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Arterial Management Systems |
 Arterial management systems manage traffic along arterial
roadways,employing traffic detectors, traffic signals, and various means
of communicating information to travelers. |
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| Benefits | |
 To improve air quality in downtown Syracuse and Onondaga
County, the New York State Department of Transportation (NYSDOT) installed
a computerized traffic signal system and optimized the signal timing of
145 intersections. The project resulted in a reduction of total delay
experienced by vehicles during the a.m.–peak, mid–day, and p.m.–peak periods
by 14–19%. |
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Freeway Management Systems |
 Freeway management systems employ traffic detectors, surveillance
cameras, and other means of monitoring traffic flow on freeways to support
the implementation of traffic management strategies such as ramp meters,
lane closures, and variable speed limits. These sensors can alSo be used
to monitor critical transportation infrastructure for security purposes. |
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| Benefits | |
 Mail–back questionnaires were sent to 428
drivers living near major freeways in Wisconsin to assess the impacts
of posting travel time and traffic information on dynamic message signs
throughout the state. A total of 221 questionnaires were returned and
analyzed. The results indicated that 12% of respondents used the information
more than five times per month to adjust travel routes during winter months,
and 18% of respondents used the information more than five times per month
to adjust travel routes during non–winter months. |
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Transit Management Systems |
Transit ITS services include surveillance and communications, such as
automated vehicle location (AVL) systems, computer–aided dispatch (CAD)
systems, and remote vehicle and facility surveillance cameras, which enable
transit agencies to improve the operational efficiency, safety, and security
of the nation's public transportation systems. Public access to bus location
data and schedule status information is increasingly popular on transit
Internet websites and at bus stops. |
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| Benefits | |
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At the Acadia National Park in Maine, electronic message signs were installed
to inform visitors of updated bus arrival and departure times at three
popular visitor destinations. A survey of park visitors who used the signage
found that 90% indicated transit information signs made it easier to get
around. |
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Incident Management Systems |
Incident management systems can reduce the effects of incident–related
congestion by decreasing the time to detect incidents, the time for responding
vehicles to arrive, and the time required for traffic to return to normal
conditions. Incident management systems make use of a variety of surveillance
technologies, often shared with freeway and arterial management systems,
as well as enhanced communications and other technologies that facilitate
coordinated response to incidents. |
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| Benefits | |
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Delay savings identified in studies of freeway service patrols implemented
in Minneapolis–St. Paul, Minnesota; Denver, Colorado; and Northwest Indiana
documented annual benefits of $1.2 to $1.8 million, through reductions
in the duration of incidents, and related congestion. |
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Emergency Management Systems |
ITS applications in emergency management include hazardous materials management,
the deployment of emergency medical services, and large– and small–scale
emergency response and evacuation operations. |
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| Benefits | |
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The Life Link project in San Antonio, Texas, enabled emergency room doctors
to communicate with emergency medical technicians (EMTs) using two–way
video, audio, and data communications. EMTs and doctors had mixed opinions
about the system; however, it was expected that this technology would
have more positive impacts in rural areas. |
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Electronic Payment Systems |
Electronic payment systems employ various communication and electronic
technologies to facilitate commerce between travelers and transportation
agencies, typically for the purpose of paying tolls, transit fares, and
parking fees. |
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| Benefits | |
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Three projects in Europe demonstrated the coordinated use of a smart card
as a payment system for public transit, shops, libraries, swimming pools,
and other city services. User acceptance and satisfaction with these systems
was very high, ranging from 71–87%. |
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Traveler Information |
 Traveler
information applications use a variety of technologies, including Internet
websites, instant messaging, telephones, satellite radio, and local television
and radio, to allow users to make more informed decisions regarding trip
departures, routes, and mode of travel. Ongoing implementation of the
designated 511 telephone number will improve access to traveler information
across the country. |
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| Benefits | |
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In Montana, 81% of survey respondents were satisfied or very satisfied
with road conditions information available through a 511 telephone service
provided by the Greater Yellowstone Regional Traveler and Weather Information
System (GYRTWIS ). 14 In Virgimia, 90% of users who agreed to participate
in a follow–up telephone survey found the 511 service deployed there useful,
and nearly half of them indicated they had changed their travel plans
on at least one occasion as a result of the information provided. |
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Information Management |
ITS information management supports the archiving and retrieval of data
generated by other ITS applications and assists in analysis functions
that benefit transportation administration, policy evaluation, safety,
planning, program assessment, operations research, and other applications.
Data archiving systems are scalable to support a single agency's operations
center and to support multiple agencies through regional data warehouses.
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| Benefits | |
| No data to report. |
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Roadway Operations and Maintenance |
ITS applications in operations and maintenance focus on integrated management
of maintenance fleets, specialized service vehicles, hazardous road conditions
remediation, and work zone mobility and safety. These applications monitor,
analyze, and disseminate roadway and infrastructure data for operational,
maintenance, and managerial uses. ITS can help secure the safety of workers
and travelers in a work zone while facilitating traffic flow through and
around the construction area. This is often achieved through the temporary
deployment of other ITS services, such as elements of traffic management
and incident management programs. |
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| Benefits | |
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Average clearance times for incidents were reduced 44% with the implementation
of motorist assistance patrols and a temporary traffic management center
during a construction project at the "Big I" interchange in Albuquerque,
New Mexico. During weekday operations, the Highway Department allocated
two courtesy patrol units to patrol the construction zone between 5 a.m.
and 8 p.m. and a wrecker was on–call from 6 a.m. to 6 p.m. |
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Road Weather Management |
Road weather management activities include road weather information systems
(RWIS), winter maintenance technologies, and coordination of operations
within and between state DOTs. ITS applications assist with the monitoring
and forecasting of roadway and atmospheric conditions, dissemination of
weather–related information to travelers, weather–related traffic control
measures such as variable speed limits, and both fixed and mobile winter
maintenance activities. |
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| Benefits | |
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The Washington State Department of Transportation (WSDOT) installed a
system in the rural and mountainous region of Spokane to collect and communicate
weather and road conditions, border crossing status, and other information
to commercial drivers, the motoring public, and WSDOT maintenance crews.
Ninety–four percent of surveyed users of a road weather information website
covering roadways in Washington state agree that the weather information
made travelers better prepared for their trips. More than half of the
respondents (56 percent) agreed the information helped them avoid travel
delays. |
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Commercial Vehicle Operations |
ITS applications for commercial vehicle operations are designed to enhance
communication between motor carriers and regulatory agencies. Examples
include electronic registration and permitting programs, electronic exchange
of inspection data between regulating agencies for better inspection targeting,
electronic screening systems, and several applications to assist operators
with fleet operations and security. |
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| Benefits | |
Three motor carriers surveyed during the Commercial Vehicle Information
System and Network (CVISN) model deployment initiative indicated that
electronic credentialing reduced paperwork and saved them 60 to 75% on
credentialing costs. In addition, motor carriers were able to commission
new vehicles 60% faster by printing their own credential paperwork and
not waiting for conventional mail delivery. |
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Intermodal Freight |
ITS can facilitate the safe, efficient, secure, and seamless movement
of freight. Applications being deployed provide for tracking of freight
and carrier assets such as containers and chassis, and improve the efficiency
of freight terminal processes, drayage operations, and international border
crossings. |
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| Benefits | |
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An electronic supply chain manifest system implemented biometric and smartcard
devices to automate manual paper–based cargo data transfers between manufacturers,
carriers, and airports in Chicago, Illinois, and New York, New York. Although
participation was limited, the system was expected to improve efficiency.
The time required for truckers to accept cargo from manufacturers decreased
by about four minutes per shipment, and the time required for airports
to accept the deliveries decreased by about three minutes per shipment.
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Vehicle Technology Applications
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Collision Avoidance Systems |
To improve the ability of drivers to avoid accidents, vehicle–mounted
collision avoidance systems continue to be tested and deployed. These
applications use a variety of sensors to monitor the vehicle's surroundings
and alert the driver of conditions that could lead to a collision. Examples
include forward collision warning, obstacle detection systems, and road
departure warning systems. |
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| Benefits | |
A National Highway Traffic Safety Administration (NHTSA) modeling study
indicated collision warning systems would be effective in 42% of rear–end
crash situations where the lead vehicle was decelerating, and effective
in 75% of rear–end crashes where the lead vehicle was not moving. Overall,
collision warning systems would be 51% effective. |
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Driver Assistance Systems |
Numerous intelligent vehicle technologies exist to assist the driver in
operating the vehicle safely. Systems are available to aid with navigation,
while others, such as vision enhancement, adaptive cruise control, and
speed control systems, are intended to facilitate safe driving during
adverse conditions. Other systems assist with difficult driving tasks
such as transit and commercial vehicle docking. |
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| Benefits | |
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Ten vehicles were equipped with adaptive cruise control, including automatic
throttle modulation and down shifting (but not braking) to maintain preset
headways during a NHTSA field test. The performance of the system was
compared to conventional cruise control and manually operated vehicles.
Results indicated that vehicles equipped with adaptive cruise control
made the fewest number of risky lane changes in response to slower traffic.
Manually operated vehicles, however, had the quickest average response
time to lead vehicle brake lights. Participants overwhelmingly ranked
adaptive cruise control over the manual and conventional cruise control–equipped
vehicles for convenience, comfort, and enjoyment, and indicated they would
most likely use the system on freeways. |
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Collision Notification Systems |
In an effort to improve response times and save lives, collision notification
systems have been designed to detect and report the location and severity
of incidents to agencies and services responsible for coordinating appropriate
emergency response actions. These systems can be activated manually (Mayday),
or automatically with automatic collision notification (ACN), and advanced
systems may transmit information on the type of crash, number of passengers,
and the likelihood of injuries. |
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| Benefits | |
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Between July 1997 and August 2000, the impacts of advanced ACN on incident
notification were tracked for vehicles with and without ACN systems in
urban and suburban areas of Erie County, New York. Based on a limited
number of crash events, the average notification time for vehicles equipped
with ACN was less than one minute with some notification times as long
as two minutes, and the average notification time for vehicles without
ACN was about three minutes, with some notification times as long as 9,
12, 30, and 46 minutes. |