- Electronic toll collection
Electronic toll collection (ETC), an adaptation of military "identification friend or foe" technology, aims to eliminate the delay on toll roads by collecting tolls electronically. It is thus a technological implementation of a road pricing concept. It determines whether the cars passing are enrolled in the program, alerts enforcers for those that are not, and electronically debits the accounts of registered car owners without requiring them to stop.
In 1959, Nobel Economics Prize winner William Vickrey was the first to propose a system of electronic tolling for the Washington metropolitan area. He proposed that each car would be equipped with a transponder. “The transponder’s personalised signal would be picked up when the car passed through an intersection, and then relayed to a central computer which would calculate the charge according to the intersection and the time of day and add it to the car’s bill”
In the 1960s and 1970’s, free flow tolling was tested with fixed transponders at the undersides of the vehicles and readers, which were located under the surface of the highway.
Norway has been the world's pioneer in the widespread implementation of this technology. ETC was first introduced in Bergen, in 1986, operating together with traditional tollbooths. In 1991, Trondheim introduced the world's first use of completely unaided full-speed electronic tolling. Norway now has 25 toll roads operating with electronic fee collection (EFC), as the Norwegian technology is called (see AutoPASS). In 1995, Portugal became the first country to apply a single, universal system to all tolls in the country, the Via Verde, which can also be used in parking lots and gas stations. The United States is another country with widespread use of ETC in several states, though many U.S. toll roads maintain the option of manual collection.
Open road tolling (ORT) is a type of electronic toll collection without the use of toll booths. The major advantage to ORT is that users are able to drive through the toll plaza at highway speeds without having to slow down to pay the toll.
In some urban settings, automated gates are in use in electronic-toll lanes, with 5 mph (8 km/h) legal limits on speed (and 2 to 3 times that as practical limits even with practice and extreme concentration)[clarification needed]; in other settings, 20 mph (35 km/h) legal limits are not uncommon. However, in other areas such as the Garden State Parkway in New Jersey, and at various locations in Florida, Pennsylvania, Delaware, and Texas, cars can travel through electronic lanes at full speed. Illinois' Open Road Tolling program features 274 contiguous miles of barrier-free roadways, where I-PASS or E-ZPass users continue to travel at highway speeds through toll plazas, while cash payers pull off the main roadway to pay at tollbooths. Currently over 80% of Illinois' 1.4 million daily drivers use an I-PASS.
Enforcement is accomplished by a combination of a camera which takes a picture of the car and a radio frequency keyed computer which searches for a drivers window/bumper mounted transponder to verify and collect payment. The system sends a notice and fine to cars that pass through without having an active account or paying a toll.
Factors hindering full-speed electronic collection include significant non-participation, entailing lines in manual lanes and disorderly traffic patterns as the electronic- and manual- collection cars "sort themselves out" into their respective lanes; problems with pursuing toll evaders; need, in at least some current (barrier) systems, to confine vehicles in lanes, while interacting with the collection devices, and the dangers of high-speed collisions with the confinement structures; vehicle hazards to toll employees present in some electronic-collection areas; the fact that in some areas at some times, long lines form even to pass through the electronic-collection lanes; and costs and other issues raised when retrofitting existing toll collection facilities. Unionized toll collectors can also be problematic.
Even if line lengths are the same in electronic lanes as in manual ones, electronic tolls save registered cars time: eliminating the stop at a window or toll machine, between successive cars passing the collection machine, means a fixed-length stretch of their journey past it is traveled at a higher average speed, and in a lower time. This is at least a psychological improvement, even if the length of the lines in automated lanes is sufficient to make the no-stop-to-pay savings insignificant compared to time still lost due waiting in line to pass the toll gate. Toll plazas are typically wider than the rest of the highway; reducing the need for them makes it possible to fit toll roads into tight corridors.
Despite these limitations, however, it is important to recognize that throughput increases if delay at the toll gate is reduced (i.e., if the tollbooth can serve more vehicles per hour). The greater the throughput of any toll lane, the fewer lanes required, so expensive construction can be deferred. Specifically, the toll-collecting authorities have incentives to resist pressure to limit the fraction of electronic lanes in order to limit the length of manual-lane lines. In the short term, the greater the fraction of automated lanes, the lower the cost of operation (once the capital costs of automating are amortized). In the long term, the greater the relative advantage that registering and turning one's vehicle into an electronic-toll one provides, the faster cars will be converted from manual-toll use to electronic-toll use, and therefore the fewer manual-toll cars will drag down average speed and thus capacity.
In some countries, some toll agencies that use similar technology have set up (or are setting up) reciprocity arrangements, which permit one to drive a vehicle on another operator's tolled road with the tolls incurred charged to the driver's toll-payment account with their home operator. An example is the United States E-ZPass tag, which is accepted on toll roads, bridges and tunnels in fourteen states from Illinois to Maine.
In Australia, the e-TAG device is accepted at all tolled motorways. A toll is debited to the customer's account with their tag provider. Some toll road operators – including Sydney's Sydney Harbour Tunnel, Lane Cove Tunnel, and Westlink M7, Melbourne's CityLink and Eastlink, and Brisbane's Gateway Motorway – encourage use of such tags, and apply an additional vehicle matching fee to vehicles without a tag.
A similar device in France, called Liber-T for light vehicles and TIS-PL for HGVs, is accepted on all toll roads in the country.
In Brazil, Sem Parar/Via-Fácil allows customers to utilize in more than 1,000 lanes in the states of São Paulo, Parana, Rio Grande do Sul, Santa Catarina, Bahia and Rio de Janeiro. Sem Parar/Via-Fácil also allows users to enter and exit more than 100 parking lots. There is also other systems such as via expressa, onda livre,auto expresso that is present in the states of Rio de Janeiro, Rio Grande do Sul, Santa Catarina, Parana and Minas Gerais.
In Pakistan, the National Database and Registration Authority is implementing an electronic toll collection system on motorways using RFID.
The European Union has created the EFC-directive, which attempts to standardize European toll collection systems. Systems deployed after 1 January 2007 must support at least one of the following technologies: satellite positioning, mobile communications using the GSM-GPRS standard or 5.8 GHz microwave technology. All toll roads in Ireland must support the eToll tag standard.
Use in urban areas and for congestion pricing
The most revolutionary application of ETC is in the urban context of congested cities, allowing to charge tolls without vehicles having to slow down. This application made feasible to concession to the private sector the construction and operation of urban freeways, as well as the introduction or improvement of congestion pricing, as a policy to restrict auto travel in downtown areas.
Between 2004 and 2005, Santiago, Chile implemented the world's first 100% full speed electronic tolling with transponders crossing through the city's core (CBD) in a system of several concessioned urban freeways (Autopista Central and Autopista Costanera Norte). The United Arab Emirates implemented in 2007 a similar road toll collection in Dubai, called Salik. Similar schemes were previously implemented but only on bypass or outer ring urban freeways in several cities around the world: Toronto in 1997 (Highway 407), several roads in Norway (AutoPASS), Melbourne in 2000 (CityLink), and Tel Aviv also in 2000 (Highway 6).
Congestion pricing or urban toll schemes were implemented to enter the downtown area using ETC technology and/or cameras and video recognition technology to get the plate numbers in several cities around the world: urban tolling in Norway's three major cities: Bergen (1986), Oslo (1990), and Trondheim (1991) (see Trondheim Toll Scheme); Singapore in 1998 (see Singapore’s Electronic Road Pricing), as an upgrade to the world's first successful congestion pricing scheme implemented with manual control in 1975 (see also Singapore's Area Licensing Scheme); Rome in 2001 as an upgrade to the manual zone control system implemented in 1998; London in 2003 and extended in 2007 (see London congestion charge); Stockholm, tested in 2006 and made the charge permanent in 2007 (see Stockholm congestion tax); and in Valletta, the capital city of Malta, since May 2007.
In January 2008, Milan began a one-year trial program called Ecopass, a traffic charge program in which low-emission-standard vehicles pay a user fee; alternative fuel vehicles and vehicles using conventional fuels but compliant with the Euro IV emission standard are exempted. The program is in effect until December 31, 2009, and a public consultation will be conducted to decide if the charge becomes permanent.
New York City considered the implementation of a congestion pricing scheme. The proposal was approved by the New York City Council on March 31, 2008, however, on April 7, 2008 the New York State Assembly decided not to vote on the proposal, which means that the plan is stalled. (see New York congestion pricing)
In 2006, San Francisco transport authorities began a comprehensive study to evaluate the feasibility of introducing congestion pricing. The charge would be combined with other traffic reduction implementations, allowing money to be raised for public transit improvements and bike and pedestrian enhancements. The various pricing scenarios considered were presented in public meetings in December 2008, with final study results expected in 2009.
Electronic toll collection systems rely on four major components: automated vehicle identification, automated vehicle classification, transaction processing, and violation enforcement.
The four components are somewhat independent, and, in fact, some toll agencies have contracted out functions separately. In some cases, this division of functions has resulted in difficulties. In one notable example, the New Jersey E-ZPass regional consortium's Violation Enforcement contractor did not have access to the Transaction Processing contractor's database of customers. This, together with installation problems in the automated vehicle identification system, led to many customers receiving erroneous violation notices, and a violation system whose net income, after expenses, was negative, as well as customer dissatisfaction.
Automated vehicle identification
Automated vehicle identification (AVI) is the process of determining the identity of a vehicle subject to tolls. The majority of toll facilities record the passage of vehicles through a limited number of toll gates. At such facilities, the task is then to identify the vehicle in the gate area.
Some early AVI systems used barcodes affixed to each vehicle, to be read optically at the toll booth. Optical systems proved to have poor reading reliability, especially when faced with inclement weather and dirty vehicles.
Most current AVI systems rely on radio-frequency identification, where an antenna at the toll gate communicates with a transponder on the vehicle via Dedicated Short Range Communications (DSRC). RFID tags have proved to have excellent accuracy, and can be read at highway speeds. The major disadvantage is the cost of equipping each vehicle with a transponder, which can be a major start-up expense, if paid by the toll agency, or a strong customer deterrent, if paid by the customer.
To avoid the need for transponders, some systems, notably the 407 ETR (Electronic Toll Route) near Toronto, use automatic number plate recognition. Here, a system of cameras captures images of vehicles passing through tolled areas, and the image of the number plate is extracted and used to identify the vehicle. This allows customers to use the facility without any advance interaction with the toll agency. The disadvantage is that fully automatic recognition has a significant error rate, leading to billing errors and the cost of transaction processing (which requires locating and corresponding with the customer) can be significant. Systems that incorporate a manual review stage have much lower error rates, but require a continuing staffing expense.
A few toll facilities cover a very wide area, making fixed toll gates impractical. The most notable of these is a truck tolling system in Germany. This system instead uses Global Positioning System location information to identify when a vehicle is located on a tolled Autobahn. Implementation of this system turned out to be far lengthier and more costly than expected.
As smart phone use becomes more commonplace, some toll road management companies have turned to mobile phone apps to inexpensively automate and expedite paying tolls from the lanes. One such example application is Alabama Freedom Pass mobile, used to link customer accounts at sites operated by American Roads LLC. The app communicates in real time with the facility transaction processing system to identify and debit customer accounts or bill a major credit card.
Automated vehicle classification
Automated vehicle classification is closely related to automated vehicle identification (AVI). Most toll facilities charge different rates for different types of vehicles, making it necessary to distinguish the vehicles passing through the toll facility.
The simplest method is to store the vehicle class in the customer record, and use the AVI data to look up the vehicle class. This is low-cost, but limits user flexibility, in such cases as the automobile owner who occasionally tows a trailer.
More complex systems use a variety of sensors. Inductive sensors embedded in the road surface can determine the gaps between vehicles, to provide basic information on the presence of a vehicle. Treadles permit counting the number of axles as a vehicle passes over them and, with offset-treadle installations, also detect dual-tire vehicles. Light-curtain laser profilers record the shape of the vehicle, which can help distinguish trucks and trailers.
Transaction processing deals with maintaining customer accounts, posting toll transactions and customer payments to the accounts, and handling customer inquiries. The transaction processing component of some systems is referred to as a "customer service center". In many respects, the transaction processing function resembles banking, and several toll agencies have contracted out transaction processing to a bank.
Customer accounts may be postpaid, where toll transactions are periodically billed to the customer, or prepaid, where the customer funds a balance in the account which is then depleted as toll transactions occur. The prepaid system is more common, as the small amounts of most tolls makes pursuit of uncollected debts uneconomic. Most postpaid accounts deal with this issue by requiring a security deposit, effectively rendering the account a prepaid one.
A violation enforcement system (VES) is useful in reducing unpaid tolls, as an unmanned toll gate otherwise represents a tempting target for toll evasion. Several methods can be used to deter toll violators.
Police patrols at toll gates can be highly effective. In addition, in most jurisdictions, the legal framework is already in place for punishing toll evasion as a traffic infraction. However, the expense of police patrols makes their use on a continuous basis impractical, such that the probability of being stopped is likely to be low enough as to be an insufficient deterrent.
A physical barrier, such as a gate arm, ensures that all vehicles passing through the toll booth have paid a toll. Violators are identified immediately, as the barrier will not permit the violator to proceed. However, barriers also force authorized customers, which are the vast majority of vehicles passing through, to slow to a near-stop at the toll gate, negating much of the speed and capacity benefits of electronic tolling.
Automatic number plate recognition, while rarely used as the primary vehicle identification method, is more commonly used in violation enforcement. In the VES context, the number of images collected is much smaller than in the AVI context. This makes manual review, with its greater accuracy over fully automated methods, practical. However, many jurisdictions require legislative action to permit this type of enforcement, as the number plate identifies only the vehicle, not its operator, and many traffic enforcement regulations require identifying the operator in order to issue an infraction.
An example of this is the vToll system on the Illinois Tollway, which requires transponder users to enter their license plate information before using the system. If the transponder fails to read, the license plate number is matched to the transponder account, and the regular toll amount is deducted from the account rather than a violation being generated. If the license plate can't be found in the database, then it is processed as a violation. An interesting aspect of Illinois' toll violation system is a 7 day grace period, allowing tollway users to pay missed tolls online with no penalty the 7 days following the missed toll.
Electronic toll collection can be a threat to location privacy. Many implementations are implemented in a privacy-insensitive manner. Using E-Cash and other modern cryptographic methods, it is possible to design systems that do not know where individuals are, but are still able to enforce fares.
- List of electronic toll collection systems
- Congestion pricing
- GNSS Road Pricing
- Open road tolling
- ^ Kelly, Frank (2006): Road Pricing: Addressing congestion, pollution and the financing of Britain’s road. Published in “Ingenia” by The Royal Academy of Engineering, volume 39, p. 36-42.
- ^ Roth, Gabriel (1996): Roads in a Market Economy, in: Jordi, Philipp (2008): "Institutional Aspects of Directive 2004/52/EC on the Interoperability of Electronic Road Toll Systems in the Community." Europainstitut der Universität Basel.
- ^ a b National Center for Policy Analysis (November 6, 2007). Life in the Slow Lane.
- ^ Directive 2004/52 with amendments, see also procedure file COD/2003/0081 with the European Parliament
- ^ http://www.vtpi.org/vickrey.htm Principles of Efficient Congestion Pricing
- ^ http://www.salik.ae/english/ Official Website of the Salik scheme
- ^ http://www.piarc.org/exec/link/library/download.htm?site=fr&objectId=853
- ^ http://www.move-forum.net/documenti/B_06032003170931.pdf Road pricing Singapore's experience
- ^ UK Commission for Integrated Transport | Road User Charging Worldwide
- ^ Rome (Italy)
- ^ Controlled Vehicular Access, CVA Technology, 1 May 2007.
- ^ Valletta traffic congestion considerably reduced [ MaltaMedia.com ]
- ^ Ken Belson (2008-01-27). "Toll Discounts for Going Green". The New York Times. http://www.nytimes.com/2008/01/27/automobiles/27GREEN.html. Retrieved 2008-01-27.
- ^ BBC News (2008-03-02). "Milan introduces traffic charge". http://news.bbc.co.uk/2/hi/europe/7167992.stm. Retrieved 2008-01-17.
- ^ Marco Bertacche (2008-01-03). "Milan Introduces Congestion Charge To Cut Pollution". The New York Sun. http://www.nysun.com/foreign/milan-introduces-congestion-charge-to-cut/68854/. Retrieved 2008-01-17.
- ^ Richard Owen (2008-01-03). "Congestion fee leaves Milan in a jam". London: Times Online. http://www.timesonline.co.uk/tol/news/world/europe/article3123679.ece. Retrieved 2008-04-16.
- ^ Edoardo Croci (2008-12-31). "Ecopass. Prorogato fino al 31 dicembre 2009. Nei primi mesi dell’anno prevista la consultazione dei cittadini" (in Italian). Comune di Milano. http://www.comune.milano.it/dseserver/webcity/comunicati.nsf/weball/077F561DB4A21D98C125752F004CDE33. Retrieved 2009-02-14. The complete pricing scheme is presented in this article.
- ^ http://www.nyc.gov/html/planyc2030/downloads/pdf/report_transportation.pdf
- ^ Transportation Alternatives: Sensible Transportation: Congestion Pricing
- ^ Gross, Daniel (2007-02-11). "What's the Toll? It Depends on the Time of Day". The New York Times. http://www.nytimes.com/2007/02/11/business/yourmoney/11view.html?_r=2&oref=slogin&oref=slogin. Retrieved 2010-05-01.
- ^ Diane Cardwell (2008-04-01). "City Council Approves Fee to Drive Below 60th". The New York Times. http://www.nytimes.com/2008/04/01/nyregion/01congestion.html?ref=nyregion. Retrieved 2008-04-01.
- ^ Ken Belson (2008-03-16). "Importing a Decongestant for Midtown Streets". The New York Times. http://www.nytimes.com/2008/03/16/automobiles/16CONGEST.html. Retrieved 2008-03-18.
- ^ Nicholas Confessore (2008-04-07). "Congestion Pricing Plan Is Dead, Assembly Speaker Says". The New York Times. http://cityroom.blogs.nytimes.com/2008/04/07/congestion-pricing-plan-is-dead-assembly-speaker-says/index.html?hp. Retrieved 2008-04-07.
- ^ Rachael Gordon (2007-09-19). "S.F. studying congestion pricing to ease traffic, promote transit". San Francisco Chronicle. http://www.sfgate.com/cgi-bin/article.cgi?f=/c/a/2007/09/19/MNKJS8LM4.DTL. Retrieved 2008-07-15.
- ^ Malia Wollan (2009-01-04). "San Francisco Studies Fees to Ease Traffic". The New York Times. http://www.nytimes.com/2009/01/04/us/04congestion.html. Retrieved 2009-02-22.
- ^ http://www.illinoistollway.com
- ^ http://www.illinoistollway.com/portal/page?_pageid=133,1392898&_dad=portal&_schema=PORTAL
- ^ http://www.illinoistollway.com/portal/page?_pageid=133,2008701&_dad=portal&_schema=PORTAL
- ^ Andrew J. Blumberg; Peter Eckersley[disambiguation needed ] (August 2009). "On Locational Privacy, and How to Avoid Losing it Forever". EFF. http://www.eff.org/wp/locational-privacy.
- ^ Josep Balasch (October 2010). "Privacy-Preserving Road Charging". Katholieke Universiteit Leuven. http://cosic.esat.kuleuven.be/road_charging/.
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