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Author: You Jin Jung
Publisher:
ISBN:
Category : Local transit
Languages : en
Pages : 144
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Book Description
Recent emphasis on sustainable development has carried over into the transportation sector, given the impacts of transportation behavior on environment and equity. Transit is widely recognized as a viable option supporting the sustainability issue providing benefits such as reducing air pollution, alleviating traffic congestion, enhancing mobility, and promoting social well-being (health through walk- and bike-access). An important tool in advancing sustainable transport is to generate more robust transit ridership models to evaluate the benefits of investments in these modes. In particular, this thesis concentrates on two sub-problems of (1) calibration procedures and (2) insufficient data for transit mode choice modules. The first purpose of this thesis is to improve the calibration procedures through better understanding of calibrated mode constants. First, the magnitude and relative importance of mode constants to measurable components are analyzed using representative data from six cities in North America. The mode constants (representing unmeasured inputs) in study cities account for 41% to 65% of total utilities. The results demonstrate that, in some cases, mode constants are large enough to render models insensitive to changes of important but omitted system factors such as reliability, comfort, convenience, visibility, access environment, and safety. The need to explicitly include mode constant endogenous to the model is verified. Second, this thesis introduces a framework to improve the utilization of new data sources such as automated vehicle location (AVL) and automated passenger counting (APC) systems in transit ridership forecasting models. The direct application of the AVL/APC data to travel forecasting requires an important intermediary step that links stops activities - boarding and alighting - to the actual location (at the TAZ level) that generated/attracted this trip. The GIS-based transit trip allocation methods are newly developed with focus on considering the case when the access shed spans multiple TAZs. The proposed methods improve practical applicability with easily obtained data in local contexts. The performance of the proposed allocation methods is further evaluated using transit on-board survey data. The results show that the buffer area ratio weighted by employment or population and footprint weighted method perform reasonably well in the study area and can effectively handle various conditions, particularly for major activity generators. The average errors between observed data and the proposed method are about 8% for alighting trips and 18% for boarding trips. Third, given the outputs from the previous research effort, the application framework of the AVL/APC data to travel forecasting model calibration is demonstrated. In the proposed framework, transit trip allocation methods are employed to identify prediction errors at finer geographic level (at TAZs). In turn, the approach makes it possible to evaluate the zonal characteristics that affect estimation accuracy. Developed multinomial regression models produce equations for the mode choice prediction errors as a function of (1) measurable but omitted market segmentation variables in current mode choice utility function including socio-economic and land use data; and (2) newly quantifiable attributes with new data source or techniques including quality of service variables. The proposed composite index can systematically evaluate and prioritize the major source of prediction errors by quantifying total magnitudes of prediction error and a possible error component. The outcomes of the research in this thesis can serve as foundation towards more reliable and accurate mode choice models and ultimately enhanced transit travel forecasting.
Author: You Jin Jung
Publisher:
ISBN:
Category : Local transit
Languages : en
Pages : 144
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Book Description
Recent emphasis on sustainable development has carried over into the transportation sector, given the impacts of transportation behavior on environment and equity. Transit is widely recognized as a viable option supporting the sustainability issue providing benefits such as reducing air pollution, alleviating traffic congestion, enhancing mobility, and promoting social well-being (health through walk- and bike-access). An important tool in advancing sustainable transport is to generate more robust transit ridership models to evaluate the benefits of investments in these modes. In particular, this thesis concentrates on two sub-problems of (1) calibration procedures and (2) insufficient data for transit mode choice modules. The first purpose of this thesis is to improve the calibration procedures through better understanding of calibrated mode constants. First, the magnitude and relative importance of mode constants to measurable components are analyzed using representative data from six cities in North America. The mode constants (representing unmeasured inputs) in study cities account for 41% to 65% of total utilities. The results demonstrate that, in some cases, mode constants are large enough to render models insensitive to changes of important but omitted system factors such as reliability, comfort, convenience, visibility, access environment, and safety. The need to explicitly include mode constant endogenous to the model is verified. Second, this thesis introduces a framework to improve the utilization of new data sources such as automated vehicle location (AVL) and automated passenger counting (APC) systems in transit ridership forecasting models. The direct application of the AVL/APC data to travel forecasting requires an important intermediary step that links stops activities - boarding and alighting - to the actual location (at the TAZ level) that generated/attracted this trip. The GIS-based transit trip allocation methods are newly developed with focus on considering the case when the access shed spans multiple TAZs. The proposed methods improve practical applicability with easily obtained data in local contexts. The performance of the proposed allocation methods is further evaluated using transit on-board survey data. The results show that the buffer area ratio weighted by employment or population and footprint weighted method perform reasonably well in the study area and can effectively handle various conditions, particularly for major activity generators. The average errors between observed data and the proposed method are about 8% for alighting trips and 18% for boarding trips. Third, given the outputs from the previous research effort, the application framework of the AVL/APC data to travel forecasting model calibration is demonstrated. In the proposed framework, transit trip allocation methods are employed to identify prediction errors at finer geographic level (at TAZs). In turn, the approach makes it possible to evaluate the zonal characteristics that affect estimation accuracy. Developed multinomial regression models produce equations for the mode choice prediction errors as a function of (1) measurable but omitted market segmentation variables in current mode choice utility function including socio-economic and land use data; and (2) newly quantifiable attributes with new data source or techniques including quality of service variables. The proposed composite index can systematically evaluate and prioritize the major source of prediction errors by quantifying total magnitudes of prediction error and a possible error component. The outcomes of the research in this thesis can serve as foundation towards more reliable and accurate mode choice models and ultimately enhanced transit travel forecasting.
Author: Daniel K. Boyle
Publisher: Transportation Research Board
ISBN: 030909819X
Category : Automatic data collection systems
Languages : en
Pages : 83
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Book Description
This report documents the state of analytical tools and technologies for measuring transit ridership via automatic passenger counter systems and other subsidiary data.
Author: Daniel K. Boyle
Publisher:
ISBN:
Category : Transportation
Languages : en
Pages : 62
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Book Description
Summarizes information from selected transit agencies about benefits and problems associated with each passenger counting technology, as reported by current users. It also presents advice for agencies considering each technology.
Author: Daniel K. Boyle
Publisher: Transportation Research Board
ISBN: 030909772X
Category : Bus lines
Languages : en
Pages : 60
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Book Description
TRB's Transit Cooperative Research Program (TCRP) Synthesis 66: Fixed-Route Transit Ridership Forecasting and Service Planning Methods examines the state of the practice in fixed-route transit ridership forecasting and service planning. The report also explores forecasting methodologies, resource requirements, data inputs, and organizational issues. In addition, the report analyzes the impacts of service changes and reviews transit agency assessments of the effectiveness and reliability of their methods and of desired improvements.
Author: Zhengyao Yu
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Public transportation users typically identify reliability as a key measure of the quality of transit service and a major determinant of transit use. Improving the reliability of a transit system can have numerous potential benefits: increased transit ridership, decreased congestion (which further improves transit reliability), and decreased emissions. With Automated Vehicle Location (AVL) and Automated Passenger Counter (APC) units becoming common on transit vehicles, some transit agencies have begun to provide real-time vehicle location and occupancy information as a means to improve perceived reliability from a user's perspective. However, what users need is more than real-time information. They need accurate predictions of how the system will evolve to better plan their trips. So far, the research of vehicle-level passenger occupancy prediction is missing and all current travel time prediction models overlook the variance of travel times and thus can provide a false sense of precision. This paper aims at establishing regression models to predict passenger occupancies and travel times as well as the uncertainties associated with the predictions. To do this, linear models and survival models were applied in travel time modeling; linear models, count models, and quantile models were applied in passenger occupancy modeling. The impacts of several operational and weather variables were examined and transferability tests validated the models' predictive power across semesters. In travel time models, only one stop pair along the bus route was picked due to some data issues. A log-logistic survival model was found to: 1) give very close point estimates to the linear model; 2) better fit the distribution of the dependent variable; and, 3) provide smaller variances and uncertainty ranges for the predictions. In passenger occupancy models, all stop pairs were included in a single model and three model frameworks (travel-length-based, segment-based and next-stop-based) were proposed and compared. The next-stop-based linear model was found to provide more accurate predictions for nearer downstream stops while the segment-based linear model performed better for stops further away. And also, in comparison to the best linear model, a quantile model was found to 1) better fit the distribution of the dependent variable; and, 2) provide smaller uncertainty ranges for the predictions.
Author: Fumitaka Kurauchi
Publisher: CRC Press
ISBN: 1498726593
Category : Political Science
Languages : en
Pages : 275
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Book Description
Collecting fares through "smart cards" is becoming standard in most advanced public transport networks of major cities around the world. Travellers value their convenience and operators the reduced money handling fees. Electronic tickets also make it easier to integrate fare systems, to create complex time and space differentiated fare systems, and to provide incentives to specific target groups. A less-utilised benefit is the data collected through smart cards. Records, even if anonymous, provide for a much better understanding of passengers’ travel behaviour as current literature shows. This information can also be used for better service planning. Public Transport Planning with Smart Card Data handles three major topics: how passenger behaviour can be estimated using smart card data, how smart card data can be combined with other trip databases, and how the public transport service level can be better evaluated if smart card data is available. The book discusses theory as well as applications from cities around the world and will be of interest to researchers and practitioners alike who are interested in the state-of-the-art as well as future perspectives that smart card data will bring.
Author: Alan J. Horowitz
Publisher:
ISBN:
Category : Computer graphics
Languages : en
Pages : 110
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Book Description
Author:
Publisher:
ISBN:
Category : Local transit
Languages : en
Pages : 534
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Book Description
Author: Doug J. Parker
Publisher: Transportation Research Board
ISBN: 0309097967
Category : Bus lines
Languages : en
Pages : 114
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Book Description
"TRB's Transit Cooperative Research Program (TCRP) Synthesis 73: AVL Systems for Bus Transit: Update explores the uses of computer-aided dispatch/automatic vehicle location (CAD/AVL) systems in fixed-route and demand-responsive services (bus AVL), as well as changes in agency practices related to the use of AVL systems."--Publisher's website.
Author: Dawei Lu
Publisher:
ISBN:
Category : Local transit
Languages : en
Pages : 166
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Book Description
Abstract: Understanding the origin-destination (OD) flow patterns of passengers is essential to transit planning. The passenger OD flows are usually estimated by on-board surveys in the transit industry. However, using on-board surveys to estimate OD flows is time consuming and labor intensive, and can suffer from response bias. Because of increased availability of automated data collection technologies and their increased acceptance by transit agencies, boarding and alighting data are now much more available to transit authorities than in the past. In this thesis, methods to estimate bus route-level transit passenger OD flows are reviewed and tested. Boarding and alighting counts at each bus stop and base OD flows are used as inputs to the estimation methods. The estimated route-level transit passenger OD matrix provides stop-to-stop passenger flows for all possible stop pairs along the transit route. The estimation methods are illustrated on a small hypothetical transit route with a specified set of input values. The estimated OD flows are compared, and all the methods yield very similar estimated matrices. Several of the methods are also applied on a full-scale transit bus route of the Central Ohio Transit Authority (COTA) bus transit network. Boarding and alighting counts for each bus stop are obtained from COTA's Automatic Passenger Counting (APC) system. Simulation analysis is also conducted on the COTA route. The empirical and simulated results show that OD matrices estimated by different methods are found to be very similar to each other, and the quality of the base OD matrix, a necessary input for several methods, has a marked effect on the quality of the estimated OD matrices. The implications on the choice of the base matrix are discussed.
