Impact of self-driving cars
This article is written like a personal reflection, personal essay, or argumentative essay that states a Wikipedia editor's personal feelings or presents an original argument about a topic. (July 2024) |
Part of a series on |
Self-driving cars & self-driving vehicles |
---|
Enablers |
Topics |
Related topics |
Part of a series on |
Automation |
---|
Automation in general |
Robotics and robots |
Impact of automation |
Trade shows and awards |
The impact of self-driving cars is anticipated to be wide-ranging in many areas of daily life. Self-driving cars (also known as autonomous vehicles or AVs) have been the subject of significant research on their environmental, practical, and lifestyle consequences and their impacts remain debated.[1][2]
Some experts claim substantial reduction in traffic collisions and the resulting severe injuries or deaths. United States government estimates suggest 94% of traffic collisions have humans as the final critical element in crash,[3] with one study estimating that converting 90% of cars on US roads to AVs would save 25,000 lives per year.[4] Other experts claim that the number of human error collisions is overestimated and that self-driving cars may actually increase collisions.[1][5]
Self-driving cars are speculated to worsen air pollution, noise pollution, and sedentary lifestyles,[4] to increase productivity and housing affordability, reclaim land used for parking,[6] cause greater energy use, traffic congestion and sprawl.[6] The impact of self-driving cars on absolute levels of individual car use is not yet clear; other forms of self-driving vehicles, such as self-driving buses, may actually decrease car use and congestion.[7]
AVs are anticipated to affect the healthcare, insurance, travel, and logistics fields. Auto insurance costs are expected to decrease, and the burden of cars on the healthcare system to reduced. Self-driving cars are predicted to cause significant job losses in the transportation industry.
Automobile industry
[edit]A McKinsey report has forecast that AVs could reach $300 to $400 billion in revenue by 2035.[8] The industry has attracted multiple car manufacturers, most notably General Motor's subsidiary Cruise[9] and Tesla.[10] Ford and Volkswagen invested billions in Argo AI but withdraw from the market by 2022, instead focusing on semi-autonomous driving (L2+, L3 under SAE classification).[11] Notably, non-car manufacturers have also investigated and speculated about self-driving cars, including Google subsidiary Waymo, among others.[10]
To help reduce the possibility of safety issues, some companies have begun to open-source parts of their driverless systems. Udacity for instance is developing an open-source software stack,[12] and some companies are having similar approaches.[13][14]
Public Health
[edit]Car crash reduction
[edit]Proponents
[edit]Estimates of numbers of crashes prevented by AVs varies widely. An NHSTA report in 2018 found that 94% of crashes had humans as the final causal step in a chain of events.[3] One study claimed that if 90% of cars in the US became self-driving, an estimated 25,000 lives would be saved annually. Lives saved by averting automobile crashes in the US has been valued at more than $200 billion annually.[4] Other studies claim self-driving car would have the potential to save 10 million lives worldwide, per decade.[4][15] Opponents argue that the number of human driven crashes is taken out of context and estimates of lives saved may not be accurate.[5]
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 would be substantially reduced.[16][17][18][19][20] Some experts advocate the idea of a "smart city" and claim data sharing infrastructure with AVs could further reduce crashes.[21]
Opponents
[edit]Lack of data remains a key challenge in comparisons of fatalities per million miles between AVs and humans.[22][23] One limited early study claimed a rate of 9.1 crashes per million miles by AVs, nearly double the rate from human driving, though crashes were less serious than humans.[22] Arstechnica calculated 102 crashes over 6 million miles, but claimed crashes were low-impact and still safer than human driving.[23] Waymo claimed only 3 crashes with injuries over 7.1 million miles, nearly twice as safe as human drivers.[24] As more cities give permission for AVs to operate, incidents and complaints have increased.[1]
Opponents of AVs have argued that current self-driving technology fails to take into account "edge cases"[10] which may make the technology more dangerous than human driving.[1][5] In 2017, driving experts were contacted by "TheDrive.com", operated byTime magazine, to rank autopilot systems.[25] None ranked any of the autopilot systems at the time as safer than human driving.[25] Factors that reduce safety may include unexpected interactions between humans and vehicle systems; complications due to technical limitations of technologies; the effect of the bugs that inevitably occur in complex interdependent software systems; sensor or data shortcomings; and compromise by malicious actors. Security problems include what an autonomous car might do if summoned to pick up the owner but another person attempts entry, what happens if someone tries to break into the car, and what happens if someone attacks the occupants, for example by exchanging gunfire.[26]
One ethicist argued that autonomous vehicles requiring any human supervision would create complacency and would be immoral to deploy.[27] Specifically, they argued humans are unlikely to effectively take over during a sudden software failure if an impending decision is required immediately.[27] 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.[28]
Other public health impacts
[edit]According to a 2020 Annual Review of Public Health review of the literature, self-driving cars "could increase some health risks (such as air pollution, noise, and sedentarism); however, if properly regulated, AVs will likely reduce morbidity and mortality from motor vehicle crashes and may help reshape cities to promote healthy urban environments."[4]
An unexpected disadvantage of the widespread acceptance of autonomous vehicles would be a reduction in the supply of organs for donation.[29] In the US, for example, 13% of the organ donation supply comes from car crash victims.[4]
Welfare
[edit]According to a 2020 study, self-driving cars will increase productivity, and housing affordability, as well as reclaim land used for parking.[6] However, self-driving cars will cause greater energy use, traffic congestion and sprawl.[6] Automated cars could reduce labor costs;[30][31] relieve travelers from driving and navigation chores, thereby replacing behind-the-wheel commuting hours with more time for leisure or work;[17][20] and also would lift constraints on occupant ability to drive, distracted and texting while driving, intoxicated, prone to seizures, or otherwise impaired.[32][33]
For the young, the elderly, people with disabilities, and low-income citizens, automated cars could provide enhanced mobility.[34][35] 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.[36]
The elderly and persons with disabilities (such as persons who are hearing-impaired, vision-impaired, mobility-impaired, or cognitively-impaired) are potential beneficiaries of adoption of autonomous vehicles; however, the extent to which such populations gain greater mobility from the adoption of AV technology depends on the specific designs and regulations adopted.[37][38]
Children and teens, who are not able to drive a vehicle themselves in case of student transport, would also benefit of the introduction of autonomous cars.[39] Daycares and schools are able to come up with automated pick-up and drop-off systems by car in addition to walking, cycling and busing, 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.[40] Self-driving cars would also exasperate existing mobility inequalities driven by the interests of car companies and technology companies while taking investment away from more equitable and sustainable mobility initiatives such as public transportation.[41]
Urban planning
[edit]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, policymakers face a number of unresolved questions about their effects.[42]
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.[42] 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.[43][44]
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.[45] 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.[46] 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.[47] However, due to the uncertainty of the future of automated vehicles, policymakers may want to plan effectively by implementing infrastructure improvements that can be beneficial to both human drivers and automated vehicles.[48] 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.[49]
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 2019[update] the US Department of Transportation 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 in the US 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.[50]
Traffic
[edit]Additional advantages could include higher speed limits;[51] smoother rides;[52] and increased roadway capacity; and minimized traffic congestion, due to decreased need for safety gaps and higher speeds.[53][54] Currently, maximum controlled-access highway throughput or capacity according to the US 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 545% 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. Human drivers at highway speeds keep between 40 and 50 m (130 and 160 ft) away from the vehicle 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.[55] The ability for authorities to manage traffic flow would increase, given the extra data and driving behavior predictability[56] combined with less need for traffic police and even road signage.
Insurance
[edit]Safer driving is expected to reduce the costs of vehicle insurance.[30][57][failed verification] The automobile insurance industry might suffer as the technology makes certain aspects of these occupations obsolete.[35] As fewer collisions implicate less money spent 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 fewer payouts may imply a demand drop for insurances in general.[citation needed]
In order to accommodate such changes, the Automated and Electric Vehicles Act 2018 was introduced. While Part 2 deals with Electric Vehicles, Part 1 covers insurance provisions for automated vehicles.
Labor market
[edit]Driving-related jobs
[edit]A direct impact of widespread adoption of automated vehicles is the loss of driving-related jobs in the road transport industry.[16][30][31][58] There could be resistance from professional drivers and unions who are threatened by job losses.[59] In addition, there could be job losses in public transit services and crash repair shops. A frequently cited paper by Michael Osborne and Carl Benedikt Frey found that automated cars would make many jobs redundant.[60] The industry has, however created thousands of jobs in low-income countries for workers who train autonomous systems.[61]
Taxis
[edit]With the aforementioned ambiguous user preference regarding the personal ownership of autonomous vehicles, it is possible that the current mobility provider trend will continue as it rises in popularity. 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.[62]
Energy and environmental impacts
[edit]Vehicle use
[edit]A review found that private autonomous vehicles may increase total travel, whereas autonomous buses may lead to reduced car use.[7]
Vehicle automation can improve fuel economy of the car by optimizing the drive cycle, as well as increasing congested traffic speeds by an estimated 8%–13%.[63][64] Reduced traffic congestion and the improvements in traffic flow due to widespread use of automated cars will translate into higher fuel efficiency, ranging from a 23%–39% increase, with the potential to further increase.[63][65] 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. However, the improvement in vehicle energy efficiency does not necessarily translate to net reduction in energy consumption and positive environmental outcomes.
Alongside the induced demand, there may also be a reduction in the use of more sustainable modes, such as public or active transport. It is expected that convenience of the automated vehicles encourages the consumers to travel more, and this induced demand may partially or fully offset the fuel efficiency improvement brought by automation.[64] Alongside the induced demand, there may also be a reduction in the use of more sustainable modes, such as public or active transport.[66] Overall, the consequences of vehicle automation on global energy demand and emissions are highly uncertain, and heavily depends on the combined effect of changes in consumer behavior, policy intervention, technological progress and vehicle technology.[64]
Production
[edit]By reducing the labor and other costs 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.[67][68] This would also dramatically reduce the size of the automotive production industry, with corresponding environmental and economic effects.
Indirect effects
[edit]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 housing is cheaper, and work in the city's core, thus increasing travel distances and inducing more urban sprawl, raising energy consumption and enlarging the carbon footprint of urban travel.[64][69][70] There is also the risk that traffic congestion might increase, rather than decrease.[64][35] 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.[35][70]
Since many autonomous vehicles are going to rely on electricity to operate, the demand for lithium batteries increases. Similarly, radar, sensors, lidar, and high-speed internet connectivity require higher auxiliary power from vehicles, which manifests as greater power draw from batteries.[64] The larger battery requirement causes a necessary increase in the 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. In 2020, Mohan, Sripad, Vaishnav & Viswanathan at Carnegie Mellon University[71] found that the electricity consumption of all the automation technology, including sensors, computation, internet access as well as the increased drag from sensors causes up to a 15% impact on the range of an automated electric vehicle, therefore, implying that the larger battery requirement might not be as large as previously assumed.
Self-parking and parking space
[edit]Self-parking
[edit]A study conducted by AAA Foundation for Traffic Safety found that drivers did not trust self-parking technology, even though the systems outperformed drivers with a backup camera. The study tested self-parking systems in a variety of vehicles (Lincoln MKC, Mercedes-Benz ML400 4Matic, Cadillac CTS-V Sport, BMW i3 and Jeep Cherokee Limited) and found that self-parking cars hit the curb 81% fewer times, used 47% fewer manoeuvres and parked 10% faster than drivers. Yet, only 25% of those surveyed said they would trust this technology.[72]
Parking space
[edit]Manually driven vehicles are reported to be used only 4–5% of the time, and being parked and unused for the remaining 95–96% of the time.[73][74] Autonomous taxis could, on the other hand, be used continuously after they have reached their destination. This could dramatically reduce the need for parking space. For example, in Los Angeles a 2015 study found 14% of the land is used for parking alone, equivalent to some 1,702 hectares (4,210 acres).[75][76] This combined with the potential reduced need for road space due to improved traffic flow, could free up large amounts of land in urban areas, which could then be used for parks, recreational areas, buildings, among other uses; making cities more livable. Besides this, privately owned self-driving cars, also capable of self-parking would provide another advantage: the ability to drop off and pick up passengers even in places where parking is prohibited. This would benefit park and ride facilities.[77]
Cybersecurity
[edit]Privacy
[edit]The vehicles' increased awareness could aid the police by reporting on illegal passenger behaviour, while possibly enabling other crimes, such as deliberately crashing into another vehicle or a pedestrian.[78] 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.[citation needed]
Privacy could be an issue when having the vehicle's location and position integrated into an interface that other people have access to.[16][79] Moreover, they require a sensor-based infrastructure that would constitute an all-encompassing surveillance apparatus.[80] This gives the car manufacturers and other companies the data needed to understand the user's lifestyle and personal preferences.[81]
Terrorist scenarios
[edit]There is the risk of terrorist attacks by automotive hacking through the sharing of information through V2V (Vehicle to Vehicle) and V2I (Vehicle to Infrastructure) protocols.[82][83][84] Self-driving cars could potentially be loaded with explosives and used as bombs.[85] According to legislation of US lawmakers, autonomous and self-driving vehicles should be equipped with defences against hacking.[86]
Car repair
[edit]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 proactively replace a part that will fail soon. This "Asset Efficiency Service" would implicate a productivity gain for the automotive repair industry.[citation needed]
Rescue, emergency response, and military
[edit]The technique used in autonomous driving also ensures life savings in other industries. The implementation of autonomous vehicles with rescue, emergency response, and military applications has already led to a decrease in deaths.[citation needed] Military personnel use 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, which will lead to a decrease in injuries, since the technological development allows autonomous vehicles to become more and more autonomous. 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 and execute routes more efficiently than human drivers. The time savings can be invaluable in these situations.[87]
Interior design and entertainment
[edit]With the driver decreasingly focused on operating a vehicle, the interior design and media-entertainment industry will have 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 travellers 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.[88]
Connected vehicle
[edit]All cars can benefit from information and connections, but autonomous cars "Will be fully capable of operating without C-V2X."[89] 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.
Hospitality industry and airlines
[edit]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 by 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 the airline industry.[90]
References
[edit]- ^ a b c d Bosa, Deirdre (3 November 2023). "San Francisco Is Teeming With Self-Driving Cars And It's A Mess". CNBC.
- ^ Othman, Kareem (2022). "Exploring the implications of autonomous vehicles: a comprehensive review". Innovative Infrastructure Solutions. 7 (2): 165. Bibcode:2022InnIS...7..165O. doi:10.1007/s41062-022-00763-6. PMC 8885781.
- ^ a b Singh, Santokh (March 2018). "Critical Reasons for Crashes Investigated in the National Motor Vehicle Crash Causation Survey". NHTSA.
- ^ a b c d e f Rojas-Rueda, David; Nieuwenhuijsen, Mark J.; Khreis, Haneen; Frumkin, Howard (2020-01-31). "Autonomous Vehicles and Public Health". Annual Review of Public Health. 41: 329–345. doi:10.1146/annurev-publhealth-040119-094035. hdl:10230/52903. ISSN 0163-7525. PMID 32004116.
- ^ a b c Cummings, Mary L. (30 July 2023). "WHAT SELF-DRIVING CARS TELL US ABOUT AI RISKS". IEEE Spectrum.
- ^ a b c d Larson, William; Zhao, Weihua (2020). "Self-driving cars and the city: Effects on sprawl, energy consumption, and housing affordability". Regional Science and Urban Economics. 81: 103484. doi:10.1016/j.regsciurbeco.2019.103484. ISSN 0166-0462. S2CID 212801721.
- ^ a b Mouratidis, Kostas; Peters, Sebastian; Van Wee, Bert (1 March 2021). "Transportation technologies, sharing economy, and teleactivities: Implications for built environment and travel". Transportation Research Part D: Transport and Environment. 92: 102716. Bibcode:2021TRPD...9202716M. doi:10.1016/j.trd.2021.102716. hdl:11250/2831169. ISSN 1361-9209.
- ^ "The future of autonomous vehicles (AV)". www.mckinsey.com. 6 January 2023. Retrieved 2024-02-14.
- ^ Wayland, Michael (19 June 2017). "GM Lets its autonomous unit be autonomous". Automotive News.
- ^ a b c Hawkins, Andrew J. (2024-02-13). "Dude, where's my self-driving car?". The Verge. Retrieved 2024-02-14.
- ^ Ferris, Robert (18 March 2023). "Why Ford And VW Shut Down Their Multi-Billion Dollar Self-Driving Project". CNBC.
- ^ "An Open Source Self-Driving Car". Udacity. Retrieved 12 July 2017.
- ^ Fazzini, Kate (13 August 2018). "Elon Musk: Tesla to open-source some self-driving software for safety". cnbc.com.
- ^ Staff, Ars (24 April 2018). "This startup's CEO wants to open-source self-driving car safety testing". Ars Technica.
- ^ Fleetwood, Janet (2017-02-16). "Public Health, Ethics, and Autonomous Vehicles". American Journal of Public Health. 107 (4): 532–537. doi:10.2105/AJPH.2016.303628. ISSN 0090-0036. PMC 5343691. PMID 28207327.
- ^ a b c Taeihagh, Araz; Lim, Hazel Si Min (2 January 2019). "Governing autonomous vehicles: emerging responses for safety, liability, privacy, cybersecurity, and industry risks". Transport Reviews. 39 (1): 103–128. arXiv:1807.05720. doi:10.1080/01441647.2018.1494640. ISSN 0144-1647. S2CID 49862783.
- ^ a b "[INFOGRAPHIC] Autonomous Cars Could Save The US$1.3 Trillion Dollars A Year". businessinsider.com. 12 September 2014. Retrieved 3 October 2014.
- ^ 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.
- ^ Whitwam, Ryan (8 September 2014). "How Google's self-driving cars detect and avoid obstacles". ExtremeTech. Retrieved 4 June 2015.
- ^ a b Cowen, Tyler (28 May 2011). "Can I See Your License, Registration and C.P.U.?". The New York Times.
- ^ Lim, THazel Si Min; Taeihagh, Araz (2019). "Algorithmic Decision-Making in AVs: Understanding Ethical and Technical Concerns for Smart Cities". Sustainability. 11 (20): 5791. arXiv:1910.13122. Bibcode:2019arXiv191013122L. doi:10.3390/su11205791. S2CID 204951009.
- ^ a b LeBeau, Phil (2015-10-29). "Crash data for self-driving cars may not tell whole story". CNBC. Retrieved 2024-02-14.
- ^ a b Lee, Timothy B. (2023-09-01). "Are self-driving cars already safer than human drivers?". Ars Technica. Retrieved 2024-02-14.
- ^ Lee, Timothy B. (2023-12-20). "7.1 million miles, 3 minor injuries: Waymo's safety data looks good". Ars Technica. Retrieved 2024-02-18.
- ^ a b Ramsey, Jonathon (8 March 2017). "The Way We Talk About Autonomy Is a Lie, and That's Dangerous". thedrive.com. Retrieved 19 March 2018.
- ^ How Autonomous Cars Work (radio interview)
- ^ a b 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. Bibcode:2017TRPC...80..206S. doi:10.1016/j.trc.2017.04.014.
- ^ Merat, Natasha; Jamson, A. Hamish (June 2009). "How do drivers behave in a highly automated car?". Drive Assessment 2009 Proceedings. pp. 514–521. doi:10.17077/DRIVINGASSESSMENT.1365. ISBN 9-78087414162-7. S2CID 17820234.
Drivers' response to all critical events was found to be much later in the automated driving condition, compared to manual driving.
- ^ Adams, Ian (30 December 2016). "Self-Driving Cars Will Make Organ Shortages Even Worse". Slate. Retrieved 9 November 2018.
- ^ a b c Light, Donald (8 May 2012). A Scenario" The End of Auto Insurance (Technical report). Celent.
- ^ a b Mui, Chunka (19 December 2013). "Will The Google Car Force A Choice Between Lives And Jobs?". Forbes. Retrieved 19 December 2013.
- ^ 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. Retrieved 30 November 2015.
- ^ "Driver licensing system for older drivers in New South Wales, Australia". NSW Government. 30 June 2016. Retrieved 16 May 2018.
- ^ Stenquist, Paul (7 November 2014). "In Self-Driving Cars, a Potential Lifeline for the Disable". The New York Times. Retrieved 29 October 2016.
- ^ a b c d Anderson, James M.; Kalra, Nidhi; Stanley, Karlyn D.; Sorensen, Paul; Samaras, Constantine; Oluwatola, Oluwatobi A. (2016). "Autonomous Vehicle Technology: A Guide for Policymakers". RAND Corporation. Retrieved 30 October 2016.
- ^ Simonite, Tom (1 November 2014). "Self-Driving Motorhome: RV of the Future?". Archived from the original on 5 January 2016. Retrieved 1 November 2015.
{{cite journal}}
: Cite journal requires|journal=
(help) - ^ Ashley Jalsey III, Driverless cars promise far greater mobility for the elderly and people with disabilities, Washington Post (23 November 2017).
- ^ Henry Claypool, Amitai Bin-Nun & Jeffrey Gerlach, Self-Driving Cars: The Impact on People with Disabilities (January 2017), Ruderman Family Foundation/Securing America's Future Energy.
- ^ "Who's Ready to Put Their Kid on a Self-Driving School Bus?". Wired. Retrieved 5 September 2020.
- ^ McParland, Tom. "Why Autonomous Cars Could Be The Change Disabled People Need". Jalopnik. Retrieved 26 November 2018.
- ^ Jain, Lochlann (2004). ""Dangerous instrumentality": the bystander as subject in automobility". Cultural Anthropology. 19 (1): 61–94. doi:10.1525/can.2004.19.1.61. S2CID 17924196.
- ^ a b Badger, Emily (15 January 2015). "5 confounding questions that hold the key to the future of driverless cars". The Washington Post. Retrieved 22 January 2015.
- ^ Lim, Hazel Si Min; Taeihagh, Araz (2018). "Autonomous Vehicles for Smart and Sustainable Cities: An In-Depth Exploration of Privacy and Cybersecurity Implications". Energies. 11 (5): 1062. arXiv:1804.10367. Bibcode:2018arXiv180410367L. doi:10.3390/en11051062. S2CID 13749987.
- ^ Lee, Timothy (31 January 2015). "Driverless cars will mean the end of mass car ownership". Vox. Retrieved 31 January 2015.
- ^ 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
- ^ 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.
- ^ Badger, Emily (15 January 2015). "5 confounding questions that hold the key to the future of driverless cars". The Washington Post. ISSN 0190-8286. Retrieved 27 November 2017.
- ^ 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. S2CID 106654883.
- ^ Litman, Todd. "Autonomous vehicle implementation predictions." Victoria Transport Policy Institute 28 (2014).
- ^ Humphreys, Pat (19 August 2016). "Retail Revolution". Transport and Travel. Retrieved 24 August 2016.
- ^ "Get ready for automated cars". Houston Chronicle. 11 September 2012. Retrieved 5 December 2012.
- ^ Simonite, Tom (25 October 2013). "Data Shows Google's Robot Cars Are Smoother, Safer Drivers Than You or I". MIT Technology Review. Archived from the original on 5 January 2016. Retrieved 15 November 2013.
- ^ 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.
- ^ "Future Car Focus: Robot Cars". MSN Autos. 2013. Archived from the original on 12 January 2013. Retrieved 27 January 2013.
- ^ 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.
- ^ Gibson, David K. (28 April 2016). "Can we banish the phantom traffic jam?". BBC.
- ^ "Autonomous Intersection Management – FCFS policy with 6 lanes in all directions". The University of Texas at Austin Computer Science Department. 12 June 2009. Archived from the original on 2021-10-30. Retrieved 28 April 2012.
- ^ "Mass unemployment fears over Google artificial intelligence plans". London. 29 December 2013. Retrieved 29 December 2013.
- ^ Dvorak, John C. (30 September 2015). "There's a Bumpy Road Ahead for Driverless Cars". PCMag. Retrieved 30 September 2015.
- ^ 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. CiteSeerX 10.1.1.395.416. doi:10.1016/j.techfore.2016.08.019. ISSN 0040-1625.
- ^ Anwar, Mohammad Amir; Graham, Mark (2020-04-20). "Digital labour at economic margins: African workers and the global information economy". Review of African Political Economy. 47 (163): 95–105. doi:10.1080/03056244.2020.1728243. hdl:10.1080/03056244.2020.1728243. ISSN 0305-6244. S2CID 214074400.
- ^ "You can take a ride in a self-driving Lyft during CES". The Verge. Retrieved 26 November 2018.
- ^ a b Fagnant, Daniel J.; Kockelman, Kara (2015-07-01). "Preparing a nation for autonomous vehicles: opportunities, barriers and policy recommendations". Transportation Research Part A: Policy and Practice. 77: 167–181. Bibcode:2015TRPA...77..167F. doi:10.1016/j.tra.2015.04.003. ISSN 0965-8564. S2CID 54752617.
- ^ a b c d e f Taiebat, Morteza; Brown, Austin; Safford, Hannah; Qu, Shen; Xu, Ming (2019). "A Review on Energy, Environmental, and Sustainability Implications of Connected and Automated Vehicles". Environmental Science & Technology. 52 (20): 11449–11465. arXiv:1901.10581. Bibcode:2019arXiv190110581T. doi:10.1021/acs.est.8b00127. PMID 30192527. S2CID 52174043.
- ^ Pyper, Julia (15 September 2015). "Self-Driving Cars Could Cut Greenhouse Gas Pollution". Scientific American. Retrieved 25 December 2018.
- ^ May, A; Shepherd, S; Pfaffenbichler, P; Emberger, G (2020-11-01). "The potential impacts of automated cars on urban transport: An exploratory analysis". Transport Policy. 98: 127–138. doi:10.1016/j.tranpol.2020.05.007. ISSN 0967-070X. S2CID 219453379. Archived from the original on 13 April 2021. Alt URL
- ^ Woodyard, Chris (5 March 2015). "McKinsey study: Self-driving cars yield big benefits". USA Today. Retrieved 4 June 2015.
- ^ "Self-driving cars: The next revolution" (PDF). kpmg.com. 5 September 2013. Retrieved 6 September 2013.
- ^ Smith, Noah (5 November 2015). "The downside of driverless cars". The Sydney Morning Herald. Retrieved 30 October 2016.
- ^ a b Ufberg, Max (15 October 2015). "Whoops: The Self-Driving Tesla May Make Us Love Urban Sprawl Again". Wired. Retrieved 28 October 2016.
- ^ Mohan, Aniruddh; Sripad, Shashank; Vaishnav, Parth; Viswanathan, Venkatasubramanian (June 2020). "Trade-offs between automation and light vehicle electrification". Nature Energy. 5 (7): 543–549. arXiv:1908.08920. Bibcode:2020NatEn...5..543M. doi:10.1038/s41560-020-0644-3. S2CID 220504021.
- ^ "AAA Studies Technology Behind Self-Driving Cars". Your AAA Network. 2019-02-18. Archived from the original on 2021-06-20. Retrieved 2020-02-21.
- ^ "Spaced Out parking report". racfoundation.org. Retrieved 3 September 2018.
- ^ ""Cars are parked 95% of the time". Let's check!". reinventingparking.org. 22 February 2013. Retrieved 3 September 2018.
- ^ Chester, Mikhail; Fraser, Andrew; Matute, Juan; Flower, Carolyn; Pendyala, Ram (2 October 2015). "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. S2CID 133540522.
- ^ Peters, Adele (20 July 2017). "See Just How Much of a City's Land Is Used For Parking Spaces". Fast Company. Retrieved 3 September 2018.
- ^ Stewart, Jack (25 March 2018). "Forget Self Driving. The Future is in Self Parking". Wired.
- ^ Miller, Owen. "Robotic Cars and Their New Crime Paradigms". Retrieved 4 September 2014.
- ^ 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. S2CID 1066738.
- ^ JafariNaimi, Nassim (2018). "Our Bodies in the Trolley's Path, or Why Self-driving Cars Must *Not* Be Programmed to Kill". Science, Technology, & Human Values. 43 (2): 302–323. doi:10.1177/0162243917718942. S2CID 148793137.
- ^ Chai, Zhanxiang; Nie, Tianxin; Becker, Jan (2021), "Top Ten Challenges Facing Autonomous Driving", Autonomous Driving Changes the Future, Singapore: Springer Singapore, pp. 137–178, doi:10.1007/978-981-15-6728-5_6, ISBN 978-981-15-6727-8, S2CID 225012885, retrieved 2020-10-25
- ^ Acharya, Anish (16 December 2014). "Are We Ready for Driver-less Vehicles? Security vs. Privacy – A Social Perspective". arXiv:1412.5207 [cs.CY].
- ^ Lin, Patrick (22 January 2014). "What If Your Autonomous Car Keeps Routing You Past Krispy Kreme?". The Atlantic. Retrieved 22 January 2014.
- ^ Glielmo, Luigi. "Vehicle-to-Vehicle/Vehicle-to-Infrastructure Control" (PDF).
- ^ Harris, Mark (16 July 2014). "FBI warns driverless cars could be used as 'lethal weapons'". The Guardian.
- ^ McCarthy, Tom (6 September 2017). "Self-driving cars must have technology to prevent use in terror, lawmakers say". The Guardian. Retrieved 30 August 2020.
- ^ Snow, Shawn (29 August 2017). "The US Army is developing autonomous armored vehicles". Army Times. Retrieved 26 November 2018.
- ^ "Driver-less car design: Sleep-walking into the future?". 5 April 2016. Archived from the original on 5 April 2016. Retrieved 26 November 2018.
- ^ Company, Ford Motor (7 January 2019). "How 'Talking' and 'Listening' Vehicles Could Make Roads Safer, Cities Better". Medium. Retrieved 2019-06-08.
{{cite web}}
:|last=
has generic name (help) - ^ "Volvo's Fully Autonomous 360c Concept Vehicle Even Lets You Sleep in It". 6 September 2018. Retrieved 26 November 2018.