Self-driving car

Waymo Chrysler Pacifica Hybrid undergoing testing in the San Francisco Bay Area.
Automated racing car on display at the 2017 New York City ePrix.

A self-driving car (also known as an autonomous car or a driverless car)[1] is a vehicle that is capable of sensing its environment and moving with little or no human input.[2]

Autonomous cars combine a variety of sensors to perceive their surroundings, such as radar, computer vision, Lidar, sonar, GPS, odometry and inertial measurement units. Advanced control systems interpret sensory information to identify appropriate navigation paths, as well as obstacles and relevant signage.[3][4]

Potential benefits include reduced costs, increased safety, increased mobility, increased customer satisfaction and reduced crime. Safety benefits include a reduction in traffic collisions,[5][6] resulting injuries and related costs, including for insurance. Automated cars are predicted to increase traffic flow;[7] provide enhanced mobility for children, the elderly,[8] disabled, and the poor; relieve travelers from driving and navigation chores; lower fuel consumption; significantly reduce needs for parking space;[9] reduce crime;[10] and facilitate business models for transportation as a service, especially via the sharing economy.[11][12]

Problems include safety,[13] technology, liability,[14][15] desire by individuals to control their cars,[16] legal framework and government regulations; risk of loss of privacy and security concerns, such as hackers or terrorism; concern about the resulting loss of driving-related jobs in the road transport industry; and risk of increased suburbanization as travel becomes more convenient.

History

General Motors' Firebird II of the 1950s was described as having an "electronic brain" that allowed it to move into a lane with a metal conductor and follow it along.
1960 Citroën DS19, modified by TRL for automatic guidance experiments, on display at the Science Museum, London.[17]

Experiments have been conducted on automating driving since at least the 1920s;[18] trials began in the 1950s. The first truly automated car was developed in 1977, by Japan's Tsukuba Mechanical Engineering Laboratory. The vehicle tracked white street markers, which were interpreted by two cameras on the vehicle, using an analog computer for signal processing. The vehicle reached speeds up to 30 kilometres per hour (19 mph), with the support of an elevated rail.[19][20]

Autonomous prototype cars appeared in the 1980s, with Carnegie Mellon University's Navlab[21] and ALV[22][23] projects funded by DARPA starting in 1984 and Mercedes-Benz and Bundeswehr University Munich's EUREKA Prometheus Project[24] in 1987. By 1985, the ALV had demonstrated self-driving speeds on two-lane roads of 31 kilometres per hour (19 mph) with obstacle avoidance added in 1986 and off-road driving in day and nighttime conditions by 1987.[25] From the 1960s through the second DARPA Grand Challenge in 2005, automated vehicle research in the U.S. was primarily funded by DARPA, the US Army and the U.S. Navy yielding incremental advances in speeds, driving competence in more complex conditions, controls and sensor systems.[26] Companies and research organizations have developed prototypes.[24][27][28][29][30][31][32][33][34]

The U.S. allocated $650 million in 1991 for research on the National Automated Highway System, which demonstrated automated driving through a combination of automation, embedded in the highway with automated technology in vehicles and cooperative networking between the vehicles and with the highway infrastructure. The program concluded with a successful demonstration in 1997 but without clear direction or funding to implement the system on a larger scale.[35] Partly funded by the National Automated Highway System and DARPA, the Carnegie Mellon University Navlab drove 4,584 kilometres (2,848 mi) across America in 1995, 4,501 kilometres (2,797 mi) or 98% of it autonomously.[36] Navlab's record achievement stood unmatched for two decades until 2015 when Delphi improved it by piloting an Audi, augmented with Delphi technology, over 5,472 kilometres (3,400 mi) through 15 states while remaining in self-driving mode 99% of the time.[37] In 2015, the US states of Nevada, Florida, California, Virginia, and Michigan, together with Washington, D.C., allowed the testing of automated cars on public roads.[38]

In 2017, Audi stated that its latest A8 would be automated at speeds of up to 60 kilometres per hour (37 mph) using its "Audi AI." The driver would not have to do safety checks such as frequently gripping the steering wheel. The Audi A8 was claimed to be the first production car to reach level 3 automated driving, and Audi would be the first manufacturer to use laser scanners in addition to cameras and ultrasonic sensors for their system.[39]

In November 2017, Waymo announced that it had begun testing driverless cars without a safety driver in the driver position;[40] however, there is still an employee in the car. In July 2018, Waymo announced that its test vehicles had traveled in automated mode for over 8,000,000 miles (13,000,000 km), increasing by 1,000,000 miles (1,600,000 kilometres) per month.[41]

Definitions

There is some inconsistency in terminology used in the self-driving car industry. Various organizations have proposed to define an accurate and consistent vocabulary.

Such confusion has been documented in SAE J3016 which states that "Some vernacular usages associate autonomous specifically with full driving automation (level 5), while other usages apply it to all levels of driving automation, and some state legislation has defined it to correspond approximately to any ADS at or above level 3 (or to any vehicle equipped with such an ADS)."

Words definition and safety considerations

Modern vehicles provide partly automated features such as keeping the car within its lane, speed controls or emergency braking. Nonetheless, differences remain between a fully autonomous self-driving car on one hand and driver assistance technologies on the other hand. According to the BBC, confusion between those concepts leads to deaths.[42]

Association of British Insurers considers the usage of the word autonomous in marketing for modern cars to be dangerous, because car ads make motorists think 'autonomous' and 'autopilot' means a vehicle can drive itself, when they still rely on the driver to ensure safety. Technology alone still is not able to drive the car.

When some car makers suggest or claim vehicles are self-driving, when they are only partly automated, drivers risk becoming excessively confident, leading to crashes, while fully self-driving cars are still a long way off in the UK.[43]

Autonomous vs. automated

Autonomous means self-governing.[44] Many historical projects related to vehicle automation have been automated (made automatic) subject to a heavy reliance on artificial aids in their environment, such as magnetic strips. Autonomous control implies satisfactory performance under significant uncertainties in the environment and the ability to compensate for system failures without external intervention.[44]

One approach is to implement communication networks both in the immediate vicinity (for collision avoidance) and farther away (for congestion management). Such outside influences in the decision process reduce an individual vehicle's autonomy, while still not requiring human intervention.

Wood et al. (2012) wrote, "This Article generally uses the term 'autonomous,' instead of the term 'automated.' " The term "autonomous" was chosen "because it is the term that is currently in more widespread use (and thus is more familiar to the general public). However, the latter term is arguably more accurate. 'Automated' connotes control or operation by a machine, while 'autonomous' connotes acting alone or independently. Most of the vehicle concepts (that we are currently aware of) have a person in the driver’s seat, utilize a communication connection to the Cloud or other vehicles, and do not independently select either destinations or routes for reaching them. Thus, the term 'automated' would more accurately describe these vehicle concepts."[45] As of 2017, most commercial projects focused on automated vehicles that did not communicate with other vehicles or with an enveloping management regime.

Put in the words of one Nissan engineer, "A truly autonomous car would be one where you request it to take you to work and it decides to go to the beach instead."[46]

EuroNCAP defines autonomous in "Autonomous Emergency Braking" as: "the system acts independently of the driver to avoid or mitigate the accident." which implies the autonomous system is not the driver.[47]

Autonomous versus cooperative

To make a car travel without any driver embedded within the vehicle some system makers used a remote driver.

But 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.

Self-driving car

Techemergence says.

“Self-driving” is a rather vague term with a vague meaning

Techemergence[48]

PC mag definition is:

A computer-controlled car that drives itself. Also called an "autonomous vehicle" and "driverless car," self-driving cars date back to the 1939 New York World's Fair when General Motors predicted the development of self-driving, radio-controlled electric cars.

PCmag.[49]

UCSUSA definition is:

Self-driving vehicles are 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. Currently, there are no legally operating, fully-autonomous vehicles in the United States.

UCSUSA[50]

NHTSA definition is:

These self-driving vehicles ultimately will integrate onto U.S. roadways by progressing through six levels of driver assistance technology advancements in the coming years. This includes everything from no automation (where a fully engaged driver is required at all times), to full autonomy (where an automated vehicle operates independently, without a human driver).

NHTSA.[51]

NHTSA definition is:

Let’s be clear: fully automated or “self-driving” vehicles aren’t arriving in showrooms tomorrow; they’re likely years, maybe even decades, away. What we’re experiencing is an evolution in vehicle safety that is leading toward cars and trucks that help us drive more safely.

NHTSA.[52]

According to Techemergence

This means the vehicle can safely drive itself under specific conditions but the driver will need to quickly intervene when called on. This is a car that could drive itself on the highway while you watch a movie but would need you to take control when you get off the highway. Some may view this as only partially self-driving.

Techemergence,[48] July 2018

According to Techemergence

it will be useful to understand that most executives referring to “self-driving” are referring to levels 3 and 4.

Techemergence,[48] July 2018

Classification

Tesla Autopilot system is considered to be an SAE level 2 system.[53]

A classification system based on six different levels (ranging from fully manual to fully automated systems) was published in 2014 by SAE International, an automotive standardization body, as J3016, Taxonomy and Definitions for Terms Related to On-Road Motor Vehicle Automated Driving Systems.[54][55] This classification system is based on the amount of driver intervention and attentiveness required, rather than the vehicle capabilities, although these are very loosely related. In the United States in 2013, the National Highway Traffic Safety Administration (NHTSA) released a formal classification system,[56] but abandoned this system in favor of the SAE standard in 2016. Also in 2016, SAE updated its classification, called J3016_201609.[57]

Levels of driving automation

In SAE's automation level definitions, "driving mode" means "a type of driving scenario with characteristic dynamic driving task requirements (e.g., expressway merging, high speed cruising, low speed traffic jam, closed-campus operations, etc.)"[58]

  • Level 0: Automated system issues warnings and may momentarily intervene but has no sustained vehicle control.
  • Level 1 ("hands on"): The driver and the automated system share control of the vehicle. Examples are Adaptive Cruise Control (ACC), where the driver controls steering and the automated system controls speed; and Parking Assistance, where steering is automated while speed is under manual control. The driver must be ready to retake full control at any time. Lane Keeping Assistance (LKA) Type II is a further example of level 1 self-driving.
  • Level 2 ("hands off"): The automated system takes full control of the vehicle (accelerating, braking, and steering). The driver must monitor the driving and be prepared to intervene immediately at any time if the automated system fails to respond properly. The shorthand "hands off" is not meant to be taken literally. In fact, contact between hand and wheel is often mandatory during SAE 2 driving, to confirm that the driver is ready to intervene.
  • Level 3 ("eyes off"): The driver can safely turn their attention away from the driving tasks, e.g. the driver can text or watch a movie. The vehicle will handle situations that call for an immediate response, like emergency braking. The driver must still be prepared to intervene within some limited time, specified by the manufacturer, when called upon by the vehicle to do so. As an example, the 2018 Audi A8 Luxury Sedan was the first commercial car to claim to be capable of level 3 self-driving. This particular car has a so-called Traffic Jam Pilot. When activated by the human driver, the car takes full control of all aspects of driving in slow-moving traffic at up to 60 kilometres per hour (37 mph). The function works only on highways with a physical barrier separating one stream of traffic from oncoming traffic.
  • Level 4 ("mind off"): As level 3, but no driver attention is ever required for safety, i.e. the driver may safely go to sleep or leave the driver's seat. Self-driving is supported only in limited spatial areas (geofenced) or under special circumstances, like traffic jams. Outside of these areas or circumstances, the vehicle must be able to safely abort the trip, i.e. park the car, if the driver does not retake control.
  • Level 5 ("steering wheel optional"): No human intervention is required at all. An example would be a robotic taxi.

In the formal SAE definition below, note in particular what happens in the shift from SAE 2 to SAE 3: the human driver no longer has to monitor the environment. This is the final aspect of the "dynamic driving task" that is now passed over from the human to the automated system. At SAE 3, the human driver still has the responsibility to intervene when asked to do so by the automated system. At SAE 4 the human driver is relieved of that responsibility and at SAE 5 the automated system will never need to ask for an intervention.

SAE (J3016) Automation Levels[58]
SAE LevelNameNarrative definitionExecution of
steering and
acceleration/
deceleration
Monitoring of driving environmentFallback performance of dynamic driving taskSystem capability (driving modes)
Human driver monitors the driving environment
0No AutomationThe full-time performance by the human driver of all aspects of the dynamic driving task, even when "enhanced by warning or intervention systems"Human driverHuman driverHuman drivern/a
1Driver AssistanceThe driving mode-specific execution by a driver assistance system of "either steering or acceleration/deceleration"using information about the driving environment and with the expectation that the human driver performs all remaining aspects of the dynamic driving taskHuman driver and systemSome driving modes
2Partial AutomationThe driving mode-specific execution by one or more driver assistance systems of both steering and acceleration/decelerationSystem
Automated driving system monitors the driving environment
3Conditional AutomationThe driving mode-specific performance by an automated driving system of all aspects of the dynamic driving taskwith the expectation that the human driver will respond appropriately to a request to interveneSystemSystemHuman driverSome driving modes
4High Automationeven if a human driver does not respond appropriately to a request to interveneSystemMany driving modes
5Full Automationunder all roadway and environmental conditions that can be managed by a human driverAll driving modes

In the district of columbia (DC) code,

“Autonomous vehicle” means a vehicle capable of navigating District roadways and interpreting traffic-control devices without a driver actively operating any of the vehicle’s control systems. The term “autonomous vehicle” excludes a motor vehicle enabled with active safety systems or driver- assistance systems, including systems to provide electronic blind-spot assistance, crash avoidance, emergency braking, parking assistance, adaptive cruise control, lane-keep assistance, lane-departure warning, or traffic-jam and queuing assistance, unless the system alone or in combination with other systems enables the vehicle on which the technology is installed to drive without active control or monitoring by a human operator.

In the same district code, it is considered that:

An autonomous vehicle may operate on a public roadway; provided, that the vehicle:

  • (1) Has a manual override feature that allows a driver to assume control of the autonomous vehicle at any time;
  • (2) Has a driver seated in the control seat of the vehicle while in operation who is prepared to take control of the autonomous vehicle at any moment; and
  • (3) Is capable of operating in compliance with the District’s applicable traffic laws and motor vehicle laws and traffic control devices.

Semi-automated vehicles

Between manually driven vehicles (SAE Level 0) and fully autonomous vehicles (SAE Level 5), there are a variety of vehicle types that can be described to have some degree of automation. These are collectively known as semi-automated vehicles. As it could be a while before the technology and infrastructure is developed for full automation, it is likely that vehicles will have increasing levels of automation. These semi-automated vehicles could potentially harness many of the advantages of fully automated vehicles, while still keeping the driver in charge of the vehicle.

Technical challenges

The challenge for driverless car designers is to produce control systems capable of analyzing sensory data in order to provide accurate detection of other vehicles and the road ahead.[59] Modern self-driving cars generally use Bayesian simultaneous localization and mapping (SLAM) algorithms,[60] which fuse data from multiple sensors and an off-line map into current location estimates and map updates. Waymo has developed a variant of SLAM with detection and tracking of other moving objects (DATMO), which also handles obstacles such as cars and pedestrians. Simpler systems may use roadside real-time locating system (RTLS) technologies to aid localization. Typical sensors include Lidar, stereo vision, GPS and IMU.[61][62] Udacity is developing an open-source software stack.[63] Control systems on automated cars may use Sensor Fusion, which is an approach that integrates information from a variety of sensors on the car to produce a more consistent, accurate, and useful view of the environment.[64]

Driverless vehicles require some form of machine vision for the purpose of visual object recognition. Automated cars are being developed with deep neural networks,[61] a type of deep learning architecture with many computational stages, or levels, in which neurons are simulated from the environment that activate the network.[65] The neural network depends on an extensive amount of data extracted from real-life driving scenarios,[61] enabling the neural network to "learn" how to execute the best course of action.[65]

In May 2018, researchers from MIT announced that they had built an automated car that can navigate unmapped roads.[66] Researchers at their Computer Science and Artificial Intelligence Laboratory (CSAIL) have developed a new system, called MapLite, which allows self-driving cars to drive on roads that they have never been on before, without using 3D maps. The system combines the GPS position of the vehicle, a "sparse topological map" such as OpenStreetMap, (i.e. having 2D features of the roads only), and a series of sensors that observe the road conditions.[67]

Nature of the digital technology

Autonomous vehicles, as a digital technology, have certain characteristics that distinguishes them from other types of technologies and vehicles. Due to these characteristics, autonomous vehicles are able to be more transformative and agile to possible changes. The characteristics will be explained based on the following subjects: homogenization and decoupling, connectivity, reprogrammable and smart, digital traces and modularity.

Homogenization and decoupling

Homogenization comes from the fact that all digital information assumes the same form. During the ongoing evolution of the digital era, certain industry standards have been developed on how to store digital information and in what type of format. This concept of homogenization also implies to autonomous vehicles. In order for autonomous vehicles to perceive their surroundings, they have to use different techniques each with their own accompanying digital information (e.g. radar, GPS, motion sensors and computer vision). Due to homogenization, the digital information from these different techniques is stored in a homogeneous way. This implies that all digital information comes in the same form, which means their differences are decoupled, and digital information can be transmitted, stored and computed in a way that the vehicles and its operating system can better understand and act upon it. Homogenization also helps to exponentially increase the computing power of hard- and software (Moore’s law) which also supports the autonomous vehicles to understand and act upon the digital information in a more cost-effective way, therefore lowering the marginal costs.;

Connectivity

Connectivity means that users of a certain digital technology can connect easily with other users, other applications or even (other) enterprises. In the case of autonomous vehicles, it is essential for them to connect with other ‘devices’ in order to function most effectively. Autonomous vehicles are equipped with communication systems which allow them to communicate with other autonomous vehicles and roadside units to provide them, amongst other things, with information about road work or traffic congestion. In addition, scientists believe that the future will have computer programs that connects and manages each individual autonomous vehicle as it navigates through an intersection. This type of connectivity must replace traffic lights and stop signs.(https://www.youtube.com/watch?v=UVQ8bGvLkCA of https://www.reuters.com/video/2012/03/22/no-lights-no-signs-no-accidents-future-i?videoId=232193655) These types of characteristics drive and further develop the ability of autonomous vehicles to understand and cooperate with other products and services (such as intersection computer systems) in the autonomous vehicles market. This could lead to a network of autonomous vehicles all using the same network and information available on that network. Eventually, this can lead to more autonomous vehicles using the network because the information has been validated through usage of other autonomous vehicles. Such movements will strengthen the value of the network and is called network externalities.;

Reprogrammeble and smart

Another characteristic of autonomous vehicles is that the core product will have a greater emphasize on the software and its possibilities, instead of the chassis and its engine. This is because autonomous vehicles have software systems that drive the vehicle meaning that updates through reprogramming or editing the software can enhance the benefits of the owner (e.g. update in better distinguishing blind person vs. non-blind person so that the vehicle will take extra caution when approaching a blind person). A characteristic of this reprogrammable part of autonomous vehicles is that the updates need not only to come from the supplier, cause through machine learning (smart) autonomous vehicles can generate certain updates and install them accordingly (e.g. new navigation maps or new intersection computer systems). These reprogrammable characteristics of the digital technology and the possibility of smart machine learning give manufacturers of autonomous vehicles the opportunity to differentiate themselves on software. This also implies that autonomous vehicles are never finished because the product can be continuously be improved.;

Digital traces

Autonomous vehicles are equipped with different sorts of sensors and radars. As said, this allows them to connect and interoperate with computers from other autonomous vehicles and/or roadside units. This implies that autonomous vehicles leave digital traces when they connect or interoperate. The data that comes from these digital traces can be used to develop new (to be determined) products or updates to enhance autonomous vehicles’ driving ability or safety.; and

Modularity

Traditional vehicles and their accompanying (traditional) technologies are manufactured as a product that will be complete, and unlike autonomous vehicles, they can only be improved if they are redesigned or reproduced. As said, autonomous vehicles are produced but due to their digital characteristics never finished. This is because autonomous vehicles are more modular since they are made up out of several modules which will be explained hereafter through a Layered Modular Architecture. The Layered Modular Architecture extends the architecture of purely physical vehicles by incorporating four loosely coupled layers of devices, networks, services and contents into Autonomous Vehicles. These loosely coupled layers can interact through certain standardized interfaces.

  • (1) The first layer of this architecture consists of the device layer. This layer consists of the following two parts: logical capability and physical machinery. The physical machinery refers to the actual vehicle itself (e.g. chassis and carrosserie). When it comes to digital technologies, the physical machinery is accompanied by a logical capability layer in the form of operating systems that helps to guide the vehicles itself and make it autonomous. The logical capability provides the control over the vehicle and connects it with the other layers.;
  • (2) On top of the device layer comes the network layer. This layer also consists of two different parts: physical transport and logical transmission. The physical transport layer refers to the radars, sensors and cables of the autonomous vehicles which enable the transmission of digital information. Next to that, the network layer of autonomous vehicles also has a logical transmission which contains communication protocols and network standard to communicate the digital information with other networks and platforms or between layers. This increases the accessibility of the autonomous vehicles and enables computational power of a network or platform.;
  • (3) The service layer contains the applications and their functionalities that serves the autonomous vehicle (and its owners) as they extract, create, store and consume content with regards to their own driving history, traffic congestion, roads or parking abilities for example.; and
  • (4) The final layer of the model is the contents layer. This layer contains the sounds, images and videos the autonomous vehicles store, extract and use to act upon and improve their driving and understanding of the environment. The contents layer also provides metadata and directory information about the content’s origin, ownership, copyright, encoding methods, content tags, geo-time stamps, and so on (Yoo et al., 2010).

The consequence of layered modular architecture of autonomous vehicles (and other digital technologies) is that it enables the emergence and development of platforms and ecosystems around a product and/or certain modules of that product. Traditionally, automotive vehicles were developed, manufactured and maintained by traditional manufacturers. Nowadays app developers and content creators can help to develop a more comprehensive product experience for the consumers which creates a platform around the product of autonomous vehicles.}}

Human factor challenges

Alongside the many technical challenges that autonomous cars face, there exist many human and social factors that may impede upon the wider uptake of the technology. As things become more automated, the human users need to have trust in the automation,[68] which can be a challenge in itself.[69]

Testing

Testing vehicles with varying degrees of automation can be done physically, in closed environments,[70] on public roads (where permitted, typically with a license or permit[71] or adhering to a specific set of operating principles)[72] or virtually, i.e. in computer simulations.[73]

When driven on public roads, automated vehicles require a person to monitor their proper operation and "take over" when needed.

Apple is currently testing self-driven cars, and has increased the number of test vehicles from 3 to 27 in January 2018,[74] and to 45 in March 2018.[75]

One way to assess the progress of automated vehicles is to compute the average distance driven between "disengagements", when the automated system is turned off, typically by a human driver. In 2017, Waymo reported 63 disengagements over 352,545 miles (567,366 km) of testing, or 5,596 miles (9,006 km) on average, the highest among companies reporting such figures. Waymo also traveled more distance in total than any other. Their 2017 rate of 0.18 disengagements per 1,000 miles (1,600 km) was an improvement from 0.2 disengagements per 1,000 miles (1,600 km) in 2016 and 0.8 in 2015. In March, 2017, Uber reported an average of 0.67 miles (1.08 km) per disengagement. In the final three months of 2017, Cruise Automation (now owned by GM) averaged 5,224 miles (8,407 km) per disruption over 62,689 miles (100,888 km).[76] In July 2018, the first electric driverless racing car "Robocar" completed 1.8 kilometers track, using its navigation system and artificial intelligence.[77]

Miles per disengagement[76]
Maker2016
Distance between
disengagements
Distance
Waymo5,127.9 miles (8,252.6 km)635,868 miles (1,023,330 km)
BMW638 miles (1,027 km)638 miles (1,027 km)
Nissan263.3 miles (423.7 km)6,056 miles (9,746 km)
Ford196.6 miles (316.4 km)590 miles (950 km)
General Motors54.7 miles (88.0 km)8,156 miles (13,126 km)
Delphi Automotive Systems14.9 miles (24.0 km)2,658 miles (4,278 km)
Tesla2.9 miles (4.7 km)550 miles (890 km)
Mercedes Benz2 miles (3.2 km)673 miles (1,083 km)
Bosch0.68 miles (1.09 km)983 miles (1,582 km)

Fields of application

Automated trucks

Several companies are said to be testing automated technology in semi trucks. Otto, a self-driving trucking company that was acquired by Uber in August 2016, demonstrated their trucks on the highway before being acquired.[78] In May 2017, San Francisco-based startup Embark[79] announced a partnership with truck manufacturer Peterbilt to test and deploy automated technology in Peterbilt's vehicles.[80] Waymo has also said to be testing automated technology in trucks,[81] however no timeline has been given for the project.

In March 2018, Starsky Robotics, the San Francisco-based automated truck company, completed a 7-mile (11 km) fully driverless trip in Florida without a single human in the truck. Starsky Robotics became the first player in the self-driving truck game to drive in fully automated mode on a public road without a person in the cab.[82]

In Europe, the truck Platooning is considered with the Safe Road Trains for the Environment approach.

Vehicular automation also covers other kinds of vehicles such as Buses, Trains, Trucks.

Lockheed Martin with funding from the U.S. Army developed an automated truck convoying system that uses a lead truck operated by a human driver with a number of trucks following autonomously.[83] Developed as part of the Army's Autonomous Mobility Applique System (AMAS), the system consists of an automated driving package that has been installed on more than nine types of vehicles and has completed more than 55,000 hours of driving at speeds up to 64 kilometres per hour (40 mph) as of 2014.[84] As of 2017 the Army was planning to field 100-200 trucks as part of a rapid-fielding program.

Transport systems

In Europe, cities in Belgium, France, Italy and the UK are planning to operate transport systems for automated cars,[85][86][87] and Germany, the Netherlands, and Spain have allowed public testing in traffic. In 2015, the UK launched public trials of the LUTZ Pathfinder automated pod in Milton Keynes.[88] Beginning in summer 2015, the French government allowed PSA Peugeot-Citroen to make trials in real conditions in the Paris area. The experiments were planned to be extended to other cities such as Bordeaux and Strasbourg by 2016.[89] The alliance between French companies THALES and Valeo (provider of the first self-parking car system that equips Audi and Mercedes premi) is testing its own system.[90] New Zealand is planning to use automated vehicles for public transport in Tauranga and Christchurch.[91][92][93][94]

In China, Baidu and King Long produce automated minibus, a vehicle with 14 seats, but without driving seat. With 100 vehicles produced, 2018 will be the first year with commercial automated service in China. Those minibuses should be at level 4, that is driverless in closed roads.

Potential advantages

Safety

Driving safety experts predict that once driverless technology has been fully developed, traffic collisions (and resulting deaths and injuries and costs), caused by human error, such as delayed reaction time, tailgating, rubbernecking, and other forms of distracted or aggressive driving should be substantially reduced.[6][11][12][95] Consulting firm McKinsey & Company estimated that widespread use of autonomous vehicles could "eliminate 90% of all auto accidents in the United States, prevent up to US$190 billion in damages and health-costs annually and save thousands of lives."[96]

According to motorist website "TheDrive.com" operated by Time magazine, none of the driving safety experts they were able to contact were able to rank driving under an autopilot system at the time (2017) as having achieved a greater level of safety than traditional fully hands-on driving, so the degree to which these benefits asserted by proponents will manifest in practice cannot be assessed.[97] Confounding factors that could reduce the net effect on safety may include unexpected interactions between humans and partly or fully automated vehicles, or between different types of vehicle system; complications at the boundaries of functionality at each automation level (such as handover when the vehicle reaches the limit of its capacity); the effect of the bugs and flaws that inevitably occur in complex interdependent software systems; sensor or data shortcomings; and successful compromise by malicious interveners.

Welfare

Automated cars could reduce labor costs;[98][99] relieve travelers from driving and navigation chores, thereby replacing behind-the-wheel commuting hours with more time for leisure or work;[6][95] and also would lift constraints on occupant ability to drive, distracted and texting while driving, intoxicated, prone to seizures, or otherwise impaired.[100][101][8] For the young, the elderly, people with disabilities, and low-income citizens, automated cars could provide enhanced mobility.[102][103][104] The removal of the steering wheel—along with the remaining driver interface and the requirement for any occupant to assume a forward-facing position—would give the interior of the cabin greater ergonomic flexibility. Large vehicles, such as motorhomes, would attain appreciably enhanced ease of use.[105]

Traffic

Additional advantages could include higher speed limits;[106] smoother rides;[107] and increased roadway capacity; and minimized traffic congestion, due to decreased need for safety gaps and higher speeds.[108][109] Currently, maximum controlled-access highway throughput or capacity according to the U.S. Highway Capacity Manual is about 2,200 passenger vehicles per hour per lane, with about 5% of the available road space is taken up by cars. One study estimated that automated cars could increase capacity by 273% (~8,200 cars per hour per lane). The study also estimated that with 100% connected vehicles using vehicle-to-vehicle communication, capacity could reach 12,000 passenger vehicles per hour (up 445% from 2,200 pc/h per lane) traveling safely at 120 km/h (75 mph) with a following gap of about 6 m (20 ft) of each other. Currently, at highway speeds drivers keep between 40 to 50 m (130 to 160 ft) away from the car in front. These increases in highway capacity could have a significant impact in traffic congestion, particularly in urban areas, and even effectively end highway congestion in some places.[110] The ability for authorities to manage traffic flow would increase, given the extra data and driving behavior predictability[7] combined with less need for traffic police and even road signage.

Lower costs

Safer driving is expected to reduce the costs of vehicle insurance.[98][111] Reduced traffic congestion and the improvements in traffic flow due to widespread use of automated cars will also translate into better fuel efficiency.[104][112][113] Additionally, self-driving cars will be able to accelerate and brake more efficiently, meaning higher fuel economy from reducing wasted energy typically associated with inefficient changes to speed (energy typically lost due to friction, in the form of heat and sound).

Parking space

Manually driven vehicles are reported to be used only 4-5% time, and being parked and unused for the remaining 95-96% of the time.[114][115] Autonomous vehicles could, on the other hand, be used continuously after it has reached its destination. This could dramatically reduce the need for parking space. For example, in Los Angeles, 14% of the land is used for parking alone,[116] equivalent to some 17,020,594 square meters.[117] This combined with the potential reduced need for road space due to improved traffic flow, could free up tremendous amounts of land in urban areas, which could then be used for parks, recreational areas, buildings, among other uses; making cities more livable.

By reducing the (labor and other) cost of mobility as a service, automated cars could reduce the number of cars that are individually owned, replaced by taxi/pooling and other car sharing services.[118][119] This would also dramatically reduce the size of the automotive production industry, with corresponding environmental and economic effects. Assuming the increased efficiency is not fully offset by increases in demand, more efficient traffic flow could free roadway space for other uses such as better support for pedestrians and cyclists.

The vehicles' increased awareness could aid the police by reporting on illegal passenger behavior, while possibly enabling other crimes, such as deliberately crashing into another vehicle or a pedestrian.[10] However, this may also lead to much expanded mass surveillance if there is wide access granted to third parties to the large data sets generated.

The future of passenger rail transport in the era of automated cars is not clear.[120]

Potential limits or obstacles

The sort of hoped-for potential benefits from increased vehicle automation described may be limited by foreseeable challenges, such as disputes over liability (will each company operating a vehicle accept that they are its "driver" and thus responsible for what their car does, or will some try to project this liability onto others who are not in control?),[14][15] the time needed to turn over the existing stock of vehicles from non-automated to automated,[121] and thus a long period of humans and autonomous vehicles sharing the roads, resistance by individuals to having to forfeit control of their cars,[16] concerns about the safety of driverless in practice,[13] and the implementation of a legal framework and consistent global government regulations for self-driving cars.[122] Other obstacles could include de-skilling and lower levels of driver experience for dealing with potentially dangerous situations and anomalies,[123] ethical problems where an automated vehicle's software is forced during an unavoidable crash to choose between multiple harmful courses of action ('the trolley problem'),[124][125][126] concerns about making large numbers of people currently employed as drivers unemployed (at the same time as many other alternate blue collar occupations may be undermined by automation), the potential for more intrusive mass surveillance of location, association and travel as a result of police and intelligence agency access to large data sets generated by sensors and pattern-recognition AI (making anonymous travel difficult), and possibly insufficient understanding of verbal sounds, gestures and non-verbal cues by police, other drivers or pedestrians.[127]

Possible technological obstacles for automated cars are:

  • Artificial Intelligence is still not able to function properly in chaotic inner-city environments.[128]
  • A car's computer could potentially be compromised, as could a communication system between cars.[129][130][131][132][133]
  • Susceptibility of the car's sensing and navigation systems to different types of weather (such as snow) or deliberate interference, including jamming and spoofing.[127]
  • Avoidance of large animals requires recognition and tracking, and Volvo found that software suited to caribou, deer, and elk was ineffective with kangaroos.[134]
  • Autonomous cars may require very high-quality specialised maps[135] to operate properly. Where these maps may be out of date, they would need to be able to fall back to reasonable behaviors.[127][136]
  • Competition for the radio spectrum desired for the car's communication.[137]
  • Field programmability for the systems will require careful evaluation of product development and the component supply chain.[133]
  • Current road infrastructure may need changes for automated cars to function optimally.[138]
  • Discrepancy between people’s beliefs of the necessary government intervention may cause a delay in accepting automated cars on the road.[139] Whether the public desires no change in existing laws, federal regulation, or another solution; the framework of regulation will likely result in differences of opinion.[139]
  • Employment - Companies working on the technology have an increasing recruitment problem in that the available talent pool has not grown with demand.[140] As such, education and training by third party organisations such as providers of online courses and self-taught community-driven projects such as DIY Robocars[141] and Formula Pi have quickly grown in popularity, while university level extra-curricular programmes such as Formula Student Driverless[142] have bolstered graduate experience. Industry is steadily increasing freely available information sources, such as code,[143] datasets[144] and glossaries[145] to widen the recruitment pool.

Potential disadvantages

A direct impact of widespread adoption of automated vehicles is the loss of driving-related jobs in the road transport industry.[98][99][146] There could be resistance from professional drivers and unions who are threatened by job losses.[147] In addition, there could be job losses in public transit services and crash repair shops. The automobile insurance industry might suffer as the technology makes certain aspects of these occupations obsolete.[104] A frequently cited paper by Michael Osborne and Carl Benedikt Frey found that automated cars would make many jobs redundant.[148]

Privacy could be an issue when having the vehicle's location and position integrated into an interface in which other people have access to.[149] In addition, there is the risk of automotive hacking through the sharing of information through V2V (Vehicle to Vehicle) and V2I (Vehicle to Infrastructure) protocols.[150][151] There is also the risk of terrorist attacks. Self-driving cars could potentially be loaded with explosives and used as bombs.[152]

The lack of stressful driving, more productive time during the trip, and the potential savings in travel time and cost could become an incentive to live far away from cities, where land is cheaper, and work in the city's core, thus increasing travel distances and inducing more urban sprawl, more fuel consumption and an increase in the carbon footprint of urban travel.[153][154] There is also the risk that traffic congestion might increase, rather than decrease.[104] Appropriate public policies and regulations, such as zoning, pricing, and urban design are required to avoid the negative impacts of increased suburbanization and longer distance travel.[104][154]

Some believe that once automation in vehicles reaches higher levels and becomes reliable, drivers will pay less attention to the road.[155] Research shows that drivers in automated cars react later when they have to intervene in a critical situation, compared to if they were driving manually.[156] Depending on the capabilities of automated vehicles and the frequency with which human intervention is needed, this may counteract any increase in safety, as compared to all-human driving, that may be delivered by other factors.

Ethical and moral reasoning come into consideration when programming the software that decides what action the car takes in an unavoidable crash; whether the automated car will crash into a bus, potentially killing people inside; or swerve elsewhere, potentially killing its own passengers or nearby pedestrians.[157] A question that programmers of AI systems find difficult to answer (as do ordinary people, and ethicists) is "what decision should the car make that causes the ‘smallest’ damage to people's lives?"

The ethics of automated vehicles are still being articulated, and may lead to controversy.[158] They may also require closer consideration of the variability, context-dependency, complexity and non-deterministic nature of human ethics. Different human drivers make various ethical decisions when driving, such as avoiding harm to themselves, or putting themselves at risk to protect others. These decisions range from rare extremes such as self-sacrifice or criminal negligence, to routine decisions good enough to keep the traffic flowing but bad enough to cause accidents, road rage and stress.

Human thought and reaction time may sometimes be too slow to detect the risk of an upcoming fatal crash, think through the ethical implications of the available options, or take an action to implement an ethical choice. Whether a particular automated vehicle's capacity to correctly detect an upcoming risk, analyse the options or choose a 'good' option from among bad choices would be as good or better than a particular human's may be difficult to predict or assess. This difficulty may be in part because the level of automated vehicle system understanding of the ethical issues at play in a given road scenario, sensed for an instant from out of a continuous stream of synthetic physical predictions of the near future, and dependent on layers of pattern recognition and situational intelligence, may be opaque to human inspection because of its origins in probabilistic machine learning rather than a simple, plain English 'human values' logic of parsable rules. The depth of understanding, predictive power and ethical sophistication needed will be hard to implement, and even harder to test or assess.

The scale of this challenge may have other effects. There may be few entities able to marshal the resources and AI capacity necessary to meet it, as well as the capital necessary to take an automated vehicle system to market and sustain it operationally for the life of a vehicle, and the legal and 'government affairs' capacity to deal with the potential for liability for a significant proportion of traffic accidents. This may have the effect of narrowing the number of different system opertors, and eroding the presently quite diverse global vehicle market down to a small number of system suppliers.

Potential changes for different industries

The traditional automobile is subject to changes that on the one hand are technology pushed, and on the other hand are demanded by the market. Where in the first case the technological discontinuity is fueled by the breakthrough technological innovation described, the second case is driven by the extent to which the market is used to adopting new technologies faster. In both cases the end of the era of incremental change was recognized, which is graphically displayed at the point where the transition is made to a new technology above. This point causes new entrants to the automotive industry to present themselves, which can be distinguished as mobility providers such as Uber and Lyft, as well as tech giants such as Google and nVidia. As new entrants to the industry will lead to a certain extent of uncertainty, due to the changing dynamics, the era of ferment will be the next phase in the Technology Life Cycle. With the entrance of tech giants, alliances between them and traditional car manufacturers are entered. This causes a variation in the innovation- and production process of autonomous vehicles. Besides that, the entrance of mobility providers has caused ambiguous user preferences. The increasing extent to which these providers are present in the industry is supported by the flattening curve on the ‘vehicles per capita’ graph. In addition, the rise of the sharing economy also contributes to this matter and allows forecasters to question whether private ownership of vehicles is still relevant when the dominant design is being selected.

Taxi industry

With the aforementioned ambiguous user preference regarding the private ownership of autonomous vehicles, it is possible that the current mobility provider trend will continue when the dominant design is selected. Established providers such as Uber and Lyft are already significantly present within the industry, and it is likely that new entrants will enter when business opportunities arise. https://www.theverge.com/2018/1/2/16841090/lyft-aptiv-self-driving-car-ces-2018.;

Healthcare-, repair-, and insurance industry

With the increasing reliance of autonomous vehicles on interconnectivity and the availability of big data which is made useable in the form of real time maps, driving decisions can be made much faster in order to prevent collisions. Numbers made available by the US government state that 94% of the vehicle accidents is due to human failures. With that in mind, it is safe to say that there is a major implication for the healthcare industry. Numbers of the National Safety Council on killed and injured people on U.S. roads multiplied by the average costs of a single incident point out that an estimated 500-billion-dollar loss is accounted for the US healthcare industry only by the time autonomous vehicles are dominating the roads. On the positive side, these numbers will positively contribute to the widespread acceptance of autonomous vehicles, as well as the possibility to better allocate healthcare resources. As collisions are less likely to occur, and the risk for human errors is reduced significantly, the repair industry will face an enormous reduction of work that has to be done on the reparation of car frames. Meanwhile, as the generated data of the autonomous vehicle is likely to predict when certain replaceable parts are in need of maintenance, car owners and the repair industry will be able to preventively replace a part that will fail soon. This ‘Asset Efficiency Service’ would implicate a productivity gain for this business. As fewer collisions implicate less money spend on repair costs, the role of the insurance industry is likely to be altered as well. It can be expected that the increased safety of transport due to autonomous vehicles will lead to a decrease in payouts for the insurers, which is positive for the industry, but on the other hand fewer payouts implicate a demand drop for insurances in general. The insurance industry has to come up with new insurance models in the near future.;

Rescue-, emergency- and military industry

The technique used in autonomous driving also ensures life savings in other industries. The implementation of autonomous vehicles within the rescue-, emergency- and military industry already leads to a decrease in death. Military personnel uses autonomous vehicles to reach dangerous and remote places on earth to deliver fuel, food and general supplies, and even rescue people. In addition, a future implication of adopting autonomous vehicles could lead to a reduction in deployed personnel, what will lead to a decrease in injuries, since the technological development allows AV’s to become more and more autonomous. Also, another future implication is the reduction of emergency drivers when autonomous vehicles are deployed as fire trucks or ambulances. An advantage could be the use of real-time traffic information and other generated data to determine routes more efficiently than human drivers. The time savings can be invaluable in these situations. (https://www.armytimes.com/news/your-army/2017/08/29/the-us-army-is-developing-autonomous-armored-vehicles/);

Interior design- and media-entertainment industry

For the interior design industry, there are exciting times ahead. The driver is decreasingly focussed on the actual driving, this implies that the interior design- and media-entertainment industry has to reconsider what passengers of autonomous vehicles are doing when they are on the road. Vehicles need to be redesigned, and possibly even be prepared for multipurpose usage. In practice, it will show that travelers have more time for business and/or leisure. In both cases, this gives increasing opportunities for the media-entertainment industry to demand attention. Moreover, the advertisement business is able to provide location based ads without risking driver safety. (http://cardesignresearch.com/en/insights/2015/01/driverless-car-design-sleepwalking-into-the-future);

Telecommunication and energy industry

As autonomous vehicles are producing enormous amounts of data that need to be transferred and analyzed, the upcoming 5G cellular network will play a pivotal role in doing so. In addition, the earlier mentioned entertainment industry is also highly dependent on this network to be active in this market segment. This implies higher revenues for the telecommunication industry. Since autonomous vehicles are solely going to rely on electricity to operate, the demand for lithium batteries increases. This causes a necessary increase in supply of these type of batteries for the chemical industry. On the other hand, with the expected increase of battery powered (autonomous) vehicles, the petroleum industry is expected to undergo a decline in demand. As this implication depends on the adoption rate of autonomous vehicles, it is unsure to what extent this implication will disrupt this particular industry. This transition phase of oil to electricity allows companies to explore whether there are business opportunities for them in the new energy ecosystem.;

Restaurant, hotel- and airline industry

Driver interactions with the vehicle will be less common within the near future, and in the more distant future the responsibility will lie entirely with the vehicle. As indicated above, this will have implications for the entertainment- and interior design industry. For roadside restaurants, the implication will be that the need for customers to stop driving and enter the restaurant will vanish, and the autonomous vehicle will have a double function. Moreover, accompanied with the rise of disruptive platforms such as Airbnb that have shaken up the hotel industry, the fast increase of developments within the autonomous vehicle industry might cause another implication for their customer bases. In the more distant future, the implication for motels might be that a decrease in guests will occur, since autonomous vehicles could be redesigned as fully equipped bedrooms. The improvements regarding the interior of the vehicles might additionally have implications for the airline industry. In the case of relatively short-haul flights, waiting times at customs or the gate imply lost time and hassle for customers. With the improved convenience in future car travel, it is possible that customers might go for this option, causing a loss in customer bases for airline industry.(https://interestingengineering.com/volvos-fully-autonomous-360c-concept-vehicle-even-lets-you-sleep-in-it); and

Elder-, disabled- and childcare industry

Autonomous vehicles will have a severe impact on the mobility options of persons that are not able to drive a vehicle themselves. To remain socially engaged with society or even able to do groceries, the elderly people of today are depending on caretakers to drive them to these places. In addition to the perceived freedom of the elderly people of the future, the demand for human aides will decrease. When we also consider the increased health of the elderly, it is safe to state that care centers will experience a decrease in the number of clients. Not only elderly people face difficulties of their decreased physical abilities, also disabled people will perceive the benefits of autonomous vehicles in the near future, causing their dependency on caretakers to decrease. Both industries are largely depending on informal caregivers, who are mostly relatives of the persons in need. Since there is less of a reliance on their time, employers of informal caregivers or even governments will experience a decrease of costs allocated to this matter. Children and teens, who are not able to drive a vehicle themselves, are also benefiting of the introduction of autonomous cars. Daycares and schools are able to come up with automated pick up and drop off systems, causing a decrease of reliance on parents and childcare workers. The extent to which human actions are necessary for driving will vanish. Since current vehicles require human actions to some extent, the driving school industry will not be disrupted until the majority of autonomous transportation is switched to the emerged dominant design. It is plausible that in the distant future driving a vehicle will be considered as a luxury, which implies that the structure of the industry is based on new entrants and a new market.(https://jalopnik.com/why-autonomous-cars-could-be-the-change-disabled-people-1688864804).}}

Incidents

Mercedes automated cruise control system

In 1999, Mercedes introduced Distronic, the first radar-assisted ACC, on the Mercedes-Benz S-Class (W220)[159][160] and the CL-Class.[161] The Distronic system was able to adjust the vehicle speed automatically to the car in front in order to always maintain a safe distance to other cars on the road.

Mercedes-Benz S 450 4MATIC Coupe. The forward-facing Distronic sensors are usually placed behind the Mercedes-Benz logo and front grille.

In 2005, Mercedes refined the system (from this point called "Distronic Plus") with the Mercedes-Benz S-Class (W221) being the first car to receive the upgraded Distronic Plus system. Distronic Plus could now completely halt the car if necessary on E-Class and most Mercedes sedans. In an episode of Top Gear, Jeremy Clarkson demonstrated the effectiveness of the cruise control system in the S-class by coming to a complete halt from motorway speeds to a round-about and getting out, without touching the pedals.[162]

By 2017, Mercedes has vastly expanded its automated driving features on production cars: In addition to the standard Distronic Plus features such as an active brake assist, Mercedes now includes a steering pilot, a parking pilot, a cross-traffic assist system, night-vision cameras with automated danger warnings and braking assist (in case animals or pedestrians are on the road for example), and various other automated -driving features.[163][164][165][166][167] In 2016, Mercedes also introduced its Active Brake Assist 4, which was the first emergency braking assistant with pedestrian recognition on the market.[168]

Due to Mercedes' history of gradually implementing advancements of their automated driving features that have been extensively tested, not many crashes that have been caused by it are known. One of the known crashes dates back to 2005, when German news magazine "Stern" was testing Mercedes' old Distronic system. During the test, the system did not always manage to brake in time.[169] Ulrich Mellinghoff, then Head of Safety, NVH, and Testing at the Mercedes-Benz Technology Centre, stated that some of the tests failed due to the vehicle being tested in a metallic hall, which caused problems with the system's radar. Later iterations of the Distronic system have an upgraded radar and numerous other sensors, which are not susceptible to a metallic environment anymore.[169][170] In 2008, Mercedes conducted a study comparing the crash rates of their vehicles equipped with Distronic Plus and the vehicles without it, and concluded that those equipped with Distronic Plus have an around 20% lower crash rate.[171] In 2013, German Formula One driver Michael Schumacher was invited by Mercedes to try to crash a Mercedes C-Class vehicle, which was equipped with all safety features that Mercedes offered for its production vehicles at the time, which included the Active Blind Spot Assist, Active Lane Keeping Assist, Brake Assist Plus, Collision Prevention Assist, Distronic Plus with Steering Assist, Pre-Safe Brake, and Stop&Go Pilot. Due to the safety features, Schumacher was unable to crash the vehicle in realistic scenarios.[172]

Tesla Autopilot

In midOctober 2015, Tesla Motors rolled out version 7 of their software in the U.S. that included Tesla Autopilot capability.[173] On 9 January 2016, Tesla rolled out version 7.1 as an over-the-air update, adding a new "summon" feature that allows cars to self-park at parking locations without the driver in the car.[174] Tesla's automated driving features can be classified as somewhere between level 2 and level 3 under the U.S. Department of Transportation’s National Highway Traffic Safety Administration (NHTSA) five levels of vehicle automation. At this level the car can be automated but requires the full attention of the driver, who must be prepared to take control at a moment's notice.[175][176][177] Autopilot should be used only on limited-access highways, and sometimes it will fail to detect lane markings and disengage itself. In urban driving the system will not read traffic signals or obey stop signs. The system also does not detect pedestrians or cyclists.[178]

Tesla Model S Autopilot system in use in July 2016; it was only suitable for limited-access highways, not for urban driving. Among other limitations, it could not detect pedestrians or cyclists.[178]

On 20 January 2016, the first known fatal crash of a Tesla with Autopilot occurred in China's Hubei province. According to China's 163.com news channel, this marked "China's first accidental death due to Tesla's automatic driving (system)." Initially, Tesla pointed out that the vehicle was so badly damaged from the impact that their recorder was not able to conclusively prove that the car had been on Autopilot at the time, however 163.com pointed out that other factors, such as the car's absolute failure to take any evasive actions prior to the high speed crash, and the driver's otherwise good driving record, seemed to indicate a strong likelihood that the car was on Autopilot at the time. A similar fatal crash occurred four months later in Florida.[179][180] In 2018, in a subsequent civil suit between the father of the driver killed and Tesla, Tesla did not deny that the car had been on Autopilot at the time of the accident, and sent evidence to the victim's father documenting that fact.[181]

The second known fatal accident involving a vehicle being driven by itself took place in Williston, Florida on 7 May 2016 while a Tesla Model S electric car was engaged in Autopilot mode. The occupant was killed in a crash with an 18-wheel tractor-trailer. On 28 June 2016 the National Highway Traffic Safety Administration (NHTSA) opened a formal investigation into the accident working with the Florida Highway Patrol. According to the NHTSA, preliminary reports indicate the crash occurred when the tractor-trailer made a left turn in front of the Tesla at an intersection on a non-controlled access highway, and the car failed to apply the brakes. The car continued to travel after passing under the truck’s trailer.[182][183] The NHTSA's preliminary evaluation was opened to examine the design and performance of any automated driving systems in use at the time of the crash, which involved a population of an estimated 25,000 Model S cars.[184] On 8 July 2016, the NHTSA requested Tesla Motors provide the agency detailed information about the design, operation and testing of its Autopilot technology. The agency also requested details of all design changes and updates to Autopilot since its introduction, and Tesla's planned updates schedule for the next four months.[185]

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." The car attempted to drive full speed under the trailer, "with the bottom of the trailer impacting the windshield of the Model S." Tesla also claimed that this was Tesla’s first known autopilot death in over 130 million miles (210 million kilometers) driven by its customers with Autopilot engaged, however by this statement, Tesla was apparently refusing to acknowledge claims that the January 2016 fatality in Hubei China had also been the result of an autopilot system error. According to Tesla there is a fatality every 94 million miles (151 million kilometers) among all type of vehicles in the U.S.[182][183][186] However, this number also includes fatalities of the crashes, for instance, of motorcycle drivers with pedestrians.[187][188]

In July 2016, the U.S. National Transportation Safety Board (NTSB) opened a formal investigation into the fatal accident while the Autopilot was engaged. The NTSB is an investigative body that has the power to make only policy recommendations. An agency spokesman said "It's worth taking a look and seeing what we can learn from that event, so that as that automation is more widely introduced we can do it in the safest way possible."[189] In January 2017, the NTSB released the report that concluded Tesla was not at fault; the investigation revealed that for Tesla cars, the crash rate dropped by 40 percent after Autopilot was installed.[190]

According to Tesla, starting 19 October 2016, all Tesla cars are built with hardware to allow full self-driving capability at the highest safety level (SAE Level 5).[191] The hardware includes eight surround cameras and twelve ultrasonic sensors, in addition to the forward-facing radar with enhanced processing capabilities.[192] The system will operate in "shadow mode" (processing without taking action) and send data back to Tesla to improve its abilities until the software is ready for deployment via over-the-air upgrades.[193] After the required testing, Tesla hopes to enable full self-driving by the end of 2019 under certain conditions.

Waymo

Google's in-house automated car.

Waymo originated as a self-driving car project within Google. In August 2012, Google announced that their vehicles had completed over 300,000 automated-driving miles (500,000 km) accident-free, typically involving about a dozen cars on the road at any given time, and that they were starting to test with single drivers instead of in pairs.[194] In late-May 2014, Google revealed a new prototype that had no steering wheel, gas pedal, or brake pedal, and was fully automated .[195] As of March 2016, Google had test-driven their fleet in automated mode a total of 1,500,000 mi (2,400,000 km).[196] In December 2016, Google Corporation announced that its technology would be spun off to a new company called Waymo, with both Google and Waymo becoming subsidiaries of a new parent company called Alphabet.[197][198]

According to Google'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.[199]

In June 2015, Brin confirmed that 12 vehicles had suffered collisions as of that date. Eight involved rear-end collisions at a stop sign or traffic light, two in which the vehicle was side-swiped by another driver, one in which another driver rolled through a stop sign, and one where a Google employee was controlling the car manually.[200] In July 2015, three Google employees suffered minor injuries when their vehicle was rear-ended by a car whose driver failed to brake at a traffic light. This was the first time that a collision resulted in injuries.[201] 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."[202][203] Google characterized the crash as a misunderstanding and a learning experience. No injuries were reported in the crash.[199]

Uber

In March 2017, an Uber test vehicle was involved in a crash in Tempe, Arizona when another car failed to yield, flipping the Uber vehicle. There were no injuries in the accident.[204]

By 22 December 2017, Uber had completed 2 million miles (3.2 million kilometers) in automated mode.[205]

On 18 March 2018, Elaine Herzberg became the first pedestrian to be killed by a self-driving car in the United States after being hit by an Uber vehicle, also in Tempe. Herzberg was crossing outside of a crosswalk, approximately 400 feet from an intersection.[206] The causes of the accidents include the following: nighttime, low visibility, pedestrian crossing from a shadowed portion of road, crossing a road that had high speed limit, and not checking for cars before crossing (blindly crossing street at night). This marks the first time an individual outside an auto-piloted car is known to have been killed by such a car. The first death of an essentially uninvolved third party is likely to raise new questions and concerns about the safety of automated cars in general.[207] Some experts say a human driver could have avoided the fatal crash.[208] Arizona Governor Doug Ducey later suspended the company's ability to test and operate its automated cars on public roadways citing an "unquestionable failure" of the expectation that Uber make public safety its top priority.[209] Uber has pulled out of all self-driving-car testing in California as a result of the accident.[210] On 24 May 2018 the National Transport Safety Board issued a preliminary report.[211]

On 9 November 2017, a Navya automated self-driving bus with passengers was involved in a crash with a truck. The truck was found to be at fault of the crash, reversing into the stationary automated bus. The automated bus did not take evasive actions or apply defensive driving such as flash headlights, sound the horn, or as one passenger commented "The shuttle didn't have the ability to move back. The shuttle just stayed still."[212]

Policy implications

Urban planning

According to a Wonkblog reporter, if fully automated cars become commercially available, they have the potential to be a disruptive innovation with major implications for society. The likelihood of widespread adoption is still unclear, but if they are used on a wide scale, policy makers face a number of unresolved questions about their effects.[138]

One fundamental question is about their effect on travel behavior. Some people believe that they will increase car ownership and car use because it will become easier to use them and they will ultimately be more useful.[138] This may in turn encourage urban sprawl and ultimately total private vehicle use. Others argue that it will be easier to share cars and that this will thus discourage outright ownership and decrease total usage, and make cars more efficient forms of transportation in relation to the present situation.[213]

Policy-makers will have to take a new look at how infrastructure is to be built and how money will be allotted to build for automated vehicles. The need for traffic signals could potentially be reduced with the adoption of smart highways.[214] Due to smart highways and with the assistance of smart technological advances implemented by policy change, the dependence on oil imports may be reduced because of less time being spent on the road by individual cars which could have an effect on policy regarding energy.[215] On the other hand, automated vehicles could increase the overall number of cars on the road which could lead to a greater dependence on oil imports if smart systems are not enough to curtail the impact of more vehicles.[216] However, due to the uncertainty of the future of automated vehicles, policy makers may want to plan effectively by implementing infrastructure improvements that can be beneficial to both human drivers and automated vehicles.[217] Caution needs to be taken in acknowledgment to public transportation and that the use may be greatly reduced if automated vehicles are catered to through policy reform of infrastructure with this resulting in job loss and increased unemployment.[218]

Other disruptive effects will come from the use of automated vehicles to carry goods. Self-driving vans have the potential to make home deliveries significantly cheaper, transforming retail commerce and possibly making hypermarkets and supermarkets redundant. As of right now the U.S. Government defines automation into six levels, starting at level zero which means the human driver does everything and ending with level five, the automated system performs all the driving tasks. Also under the current law, manufacturers bear all the responsibility to self-certify vehicles for use on public roads. This means that currently as long as the vehicle is compliant within the regulatory framework, there are no specific federal legal barriers to a highly automated vehicle being offered for sale. Iyad Rahwan, an associate professor in the MIT Media lab said, "Most people want to live in a world where cars will minimize casualties, but everyone wants their own car to protect them at all costs." Furthermore, industry standards and best practice are still needed in systems before they can be considered reasonably safe under real-world conditions.[219]

Legislation

The 1968 Vienna Convention on Road Traffic, subscribed to by over 70 countries worldwide, establishes principles to govern traffic laws. One of the fundamental principles of the Convention has been the concept that a driver is always fully in control and responsible for the behavior of a vehicle in traffic.[220] The progress of technology that assists and takes over the functions of the driver is undermining this principle, implying that much of the groundwork must be rewritten.

U.S. states that allow testing of driverless cars on public roads

In the United States, a non-signatory country to the Vienna Convention, state vehicle codes generally do not envisage — but do not necessarily prohibit — highly automated vehicles.[221][222] To clarify the legal status of and otherwise regulate such vehicles, several states have enacted or are considering specific laws.[223] In 2016, 7 states (Nevada, California, Florida, Michigan, Hawaii, Washington, and Tennessee), along with the District of Columbia, have enacted laws for automated vehicles. Incidents such as the first fatal accident by Tesla's Autopilot system have led to discussion about revising laws and standards for automated cars.

In September 2016, the US National Economic Council and Department of Transportation released federal standards that describe how automated vehicles should react if their technology fails, how to protect passenger privacy, and how riders should be protected in the event of an accident. The new federal guidelines are meant to avoid a patchwork of state laws, while avoiding being so overbearing as to stifle innovation.[224]

In June 2011, the Nevada Legislature passed a law to authorize the use of automated cars. Nevada thus became the first jurisdiction in the world where automated vehicles might be legally operated on public roads. According to the law, the Nevada Department of Motor Vehicles (NDMV) is responsible for setting safety and performance standards and the agency is responsible for designating areas where automated cars may be tested.[225][226][227] This legislation was supported by Google in an effort to legally conduct further testing of its Google driverless car.[228] The Nevada law defines an automated vehicle to be "a motor vehicle that uses artificial intelligence, sensors and global positioning system coordinates to drive itself without the active intervention of a human operator." The law also acknowledges that the operator will not need to pay attention while the car is operating itself. Google had further lobbied for an exemption from a ban on distracted driving to permit occupants to send text messages while sitting behind the wheel, but this did not become law.[228][229][230] Furthermore, Nevada's regulations require a person behind the wheel and one in the passenger’s seat during tests.[231]

In April 2012, Florida became the second state to allow the testing of automated cars on public roads,[232] and California became the third when Governor Jerry Brown signed the bill into law at Google Headquarters in Mountain View.[233] In December 2013, Michigan became the fourth state to allow testing of driverless cars on public roads.[234] In July 2014, the city of Coeur d'Alene, Idaho adopted a robotics ordinance that includes provisions to allow for self-driving cars.[235]

A Toyota Prius modified by Google to operate as a driverless car.

On 19 February 2016, Assembly Bill No. 2866 was introduced in California that would allow automated vehicles to operate on the road, including those without a driver, steering wheel, accelerator pedal, or brake pedal. The Bill states the Department of Motor Vehicles would need to comply with these regulations by 1 July 2018 for these rules to take effect. This bill has yet to pass the house of origin.[236]

In September 2016, the U.S. Department of Transportation released its Federal Automated Vehicles Policy,[237] and California published discussions on the subject in October 2016.[238]

In December 2016, the California Department of Motor Vehicles ordered Uber to remove its self-driving vehicles from the road in response to two red-light violations. Uber immediately blamed the violations on "human-error", and has suspended the drivers.[239]

Legislation in Europe

In 2013, the government of the United Kingdom permitted the testing of automated cars on public roads.[240] Before this, all testing of robotic vehicles in the UK had been conducted on private property.[240]

In 2014, the Government of France announced that testing of automated cars on public roads would be allowed in 2015. 2000 km of road would be opened through the national territory, especially in Bordeaux, in Isère, Île-de-France and Strasbourg. At the 2015 ITS World Congress, a conference dedicated to intelligent transport systems, the very first demonstration of automated vehicles on open road in France was carried out in Bordeaux in early October 2015.[241]

In 2015, a preemptive lawsuit against various automobile companies such as GM, Ford, and Toyota accused them of "Hawking vehicles that are vulnerable to hackers who could hypothetically wrest control of essential functions such as brakes and steering."[242]

In spring of 2015, the Federal Department of Environment, Transport, Energy and Communications in Switzerland (UVEK) allowed Swisscom to test a driverless Volkswagen Passat on the streets of Zurich.[243]

As of April 2017, it is possible to conduct public road tests for development vehicles in Hungary, furthermore the construction  of a closed test track, the Zala Zone test track,[244] suitable for testing highly automated functions is also under way near the city of Zalaegerszeg.[245]

Legislation in Asia

In 2016, the Singapore Land Transit Authority in partnership with UK automotive supplier Delphi Automotive Plc will launch preparations for a test run of a fleet of automated taxis for an on-demand automated cab service to take effect in 2017.[246]

Liability

Self-driving car liability is a developing area of law and policy that will determine who is liable when an automated car causes physical damage to persons, or breaks road rules.[247] When automated cars shift the control of driving from humans to automated car technology, there may be a need for existing liability laws to evolve in order to fairly identify the parties responsible for damage and injury, and to address the potential for conflicts of interest between human occupants, system operator, insurers, and the public purse.[104] Increases in the use of automated car technologies (e.g. advanced driver-assistance systems) may prompt incremental shifts in this responsibility for driving. It is claimed by proponents to have potential to affect the frequency of road accidents, although it is difficult to assess this claim in the absence of data from substantial actual use.[248] If there was a dramatic improvement in safety, the operators may seek to project their liability for the remaining accidents onto others as part of their reward for the improvement. However, there is no obvious reason why they should escape liability if any such effects were found to be modest or nonexistent, since part of the purpose of such liability is to give an incentive to the party controlling something to do whatever is necessary to avoid it causing harm. Potential users may be reluctant to trust an operator if it seeks to pass its normal liability on to others.

In any case, a well-advised person who is not controlling a car at all (Level 5) would be understandably reluctant to accept liability for something out of their control. And when there is some degree of sharing control possible (Level 3 or 4), a well-advised person would be concerned that the vehicle might try to pass back control at the last seconds before an accident, to pass responsibility and liability back too, but in circumstances where the potential driver has no better prospects of avoiding the crash than the vehicle, since they have not necessarily been paying close attention, and if it is too hard for the very smart car it might be too hard for a human. Since operators, especially those familiar with trying to ignore existing legal obligations (under a motto like 'seek forgiveness, not permission'), such as Waymo or Uber, could be normally expected to try to avoid responsibility to the maximum degree possible, there is potential for attempt to let the operators evade being held liable for accidents while they are in control.

As higher levels of automation are commercially introduced (level 3 and 4), the insurance industry may see a greater proportion of commercial and product liability lines while personal automobile insurance shrinks.[249]

Vehicular communication systems

Individual vehicles may benefit from information obtained from other vehicles in the vicinity, especially information relating to traffic congestion and safety hazards. Vehicular communication systems use vehicles and roadside units as the communicating nodes in a peer-to-peer network, providing each other with information. As a cooperative approach, vehicular communication systems can allow all cooperating vehicles to be more effective. According to a 2010 study by the National Highway Traffic Safety Administration, vehicular communication systems could help avoid up to 79 percent of all traffic accidents.[250]

In 2012, computer scientists at the University of Texas in Austin began developing smart intersections designed for automated cars. The intersections will have no traffic lights and no stop signs, instead using computer programs that will communicate directly with each car on the road.[251]

An efficient intersection management technique called Crossroads was proposed in 2017 that is robust to network delay of V2I communication and Worst-case Execution time of the intersection manager.[252]

Among connected cars, an unconnected one is the weakest link and will be increasingly banned from busy high-speed roads, predicted a Helsinki think tank in January 2016.[253]

Public opinion surveys

In a 2011 online survey of 2,006 US and UK consumers by Accenture, 49% said they would be comfortable using a "driverless car".[254]

A 2012 survey of 17,400 vehicle owners by J.D. Power and Associates found 37% initially said they would be interested in purchasing a "fully autonomous car". However, that figure dropped to 20% if told the technology would cost $3,000 more.[255]

In a 2012 survey of about 1,000 German drivers by automotive researcher Puls, 22% of the respondents had a positive attitude towards these cars, 10% were undecided, 44% were skeptical and 24% were hostile.[256]

A 2013 survey of 1,500 consumers across 10 countries by Cisco Systems 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.[257]

In a 2014 US telephone survey by Insurance.com, over three-quarters of licensed drivers said they would at least 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 instead.[258]

In a February 2015 survey of top auto journalists, 46% predict that either Tesla or Daimler will be the first to the market with a fully autonomous vehicle, while (at 38%) Daimler is predicted to be the most functional, safe, and in-demand autonomous vehicle.[259]

In 2015 a questionnaire survey by Delft University of Technology explored the opinion of 5,000 people from 109 countries on automated driving. Results showed that respondents, on average, found manual driving the most enjoyable mode of driving. 22% of the respondents did not want to spend any money for a fully automated driving system. Respondents were found to be most concerned about software hacking/misuse, and were also concerned about legal issues and safety. Finally, respondents from more developed countries (in terms of lower accident statistics, higher education, and higher income) were less comfortable with their vehicle transmitting data.[260] The survey also gave results on potential consumer opinion on interest of purchasing an automated car, stating that 37% of surveyed current owners were either "definitely" or "probably" interested in purchasing an automated car.[260]

In 2016, a survey in Germany examined the opinion of 1,603 people, who were representative in terms of age, gender, and education for the German population, towards partially, highly, and fully automated cars. Results showed that men and women differ in their willingness to use them. Men felt less anxiety and more joy towards automated cars, whereas women showed the exact opposite. The gender difference towards anxiety was especially pronounced between young men and women but decreased with participants' age.[261]

In 2016, a PwC survey, in the United States, showing the opinion of 1,584 people, highlights that "66 percent of respondents said they think autonomous cars are probably smarter than the average human driver". People are still worried about safety and mostly the fact of having the car hacked. Nevertheless, only 13% of the interviewees see no advantages in this new kind of cars.[262]

A Pew Research Center survey of 4,135 U.S. adults conducted 1–15 May 2017 finds that many Americans anticipate significant impacts from various automation technologies in the course of their lifetimes—from the widespread adoption of automated vehicles to the replacement of entire job categories with robot workers.[263]

Moral issues

With the emergence of automated automobiles various ethical issues arise. While the introduction of automated vehicles to the mass market is said to be inevitable due to an (untestable) potential for reduction of crashes by "up to" 90%[264] and their potential greater accessibility to disabled, elderly, and young passengers, a range of ethical issues have not been fully addressed. Those include, but are not limited to: the moral, financial, and criminal responsibility for crashes and breaches of law; the decisions a car is to make right before a (fatal) crash; privacy issues including potential for mass surveillance; potential for massive job losses and unemployment among drivers; de-skilling and loss of independence by vehicle users; exposure to hacking and malware; and the further concentration of market and data power in the hands of a few global conglomerates capable of consolidating AI capacity, and of lobbying governments to facilitate the shift of liability onto others and their potential destruction of existing occupations and industries.

There are different opinions on who should be held liable in case of a crash, especially with people being hurt. Many experts see the car manufacturers themselves responsible for those crashes that occur due to a technical malfunction or misconstruction.[265] Besides the fact that the car manufacturer would be the source of the problem in a situation where a car crashes due to a technical issue, there is another important reason why car manufacturers could be held responsible: it would encourage them to innovate and heavily invest into fixing those issues, not only due to protection of the brand image, but also due to financial and criminal consequences. However, there are also voices [who?] that argue those using or owning the vehicle should be held responsible since they know the risks involved in using such a vehicle. Experts [who?] suggest introducing a tax or insurances that would protect owners and users of automated vehicles of claims made by victims of an accident.[265] Other possible parties that can be held responsible in case of a technical failure include software engineers that programmed the code for the automated operation of the vehicles, and suppliers of components of the AV.[266]

Taking aside the question of legal liability and moral responsibility, the question arises how automated vehicles should be programmed to behave in an emergency situation where either passengers or other traffic participants are endangered. A moral dilemma that a software engineer or car manufacturer might face in programming the operating software is described in an ethical thought experiment, the trolley problem: a conductor of a trolley has the choice of staying on the planned track and running over 5 people, or turn the trolley onto a track where it would kill only one person, assuming there is no traffic on it.[267] There are two main considerations that need to be addressed. First, what moral basis would be used by an automated vehicle to make decisions? Second, how could those be translated into software code? Researchers have suggested, in particular, two ethical theories to be applicable to the behavior of automated vehicles in cases of emergency: deontology and utilitarianism.[268] Asimov’s three laws of robotics are a typical example of deontological ethics. The theory suggests that an automated car needs to follow strict written-out rules that it needs to follow in any situation. Utilitarianism suggests the idea that any decision must be made based on the goal to maximize utility. This needs a definition of utility which could be maximizing the number of people surviving in a crash. Critics suggest that automated vehicles should adapt a mix of multiple theories to be able to respond morally right in the instance of a crash.[268]

(Many 'Trolley' discussions skip over the practical problems of how a probabilistic machine learning vehicle AI could be sophisticated enough to understand that a deep problem of moral philosophy is presenting itself from instant to instant while using a dynamic projection into the near future, what sort of moral problem it actually would be if any, what the relevant weightings in human value terms should be given to all the other humans involved who will be probably unreliably identified, and how reliably it can assess the probable outcomes. These practical difficulties, and those around testing and assessment of solutions to them, may present as much of a challenge as the theoretical abstractions.)

Privacy-related issues arise mainly from the interconnectivity of automated cars, making it just another mobile device that can gather any information about an individual. This information gathering ranges from tracking of the routes taken, voice recording, video recording, preferences in media that is consumed in the car, behavioral patterns, to many more streams of information.[269][270] The data and communications infrastructure needed to support these vehicles may also be capable of surveillance, especially if coupled to other data sets and advanced analytics.

The implementation of automated vehicles to the mass market might cost up to 5 million jobs in the US alone, making up almost 3% of the workforce.[271] Those jobs include drivers of taxis, buses, vans, trucks, and e-hailing vehicles. Many industries, such as the auto insurance industry are indirectly affected. This industry alone generates an annual revenue of about $220 billions, supporting 277,000 jobs.[272] To put this into perspective – this is about the number of mechanical engineering jobs.[273] The potential loss of a majority of those jobs will have a tremendous impact on those individuals involved.[274] Both India and China have placed bans on automated cars with the former citing protection of jobs.

Anticipated launch of cars

In December 2015, Tesla CEO Elon Musk predicted that a completely automated car would be introduced by the end of 2018;[275] in December 2017, he announced that it would take another two years to launch a fully self-driving Tesla onto the market.[276]

BMW's all-electric automated car, called iNext, is expected to be ready by 2021; Toyota’s first self-driving car is due to hit the market in 2020, as is the driverless car being developed by Nissan.[277]

In fiction

Minority Report's Lexus 2054 on display in Paris in October 2002.

In film

The automated and occasionally sentient self-driving car story has earned its place in both literary science fiction and pop sci-fi.[278]

I, Robot's Audi RSQ at the CeBIT expo in March 2005.
  • The film Eagle Eye (2008) Shia LaBeouf and Michelle Monaghan are driven around in a Porsche Cayenne that is controlled by ARIIA ( a giant supercomputer ).
  • The film I, Robot (2004), set in Chicago in 2035, features automated vehicles driving on highways, allowing the car to travel safer at higher speeds than if manually controlled. The option to manually operate the vehicles is available.
  • The film Logan set in 2029, features fully automated trucks.
  • Blade Runner 2049 (2017) opens with LAPD Replicant cop K waking up in his 3-wheeled automated flying vehicle (featuring a separable surveillance roof drone) on approach to a protein farm in northern California.
  • Geostorm, set in 2022, features a self-driving taxi stolen by protagonists Max Lawson and Sarah Wilson to protect the President from mercenaries and a superstorm.

In literature

Intelligent or self-driving cars are a common theme in science fiction literature. Examples include:

In television

  • "CSI: Cyber" Season 2, episode 6, Gone in 60 Seconds, features three seemingly normal customized vehicles, a 2009 Nissan Fairlady Z Roadster, a BMW M3 E90 and a Cadillac CTS-V, and one stock luxury BMW 7 Series, being remote-controlled by a computer hacker.
  • "Handicar", season 18, episode 4 of 2014 TV series South Park features a Japanese automated car that takes part in the Wacky Races-style car race.
  • KITT and KARR, the Pontiac Trans Ams in the 1982 TV series Knight Rider, were sentient and autonomous.
  • "Driven", series 4 episode 11 of the 2003 TV series NCIS features a robotic vehicle named "Otto", part of a high-level project of the Department of Defense, which causes the death of a Navy Lieutenant, and then later almost kills Abby.
  • The TV series "Viper" features a silver/grey armored assault vehicle, called The Defender, which masquerades as a flame-red 1992 Dodge Viper RT/10 and later as a 1998 cobalt blue Dodge Viper GTS. The vehicle's sophisticated computer systems allow it to be controlled via remote on some occasions.
  • "Black Mirror" episode "Hated in the Nation" briefly features a self-driving SUV with a touchscreen interface on the inside.
  • Bull has a show discussing the effectiveness and safety of self-driving cars in an episode call E.J.[280]
  • The cartoon 'Blaze and the Monster Machines' features automated/autonomous cars and trucks.

See also

Manufacturers

Automated driving functions

References

  1. Thrun, Sebastian (2010). "Toward Robotic Cars". Communications of the ACM. 53 (4): 99–106. doi:10.1145/1721654.1721679.
  2. 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. 3. Kyongju. pp. 1507–1512. doi:10.1109/IROS.1999.811692. ISBN 0-7803-5184-3.
  3. Lassa, Todd (January 2013). "The Beginning of the End of Driving". Motor Trend. Retrieved 1 September 2014.
  4. European Roadmap Smart Systems for Automated Driving Archived 12 February 2015 at the Wayback Machine., European Technology Platform on Smart Systems Integration (EPoSS), 2015.
  5. Umar Zakir Abdul, Hamid; et al. (2016). "Current Collision Mitigation Technologies for Advanced Driver Assistance Systems–A Survey" (PDF). PERINTIS eJournal. 6 (2). Retrieved 14 June 2017.
  6. 1 2 3 "[INFOGRAPHIC] Autonomous Cars Could Save The US $1.3 Trillion Dollars A Year". businessinsider.com. 12 September 2014. Retrieved 3 October 2014.
  7. 1 2 Gibson, David K. (28 April 2016). "Can we banish the phantom traffic jam?". BBC.
  8. 1 2 "Driver licensing system for older drivers in New South Wales, Australia". NSW Government. 30 June 2016. Retrieved 16 May 2018.
  9. "BMW Remote Controlled Parking". www.bmwblog.com. 10 October 2010. Retrieved 16 October 2011.
  10. 1 2 Miller, Owen. "Robotic Cars and Their New Crime Paradigms". Retrieved 4 September 2014.
  11. 1 2 Miller, John (19 August 2014). "Self-Driving Car Technology's Benefits, Potential Risks, and Solutions". theenergycollective.com. Archived from the original on 8 May 2015. Retrieved 4 June 2015.
  12. 1 2 Whitwam, Ryan (8 September 2014). "How Google's self-driving cars detect and avoid obstacles". ExtremeTech. Retrieved 4 June 2015.
  13. 1 2 Henn, Steve (31 July 2015). "Remembering When Driverless Elevators Drew Skepticism". NPR. Retrieved 14 August 2016.
  14. 1 2 Nicholas, Negroponte (1 January 2000). Being digital. Vintage Books. ISBN 0679762906. OCLC 68020226.
  15. 1 2 Adhikari, Richard (11 February 2016). "Feds Put AI in the Driver's Seat". Technewsworld. Retrieved 12 February 2016.
  16. 1 2 "New Allstate Survey Shows Americans Think They Are Great Drivers – Habits Tell a Different Story". PR Newswire. 2 August 2011. Retrieved 7 September 2013.
  17. "Citroen type DS19 automatically guided motor car". collection.sciencemuseum.org.uk. Retrieved 7 May 2018.
  18. "'Phantom Auto' will tour city". The Milwaukee Sentinel. Google News Archive. 8 December 1926. Retrieved 23 July 2013.
  19. Tom Vanderblit. "Autonomous Cars Through The Ages". Wired. Retrieved 26 July 2018.
  20. Marc Weber. "Where to? A History of Autonomous Vehicles". Computer History Museum. Retrieved 26 July 2018.
  21. "Carnegie Mellon". Navlab: The Carnegie Mellon University Navigation Laboratory. The Robotics Institute. Retrieved 20 December 2014.
  22. Kanade, Takeo (February 1986). "Autonomous land vehicle project at CMU". CSC '86 Proceedings of the 1986 ACM fourteenth annual conference on Computer science. doi:10.1145/324634.325197.
  23. 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.
  24. 1 2 Schmidhuber, Jürgen (2009). "Prof. Schmidhuber's highlights of robot car history". Retrieved 15 July 2011.
  25. 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.
  26. Council, National Research (2002). "Technology Development for Army Unmanned Ground Vehicles". doi:10.17226/10592.
  27. Ackerman, Evan (25 January 2013). "Video Friday: Bosch and Cars, ROVs and Whales, and Kuka Arms and Chainsaws". IEEE Spectrum. Retrieved 26 February 2013.
  28. "Audi of America / news / Pool / Reaffirmed Mission for Autonomous Audi TTS Pikes Peak". AudiUSA.com. Archived from the original on 10 July 2012. Retrieved 28 April 2012.
  29. "Nissan car drives and parks itself at Ceatec". BBC. 4 October 2012. Retrieved 4 January 2013.
  30. "Toyota sneak previews self-drive car ahead of tech show". BBC. 4 January 2013. Retrieved 4 January 2013.
  31. Rosen, Rebecca. "Google's Self-Driving Cars: 300,000 Miles Logged, Not a Single Accident Under Computer Control". The Atlantic. Retrieved 10 August 2012.
  32. "Vislab, University of Parma, Italy – 8000 miles driverless test begins". Archived from the original on 14 November 2013. Retrieved 27 October 2013.
  33. "VisLab Intercontinental Autonomous Challenge: Inaugural Ceremony – Milan, Italy". Retrieved 27 October 2013.
  34. Selyukh, Alina. "A 24-Year-Old Designed A Self-Driving Minibus; Maker Built It In Weeks". All Tech Considered. NPR. Retrieved 21 July 2016.
  35. Novak, Matt. "The National Automated Highway System That Almost Was". Smithsonian. Retrieved 2018-06-08.
  36. "Back to the Future: Autonomous Driving in 1995 - Robotics Business Review". Robotics Business Review. 2015-04-03. Retrieved 2018-06-08.
  37. "This Is Big: A Robo-Car Just Drove Across the Country". WIRED. Retrieved 2018-06-08.
  38. Ramsey, John (1 June 2015). "Self-driving cars to be tested on Virginia highways". Richmond Times-Dispatch. Retrieved 4 June 2015.
  39. McAleer, Michael (11 July 2017). "Audi's self-driving A8: drivers can watch YouTube or check emails at 60km/h". The Irish Times. Retrieved 11 July 2017.
  40. Hawkins, Andrew J. (7 November 2017). "Waymo is first to put fully self-driving cars on US roads without a safety driver". www.theverge.com. Retrieved 7 November 2017.
  41. "On the Road – Waymo". Waymo. Retrieved 2018-07-27.
  42. Leggett, Theo (22 May 2018). "Who is to blame for 'self-driving car' deaths?" via www.bbc.co.uk.
  43. Cellan-Jones, Rory (12 June 2018). "Insurers warning on 'autonomous' cars" via www.bbc.co.uk.
  44. 1 2 Antsaklis, Panos J.; Passino, Kevin M.; Wang, S.J. (1991). "An Introduction to Autonomous Control Systems" (PDF). IEEE Control Systems. 11 (4): 5–13. doi:10.1109/37.88585.
  45. Wood, S. P.; Chang, J.; Healy, T.; Wood, J. "The potential regulatory challenges of increasingly autonomous motor vehicles". 52nd Santa Clara Law Review. 4 (9): 1423–1502.
  46. Automated vs. Autonomous Vehicles: Is There a Difference?
  47. "Autonomous Emergency Braking - Euro NCAP". www.euroncap.com.
  48. 1 2 3 "The Self-Driving Car Timeline - Predictions from the Top 11 Global Automakers". 29 May 2017.
  49. "self-driving car Definition from PC Magazine Encyclopedia". www.pcmag.com.
  50. "Self-Driving Cars Explained".
  51. matthew.lynberg.ctr@dot.gov (7 September 2017). "Automated Vehicles for Safety". NHTSA.
  52. lynn.greenbauer.ctr@dot.gov (11 September 2017). "A Vision for Safety". NHTSA.
  53. Epstein, Zach (21 July 2016). "Tesla Autopilot Crash Avoidance Model S Autopilot saves man's life". BGR. Retrieved 26 August 2016.
  54. "AdaptIVe system classification and glossary on Automated driving" (PDF). Archived from the original (PDF) on 7 October 2017. Retrieved 11 September 2017.
  55. "AUTOMATED DRIVING LEVELS OF DRIVING AUTOMATION ARE DEFINED IN NEW SAE INTERNATIONAL STANDARD J3016" (PDF). 2017. Archived from the original (PDF) on 20 November 2016.
  56. "U.S. Department of Transportation Releases Policy on Automated Vehicle Development". National Highway Traffic Safety Administration. 30 May 2013. Retrieved 18 December 2013.
  57. SAE International
  58. 1 2 "Wayback Machine" (PDF). 3 September 2017. Archived from the original (PDF) on 3 September 2017.
  59. Zhu, Wentao; Miao, Jun; Hu, Jiangbi; Qing, Laiyun (27 March 2014). "Vehicle detection in driving simulation using extreme learning machine". Neurocomputing. 128: 160–165. doi:10.1016/j.neucom.2013.05.052.
  60. Durrant-Whyte, H.; Bailey, T. (5 June 2006). "Simultaneous localization and mapping". IEEE Robotics & Automation Magazine. 13 (2): 99–110. doi:10.1109/mra.2006.1638022. ISSN 1070-9932.
  61. 1 2 3 Huval, Brody; Wang, Tao; Tandon, Sameep; Kiske, Jeff; Song, Will; Pazhayampallil, Joel. "An Empirical Evaluation of Deep Learning on Highway Driving". arXiv:1504.01716.
  62. Peter Corke, Jorge Lobo, Jorge Dias (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.
  63. "An Open Source Self-Driving Car". Udacity. Retrieved 12 July 2017.
  64. "How Self-Driving Cars Work". 14 December 2017. Retrieved 18 April 2018.
  65. 1 2 Schmidhuber, Jürgen (January 2015). "Deep learning in neural networks: An overview". Neural Networks. 61: 85–117. arXiv:1404.7828. doi:10.1016/j.neunet.2014.09.003. Retrieved 29 November 2017.
  66. Hawkins, Andrew J. (13 May 2018). "MIT built a self-driving car that can navigate unmapped country roads". www.theverge.com. Retrieved 14 May 2018.
  67. 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.
  68. "Trust in Automation – Before and After the Experience of Take-over Scenarios in a Highly Automated Vehicle". Procedia Manufacturing. 3: 3025–3032. 2015-01-01. doi:10.1016/j.promfg.2015.07.847. ISSN 2351-9789.
  69. "Survey Data Suggests Self-Driving Cars Could Be Slow To Gain Consumer Trust". GM Authority. Retrieved 2018-09-03.
  70. "Mcity testing center". University of Michigan. 8 December 2016. Retrieved 13 February 2017.
  71. "Adopted Regulations for Testing of Autonomous Vehicles by Manufacturers". DMV. 18 June 2016. Retrieved 13 February 2017.
  72. "The Pathway to Driverless Cars: A Code of Practice for testing". 19 July 2015. Retrieved 8 April 2017.
  73. "Automobile simulation example". Cyberbotics. 18 June 2018. Retrieved 18 June 2018.
  74. Krok, Andrew. "Apple increases self-driving test fleet from 3 to 27". Roadshow. Retrieved 26 January 2018.
  75. Hall, Zac. "Apple ramping self-driving car testing, more CA permits than Tesla and Uber". Electrek. Retrieved 21 March 2018.
  76. 1 2 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.
  77. "First self-driving race car completes 1.8 kilometre track". euronews. 2018-07-16. Retrieved 2018-07-17.
  78. Dillet, Romain (18 August 2016). "Uber acquires Otto to lead Uber's self-driving car effort". TechCrunch. Retrieved 26 October 2017.
  79. "Embark – Self-Driving Semi Trucks". www.embarktrucks.com.
  80. Etherington, Darrell (18 July 2017). "Self-driving truck startup Embark raises $15M, partners with Peterbilt". TechCrunch. Retrieved 26 October 2017.
  81. "Waymo working on self-driving trucks". Reuters. 1 June 2017. Retrieved 4 December 2017.
  82. "Truck completes fully automated route without driver in cab". www.ccjdigital.com. Retrieved 2018-06-01.
  83. "Lockheed Martin Wins Contract to Develop Autonomous Operation of Tactical Vehicles | Unmanned Systems Technology". Unmanned Systems Technology. 2012-10-25. Retrieved 2018-06-08.
  84. "Driverless Convoy Technology May Be Fielded Soon". Military.com. 2017-03-30. Retrieved 2018-06-08.
  85. "Driverless cars take to the road". E.U.CORDIS Research Program CitynetMobil. Retrieved 27 October 2013.
  86. "Snyder OKs self-driving vehicles on Michigan's roads". Detroit News. 27 December 2013. Retrieved 1 January 2014.
  87. "BBC News - UK to allow driverless cars on public roads in January". BBC News. Retrieved 4 March 2015.
  88. Burn-Callander, Rebecca (11 February 2015). "This is the Lutz pod, the UK's first driverless car". Daily Telegraph. Retrieved 11 February 2015.
  89. "Autonomous vehicle: the automated driving car of the future". PSA PEUGEOT CITROËN. Archived from the original on 26 September 2015. Retrieved 2 October 2015.
  90. Valeo Autonomous iAV Car Driving System CES 2015. YouTube. 5 January 2015.
  91. Hayward, Michael (26 January 2017). "First New Zealand autonomous vehicle demonstration kicks off at Christchurch Airport". www.stuff.co.nz. Retrieved 23 March 2017.
  92. "Self-driving car to take on Tauranga traffic this week". Bay of Plenty Times. 15 November 2016. Retrieved 23 March 2017.
  93. "NZ's first self-drive vehicle demonstration begins". www.stuff.co.nz. 17 November 2016. Retrieved 23 March 2017.
  94. Frykberg, Eric (28 June 2016). "Driverless buses: 'It is going to be big'". Radio New Zealand. Retrieved 23 March 2017.
  95. 1 2 Cowen, Tyler (28 May 2011). "Can I See Your License, Registration and C.P.U.?". The New York Times.
  96. Ramsey, Mike (3 May 2015). "Self-Driving Cars Could Cut Down on Accidents, Study Says". The Wall Street Journal. Retrieved 29 October 2016.
  97. Ramsey, Jonathon (8 March 2017). "The Way We Talk About Autonomy Is a Lie, and That's Dangerous". www.thedrive.com. Retrieved 19 March 2018.
  98. 1 2 3 Light, Donald (8 May 2012). A Scenario" The End of Auto Insurance (Technical report). Celent.
  99. 1 2 Mui, Chunka (19 December 2013). "Will The Google Car Force A Choice Between Lives And Jobs?". Forbes. Retrieved 19 December 2013.
  100. Gosman, Tim (24 July 2016). "Along for the ride: How driverless cars can become commonplace". Brand Union. Retrieved 29 October 2016.
  101. Dudley, David (January 2015). "The Driverless Car Is (Almost) Here; The self-driving car — a godsend for older Americans — is now on the horizon". AARP The Magazine. AARP. Retrieved 30 November 2015.
  102. Stenquist, Paul (7 November 2014). "In Self-Driving Cars, a Potential Lifeline for the Disable". The New York Times. Retrieved 29 October 2016.
  103. Curry, David (22 April 2016). "Will elderly and disabled gain most from autonomous cars?". ReadWrite. Retrieved 29 October 2016.
  104. 1 2 3 4 5 6 James M. Anderson; Nidhi Kalra; Karlyn D. Stanley; Paul Sorensen; Constantine Samaras; Oluwatobi A. Oluwatola (2016). "Autonomous Vehicle Technology: A Guide for Policymakers". RAND Corporation. Retrieved 30 October 2016.
  105. Simonite, Tom (1 November 2014). "Self-Driving Motorhome: RV Of the Future?". Retrieved 1 November 2015.
  106. "Get ready for automated cars". Houston Chronicle. 11 September 2012. Retrieved 5 December 2012.
  107. Simonite, Tom (25 October 2013). "Data Shows Google's Robot Cars Are Smoother, Safer Drivers Than You or I". MIT Technology Review. Retrieved 15 November 2013.
  108. O'Toole, Randal (18 January 2010). Gridlock: Why We're Stuck in Traffic and What To Do About It. Cato Institute. p. 192. ISBN 978-1-935308-24-9.
  109. "Future Car Focus: Robot Cars". MSN Autos. 2013. Retrieved 27 January 2013.
  110. Ackerman, Evan (4 September 2012). "Study: Intelligent Cars Could Boost Highway Capacity by 273%". Institute of Electrical and Electronics Engineers (IEEE). IEEE Spectrum. Retrieved 29 October 2016.
  111. "Autonomous Intersection Management – FCFS policy with 6 lanes in all directions". YouTube. 12 June 2009. Retrieved 28 April 2012.
  112. Pyper, Julia (15 September 2015). "Self-Driving Cars Could Cut Greenhouse Gas Pollution". Scientific American. Retrieved 29 October 2016.
  113. Wang, Ucilia (17 August 2015). "ARE SELF-DRIVING VEHICLES GOOD FOR THE ENVIRONMENT?". Ensia. Retrieved 28 October 2016.
  114. "Spaced Out parking report". www.racfoundation.org. Retrieved 2018-09-03.
  115. ""Cars are parked 95% of the time". Let's check!". www.reinventingparking.org. Retrieved 2018-09-03.
  116. Chester, Mikhail; Fraser, Andrew; Matute, Juan; Flower, Carolyn; Pendyala, Ram (2015-10-02). "Parking Infrastructure: A Constraint on or Opportunity for Urban Redevelopment? A Study of Los Angeles County Parking Supply and Growth". Journal of the American Planning Association. 81 (4): 268–286. doi:10.1080/01944363.2015.1092879. ISSN 0194-4363.
  117. "See Just How Much Of A City's Land Is Used For Parking Spaces". Fast Company. 2017-07-20. Retrieved 2018-09-03.
  118. Woodyard, Chris (5 March 2015). "McKinsey study: Self-driving cars yield big benefits". USA Today. Retrieved 4 June 2015.
  119. "Self-driving cars: The next revolution" (PDF). kpmg.com. 5 September 2013. Retrieved 6 September 2013.
  120. Wiseman, Yair (February 2018). "In an Era of Autonomous Vehicles, Rails are Obsolete" (PDF). International Journal of Control and Automation. SERSC Australia. 11 (2): 151–160 via semanticscholar.
  121. Nichols, Greg (13 February 2016). "NHTSA chief takes conservative view on autonomous vehicles: "If you had perfect, connected autonomous vehicles on the road tomorrow, it would still take 20 to 30 years to turn over the fleet."". ZDNet. Retrieved 17 February 2016.
  122. "Will Regulators Allow Self-Driving Cars In A Few Years?". Forbes. 24 September 2013. Retrieved 5 January 2014.
  123. "Reliance on autopilot is now the biggest threat to flight safety, study says". 18 November 2013. Retrieved 19 November 2013.
  124. Patrick Lin (8 October 2013). "The Ethics of Autonomous Cars". The Atlantic.
  125. Tim Worstall (18 June 2014). "When Should Your Driverless Car From Google Be Allowed To Kill You?". Forbes.
  126. Alexander Skulmowski; Andreas Bunge; Kai Kaspar; Gordon Pipa (16 December 2014). "Forced-choice decision-making in modified trolley dilemma situations: a virtual reality and eye tracking study". Front. Behav. Neurosci.
  127. 1 2 3 Gomes, Lee (28 August 2014). "Hidden Obstacles for Google's Self-Driving Cars". MIT Technology Review. Retrieved 22 January 2015.
  128. SingularityU The Netherlands (1 September 2016), Carlo van de Weijer on real intelligence, retrieved 21 November 2016
  129. "Hackers find ways to hijack car computers and take control". 3 September 2013. Retrieved 7 September 2013.
  130. Philip E. Ross (11 April 2014). "A Cloud-Connected Car Is a Hackable Car, Worries Microsoft". IEEE Spectrum. Retrieved 23 April 2014.
  131. Moore-Colyer, Roland (12 February 2015). "Driverless cars face cyber security, skills and safety challenges". www.v3.co.uk. Retrieved 24 April 2015.
  132. 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.
  133. 1 2 Ron Tussy (29 April 2016). "Challenges facing Autonomous Vehicle Development". AutoSens. Retrieved 5 May 2016.
  134. Zhou, Naaman (1 July 2017). "Volvo admits its self-driving cars are confused by kangaroos". The Guardian. Retrieved 1 July 2017.
  135. Boyd, Jhon (8 December 2016). "Mitsubishi Electric joins race to make maps for self-drive cars". www.atimes.com. Retrieved 12 December 2016.
  136. Denaro, Bob (1 April 2016). "ITS International" (PDF). Civil Maps – Automated Vehicle: Myth vs. Reality. ITS International. Retrieved 22 June 2016.
  137. Glenn Garvin (21 March 2014). "Automakers say self-driving cars are on the horizon". Miami Herald. Retrieved 22 March 2014.
  138. 1 2 3 Badger, Emily (15 January 2015). "5 confounding questions that hold the key to the future of driverless cars". Wonk Blog. The Washington Post. Retrieved 22 January 2015.
  139. 1 2 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.
  140. Article on The Next Web by David Silver
  141. "'Year in review' by DIY Robocars creator Chris Anderson".
  142. Article on IEEE
  143. "udacity/self-driving-car". GitHub.
  144. "Berkeley Deep Drive". bdd-data.berkeley.edu.
  145. "Glossary - Level Five Jobs". levelfivejobs.com.
  146. "Mass unemployment fears over Google artificial intelligence plans". London. 29 December 2013. Retrieved 29 December 2013.
  147. Dvorak, John C. (30 September 2015). "There's a Bumpy Road Ahead for Driverless Cars". PCMag. Retrieved 30 September 2015.
  148. Benedikt Frey, Carl; Osborne, Michael A. (1 January 2017). "The future of employment: How susceptible are jobs to computerisation?". Technological Forecasting and Social Change. 114: 254–280. doi:10.1016/j.techfore.2016.08.019. ISSN 0040-1625.
  149. Neumann, Peter G. (September 2016). "Risks of Automation: A Cautionary Total-system Perspective of Our Cyberfuture". Commun. ACM. 59 (10): 26–30. doi:10.1145/2988445. ISSN 0001-0782.
  150. Acharya, Anish (16 December 2014). "Are We Ready for Driver-less Vehicles? Security vs. Privacy – A Social Perspective". arXiv:1412.5207.
  151. Patrick Lin (22 January 2014). "What If Your Autonomous Car Keeps Routing You Past Krispy Kreme?". The Atlantic. Retrieved 22 January 2014.
  152. Mark Harris (16 July 2014). "FBI warns driverless cars could be used as 'lethal weapons'". theGuardian.com.
  153. Smith, Noah (5 November 2015). "The downside of driverless cars". The Sydney Morning Herald. Retrieved 30 October 2016.
  154. 1 2 Ufberg, Max (15 October 2015). "Whoops: The Self-Driving Tesla May Make Us Love Urban Sprawl Again". Wired. Retrieved 28 October 2016.
  155. Sparrow, Robert; Howard, Mark (2017). "When human beings are like drunk robots: Driverless vehicles, ethics, and the future of transport". Transportation Research Part C: Emerging Technologies. 80: 206–215. doi:10.1016/j.trc.2017.04.014.
  156. Natasha Merat and A. Hamish Jamson. "HOW DO DRIVERS BEHAVE IN A HIGHLY AUTOMATED CAR? " Institute for Transport Studies University of Leeds. Quote: "Drivers' response to all critical events was found to be much later in the automated driving condition, compared to manual driving."
  157. Spangler, Todd. "Self-driving cars programmed to decide who dies in a crash". USA Today. Detroit Free Press. Retrieved 29 November 2017.
  158. Goodall, Noah (June 2016). "Can you program ethics into a self-driving car?". IEEE Spectrum. 53: 25–28. doi:10.1109/MSPEC.2016.7473149. Retrieved 29 November 2017.
  159. "Mercedes-Benz S-Class, W 220 series (1998 to 2005)".
  160. "Innovation as a tradition". 27 November 2014. Archived from the original on 29 December 2014.
  161. "Technical highlights of the CL-Class and its predecessor series".
  162. Clarkson, Jeremy (4 July 2009), Radar Guided Cruise Control, retrieved 11 July 2017
  163. "Welcome to the Mercedes-Benz international website". Mercedes-Benz. Retrieved 11 July 2017.
  164. Ward, James (16 June 2014). "Mercedes-Benz E400: Distronic Plus with Steering Assist demonstrated". www.caradvice.com.au. Retrieved 11 July 2017.
  165. Mercedes Blog-Team (18 March 2015). "Daimler-Blog - Einfach Technik: So funktioniert DISTRONIC PLUS". Daimler-Blog (in German). Retrieved 11 July 2017.
  166. blogsadmin (28 September 2015). "How to Use DISTRONIC PLUS Cruise Control in 2016 Mercedes-Benz". www.mbscottsdale.com. Retrieved 11 July 2017.
  167. blogsadmin (28 February 2016). "How To Use Mercedes-Benz DISTRONIC PLUS". www.loebermotors.com. Retrieved 11 July 2017.
  168. Daimler AG (2016). "Mercedes-Benz Trucks: Safety: New assistance systems: Active Brake Assist 4 emergency: braking assistant featuring pedestrian recognition and: Sideguard Assist". media.daimler.com. Retrieved 11 July 2017.
  169. 1 2 "Mercedes S-Klasse: Panne bei Crash-Test". Stern (in German). 16 November 2005. Retrieved 11 July 2017.
  170. "Pedestrian protection: Not just a question of compliance with crash-test regulations for Mercedes-Benz". media.daimler.com. Retrieved 11 July 2017.
  171. Philips, T. (10 June 2008). "Mercedes-Benz Accident Study Shows 20 Percent Of Rear End Collisions Can Be Avoided With DISTRONIC PLUS and Brake Assist PLUS". www.emercedesbenz.com. Archived from the original on 24 September 2015. Retrieved 11 July 2017.
  172. Humphries, Matthew (12 December 2013). "Michael Schumacher tries to crash a Mercedes C-Class. Fails". Geek.com. Retrieved 11 July 2017.
  173. Nelson, Gabe (14 October 2015). "Tesla beams down 'autopilot' mode to Model S". Automotive News. Retrieved 19 October 2015.
  174. Zhang, Benjamin (10 January 2016). "ELON MUSK: In 2 years your Tesla will be able to drive from New York to LA and find you". Automotive News. Retrieved 12 January 2016.
  175. Charlton, Alistair (13 June 2016). "Tesla Autopilot is 'trying to kill me', says Volvo R&D chief". International Business Times. Retrieved 1 July 2016.
  176. Golson, Jordan (27 April 2016). "Volvo autonomous car engineer calls Tesla's Autopilot a 'wannabe'". The Verge. Retrieved 1 July 2016.
  177. Korosec, Kirsten (15 December 2015). "Elon Musk Says Tesla Vehicles Will Drive Themselves in Two Years". Fortune. Retrieved 1 July 2016.
  178. 1 2 Abuelsamid, Sam (1 July 2016). "Tesla Autopilot Fatality Shows Why Lidar And V2V Will Be Necessary For Autonomous Cars". Forbes. Retrieved 1 July 2016.
  179. 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.
  180. "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.
  181. 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.
  182. 1 2 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.
  183. 1 2 Vlasic, Bill; Boudette, Neal E. (30 June 2016). "Self-Driving Tesla Involved in Fatal Crash". The New York Times. Retrieved 1 July 2016.
  184. Office of Defects Investigations, NHTSA (28 June 2016). "ODI Resume - Investigation: PE 16-007" (PDF). National Highway Traffic Safety Administration (NHTSA). Retrieved 2 July 2016.
  185. Shepardson, David (12 July 2016). "NHTSA seeks answers on fatal Tesla Autopilot crash". Automotive News. Retrieved 13 July 2016.
  186. "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.
  187. Abuelsamid, Sam. "Adding Some Statistical Perspective To Tesla Autopilot Safety Claims".
  188. Administration, National Highway Traffic Safety. "FARS Encyclopedia".
  189. Alan Levin and Jeff Plungis (8 July 2016). "NTSB to scrutinize driver automation with probe of Tesla crash". Automotive News. Retrieved 11 July 2016.
  190. "Fatal Tesla Autopilot accident investigation ends with no recall ordered". The Verge. 19 January 2016. Retrieved 19 January 2017.
  191. "All Tesla Cars Being Produced Now Have Full Self-Driving Hardware".
  192. "Autopilot: Full Self-Driving Hardware on All Cars". Tesla Motors. Retrieved 21 October 2016.
  193. Guess, Megan (20 October 2016). "Teslas will now be sold with enhanced hardware suite for full autonomy". Ars Technica. Retrieved 20 October 2016.
  194. Self-driving Car Logs More Miles, googleblog
  195. A First Drive. YouTube. 27 May 2014.
  196. "Google Self-Driving Car Project, Monthly Report, March 2016" (PDF). Google. Retrieved 23 March 2016.
  197. "Waymo".
  198. Davies, Alex. "Meet the Blind Man Who Convinced Google Its Self-Driving Car Is Finally Ready".
  199. 1 2 "For the first time, Google's self-driving car takes some blame for a crash". Washington Post. 29 February 2016.
  200. "Google founder defends accident records of self-driving cars". Associated Press. Los Angeles Times. 3 June 2015. Retrieved 1 July 2016.
  201. VISHAL MATHUR (17 July 2015). "Google Autonomous Car Experiences Another Crash". Government Technology. Retrieved 18 July 2015.
  202. "Google's Self-Driving Car Caused Its First Crash". Wired. February 2016.
  203. "Passenger bus teaches Google robot car a lesson". Los Angeles Times. 29 February 2016.
  204. "Uber to Suspend Autonomous Tests After Arizona Accident". 25 March 2017 via www.bloomberg.com.
  205. "Uber's Self-Driving Cars Hit 2 Million Miles As Program Regains Momentum". 22 December 2017 via www.forbes.com.
  206. Bensinger, Greg; Higgins, Tim (22 March 2018). "Video Shows Moments Before Uber Robot Car Rammed Into Pedestrian". Wall Street Journal. Retrieved 25 March 2018.
  207. Lubben, Alex (19 March 2018). "Self-driving Uber killed a pedestrian as human safety driver watched". Vice News. Retrieved 19 March 2018.
  208. "Human Driver Could Have Avoided Fatal Uber Crash, Experts Say". 22 March 2018 via www.bloomberg.com.
  209. The Associated Press; abc15.com staff (27 March 2018). "Governor Ducey suspends Uber from automated vehicle testing". KNXV-TV. Retrieved 27 March 2018.
  210. 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.
  211. "Preliminary Report Released for Crash Involving Pedestrian, Uber Technologies, Inc., Test Vehicle" (PDF). 24 May 2018.
  212. Gibbs, Samuel (9 November 2017). "Self-driving bus involved in crash less than two hours after Las Vegas launch". The Guardian. Retrieved 9 November 2017.
  213. Lee, Timothy (31 January 2015). "Driverless cars will mean the end of mass car ownership". Vox. Retrieved 31 January 2015.
  214. O'Toole, Randal, Policy Implications of Autonomous Vehicles (18 September 2014). Cato Institute Policy Analysis No. 758. Available at SSRN: https://ssrn.com/abstract=2549392
  215. Pinto, Cyrus (2012). "How autonomous vehicle policy in California and Nevada addresses technological and non-technological liabilities". Intersect: The Stanford Journal of Science, Technology and Society. 5.
  216. Badger, Emily (15 January 2015). "5 confounding questions that hold the key to the future of driverless cars". Washington Post. ISSN 0190-8286. Retrieved 27 November 2017.
  217. Guerra, Erick (1 June 2016). "Planning for Cars That Drive Themselves: Metropolitan Planning Organizations, Regional Transportation Plans, and Autonomous Vehicles". Journal of Planning Education and Research. 36 (2): 210–224. doi:10.1177/0739456X15613591. ISSN 0739-456X.
  218. Litman, Todd. "Autonomous vehicle implementation predictions." Victoria Transport Policy Institute 28 (2014).
  219. Humphreys, Pat (19 August 2016). "Retail Revolution". Transport and Travel. Retrieved 24 August 2016.
  220. "GAR - 1968 Vienna Convention". 1 December 2017. Archived from the original on 1 December 2017.
  221. Bryant Walker Smith (1 November 2012). "Automated Vehicles Are Probably Legal in The United States". The Center for Internet and Society (CIS) at Stanford Law School. Retrieved 31 January 2013.
  222. Canis, Bill (19 September 2017). Issues in Autonomous Vehicle Deployment (PDF). Washington, DC: Congressional Research Service. Retrieved 16 October 2017.
  223. Bryant Walker Smith. "Automated Driving: Legislative and Regulatory Action". The Center for Internet and Society (CIS) at Stanford Law School. Retrieved 31 January 2013.
  224. Kang, Cecilia (19 September 2016). "Self-Driving Cars Gain Powerful Ally: The Government". The New York Times. ISSN 0362-4331. Retrieved 28 September 2016.
  225. "Nevada enacts law authorizing autonomous (driverless) vehicles". Green Car Congress. 25 June 2011. Retrieved 25 June 2011.
  226. Alex Knapp (22 June 2011). "Nevada Passes Law Authorizing Driverless Cars". Forbes. Archived from the original on 28 June 2011. Retrieved 25 June 2011.
  227. Christine Dobby (24 June 2011). "Nevada state law paves the way for driverless cars". Financial Post. Retrieved 25 June 2011.
  228. 1 2 John Markoff (10 May 2011). "Google Lobbies Nevada To Allow Self-Driving Cars". The New York Times. Retrieved 11 May 2011.
  229. "Bill AB511 Nevada Legislature" (PDF). Nevada Legislature. Retrieved 25 June 2011.
  230. Tim Healey (24 June 2011). "Nevada Passes Law Allowing Self-Driving Cars". Motor Trend. Retrieved 25 June 2011.
  231. Cy Ryan (7 May 2012). "Nevada issues Google first license for self-driving car". Las Vegas Sun. Retrieved 12 May 2012.
  232. Ana Valdes (July 5, 2012). Florida Embraces Self-Driving Cars Archived 12 April 2013 at the Wayback Machine. Retrieved March 31, 2013.
  233. John Oram (9-27-2012). Governor Brown Signs California Driverless Car Law at Google HQ Retrieved March 31, 2013.
  234. "New Law Allows Driverless Cars On Michigan Roads". CBS Detroit. 28 December 2013. Retrieved 2 November 2014.
  235. CDA Press (July 8, 2014). Aye, robot: Cd'A City Council approves robot ordinance
  236. "Bill Text – AB-2866 Autonomous vehicles". leginfo.legislature.ca.gov. Retrieved 21 April 2016.
  237. "Federal Automated Vehicles Policy". Department of Transportation. Retrieved 20 October 2016.
  238. "Public Workshop Autonomous Vehicles" (PDF). 19 October 2016. Retrieved 20 September 2017.
  239. "Uber blames humans for self-driving car traffic offenses as California orders a halt". The Guardian. Retrieved 15 December 2016.
  240. 1 2 "UK to road test driverless cars". BBC. 16 July 2013. Retrieved 17 July 2013.
  241. "Des véhicules autonomes sur route ouverte à Bordeaux en octobre 2015". usine-digitale.fr.
  242. Greenblatt, Nathan. "Self-Driving Cars Will Be Ready Before Our Laws Are". IEEE Spectrum.
  243. "Swisscom reeals the first driverless car on Swiss roads". Swisscom. 12 May 2015. Archived from the original on 28 September 2015. Retrieved 1 August 2015.
  244. "Zalazone home page". zalazone.hu. Retrieved 24 January 2018.
  245. "Hungary as one of the European hubs for automated and connected driving" (PDF). Zala Zone. Retrieved 23 January 2018.
  246. Maierbrugger, Arno (1 August 2016). "Singapore to launch self-driving taxis next year | Investvine". Retrieved 9 August 2016.
  247. Slone, Sean. "State Laws on Autonomous Vehicles". Retrieved 11 December 2016.
  248. "Ten ways autonomous driving could redefine the automotive world". Retrieved 11 December 2016.
  249. "Marketplace of change: Automobile insurance in the era of autonomous vehicles".
  250. "Frequency of Target Crashes for IntelliDrive Safety Systems" (PDF).
  251. "No lights, no signs, no accidents – future intersections for driverless cars (video)". Reuters.com. 22 March 2012. Retrieved 28 April 2012.
  252. "Crossroads: Time-Sensitive Autonomous Intersection Management Technique". Institute of Electrical and Electronics Engineers Inc. 18 June 2017.
  253. "Mobility 2020". Nordic Communications Corporation. 8 January 2016.
  254. "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.
  255. Yvkoff, Liane (27 April 2012). "Many car buyers show interest in autonomous car tech". CNET. Retrieved 30 June 2013.
  256. "Große Akzeptanz für selbstfahrende Autos in Deutschland". motorvision.de. 9 October 2012. Archived from the original on 15 May 2016. Retrieved 6 September 2013.
  257. "Autonomous Cars Found Trustworthy in Global Study". autosphere.ca. 22 May 2013. Retrieved 6 September 2013.
  258. "Autonomous cars: Bring 'em on, drivers say in Insurance.com survey". Insurance.com. 28 July 2014. Retrieved 29 July 2014.
  259. "Autonomous Vehicle Predictions: Auto Experts Offer Insights on the Future of Self-Driving Cars". PartCatalog.com. 16 March 2015. Retrieved 18 March 2015.
  260. 1 2 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. doi:10.1016/j.trf.2015.04.014.
  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. 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, Aaaron; Anderson, Monica. "Automation in Everyday Life".
  264. "Preparing a nation for autonomous vehicles: Opportunities, barriers and policy recommendations". Transportation Research Part A: Policy and Practice. 77.
  265. 1 2 "Responsibility for Crashes of Autonomous Vehicles: An Ethical Analysis". Sci Eng Ethics. 21.
  266. "The Coming Collision Between Autonomous Vehicles and the Liability System". Santa Clara Law Review. 52.
  267. "The Trolley Problem". The Yale Law Journal. 94 (6).
  268. 1 2 Meyer, G.; Beiker, S (2014). Road vehicle automation. Springer International Publishing. pp. 93–102.
  269. Lafrance, Adrienne (21 March 2016). "How Self-Driving Cars Will Threaten Privacy". Retrieved 4 November 2016.
  270. 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).
  271. Greenhouse, Steven. "Autonomous vehicles could cost America 5 million jobs. What should we do about it?". latimes.com. Retrieved 7 December 2016.
  272. Bertoncello, M.; Wee, D. "Ten ways autonomous driving could redefine the automotive world". McKinsey & Company. Retrieved 7 December 2016.
  273. "Employment by detailed occupation". www.bls.gov. United States Department of Labor. Retrieved 7 December 2016.
  274. Fagnant, D. J.; Kockelman, K. (2015). "Preparing a nation for autonomous vehicles: Opportunities, barriers, and policy recommendations". Transportation Research Part A: Policy and Practice. 77: 167–181. doi:10.1016/j.tra.2015.04.003.
  275. Lambert, Fred (21 December 2015). "Tesla CEO Elon Musk drops his prediction of full autonomous driving from 3 years to just 2". electrek.co. Retrieved 23 May 2018.
  276. Lambert, Fred (8 December 2017). "Elon Musk updates timeline for a self-driving car, but how does Tesla play into it?". electrek.co. Retrieved 23 May 2018.
  277. Todorova, Lidia (20 June 2016). "Autonomous cars – when will they take over?". automobilesreview.com. Retrieved 20 April 2018.
  278. Britt, Ryan. "The 5 Best (and Worst) Autonomous Cars in All of Sci-Fi".
  279. "3D-Drucker: Warum die Industrie wieder einen Trend verschläft" (in German). t3n News. Retrieved 22 January 2017.
  280. "'Bull' episode 10 preview: The self-driving car case and Ginny Bretton". 3 January 2017.
  281. N.V., Mobileye. "Mobileye Announces Expiration of HSR Waiting Period". www.prnewswire.com. Retrieved 12 July 2017.

Further reading

  • O'Toole, Randal (18 January 2010). Gridlock: Why We're Stuck in Traffic and What To Do About It. Cato Institute. ISBN 978-1-935308-24-9.
  • Macdonald, Iain David Graham (2011). A Simulated Autonomous Car (PDF) (thesis). The University of Edinburgh. Retrieved 17 April 2013.
  • Knight, Will (22 October 2013). "The Future of Self-driving Cars". MIT Technology Review. Retrieved 22 July 2016.
  • Glancy, Dorothy (2016). A Look at the Legal Environment for Driverless Vehicles (PDF) (Report). National Cooperative Highway Research Program Legal Research Digest. 69. Washington, DC: Transportation Research Board. ISBN 978-0-309-37501-6. Retrieved 22 July 2016.
  • Newbold, Richard (17 June 2015). "The driving forces behind what would be the next revolution in the haulage sector". The Loadstar. Retrieved 22 July 2016.
  • Bergen, Mark (27 October 2015). "Meet the Companies Building Self-Driving Cars for Google and Tesla (And Maybe Apple)". re/code.
  • John A. Volpe National Transportation Systems Center (March 2016). "Review of Federal Motor Vehicle Safety Standards (FMVSS) for Automated Vehicles: Identifying potential barriers and challenges for the certification of automated vehicles using existing FMVSS" (PDF). National Transportation Library. U.S. Department of Transportation.
  • Slone, Sean (August 2016). "State Laws on Autonomous Vehicles" (PDF). Capitol Research - Transportation Policy. Council of State Governments. Retrieved 28 September 2016.
  • Steve Henn (31 July 2015). "Remembering When Driverless Elevators Drew Skepticism".
  • James M. Anderson et. al. (2016). "Autonomous Vehicle Technology: A Guide for Policymakers" (PDF). RAND Corporation.


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