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Author: Karzan Bahaaldin
Publisher:
ISBN:
Category : Emergency communication systems
Languages : en
Pages : 258
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Book Description
No-notice evacuations of metropolitan areas can place significant demands on transportation infrastructure. In preparation, emergency managers and transportation engineers study potential demands and many create evacuation traffic management plans. The findings from a St. Louis Metro East evacuation study revealed some problematic areas of the transportation network. At these locations the traffic backed up during a simulated evacuation, caused a significant amount of delay, and increased the evacuation clearance time. An emerging paradigm called Connected Vehicle (CV) technology can provide real-time communication between vehicles in a traffic stream. The objectives of this research were to evaluate the impacts of CVs on evacuation from a downtown metropolitan area. The microsimulation software VISSIM was used to model the roadway network and the evacuation traffic. The model was built, calibrated and validated for studying the performance of traffic during the evacuation. This model helped researchers to find the time required to evacuate people in this area for different disaster scenarios. Because it is unlikely that vehicles equipped with CV technologies will become commonplace soon, the researcher tested different levels of deployment, also known as penetration rate. This study included penetration rates from 0 to 30 percent CVs; evaluating the average speed, average and total delays. The findings suggest significant reductions in total delays when CVs reached a penetration rate of 30 percent or greater. Results showed that the presence of CVs at a penetration rate of 30 percent could reduce the overall traffic delay by 60 percent over the evacuation period. A sensitivity analysis was conducted and the finding showed that a 10 percent increase in the penetration rate will significantly improve traffic flow. The findings of this study suggest that the communication capabilities of CVs can reduce delays and improve the traffic flow rate during a no-notice evacuation. Additionally, the benefits could be greater for evacuations with higher volumes, evacuations that last longer, and evacuations with higher proportions of CVs in the vehicle stream.
Author: Karzan Bahaaldin
Publisher:
ISBN:
Category : Emergency communication systems
Languages : en
Pages : 258
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Book Description
No-notice evacuations of metropolitan areas can place significant demands on transportation infrastructure. In preparation, emergency managers and transportation engineers study potential demands and many create evacuation traffic management plans. The findings from a St. Louis Metro East evacuation study revealed some problematic areas of the transportation network. At these locations the traffic backed up during a simulated evacuation, caused a significant amount of delay, and increased the evacuation clearance time. An emerging paradigm called Connected Vehicle (CV) technology can provide real-time communication between vehicles in a traffic stream. The objectives of this research were to evaluate the impacts of CVs on evacuation from a downtown metropolitan area. The microsimulation software VISSIM was used to model the roadway network and the evacuation traffic. The model was built, calibrated and validated for studying the performance of traffic during the evacuation. This model helped researchers to find the time required to evacuate people in this area for different disaster scenarios. Because it is unlikely that vehicles equipped with CV technologies will become commonplace soon, the researcher tested different levels of deployment, also known as penetration rate. This study included penetration rates from 0 to 30 percent CVs; evaluating the average speed, average and total delays. The findings suggest significant reductions in total delays when CVs reached a penetration rate of 30 percent or greater. Results showed that the presence of CVs at a penetration rate of 30 percent could reduce the overall traffic delay by 60 percent over the evacuation period. A sensitivity analysis was conducted and the finding showed that a 10 percent increase in the penetration rate will significantly improve traffic flow. The findings of this study suggest that the communication capabilities of CVs can reduce delays and improve the traffic flow rate during a no-notice evacuation. Additionally, the benefits could be greater for evacuations with higher volumes, evacuations that last longer, and evacuations with higher proportions of CVs in the vehicle stream.
Author: Chuang Chen
Publisher:
ISBN:
Category :
Languages : en
Pages : 48
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Book Description
Author: Lishengsa Yue
Publisher:
ISBN:
Category :
Languages : en
Pages : 240
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Book Description
Finally, this study conducted a Monte-Carlo simulation and identified the parameters of ADAS-CV that may achieve the maximum safety effectiveness in different pre-crash scenarios.
Author: Arash Khoda Bakhshi
Publisher:
ISBN:
Category : Interstate 80
Languages : en
Pages : 342
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Book Description
Traffic crashes impose a significant socio-economic cost on societies. According to the World Health Organization (WHO), 1.2 million people die every year, and more than 50 million people are injured due to fatal and non-fatal crashes globally. Safety concerns are more serious on rural corridors that play crucial roles in freight movement, such as Interstate 80 (I-80) in the State of Wyoming. Being affected by Wyoming’s adverse weather conditions, high altitude, challenging geometric characteristics, and critical traffic composition, there has been a notable crash and critical crash rate on 402-miles of this major freight corridor in Wyoming. To alleviate these safety concerns, the United States Department of Transportation Federal Highway Administration (USDOT FHWA) selected the Wyoming Department of Transportation (WYDOT) to deploy a Connected Vehicle (CV) Pilot Program along I-80 in Wyoming (WYDOT CV Pilot). The WYDOT CV Pilot focuses on the needs of the commercial vehicle operator and will develop CV applications to support a flexible range of services under Vehicular Ad-hoc Network (VANET), including roadside alerts, parking notifications, and dynamic travel guidance. In this regard, evaluation of the safety impacts of the CV Pilot is central to the USDOT’s strategic goals. The literature pointed out that the Market Penetration Rate (MPR) of CVs should be large enough to ensure safety and operational benefits of CVs. However, at early stages of the WYDOT CV Pilot, CVs will be contributing to a small fraction of the entire traffic stream, challenging traditional safety performance evaluation methodologies to assess the effectiveness of the CV technology. With these concerns, a comprehensive Analysis, Modeling, and Simulation (AMS) framework in addition to reliable baseline Analyses are required to scrutinize the safety performance of CVs under various MPR. These requirements have been fulfilled in this research through the use of advanced statistical modeling, Machine Learning, Deep Learning, data mining techniques, data visualization, and taking practical advantages of simulation- and driving simulator-based analyses. In the developed baseline and under the concept of Real-Time Risk Assessment (RTRA), significant real-time traffic-related variables contributing to crash and critical crash occurrences on the 402-miles I-80 in Wyoming during CV pre-deployment were identified. Using advanced statistical modeling and data visualization tools provided by Machine Learning techniques, the causal effect of these significant factors on the crash/ critical crash probabilities were explored. These causations are expected to be affected due to CV technology under notable MPRs in the future. Accordingly, the conducted baseline will be used as a benchmark against explored crash causations during CV post-deployment to grasp how this technology alleviates or changes the causality patterns, revealing the WYDOT CV Pilot safety performance. Furthermore, based on the preprocessed real-time traffic observation from the RTRA, the research calibrated and validated a reliable AMS framework to assess the safety effectiveness of the WYDOT CV Pilot that mainly goes around level-0 and level-1 of automated driving systems. At these levels, drivers are in charge of the execution of steering, acceleration/deceleration, and monitoring of the driving environment; thus, the human factor contributing to more than 90% of traffic crashes is still in that safety loop. Having said that, the AMS framework primarily aims to show how various CV applications, designed under WYDOT CV Pilot, would alter CV drivers’ behavior under traffic critical safety events and measure the effect of this alteration on I-80 traffic safety performance. Accordingly, drivers' behavioral alterations due to CV notification were quantified under the concept of with/without analysis and in a series of comprehensive high-fidelity driving simulator experiments conducted at the University of Wyoming Driving Simulator Lab (WyoSafeSim). These quantifications were analyzed separately and were conflated with traffic microsimulation modeling to reveal the safety effects of CV technology on the I-80 traffic stream under varying CV MPRs. This dissertation's findings and insights would be of interest to the WYDOT, the USDOT FHWA, and practitioners in the safety domain. The provided crowd-sourced real-time traffic dataset in the conducted baseline would help the WYDOT in understanding the current safety performance of I-80, identifying black-spot points in high-risk I-80 segments, and developing proactive countermeasures and interventions for Active Traffic Management (ATM) to alleviate the risk of traffic crashes on this major freight corridor. The data-driven crowdsourcing procedure performed on the AMS framework would shed some light on realizing the impact of CV technology on enhancing drivers’ situational awareness and minimizing the rate of motor vehicle crashes, which is not limited to I-80 in Wyoming. The integration of a high-fidelity driving simulator with traffic microsimulation modeling, as a two-pronged approach applied in the AMS framework, would show a fruitful pathway for the safety performance assessment of other CV pilots deployed by the FHWA with small CV MPRs at early deployment stages. Besides, beyond the main scope of assessing CV applications designed for WYDOT CV Pilot, the developed AMS framework could be utilized to evaluate the safety effect of other CV applications, such as the application of CV Variable Speed Limit (VSL) on lengthy rural corridors for the sake of spatiotemporal speed harmonization. The developed Road Weather Connected Vehicle Applications AMS framework was further extended by incorporating driver behavior and performance in adverse weather conditions utilizing a comprehensive Naturalistic Driving Study (NDS) dataset from the second Strategic Highway Research Program (SHRP2). The developed AMS framework could be helpful for a wide array of safety and operations of the next generation active traffic management.
Author: Md Hasibur Rahman
Publisher:
ISBN:
Category :
Languages : en
Pages : 189
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Book Description
Furthermore, the study considered the performance of different communication system along with the traffic condition by utilizing Dedicated Short-Range Communications (DSRC or IEEE 802.11p) and wireless access (IEEE 1609 protocol) for the application of vehicle ad-hoc network (VANET). To this end, the study evaluated the safety effectiveness of different communication protocols under the CAV environment. Aimsun Next and SUMO & OMNET++ based Veins simulator were used as the simulation platform. Different car-following models, signal control algorithm, and communication systems were coded by using the application programming interface (API) and C++ language. For the traffic efficiency, the study utilized travel time and travel time rate (TTR) while for the safety evaluation, different surrogate safety measures; speed, and crash-risk models were used. Also, several statistical tests (e.g., t-test, ANOVA) and modeling techniques (e.g., generalized estimating equation, logistic regression, etc.) were developed to analyze both safety and mobility. The results of this study implied that CAV could improve both safety and efficiency at the network level with different MPRs. Also, CAV is more efficient compared to the only AV in terms of both traffic safety and mobility. Different communication protocols have a significant effect on traffic safety under the CAV environment. Finally, the results of this study provide insight to transportation planners and the decision makers about the benefits of CAV at the network level, different CAV technologies, and the performance of different communication systems under the CAV environment.
Author: John Renne
Publisher: Elsevier
ISBN: 0128173068
Category : Transportation
Languages : en
Pages : 234
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Book Description
Creating Resilient Transportation Systems: Policy, Planning and Implementation demonstrates how the transportation sector is a leading producer of carbon emissions that result in climate change and extreme weather disruptions and disasters. In the book, Renne, Wolshon, Murray-Tuite, Pande and Kim demonstrate how to minimize the transportation impacts associated with these urban disasters, with an ultimate goal of returning them to at least status quo in the shortest feasible time. Assesses the short and long-term impacts of transportation systems on the natural environment at local, regional and global scales Examines transportation systems in relation to risk, vulnerability, adaptation, mitigation, sustainability, climate change and livability Shows how urban transportation investments in transit, walking and bicycling result in significantly lower per capita carbon emissions when compared to investing in sprawling, automobile dependent regions
Author: Michael K. Lindell
Publisher: CRC Press
ISBN: 1351645323
Category : Political Science
Languages : en
Pages : 346
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Book Description
Large-Scale Evacuation introduces the reader to the steps involved in evacuation modelling for towns and cities, from understanding the hazards that can require large-scale evacuations, through understanding how local officials decide to issue evacuation advisories and households decide whether to comply, to transportation simulation and traffic management strategies. The author team has been recognized internationally for their research and consulting experience in the field of evacuations. Collectively, they have 125 years of experience in evacuation, including more than 140 projects for federal and state agencies. The text explains how to model evacuations that use the road transportation network by combining perspectives from social scientists and transportation engineers, fields that have commonly approached evacuation modelling from distinctly different perspectives. In doing so, it offers a step-by-step guide through the key questions needed to model an evacuation and its impacts to the evacuation route system as well as evacuation management strategies for influencing demand and expanding capacity. The authors also demonstrate how to simulate the resulting traffic and evacuation management strategies that can be used to facilitate evacuee movement and reduce unnecessary demand. Case studies, which identify key points to analyze in an evacuation plan, discuss evacuation termination and re-entry, and highlight challenges that someone developing an evacuation plan or model should expect, are also included. This textbook will be of interest to researchers, practitioners, and advanced students.
Author: Scott Walbridge
Publisher: Springer Nature
ISBN: 9811910650
Category : Technology & Engineering
Languages : en
Pages : 686
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Book Description
This book comprises the proceedings of the Annual Conference of the Canadian Society of Civil Engineering 2021. The contents of this volume focus on specialty conferences in construction, environmental, hydrotechnical, materials, structures, transportation engineering, etc. This volume will prove a valuable resource for those in academia and industry.
Author: Dusan Teodorovic
Publisher: Routledge
ISBN: 1317630912
Category : Architecture
Languages : en
Pages : 483
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Book Description
The Routledge Handbook of Transportation offers a current and comprehensive survey of transportation planning and engineering research. It provides a step-by-step introduction to research related to traffic engineering and control, transportation planning, and performance measurement and evaluation of transportation alternatives. The Handbook of Transportation demonstrates models and methods for predicting travel and freight demand, planning future transportation networks, and developing traffic control systems. Readers will learn how to use various engineering concepts and approaches to make future transportation safer, more efficient, and more sustainable. Edited by Dušan Teodorović and featuring 29 chapters from more than 50 leading global experts, with more than 200 illustrations, the Routledge Handbook of Transportation is designed as an invaluable resource for professionals and students in transportation planning and engineering.
Author: Md Sharikur Rahman
Publisher:
ISBN:
Category :
Languages : en
Pages : 156
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Book Description
Currently, CAV fleet data are not easily obtainable which is one of the primary reasons to deploy the simulation techniques in this study to evaluate the impacts of CAVs in the roadway. The car following, lane changing, and the platooning behavior of the CAV technologies were modeled in the C++ programming language by considering realistic car following and lane changing models in PTV VISSIM. Surrogate safety assessment techniques were considered to evaluate the safety effectiveness of these CAV technologies, while the average travel time, average speed, and average delay were evaluated as traffic operational measures. Several statistical tests (i.e., Two sample t-test, ANOVA) and the modelling techniques (Tobit, Negative binomial, and Logistic regression) were conducted to evaluate the CAV effectiveness with different MPRs over the baseline scenario. The statistical tests and modeling results suggested that the higher the MPR of CAVs implemented, the higher were the safety and mobility benefits achieved for different roadways (i.e., freeway, expressway, arterials, managed lane), weather (i.e., clear, foggy), and traffic conditions (i.e., peak and off-peak period). Interestingly, from the safety and operation perspective, at least 30% and 20% MPR were needed to achieve both the safety and operational benefits of peak and off-peak period, respectively. This dissertation has major implications for improving transportation infrastructure by recommending optimal MPR of CAVs to achieve balanced mobility and safety benefits considering varying roadway, traffic, and weather condition.
