Vehicular communication systems
Vehicular communication systems are networks in which vehicles and roadside units are the communicating nodes, providing each other with information, such as safety warnings and traffic information. They can be effective in avoiding accidents and traffic congestion. Both types of nodes are dedicated short-range communications (DSRC) devices. DSRC works in 5.9 GHz band with bandwidth of 75 MHz and approximate range of 1000 m.[1] Vehicular communications is usually developed as a part of intelligent transportation systems (ITS).
The main motivation for vehicular communication systems is safety and eliminating the excessive cost of traffic collisions. According to World Health Organizations (WHO), road accidents annually cause approximately 1.2 million deaths worldwide; one fourth of all deaths caused by injury. Also about 50 million persons are injured in traffic accidents. If preventive measures are not taken road death is likely to become the third-leading cause of death in 2020 from ninth place in 1990.[2] A study from the American Automobile Association (AAA) concluded that car crashes cost the United States $300 billion per year.[3] It can be used for Automated traffic intersection control.[1]
However the deaths caused by car crashes are in principle avoidable. US Department of Transport states that 21,000 of the annual 43,000 road accident deaths in the US are caused by roadway departures and intersection-related incidents.[4] This number can be significantly lowered by deploying local warning systems through vehicular communications. Departing vehicles can inform other vehicles that they intend to depart the highway and arriving cars at intersections can send warning messages to other cars traversing that intersection. Studies show that in Western Europe a mere 5 km/h decrease in average vehicle speeds could result in 25% decrease in deaths.[5]
Intelligent Transportation Society of America (ITSA) aims to improve cooperation among public and private sector organizations. ITSA summarizes its mission statement as “vision zero” meaning its goal is to reduce the fatal accidents and delays as much as possible.
Many universities are pursuing research and development of vehicular ad hoc networks. For example, University of California, Berkeley is participating in California Partners for Advanced Transit and Highways (PATH).[6]
V2V (short for vehicle to vehicle) is an automobile technology designed to allow automobiles to "talk" to each other. The systems will use a region of the 5.9 GHz band set aside by the United States Congress in 1999, the unlicensed frequency also used by WiFi. V2V is currently in active development by General Motors, which demonstrated the system in 2006 using Cadillac vehicles. Other automakers working on V2V include BMW, Daimler, Honda, Audi, Volvo and the Car-to-Car communication consortium.[7] V2V is also known as VANETs (Vehicular Ad Hoc Networks). It is a variation of MANETs (Mobile Ad Hoc Networks), with the emphasis being now the node is the vehicular. In 2001, it was mentioned in a publication [8] that ad hoc networks can be formed by cars and such networks can help overcome blind spots, avoid accidents, etc. Over the years, there have been considerable research and projects in this area, applying VANETs for a variety of applications, ranging from safety to navigation and law enforcement. In April 2014 it was reported that U.S. regulators were close to approving V2V standards for the U.S. market, and that officials were planning for the technology to become mandatory by 2017.[9] PKI (public key infrastructure) is the current security system being used in V2V communications.[10]
See also
- Artificial Passenger
- Carputer
- Dedicated Short Range Communications
- Intelligent transportation system
- Intelligent Transportation Systems Institute
- Mobile phone tracking
- Mobile ad hoc network
- Radio
- Wireless LAN
- Vehicle-to-vehicle
References
- 1 2 "Dedicated_Short_Range_Communications_(DSRC)_Home". leearmstrong.com. Retrieved 2008-02-29.
- ↑ M. Peden; Richard Scurfield; D. Sleet; D. Mohan; et al. "World report on road traffic injury prevention" (PDF). World Health Organization. Retrieved 2008-02-29.
- ↑ "Crashes Vs. Congestion -- What's the Cost to Society?" (PDF). American Automobile Association. Retrieved 2011-11-30.
- ↑ "Vehicle Infrastructure Integration (VII)". its.dot.gov. Retrieved 2008-02-29.
- ↑ "The world health report 2002 - Reducing Risks, Promoting Healthy Life". World Health Organization. Retrieved 2008-02-29.
- ↑ "UC_Berkeley-Audi_Pact_Places_Smart-Engine_Research_on_Bay_Area_Roads". berkeley.edu. Retrieved 2008-02-29.
- ↑ http://www.car-to-car.org/index.php?id=8
- ↑ http://www.patentgenius.com/patent/7065548.html
- ↑ http://www.voanews.com/content/vehicles-may-soon-be-talking-to-each-other-/1886895.html
- ↑ Harding, J (2014). "Vehicle-to-vehicle communications: Readiness of V2V technology for application" (PDF). nhtsa.gov.
External links
- Vehicular Networks for Collision Avoidance at Intersections, Society for Automotive Engineers (SAE) World Congress,April,2011, Detroit, MI, USA.
- U.S. Department of Transportation (USDOT), ITS Joint Program Office Home
- Dedicated Short Range Communications
- Intelligent Transportation Systems, Transport Canada
- PATH project, University of California, Berkeley
- Status of Project IEEE 802.11 Task Group p
- US Department of Transportation, ITS application overview
- Vehicle-to-vehicle communication can prevent crashes, Consumer Reports
- DANCE 2022 -- Digital Automobile Network for Crash Elimination by 2022
- DSRC/Wave Vehicle Communication and Traffic Simulator eTEXAS
- How Connected Vehicles Work Factsheet - U.S. Department of Transportation