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Car dependency

From Wikipedia, the free encyclopedia

Traffic in Los Angeles

Car dependency is a phenomenon in urban planning wherein existing and planned infrastructure prioritizes the use of automobiles over other modes of transportation, such as public transit, bicycles, and walking.

Description

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In many modern cities, automobiles are convenient and sometimes necessary to move easily.[1][2] When it comes to automobile use, there is a spiraling effect where traffic congestion produces the 'demand' for more and bigger roads and the removal of 'impediments' to traffic flow. For instance, pedestrians, signalized crossings, traffic lights, cyclists, and various forms of street-based public transit, such as trams.

These measures make automobile use more advantageous at the expense of other modes of transport, inducing greater traffic volumes. Additionally, the urban design of cities adjusts to the needs of automobiles in terms of movement and space. Buildings are replaced by parking lots. Open-air shopping streets are replaced by enclosed shopping malls. Walk-in banks and fast-food stores are replaced by drive-in versions of themselves that are inconveniently located for pedestrians. Town centers with a mixture of commercial, retail, and entertainment functions are replaced by single-function business parks, 'category-killer' retail boxes, and 'multiplex' entertainment complexes, each surrounded by large tracts of parking.

These kinds of environments require automobiles to access them, thus inducing even more traffic onto the increased road space. This results in congestion, and the cycle above continues. Roads get ever bigger, consuming ever greater tracts of land previously used for housing, manufacturing, and other socially and economically useful purposes. Public transit becomes less viable and socially stigmatized, eventually becoming a minority form of transportation. People's choices and freedoms to live functional lives without the use of the car are greatly reduced. Such cities are automobile-dependent.

Automobile dependency is seen primarily as an issue of environmental sustainability due to the consumption of non-renewable resources and the production of greenhouse gases responsible for global warming. It is also an issue of social and cultural sustainability. Like gated communities, the private automobile produces physical separation between people and reduces the opportunities for unstructured social encounters that is a significant aspect of social capital formation and maintenance in urban environments.

Origins of car dependency

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Cars per 1000 inhabitants in US, European, and Australian cities, 1960–2000

As automobile use rose drastically in the 1910s, American road administrators favored building roads to accommodate traffic.[3] Administrators and engineers in the interwar period spent their resources making small adjustments to accommodate traffic such as widening lanes and adding parking spaces, as opposed to larger projects that would change the built environment altogether.[3] American cities began to tear out tram systems in the 1920s. Car dependency itself saw its formation around the Second World War, when urban infrastructure began to be built exclusively around the car.[4] The resultant economic and built environment restructuring allowed wide adoption of automobile use. In the United States, the expansive manufacturing infrastructure, increase in consumerism, and the establishment of the Interstate Highway System set forth the conditions for car dependence in communities. In 1956, the Highway Trust Fund[5] was established in America, reinvesting gasoline taxes back into car-based infrastructure.

Urban design factors

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Land-use (zoning)

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In 1916 the first zoning ordinance was introduced in New York City, the 1916 Zoning Resolution. Zoning was created as a means of organizing specific land uses in a city so as to avoid potentially harmful adjacencies like heavy manufacturing and residential districts, which were common in large urban areas in the 19th and early 20th centuries. Zoning code also determines the permitted residential building types and densities in specific areas of a city by defining such things as single-family homes, and multi-family residential as being allowed as of right or not in certain areas. The overall effect of zoning in the last century has been to create areas of the city with similar land use patterns in cities that had previously been a mix of heterogenous residential and business uses. The problem is particularly severe right outside of cities, in suburban areas located around the periphery of a city where strict zoning codes almost exclusively allow for single family detached housing.[6] Strict zoning codes that result in a heavily segregated built environment between residential and commercial land uses contributes to car dependency by making it nearly impossible to access all one's given needs, such as housing, work, school and recreation without the use of a car. One key solution to the spatial problems caused by zoning would be a robust public transportation network. There is also currently a movement to amend older zoning ordinances to create more mixed-use zones in cities that combine residential and commercial land uses within the same building or within walking distance to create the so-called 15-minute city.

Parking minimums are also a part of modern zoning codes, and contribute to car dependency through a process known as induced demand. Parking minimums require a certain number of parking spots based on the land use of a building and are often designed in zoning codes to represent the maximum possible need at any given time.[7] This has resulted in cities having nearly eight parking spaces for every car in America, which have created cities almost fully dedicated to parking from free on-street parking to parking lots up to three times the size of the businesses they serve.[7] This prevalence in parking has perpetuated a loss in competition between other forms of transportation such that driving becomes the de facto choice for many people even when alternatives do exist.

Street design

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The design of city roads can contribute significantly to the perceived and actual need to use a car over other modes of transportation in daily life. In the urban context car dependence is induced in greater numbers by design factors that operate in opposite directions - first, design that makes driving easier and second, design that makes all other forms of transportation more difficult. Frequently these two forces overlap in a compounding effect to induce more car dependence in an area that would have potential for a more heterogenous mix of transportation options. These factors include things like the width of roads, that make driving faster and therefore 'easier' while also making a less safe environment for pedestrians or cyclists that share the same road. The prevalence of on-street parking on most residential and commercial also streets makes driving easier while taking away street space that could be used for protected bike lanes, dedicated bus lanes, or other forms of public transportation.

Negative externalities of automobiles

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Automobile Inefficiencies

According to the Handbook on estimation of external costs in the transport sector[8] made by the Delft University, which is the main reference in European Union for assessing the externalities of cars, the main external costs of driving a car are:

Other negative externalities may include increased cost of building infrastructure, inefficient use of space and energy, pollution and per capita fatality.[9][10]

Addressing the issue

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There are a number of planning and design approaches to redressing automobile dependency,[11] known variously as New Urbanism, transit-oriented development, and smart growth. Most of these approaches focus on the physical urban design, urban density and landuse zoning of cities. Paul Mees argued that investment in good public transit, centralized management by the public sector and appropriate policy priorities are more significant than issues of urban form and density.

Removal of minimum parking requirements from building codes can alleviate the problems generated by car dependency. Minimum parking requirements occupy valuable space that otherwise can be used for housing. However, removal of minimum parking requirements will require implementation of additional policies to manage the increase in alternative parking methods.[12]

There are, of course, many who argue against a number of the details within any of the complex arguments related to this topic, particularly relationships between urban density and transit viability, or the nature of viable alternatives to automobiles that provide the same degree of flexibility and speed. There is also research into the future of automobility itself in terms of shared usage, size reduction, road-space management and more sustainable fuel sources.

Car-sharing is one example of a solution to automobile dependency. Research has shown that in the United States, services like Zipcar, have reduced demand by about 500,000 cars.[13] In the developing world, companies like eHi,[14] Carrot,[15][16] Zazcar[17] and Zoom have replicated or modified Zipcar's business model to improve urban transportation to provide a broader audience with greater access to the benefits of a car and provide "last-mile" connectivity between public transportation and an individual's destination. Car sharing also reduces private vehicle ownership.

Urban sprawl and smart growth

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A diagram showing an inverse correlation between urban density and car use for selected North American cities
Car dependency is inherent with wide, high speed roadways and spaced out business properties. US 22 in Springfield, New Jersey.
Urban Transport and Morphology - Los Angeles

Whether smart growth does or can reduce problems of automobile dependency associated with urban sprawl has been fiercely contested for several decades. The influential study in 1989 by Peter Newman and Jeff Kenworthy compared 32 cities across North America, Australia, Europe and Asia.[18] The study has been criticised for its methodology,[19] but the main finding, that denser cities, particularly in Asia, have lower car use than sprawling cities, particularly in North America, has been largely accepted, but the relationship is clearer at the extremes across continents than it is within countries where conditions are more similar.

Within cities, studies from across many countries (mainly in the developed world) have shown that denser urban areas with greater mixture of land use and better public transport tend to have lower car use than less dense suburban and exurban residential areas. This usually holds true even after controlling for socio-economic factors such as differences in household composition and income.[20]

This does not necessarily imply that suburban sprawl causes high car use, however. One confounding factor, which has been the subject of many studies, is residential self-selection:[21] people who prefer to drive tend to move towards low-density suburbs, whereas people who prefer to walk, cycle or use transit tend to move towards higher density urban areas, better served by public transport. Some studies have found that, when self-selection is controlled for, the built environment has no significant effect on travel behaviour.[22] More recent studies using more sophisticated methodologies have generally rejected these findings: density, land use and public transport accessibility can influence travel behaviour, although social and economic factors, particularly household income, usually exert a stronger influence.[23]

The paradox of intensification

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Reviewing the evidence on urban intensification, smart growth and their effects on automobile use, Melia et al. (2011)[24] found support for the arguments of both supporters and opponents of smart growth. Planning policies that increase population densities in urban areas do tend to reduce car use, but the effect is weak. So, doubling the population density of a particular area will not halve the frequency or distance of car use.

These findings led them to propose the paradox of intensification:

  • All other things being equal, urban intensification which increases population density will reduce per capita car use, with benefits to the global environment, but will also increase concentrations of motor traffic, worsening the local environment in those locations where it occurs.

At the citywide level, it may be possible, through a range of positive measures to counteract the increases in traffic and congestion that would otherwise result from increasing population densities:[25] Freiburg im Breisgau in Germany is one example of a city which has been more successful in reducing automobile dependency and constraining increases in traffic despite substantial increases in population density.[26]

This study also reviewed evidence on local effects of building at higher densities. At the level of the neighbourhood or individual development, positive measures (like improvements to public transport) will usually be insufficient to counteract the traffic effect of increasing population density.

This leaves policy-makers with four choices:

  • intensify and accept the local consequences
  • sprawl and accept the wider consequences
  • a compromise with some element of both
  • or intensify accompanied by more direct measures such as parking restrictions, closing roads to traffic and carfree zones.

See also

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Notes and references

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  1. ^ Turcotte, Martin (2008). "Dependence on cars in urban neighborhoods". Canadian Social Trends. Statistics Canada. Archived from the original on 8 January 2019.
  2. ^ Mattioli, Giulio; Roberts, Cameron; Steinberger, Julia K.; Brown, Andrew (2020). "The political economy of car dependence: A systems of provision approach". Energy Research & Social Science. 66: 101486. Bibcode:2020ERSS...6601486M. doi:10.1016/j.erss.2020.101486.
  3. ^ a b Wells, Christopher W.; Cronon, William (2014). Car country : an environmental history. University of Washington Press. ISBN 978-0-295-99429-1. OCLC 932622166.
  4. ^ Robinson, Grayson (2 May 2021). "The History Behind Car (In)Dependence in the US vs World". ArcGIS StoryMaps. Retrieved 1 December 2021.
  5. ^ 70 Stat. 374
  6. ^ Bronin, Sarah (2021). "Zoning by a Thousand Cuts: The Prevalence and Nature of Incremental Regulatory Constraints on Housing". Cornell Journal of Law and Public Policy.
  7. ^ a b Shoup, Donald (2011). The High Cost of Free Parking. New York: Routledge. ISBN 978-1884829987.
  8. ^ Maibach, M.; Schreyer, C.; Sutter, D.; van Essen, H.P.; et al. (February 2008). Handbook on estimation of external costs in the transport sector (PDF) (Report). CE Delft. p. 332. Archived from the original (PDF) on 2 November 2012. Retrieved 20 September 2015.
  9. ^ "What Is Automobile Dependency?". WorldAtlas. 7 January 2019. Retrieved 2 December 2023.
  10. ^ Wang, Xiaoquan; Shao, Chunfu; Yin, Chaoying; Zhuge, Chengxiang (September 2018). "Exploring the Influence of Built Environment on Car Ownership and Use with a Spatial Multilevel Model: A Case Study of Changchun, China". International Journal of Environmental Research and Public Health. 15 (9): 1868. doi:10.3390/ijerph15091868. ISSN 1661-7827. PMC 6165495. PMID 30158467.
  11. ^ Reid, Carlton (17 August 2023). "Sticks Not Carrots Needed To Get Drivers Out Of Cars, Say Climate Scientists". Forbes. Retrieved 23 August 2023.
  12. ^ Samsonova, Tatiana (25 February 2021). "Reversing Car Dependency". The International Transport Forum. 181: 41 – via OECD/ITF.
  13. ^ Boudette, Neal E. (3 February 2014). "Car-Sharing, Social Trends Portend Challenge for Auto Sales". Wall Street Journal.
  14. ^ eHi
  15. ^ "Carrot". Archived from the original on 16 November 2018. Retrieved 20 March 2018.
  16. ^ "Sustainable Cities Collective".
  17. ^ "Zazcar". Archived from the original on 11 October 2019. Retrieved 14 May 2021.
  18. ^ Cities and Automobile Dependence: An International Sourcebook, Newman P and Kenworthy J, Gower, Aldershot, 1989.
  19. ^ Mindali, O.; Raveh, A.; Salomon, I. (2004). "Urban density and energy consumption: a new look at old statistics". Transportation Research Part A: Policy and Practice. 38 (2): 143–162. Bibcode:2004TRPA...38..143M. doi:10.1016/j.tra.2003.10.004.
  20. ^ e.g., Frank, L.; Pivot, G. (1994). "Impact of Mixed Use and Density on Three Modes of Travel". Transportation Research Record (1446): 44–52.
  21. ^ Transport Reviews Volume 29 Issue 3 (2009) was entirely devoted to this issue
  22. ^ e.g., Bagley, M. N.; Mokhtarian, P. L. (2002). "The impact of residential neighborhood type on travel behavior: A structural equations modeling approach". Annals of Regional Science. 36 (2): 279. Bibcode:2002ARegS..36..279B. doi:10.1007/s001680200083.
  23. ^ e.g., Handy, S.; Cao, X.; Mokhtarian, P.L. (2005). "Correlation or causality between the built environment and travel behavior? Evidence from Northern California". Transportation Research Part D: Transport and Environment. 10 (6): 427–444. Bibcode:2005TRPD...10..427H. doi:10.1016/j.trd.2005.05.002.
  24. ^ Melia, S.; Barton, H.; Parkhurst, G. (2011). "The Paradox of Intensification". Transport Policy. 18 (1): 46–52. doi:10.1016/j.tranpol.2010.05.007.
  25. ^ Ostermeijer, Francis; Koster, Hans R A; van Ommeren, Jos; Nielsen, Victor Mayland (18 February 2022). "Automobiles and urban density". Journal of Economic Geography. 22 (5): 1073–1095. doi:10.1093/jeg/lbab047.
  26. ^ Broaddus, Andrea (2010). "Tale of Two Ecosuburbs in Freiburg, Germany". Journal of the Transportation Research Board. December: 114–122. doi:10.3141/2187-15. S2CID 15698518 – via SAGE.

Bibliography

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