Page Mill Road in Palo Alto, California, United States, is a typical arterial road in a suburban area; this also has a bike lane

An arterial road or arterial thoroughfare is a high-capacity urban road that sits below freeways/motorways on the road hierarchy in terms of traffic flow and speed.[1][2] The primary function of an arterial road is to deliver traffic from collector roads to freeways or expressways, and between urban centres at the highest level of service possible. Therefore, many arteries are limited-access roads, or feature restrictions on private access. Because of their relatively high accessibility, many major roads face large amounts of land use and urban development, making them significant urban places.[3]

In traffic engineering hierarchy, an arterial road delivers traffic between collector roads and freeways. For new arterial roads, intersections are often reduced to increase traffic flow. In California, arterial roads are usually spaced every half mile, and have intersecting collector(s) and streets. Some arterial roads, characterized by a small fraction of intersections and driveways compared to most arterial roads, are also considered to be expressways in some countries and US states.

Definition

The Traffic Engineering Handbook describes "Arterials" as being either principal or minor. Both classes serve to carry longer-distance flows between important centers of activity. Arterials are laid out as the backbone of a traffic network and should be designed to afford the highest level of service, as is practical, as per the aforementioned "Traffic Engineering Handbook".[4]

Development

The construction and development of arterial roads is achieved through two methods. By far the most common is the upgrading of an existing right-of-way during subdivision development. When existing structures prohibit the widening of an existing road however, bypasses are often constructed. Because of the placement and general continuity of arterial road corridors, sewers, water mains, conduits and other infrastructure are placed beneath or beside the roadbed.

Specifications

In North America, signalized at-grade intersections are used to connect arterials to collector roads and other local roads (except where the intersecting road is a minor side street, in which case a stop sign is used instead). In Europe, large roundabouts are more commonly seen at the busier junctions. Speed limits are typically between 30 and 50 mph (50 and 80 km/h), depending on the density of use of the surrounding development. In school zones, speeds may be further reduced; likewise, in sparsely developed or rural areas, speeds may be increased. In western Canada, where freeways are scarce compared to the rest of North America, flashing early-warning amber lights are sometimes placed ahead of traffic lights on heavy signalized arterial roads so the speed limits can be raised to speeds of over 80 km/h. These warning lights are commonly found on high-speed arterial roads in British Columbia.

The width of arterial roads can range from four lanes to ten or even more; either as a dual carriageway or sharing a common center lane, such as a contraflow lane or as a central turning lane.

Environmental issues

As with other roadway environmental consequences derive from arterial roadways, including air pollution generation, noise pollution and surface runoff of water pollutants. Air pollution generation from arterials can be rather concentrated, since traffic volumes can be relatively high, and traffic operating speeds are often low to moderate.[5] Sound levels can also be considerable due to moderately high traffic volumes characteristic of arterials, and also due to considerable braking and acceleration that often occur on arterials that are heavily signalized.[6]

See also

References

  1. Road Function Classifications (PDF) (Report). U.S. Federal Highway Administration. November 2000.
  2. "Mobility and transport: Road classification". European Commission.
  3. McLeod, Sam; Curtis, Carey (2019). "Contested urban streets: Place, traffic and governance conflicts of potential activity corridors". Cities. 88: 222–234. doi:10.1016/j.cities.2018.11.002. S2CID 159002874.
  4. Neuman, Timothy R. (1992). "Roadway Geometric Design". In Institute of Traffic Engineers (ed.). Traffic Engineering Handbook. Prentice Hall. p. 155. ISBN 978-0-13-926791-8.
  5. "Roadway air dispersion model". United States Environmental Protection Agency.
  6. Hogan, C. Michael (September 1973). "Analysis of highway noise". Journal of Water, Air, & Soil Pollution. Vol. 2, no. 3 (Biomedical and Life Sciences and Earth and Environmental Science Issue). pp. 387–392. doi:10.1007/BF00159677. ISSN 0049-6979.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.