Universal incident detection :

Zhang, Kun.

Unknown Date

Road incidents and incident induced traffic congestions are a big threat to the mobility and safety of our daily life. Timely and accurate incident detection using automated incident detection (AID) systems is essential to effectively tackle incident induced congestion problems and to improve traffic management. The core of an AID system is an incident detection algorithm that interprets real time traffic data and makes decision on incidents. / Literature review of existing AID algorithms and their applications reveals that 1) there is no single freeway algorithm that can fulfil the universality aspect of incident detection which is required by the advanced traffic management systems, and 2) how to achieve the effective and stable arterial road incident detection remains a big issue of AID research. In addition, there exists a strong need for incorporating existing expert traffic knowledge into AID algorithms to enhance incident detection performance. / Thesis (PhDTransportSystemsEngineering)--University of South Australia, 2005.

Traffic congestion

Electronic traffic controls

Intelligent Vehicle Highway Systems.

Traffic flow

Bayesian statistical decision theory.

Advanced motion control and sensing for intelligent vehicles

Li, Li, Wang, Fei-Yue.

January 2007

Mainly based on Li Li's Ph. D. dissertation: University of Arizona, Tucson, 2005. / Includes bibliographical references and index.

Methodologies for integrating traffic flow theory, ITS and evolving surveillance technologies /

Nam, Do H.,

January 1995

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1995. / Vita. Abstract. Includes bibliographical references (leaves 137-140). Also available via the Internet.

Applications of vehicle location and communication technology in fleet management systems

Wong, Chi-tak, Keith.

January 2001

Thesis (M.A.)--University of Hong Kong, 2001. / Includes bibliographical references (leaves 62). Also available in print.

Incident detection on arterials using neural network data fusion of simulated probe vehicle and loop detector data /

Thomas, Kim.

January 2005

Thesis (M.Phil.) - University of Queensland, 2005. / Includes bibliography.

A wireless sensor network for smart roadbeds and intelligent transportation systems /

Knaian, Ara N.

January 1900

Thesis (Master of Engineering in Electrical Engineering and Computer Science)--Massachusetts Institute of Technology, 2000. / Cover title. Also available online via the MIT website (www.media.mit.edu). Includes bibliographical references (leaves 36-38).

Effectiveness of the Statewide Deployment and Integration of Advanced Traveler Information Systems

Belz, Nathan P.

January 2008

No description available.

Highway communications -- Maine

Traffic flow -- Maine

Development of a public transit information system using GIS and ITS technologies /

Riley, Sarah J.

January 1900

Thesis (M. App. Sc.)--Carleton University, 2002. / Includes bibliographical references (p. 205-210). Also available in electronic format on the Internet.

Extension and Generalization of Newell's Simplified Theory of Kinematic Waves

Ni, Daiheng

19 November 2004

Flow of traffic on freeways and limited access highways can be represented as a series of kinemetic waves. Solutions to these systems of equations become problematic under congested traffic flow conditions, and under complicated (real-world) networks. A simplified theory of kinematics waves was previously proposed. Simplifying elements includes translation of the problem to moving coordinate system, adoption of bi-linear speed-density relationships, and adoption of restrictive constraints at the on- and off-ramps. However, these simplifying assumptions preclude application of this technique to most practical situations. This research explores the limitations of the simplified theory of kinematic waves. First this research documents a relaxation of several key constraints. In the original theory, priority was given to on-ramp merging vehicles so that they can bypass any queue at the merge. This research proposes to relax this constraint using a capacity-based weighted fair queuing (CBWFQ) merge model. In the original theory, downstream queue affects upstream traffic as a whole and exiting traffic can always be able to leave as long as it gets to the diverge. This research proposes that this diverge constraint be replaced with a contribution-based weighted splitting (CBWS) diverge model. This research proposes a revised notation system, permitting the solution techniques to be extended to freeway networks with multiple freeways and their ramps. This research proposes a generalization to permit application of the revised theory to general transportation networks. A generalized CBWFQ merge model and a generalized CBWS diverge model are formulated to deal with merging and diverging traffic. Finally, this research presents computational procedure for solving the new system of equations. Comparisons of model predictions with field observations are conducted on GA 400 in Atlanta. Investigations into the performance of the proposed CBWFQ and CBWS models are conducted. Results are quite encouraging, quantitative measures suggest satisfactory accuracy with narrow confidence interval.

Intelligent transportation systems (ITS)

Freeway

Queuing

Kinematic wave

Traffic simulation

Macroscopic model

Traffic engineering Data processing

Intelligent Vehicle Highway Systems

Kinematics

Traffic engineering Computer programs

Microsimulation of Public Transport Stops for the Optimization of Waiting Times for Users Using the Social Force Model

Mendoza, Francis, Tong, Mayling, Silvera, Manuel, Campos, Fernando

01 January 2021

El texto completo de este trabajo no está disponible en el Repositorio Académico UPC por restricciones de la casa editorial donde ha sido publicado. / Cities in the world aim to ensure the mobility of people, through the implementation of efficient Integrated Transportation Systems (ITS). This aims to improve the transport of people, which guarantees that they can be mobilized safely and without delays in the terminals and bus stops of the public transport system. The present article proposes a design of public transport stops aimed at optimizing the waiting time of users when transferring from one bus to another. For the validity of the proposal, the social force model of the Vissim program was used, where the behavior of the users within the bus stops was reflected. The results showed that the waiting times in the calibrated and validated microsimulation model were optimized by approximately 20%, which generates an improvement in the efficiency of the public transport system. / Revisión por pares

Bus stops

Public transport

Social force model

Transshipment

Bus terminals

Buses

Intelligent vehicle highway systems

Integrated Transportation systems

Microsimulation

Public transport