "2020 Autonomous Vehicle Technology Report". Wevolver. 20 February 2020. Retrieved 11 April 2022.
  103. ^ Huval, Brody; Wang, Tao; Tandon, Sameep; Kiske, Jeff; Song, Will; Pazhayampallil, Joel (2015). "An Empirical Evaluation of Deep Learning on Highway Driving". arXiv:1504.01716 [cs.RO].
  104. ^ Corke, Peter; Lobo, Jorge; Dias, Jorge (1 June 2007). "An Introduction to Inertial and Visual Sensing". The International Journal of Robotics Research. 26 (6): 519–535. CiteSeerX 10.1.1.93.5523. doi:10.1177/0278364907079279. S2CID 206499861.
  105. ^ Ahangar, M. Nadeem; Ahmed, Qasim Z.; Khan, Fahd A.; Hafeez, Maryam (January 2021). "A Survey of Autonomous Vehicles: Enabling Communication Technologies and Challenges". Sensors. 21 (3): 706. Bibcode:2021Senso..21..706A. doi:10.3390/s21030706. ISSN 1424-8220. PMC 7864337. PMID 33494191.
  106. ^ Li, Li; Shum, Hubert P. H.; Breckon, Toby P. (2023). "Less is More: Reducing Task and Model Complexity for 3D Point Cloud Semantic Segmentation". 2023 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR). IEEE/CVF. pp. 9361–9371. arXiv:2303.11203. doi:10.1109/CVPR52729.2023.00903. ISBN 979-8-3503-0129-8.
  107. ^ Durrant-Whyte, H.; Bailey, T. (5 June 2006). "Simultaneous localization and mapping". IEEE Robotics & Automation Magazine. 13 (2): 99–110. CiteSeerX 10.1.1.135.9810. doi:10.1109/mra.2006.1638022. ISSN 1070-9932. S2CID 8061430.
  108. ^ "A Brief Survey on SLAM Methods in Autonomous Vehicle".
  109. ^ "Tesla Vision Update: Replacing Ultrasonic Sensors with Tesla Vision | Tesla Support". Tesla. Retrieved 31 August 2023.
  110. ^ Althoff, Matthias; Sontges, Sebastian (June 2017). "Computing possible driving corridors for automated vehicles".
  111. ^ Deepshikha Shukla (16 August 2019). "Design Considerations For Autonomous Vehicles". Retrieved 18 April 2018.
  112. ^ Connor-Simons, Adam; Gordon, Rachel (7 May 2018). "Self-driving cars for country roads: Today's automated vehicles require hand-labeled 3-D maps, but CSAIL's MapLite system enables navigation with just GPS and sensors". Retrieved 14 May 2018.
  113. ^ "How Self-Driving Cars Work". 14 December 2017. Retrieved 18 April 2018.
  114. ^ Yeong, De Jong; Velasco-Hernandez, Gustavo; Barry, John; Walsh, Joseph (2021). "Sensor and Sensor Fusion Technology in Autonomous Vehicles: A Review". Sensors. 21 (6): 2140. Bibcode:2021Senso..21.2140Y. doi:10.3390/s21062140. ISSN 1424-8220. PMC 8003231. PMID 33803889.
  115. ^ Tara, Roopinder (2 October 2023). "Now Revealed: Why Teslas Have Only Camera-Based Vision". Engineering.com. Retrieved 13 February 2024.
  116. ^ "Informing smarter lidar solutions for the future". Waymo. 21 September 2022. Retrieved 13 February 2024.
  117. ^ Alain Dunoyer (27 January 2022). "Why driver monitoring will be critical to next-generation autonomous vehicles". SBD Automotive. Retrieved 13 May 2022.
  118. ^ "How road rage really affects your driving -- and the self-driving cars of the future". ScienceDaily. Retrieved 25 November 2023.
  119. ^ Mike Beevor (11 April 2019). "Driving autonomous vehicles forward with intelligent infrastructure". Smart Cities World. Retrieved 27 April 2022.
  120. ^ "Frequency of Target Crashes for IntelliDrive Safety Systems" (PDF). NHTSA. October 2010. Archived from the original (PDF) on 5 April 2021. Retrieved 27 April 2022.
  121. ^ "ISO/TC 22: Road vehicles". ISO. 2 November 2016. Retrieved 11 May 2022.
  122. ^ "ISO/TC 204: Intelligent transport systems". ISO. 7 July 2021. Retrieved 11 May 2022.
  123. ^ "Standards Collection". connected automated driving.eu. 18 June 2019. Retrieved 23 November 2021.
  124. ^ "UN Regulation No. 156 – Software update and software update management system". UNECE. 4 March 2021. Retrieved 20 March 2022.
  125. ^ Shalev-Shwartz, Shai; Shammah, Shaked; Shashua, Amnon (2017). "On a Formal Model of Safe and Scalable Self-driving Cars". arXiv:1708.06374 [cs.RO].
  126. ^ "WG: VT/ITS/AV Decision Making". IEEE Standards Association. Retrieved 18 July 2022.
  127. ^ Hasuo, Ichiro; Eberhart, Clovis; Haydon, James; Dubut, Jérémy; Bohrer, Brandon; Kobayashi, Tsutomu; Pruekprasert, Sasinee; Zhang, Xiao-Yi; Andre Pallas, Erik; Yamada, Akihisa; Suenaga, Kohei; Ishikawa, Fuyuki; Kamijo, Kenji; Shinya, Yoshiyuki; Suetomi, Takamasa (5 July 2022). "Goal-Aware RSS for Complex Scenarios Via Program Logic". IEEE Transactions on Intelligent Vehicles. 8 (4): 3040–3072. arXiv:2207.02387. doi:10.1109/TIV.2022.3169762. S2CID 250311612.
  128. ^ Tucker, Sean (19 December 2023). "Thanks to Mercedes, Turquoise Lights Mean Self-Driving". Kelley Blue Book. Retrieved 3 February 2024.
  129. ^ "How AI Is Making Autonomous Vehicles Safer". hai.stanford.edu. 7 March 2022. Retrieved 23 April 2024.
  130. ^ Henn, Steve (31 July 2015). "Remembering When Driverless Elevators Drew Skepticism". NPR.org. NPR. Retrieved 14 August 2016.
  131. ^ a b Gomes, Lee (28 August 2014). "Hidden Obstacles for Google's Self-Driving Cars". MIT Technology Review. Archived from the original on 16 March 2015. Retrieved 22 January 2015.
  132. ^ Negroponte, Nicholas (1 January 2000). Being digital. Vintage Books. ISBN 978-0679762904. OCLC 68020226.
  133. ^ Adhikari, Richard (11 February 2016). "Feds Put AI in the Driver's Seat". Technewsworld. Retrieved 12 February 2016.
  134. ^ "New Allstate Survey Shows Americans Think They Are Great Drivers – Habits Tell a Different Story" (Press release). PR Newswire. 2 August 2011. Retrieved 7 September 2013.
  135. ^ Lin, Patrick (8 October 2013). "The Ethics of Autonomous Cars". The Atlantic.
  136. ^ Skulmowski, Alexander; Bunge, Andreas; Kaspar, Kai; Pipa, Gordon (16 December 2014). "Forced-choice decision-making in modified trolley dilemma situations: a virtual reality and eye tracking study". Frontiers in Behavioral Neuroscience. 8: 426. doi:10.3389/fnbeh.2014.00426. PMC 4267265. PMID 25565997.
  137. ^ Alsulami, Abdulaziz A.; Abu Al-Haija, Qasem; Alqahtani, Ali; Alsini, Raed (15 July 2022). "Symmetrical Simulation Scheme for Anomaly Detection in Autonomous Vehicles Based on LSTM Model". Symmetry. 14 (7): 1450. Bibcode:2022Symm...14.1450A. doi:10.3390/sym14071450. ISSN 2073-8994.
  138. ^ Moore-Colyer, Roland (12 February 2015). "Driverless cars face cyber security, skills and safety challenges". v3.co.uk. Retrieved 24 April 2015.
  139. ^ Petit, J.; Shladover, S.E. (1 April 2015). "Potential Cyberattacks on Automated Vehicles". IEEE Transactions on Intelligent Transportation Systems. 16 (2): 546–556. doi:10.1109/TITS.2014.2342271. ISSN 1524-9050. S2CID 15605711.
  140. ^ Tussy, Ron (29 April 2016). "Challenges facing Autonomous Vehicle Development". AutoSens. Retrieved 5 May 2016.
  141. ^ "Will Regulators Allow Self-Driving Cars in a Few Years?". Forbes. 24 September 2013. Retrieved 5 January 2014.
  142. ^ Newton, Casey (18 November 2013). "Reliance on autopilot is now the biggest threat to flight safety, study says". The Verge. Retrieved 19 November 2013.
  143. ^ Stumpf, Rob (8 March 2021). "Tesla Admits Current "Full Self-Driving Beta" Will Always Be a Level 2 System: Emails". The Drive. Retrieved 29 August 2021.
  144. ^ Keith Barry. "Senators Call for Investigation of Tesla's Marketing Claims of Its Autopilot and "Full Self-Driving" Features". Consumer Reports. Retrieved 13 April 2020.
  145. ^ "メルセデス・ベンツ日本に措置命令 事実と異なる記載 消費者庁" [Administrative order to Mercedes-Benz Japan Co., Ltd. for the descriptions that are different from the fact – The Consumer Affairs Agency]. NHK, Japan (in Japanese). 10 December 2021. Retrieved 13 April 2022.
  146. ^ Steph Willems (28 July 2016). "Mercedes-Benz Slammed Over Misleading Commercial". The Truth About Cars. Retrieved 15 April 2022.
  147. ^ Aaron Brown (29 July 2016). "Mercedes-Benz to Stop Running "Self-Driving Car" Ads". The Drive. Retrieved 15 April 2022.
  148. ^ "Mercedes rejects claims about "misleading" self-driving car ads". Reuters. 25 April 2016. Archived from the original on 31 May 2022. Retrieved 15 April 2022.
  149. ^ "California DMV accuses Tesla of deceptive marketing for its self-driving tech". CBT Automotive Network. 9 August 2022. Retrieved 22 November 2022.
  150. ^ Sparkes, Matthew (13 November 2023). "Self-driving car-makers could face prison for misleading adverts in UK". New Scientist. Retrieved 2 February 2024.
  151. ^ James Andrew Lewis (28 June 2021). "National Security Implications of Leadership in Autonomous Vehicles". CSIS. Retrieved 12 April 2022.
  152. ^ Allyson Chiu (11 July 2018). "Ex-Apple engineer arrested on his way to China, charged with stealing company's autonomous car secrets". The Washington Post. Retrieved 18 April 2022.
  153. ^ Kif Leswing (22 August 2022). "Former Apple engineer accused of stealing automotive trade secrets pleads guilty". CNBC. Retrieved 23 August 2022.
  154. ^ Sean O'Kane (30 January 2019). "A second Apple employee was charged with stealing self-driving car project secrets". The Verge. Retrieved 18 April 2022.
  155. ^ "Four Chinese Nationals Working with the Ministry of State Security Charged with Global Computer Intrusion Campaign Targeting Intellectual Property and Confidential Business Information, Including Infectious Disease Research". DOJ, US. 19 July 2021. Retrieved 14 June 2022.
  156. ^ Katie Benner (19 July 2021). "The Justice Dept. accuses Chinese security officials of a hacking attack seeking data on viruses like Ebola". The New York Times. Retrieved 14 June 2022.
  157. ^ Mark Schaub; Atticus Zhao; Mark Fu (24 August 2021). "China MIIT formulating new rules on data security". King & Wood Mallesons. Retrieved 23 April 2022.
  158. ^ Justin Ling (1 July 2022). "Is Your New Car a Threat to National Security?". Wired. Retrieved 3 July 2022.
  159. ^ Charles McLellan (4 November 2019). "What is V2X communication? Creating connectivity for the autonomous car era". ZDNet. Retrieved 8 May 2022.
  160. ^ "Autonomous Vehicles Join the List of US National Security Threats". Wired. 21 November 2022. Retrieved 22 November 2022.
  161. ^ Shepardson, David (16 November 2023). "US lawmakers raise concerns over Chinese self-driving testing data collection". [Reuters]. Retrieved 1 February 2024.
  162. ^ "What's big, orange and covered in LEDs? This start-up's new approach to self-driving cars". NBC News. 3 August 2018.
  163. ^ Crosato, Luca; Shum, Hubert P. H.; Ho, Edmond S. L.; Wei, Chongfeng; Sun, Yuzhu (2024). A Virtual Reality Framework for Human-Driver Interaction Research: Safe and Cost-Effective Data Collection. 2024 ACM/IEEE International Conference on Human Robot Interaction. ACM/IEEE. doi:10.1145/3610977.3634923.
  164. ^ City University of Hong Kong (6 September 2023). "Novel AI system enhances the predictive accuracy of autonomous driving". techxplore.com.
  165. ^ "Human Factors behind Autonomous Vehicles". Robson Forensic. 25 April 2018. Retrieved 17 April 2022.
  166. ^ Gold, Christian; Körber, Moritz; Hohenberger, Christoph; Lechner, David; Bengler, Klaus (1 January 2015). "Trust in Automation – Before and After the Experience of Take-over Scenarios in a Highly Automated Vehicle". Procedia Manufacturing. 3: 3025–3032. doi:10.1016/j.promfg.2015.07.847. ISSN 2351-9789.
  167. ^ "Survey Data Suggests Self-Driving Cars Could Be Slow To Gain Consumer Trust". GM Authority. Retrieved 3 September 2018.
  168. ^ "California agency approves San Francisco robotaxi expansion amid heavy opposition". CNBC. 11 August 2023. Retrieved 2 February 2024.
  169. ^ "Remembering When Driverless Elevators Drew Skepticism". NPR.org.
  170. ^ "Episode 642: The Big Red Button". NPR.org.
  171. ^ Metz, Barbara; Wörle, Johanna; Hanig, Michael; Schmitt, Marcus; Lutz, Aaron; Neukum, Alexandra (1 August 2021). "Repeated usage of a motorway automated driving function: Automation level and behavioural adaption". Transportation Research Part F: Traffic Psychology and Behaviour. 81: 82–100. Bibcode:2021TRPF...81...82M. doi:10.1016/j.trf.2021.05.017. ISSN 1369-8478.
  172. ^ a b Talbott, Selika Josiah. "The Political Economy Of Autonomous Vehicles". Forbes. Retrieved 23 April 2024.
  173. ^ "Occupational Outlook Handbook: Heavy and Tractor trailer Truck Drivers". U.S. Bureau of Labor Statistics. Office of Occupational Statistics and Employment Projections. Retrieved 24 April 2024.
  174. ^ "Occupational Outlook Handbook: Delivery Truck Drivers and Driver/Sales Workers". U.S. Bureau of Labor Statistics. Office of Occupational Statistics and Employment Projections. Retrieved 24 April 2024.
  175. ^ "Occupational Outlook Handbook: Taxi Drivers, Shuttle Drivers, and Chauffeurs". U.S. Bureau of Labor Statistics. Office of Occupational Statistics and Employment Projections. Retrieved 24 April 2024.
  176. ^ "Occupational Outlook Handbook: Bus Drivers". U.S. Bureau of Labor Statistics. Office of Occupational Statistics and Employment Projections. Retrieved 24 April 2024.
  177. ^ Goodman, Mance, Christopher, Steven. "Employment Loss and the 2007–09 Recession: An Overview" (PDF). U.S. Bureau of Labor Statistics. Retrieved 24 April 2024.{{cite web}}: CS1 maint: multiple names: authors list (link)
  178. ^ "Diversity and STEM: Women, Minorities, and Persons with Disabilities 2023 | NSF - National Science Foundation". ncses.nsf.gov. Retrieved 23 April 2024.
  179. ^ Samuel, Sigal (5 March 2019). "A new study finds a potential risk with self-driving cars: failure to detect dark-skinned pedestrians". Vox. VoxMedia. Retrieved 22 April 2024.
  180. ^ Alexander Hevelke; Julian Nida-Rümelin (2015). "Responsibility for Crashes of Autonomous Vehicles: An Ethical Analysis". Sci Eng Ethics. 21 (3): 619–630. doi:10.1007/s11948-014-9565-5. PMC 4430591. PMID 25027859.
  181. ^ a b "The Ethical Considerations of Self-Driving Cars". Montreal AI Ethics Institute. 18 May 2022. Retrieved 23 April 2024.
  182. ^ Himmelreich, Johannes (17 May 2018). "Never Mind the Trolley: The Ethics of Autonomous Vehicles in Mundane Situations". Ethical Theory and Moral Practice. 21 (3): 669–684. doi:10.1007/s10677-018-9896-4. ISSN 1386-2820. S2CID 150184601.
  183. ^ Meyer, G.; Beiker, S (2014). Road vehicle automation. Springer International Publishing. pp. 93–102.
  184. ^ Karnouskos, Stamatis (2020). "Self-Driving Car Acceptance and the Role of Ethics". IEEE Transactions on Engineering Management. 67 (2): 252–265. doi:10.1109/TEM.2018.2877307. ISSN 0018-9391. S2CID 115447875.
  185. ^ Jean-François Bonnefon; Azim Shariff; Iyad Rahwan (2016). "The Social Dilemma of Autonomous Vehicles". Science. 352 (6293): 1573–6. arXiv:1510.03346. Bibcode:2016Sci...352.1573B. doi:10.1126/science.aaf2654. PMID 27339987. S2CID 35400794.
  186. ^ Lim, Hazel Si Min; Taeihagh, Araz (2018). "Autonomous Vehicles for Smart and Sustainable Cities: An In-Depth Exploration of Privacy and Cybersecurity Implications". Energies. 11 (5): 1062. arXiv:1804.10367. Bibcode:2018arXiv180410367L. doi:10.3390/en11051062. S2CID 13749987.
  187. ^ Lafrance, Adrienne (21 March 2016). "How Self-Driving Cars Will Threaten Privacy". Retrieved 4 November 2016.
  188. ^ Jack, Boeglin (1 January 2015). "The Costs of Self-Driving Cars: Reconciling Freedom and Privacy with Tort Liability in Autonomous Vehicle Regulation". Yale Journal of Law and Technology. 17 (1).
  189. ^ Steve McEvoy (26 January 2023). "What are the next steps to reaching Level 4 autonomy?". Automotive World. Retrieved 5 April 2023.
  190. ^ "Japan Planning 100-kilometer Lane for Self-Driving Vehicles". Yomiuri Shimbun. 1 April 2023. Retrieved 11 April 2023.
  191. ^ "気仙沼線 BRT における自動運転レベル4認証取得を目指します" [Challenging self-driving Level 4 approval of Kesennuma Line BRT] (PDF). JR East. 4 April 2023. Retrieved 5 April 2023.
  192. ^ "Automobile simulation example". Cyberbotics. 18 June 2018. Retrieved 18 June 2018.
  193. ^ Hallerbach, S.; Xia, Y.; Eberle, U.; Koester, F. (2018). "Simulation-Based Identification of Critical Scenarios for Cooperative and Automated Vehicles". SAE International Journal of Connected and Automated Vehicles. 1 (2). SAE International: 93–106. doi:10.4271/2018-01-1066.
  194. ^ "Mcity testing center". University of Michigan. 8 December 2016. Archived from the original on 16 February 2017. Retrieved 13 February 2017.
  195. ^ "Adopted Regulations for Testing of Autonomous Vehicles by Manufacturers". DMV. 18 June 2016. Retrieved 13 February 2017.
  196. ^ "The Pathway to Driverless Cars: A Code of Practice for testing". 19 July 2015. Retrieved 8 April 2017.
  197. ^ "Apply for an Autonomous Vehicle Technology Demonstration / Testing Permit". 9 May 2017.
  198. ^ "Disengagement Reports". California DMV. Retrieved 24 April 2022.
  199. ^ a b Brad Templeton (9 February 2021). "California Robocar Disengagement Reports Reveal Tidbits About Tesla, AutoX, Apple, Others". Forbes. Retrieved 24 April 2022.
  200. ^ a b Wang, Brian (25 March 2018). "Uber' self-driving system was still 400 times worse [than] Waymo in 2018 on key distance intervention metric". NextBigFuture.com. Retrieved 25 March 2018.
  201. ^ "California DMV releases autonomous vehicle disengagement reports for 2019". VentureBeat. 26 February 2020. Retrieved 30 November 2020.
  202. ^ Rebecca Bellan (10 February 2022). "Despite a drop in how many companies are testing autonomous driving on California roads, miles driven are way up". TechCrunch. Retrieved 25 April 2022.
  203. ^ David Zipper (8 December 2022). "Self-Driving Taxis Are Causing All Kinds of Trouble in San Francisco". Slate. Retrieved 9 December 2022.
  204. ^ "(GRVA) New Assessment/Test Method for Automated Driving (NATM) – Master Document". UNECE. 13 April 2021. Retrieved 23 April 2022.
  205. ^ "L3Pilot: Joint European effort boosts automated driving". Connected Automated Driving. 15 October 2021. Retrieved 9 November 2021.
  206. ^ "From the Final Event Week: On Motorways". L3Pilot. 13 October 2021. Archived from the original on 27 April 2022. Retrieved 27 April 2022.
  207. ^ "L3Pilot Final Project Results published". L3Pilot. 28 February 2022. Archived from the original on 22 May 2022. Retrieved 27 April 2022.
  208. ^ "ISO 34502:2022 Road vehicles — Test scenarios for automated driving systems — Scenario based safety evaluation framework". ISO. November 2022. Retrieved 17 November 2022.
  209. ^ "New International Standard Issued for the Scenario-Based Safety Evaluation Framework for Automated Driving Systems Formulated by Japan". METI, Japan. 16 November 2022. Retrieved 14 December 2022.
  210. ^ "New driver-assistance technology dramatically improves collision-avoidance performance". Nissan. Retrieved 15 December 2022.
  211. ^ Graham Hope (26 April 2022). "Nissan Tests Collision Avoidance Tech for Self-Driving Cars". IoT World Today. Retrieved 15 December 2022.
  212. ^ "Waymo's Collision Avoidance Testing: Evaluating our Driver's Ability to Avoid Crashes Compared to Humans". Waymo. 14 December 2022. Retrieved 15 December 2022.
  213. ^ "SIP自動運転の成果を活用した安全性評価用シミュレーションソフトの製品化~戦略的イノベーション創造プログラム(SIP)研究成果を社会実装へ~" [Commercial product of the achievement of SIP-adus: Driving Intelligence Validation Platform]. Cabinet Office, Japan. 6 September 2022. Retrieved 10 September 2022.
  214. ^ "DIVP". DVIP. Retrieved 10 September 2022.
  215. ^ Seigo Kuzumaki. "Development of "Driving Intelligence Validation Platform" for ADS safety assurance" (PDF). SIP-adus. Retrieved 12 September 2022.
  216. ^ "Toyota pushes AI to drive like pros". Yomiuri Shimbun. 17 November 2021. Retrieved 20 November 2022.
  217. ^ "Microsoft and Toyota Join Forces in FIA World Rally Championship". Toyotal. 20 September 2016. Retrieved 20 November 2022.
  218. ^ "Driver disguises himself as car seat for study". BBC News.
  219. ^ Mulac, Jordan h (28 February 2023). "Tesla admits its semi-autonomous driving tech is not the world's most advanced". Drive. Retrieved 2 February 2024.
  220. ^ "Tesla Fatalities Dataset". Retrieved 17 October 2020.
  221. ^ Horwitz, Josh; Timmons, Heather (20 September 2016). "There are some scary similarities between Tesla's deadly crashes linked to Autopilot". Quartz. Retrieved 19 March 2018.
  222. ^ "China's first accidental death due to Tesla's automatic driving: not hitting the front bumper". China State Media (in Chinese). 14 September 2016. Retrieved 18 March 2018.
  223. ^ Felton, Ryan (27 February 2018). "Two Years On, A Father Is Still Fighting Tesla Over Autopilot And His Son's Fatal Crash". jalopnik.com. Retrieved 18 March 2018.
  224. ^ Yadron, Danny; Tynan, Dan (1 July 2016). "Tesla driver dies in first fatal crash while using autopilot mode". The Guardian. San Francisco. Retrieved 1 July 2016.
  225. ^ Vlasic, Bill; Boudette, Neal E. (30 June 2016). "Self-Driving Tesla Involved in Fatal Crash". The New York Times. Retrieved 1 July 2016.
  226. ^ "A Tragic Loss" (Press release). Tesla Motors. 30 June 2016. Retrieved 1 July 2016. This is the first known fatality in just over 130 million miles where Autopilot was activated. Among all vehicles in the US, there is a fatality every 94 million miles. Worldwide, there is a fatality approximately every 60 million miles.
  227. ^ Abuelsamid, Sam. "Adding Some Statistical Perspective To Tesla Autopilot Safety Claims". Forbes.
  228. ^ Administration, National Highway Traffic Safety. "FARS Encyclopedia".
  229. ^ "Fatal Tesla Autopilot accident investigation ends with no recall ordered". The Verge. 19 January 2016. Retrieved 19 January 2017.
  230. ^ "Google founder defends accident records of self-driving cars". Los Angeles Times. Associated Press. 3 June 2015. Retrieved 1 July 2016.
  231. ^ Mathur, Vishal (17 July 2015). "Google Autonomous Car Experiences Another Crash". Government Technology. Retrieved 18 July 2015.
  232. ^ a b "For the first time, Google's self-driving car takes some blame for a crash". The Washington Post. 29 February 2016.
  233. ^ "Google's Self-Driving Car Caused Its First Crash". Wired. February 2016.
  234. ^ "Passenger bus teaches Google robot car a lesson". Los Angeles Times. 29 February 2016.
  235. ^ Bensinger, Greg; Higgins, Tim (22 March 2018). "Video Shows Moments Before Uber Robot Car Rammed into Pedestrian". The Wall Street Journal. Retrieved 25 March 2018.
  236. ^ "Human Driver Could Have Avoided Fatal Uber Crash, Experts Say". Bloomberg.com. 22 March 2018.
  237. ^ "Governor Ducey suspends Uber from automated vehicle testing". KNXV-TV. Associated Press. 27 March 2018. Retrieved 27 March 2018.
  238. ^ Said, Carolyn (27 March 2018). "Uber puts the brakes on testing robot cars in California after Arizona fatality". San Francisco Chronicle. Retrieved 8 April 2018.
  239. ^ "Uber self-driving cars allowed back on California roads". BBC News. 5 February 2020. Retrieved 24 October 2022.
  240. ^ "Uber back-up driver faulted in fatal autonomous car crash". Financial Times. 19 November 2019. Retrieved 24 October 2022.
  241. ^ "'Inadequate Safety Culture' Contributed to Uber Automated Test Vehicle Crash – NTSB Calls for Federal Review Process for Automated Vehicle Testing on Public Roads". ntsb.gov. Retrieved 24 October 2022.
  242. ^ Smiley, Lauren. "'I'm the Operator': The Aftermath of a Self-Driving Tragedy". Wired. ISSN 1059-1028. Retrieved 24 October 2022.
  243. ^ Vanek, Corina (21 July 2023). "Arizona driver in fatal autonomous Uber crash in 2018 pleads guilty, sentenced to probation". The Arizona Republic. Retrieved 2 February 2024.
  244. ^ Rearick, Brenden (16 August 2021). "NIO Stock: 10 Things to Know About the Fatal Crash Dragging Down Nio Today". InvestorPlace. Retrieved 17 February 2022.
  245. ^ Ruffo, Gustavo Henrique (17 August 2021). "Nio's Autopilot, NOP, Faces Intense Scrutiny With First Fatal Crash in China". autoevolution. Retrieved 17 February 2022.
  246. ^ Rita Liao (14 December 2021). "California suspends Pony.ai driverless test permit after crash". TechCrunch. Retrieved 23 April 2022.
  247. ^ Rebecca Bellan (25 May 2022). "Pony.ai loses permit to test autonomous vehicles with driver in California". TechCrunch. Retrieved 30 May 2022.
  248. ^ Aarian Marshall (27 May 2022). "An Autonomous Car Blocked a Fire Truck Responding to an Emergency". Wired. Retrieved 30 May 2022.
  249. ^ Graham Hope (29 May 2022). "GM's Cruise Autonomous Car Blocks Fire Truck on Emergency Call". IoT World Today. Retrieved 30 May 2022.
  250. ^ Moreno, Julie (15 March 2024). "NTSB investigating deadly crash in San Antonio involving a semi-autonomous vehicle". KSAT. Retrieved 8 September 2024.
  251. ^ a b c Torrejón, Rodrigo (3 September 2024). "Woman who used hands-free driving system in fatal DUI crash on I-95 turns herself in to face charges, police say". Philadelphia Inquirer. Retrieved 8 September 2024.
  252. ^ Bell, Sebastien (18 March 2024). "Feds Investigate Ford BlueCruise's Role In Deadly Mustang Mach-E Crash". Carscoops. Retrieved 8 September 2024.
  253. ^ "Standing General Order on Crash Reporting | NHTSA". www.nhtsa.gov. Retrieved 14 August 2024.
  254. ^ "Data Analysis: Self-Driving Car Accidents [2019-2024]". Craft Law Firm. Retrieved 14 August 2024.
  255. ^ "Consumers in US and UK Frustrated with Intelligent Devices That Frequently Crash or Freeze, New Accenture Survey Finds". Accenture. 10 October 2011. Retrieved 30 June 2013.
  256. ^ Yvkoff, Liane (27 April 2012). "Many car buyers show interest in autonomous car tech". CNET. Retrieved 30 June 2013.
  257. ^ "Große Akzeptanz für selbstfahrende Autos in Deutschland". motorvision.de. 9 October 2012. Archived from the original on 15 May 2016. Retrieved 6 September 2013.
  258. ^ "Autonomous Cars Found Trustworthy in Global Study". autosphere.ca. 22 May 2013. Retrieved 6 September 2013.
  259. ^ "Autonomous cars: Bring 'em on, drivers say in Insurance.com survey". Insurance.com. 28 July 2014. Retrieved 29 July 2014.
  260. ^ a b Kyriakidis, M.; Happee, R.; De Winter, J. C. F. (2015). "Public opinion on automated driving: Results of an international questionnaire among 5,000 respondents". Transportation Research Part F: Traffic Psychology and Behaviour. 32: 127–140. Bibcode:2015TRPF...32..127K. doi:10.1016/j.trf.2015.04.014. S2CID 2071964.
  261. ^ Hohenberger, C.; Spörrle, M.; Welpe, I. M. (2016). "How and why do men and women differ in their willingness to use automated cars? The influence of emotions across different age groups". Transportation Research Part A: Policy and Practice. 94: 374–385. Bibcode:2016TRPA...94..374H. doi:10.1016/j.tra.2016.09.022.
  262. ^ Hall-Geisler, Kristen (22 December 2016). "Autonomous cars seen as smarter than human drivers". TechCrunch. Retrieved 26 December 2016.
  263. ^ Smith, Aaron; Anderson, Monica (4 October 2017). "Automation in Everyday Life".
  264. ^ Hewitt, Charlie; Politis, Ioannis; Amanatidis, Theocharis; Sarkar, Advait (2019). "Assessing public perception of self-driving cars: The autonomous vehicle acceptance model". Proceedings of the 24th International Conference on Intelligent User Interfaces. ACM Press. pp. 518–527. doi:10.1145/3301275.3302268. ISBN 9781450362726. S2CID 67773581.
  265. ^ "Majority of world's population feel self-driving cars are unsafe". Lloyd's Register Foundation. 25 November 2022. Retrieved 4 December 2022.
  266. ^ Saravanos, Antonios; Pissadaki, Eleftheria K.; Singh, Wayne S.; Delfino, Donatella (April 2024). "Gauging Public Acceptance of Conditionally Automated Vehicles in the United States". Smart Cities. 7 (2): 913–931. arXiv:2402.11444. doi:10.3390/smartcities7020038. ISSN 2624-6511.
  267. ^ Brodsky, Jessica (2016). "Autonomous Vehicle Regulation: How an Uncertain Legal Landscape May Hit the Brakes on Self-Driving Cars". Berkeley Technology Law Journal. 31 (Annual Review 2016): 851–878. Retrieved 29 November 2017.
  268. ^ Hancock, P. A.; Nourbakhsh, Illah; Stewart, Jack (16 April 2019). "On the future of transportation in an era of automated and autonomous vehicles". Proceedings of the National Academy of Sciences of the United States of America. 116 (16): 7684–7691. Bibcode:2019PNAS..116.7684H. doi:10.1073/pnas.1805770115. ISSN 0027-8424. PMC 6475395. PMID 30642956.
  269. ^ "Self-Driving Cars: Everything You Need To Know". Kelley Blue Book. 3 March 2023. Retrieved 9 April 2023.
  270. ^ How Much Automation Does Your Car Really Have? Jeff S. Bartlett, November 4, 2021 https://www.consumerreports.org/cars/automotive-technology/how-much-automation-does-your-car-really-have-level-2-a3543419955/
  271. ^ "Ford BlueCruise Version 1.2 Hands-Off Review: More Automation, Improved Operation". MotorTrend. 15 March 2023. Retrieved 9 April 2023.
  272. ^ "Ford updates its BlueCruise driver assist with hands-free lane changing and more". Engadget. 9 September 2022. Retrieved 9 April 2023.
  273. ^ "Ford launches hands-free driving on UK motorways". BBC. 14 April 2023. Retrieved 18 April 2023.
  274. ^ Stumpf, Rob (8 March 2021). "Tesla Admits Current "Full Self-Driving Beta" Will Always Be a Level 2 System: Emails". The Drive. Retrieved 29 August 2021.
  275. ^ a b Lambert, Fred (22 January 2024). "Tesla finally releases FSD v12, its last hope for self-driving". Electrek. Retrieved 3 February 2024.
  276. ^ Templeton, Brad (18 April 2024). "Tesla, Waymo, Nuro, Zoox And Many Others Embrace New AI To Drive". Forbes. Retrieved 4 May 2024.
  277. ^ a b Mengdan, Shen (3 April 2024). "Tesla's FSD enters a new phase as self-driving competition intensifies". SHINE. Retrieved 4 May 2024.
  278. ^ Ashraf, Anan (8 April 2024). "How Many Tesla Cars Are Deployed With FSD In America? AI Head Reveals Latest Numbers - Tesla (NASDAQ:TSLA)". Benzinga. Retrieved 4 May 2024.
  279. ^ Hawkins, Andrew (7 March 2023). "GM's Ultra Cruise will use radar, camera, and lidar to enable hands-free driving". The Verge. Retrieved 9 April 2023.
  280. ^ New UN regulation paves the way for the roll-out of additional driver assistance systems, 1 February 2024, UNECE
  281. ^ Paving the way to driving automation in EU, 19 January 2023, CCAM
  282. ^ a b c Jones, Rachyl (18 April 2024). "Exclusive: Mercedes becomes the first automaker to sell autonomous cars in the U.S. that don't come with a requirement that drivers watch the road". Fortune. Retrieved 20 April 2024.
  283. ^ "Honda Unveils Next-generation Technologies of Honda SENSING 360 and Honda SENSING Elite". Honda. 1 December 2022. Retrieved 1 December 2022.
  284. ^ "Honda to develop advanced level 3 self-driving technology by 2029". Reuters. 1 December 2022. Retrieved 1 December 2022.
  285. ^ Smith, Christopher (28 January 2022). "Level 3 Automated Driving Tech Has Major Limitations: Report". Motor1.com. Retrieved 2 February 2024.
  286. ^ Mihalascu, Dan (9 June 2023). "Mercedes Drive Pilot Level 3 ADAS Approved For Use In California". InsideEVs. Retrieved 2 February 2024.
  287. ^ Angel Sergeev (31 March 2017). "BMW Details Plan For Fully Automated Driving By 2021". Motor1.com.
  288. ^ Level 3 highly automated driving available in the new BMW 7 Series from next spring, 10.11.2023, Press Release, Christophe Koenig, BMW Group https://www.press.bmwgroup.com/global/article/detail/T0438214EN/level-3-highly-automated-driving-available-in-the-new-bmw-7-series-from-next-spring
  289. ^ Kang/CnEVPost, Lei (18 December 2023). "IM Motors gets permit to test L3 self-driving vehicles in Shanghai". CnEVPost.
  290. ^ "Breaking The News". breakingthenews.net.
  291. ^ Paul Myles (17 September 2021). "Stellantis Shows Off its Level 3 Technology". Informa. Retrieved 29 November 2021.
  292. ^ Jay Ramey (11 January 2022). "Polestar 3 with Level 3 Autonomous Tech on the Way". Autoweek. Retrieved 31 May 2022.
  293. ^ hannovermesse (26 January 2022). "Bosch and CARIAD advance automated driving". hannovermesse. Retrieved 26 January 2022.
  294. ^ Seo Jin-woo; Jung You-jung; Lee Ha-yeon (16 February 2022). "Korean firms enhance car cybersecurity before Level 3 autonomous car releases". Pulse by Maeil Business Newspaper. Retrieved 22 April 2022.
  295. ^ Herh, Michael (1 December 2023). "Hyundai Motor Puts Level 3 Autonomous Driving Technology on Back Burner". Businesskorea (in Korean). Retrieved 2 February 2024.
  296. ^ Ludlow, Edward (15 April 2024). "Waymo, Cruise and Zoox Inch Forward Ahead of Tesla Joining Robotaxi Race". Bloomberg.com. Retrieved 30 April 2024.
  297. ^ "Level 4 Autonomous Driving Allowed in Japan". Yomiuri Shimbun. 1 April 2023. Retrieved 3 April 2023.
  298. ^ "国内初!自動運転車に対するレベル4の認可を取得しました" [Domestically the first! Approved as Level 4 self-driving car]. METI, Japan. 31 March 2023. Retrieved 3 April 2023.
  299. ^ "Toyota to Offer Rides in SAE Level-4 Automated Vehicles on Public Roads in Japan Next Summer" (Press release). Toyota. 24 October 2019. Retrieved 17 March 2022.
  300. ^ River Davis (2 August 2021). "Hyperdrive Daily: The Driverless Shuttle Helping Toyota Win Gold". Bloomberg News. Retrieved 7 November 2021.
  301. ^ "Automotive luxury experienced in a completely new way – The main points of the new Mercedes-Benz S-Class at a glance". Mercedes me media. 2 September 2020. Retrieved 21 May 2022.
  302. ^ "Bosch – Stuttgart Airport Set to Welcome Fully Automated and Driverless Parking". IoT Automotive News. Retrieved 21 May 2022.
  303. ^ "Mercedes-Benz and Bosch driverless parking system: Approved for commercial use". Mercedes-Benz Group. 30 November 2022. Retrieved 3 February 2024.
  304. ^ "Honda to Start Testing Program in September Toward Launch of Autonomous Vehicle Mobility Service Business in Japan" (Press release). Honda. 8 September 2021. Retrieved 16 March 2022.
  305. ^ MILLER, CALEB (29 November 2023). "GM's Self-Driving Cruise Origin Indefinitely Delayed Amid Major Setbacks". Car and Driver.
  306. ^ Anthony James (5 January 2022). "New Benteler brand Holon presents world's first autonomous mover built to automotive standards". ADAS & Autonomous Vehicle International. Retrieved 21 January 2023.

Further reading

[edit]

Media related to Self-driving cars at Wikimedia Commons

These books are based on presentations and discussions at the Automated Vehicles Symposium organized annually by TRB and AUVSI.