Solving real-size stochastic railway rapid transit network construction scheduling problems

The problem of Rapid Transit Network Design (RTND) is studied in this paper. Due to the noticeable contribution of rapid transit lines in public transportation network of large urban areas, this problem is interesting to the transportation specialists. On the other hand, the success stories of Bus Rapid Transit (BRT) systems in different countries have motivated us to study BRT network planning. BRT systems can be developed with less investment costs and construction time in comparison with rail-based systems. Therefore, planning Bus Rapid Transit lines, either to develop a new rapid transit network or extend a current one can be an interesting research topic. This problem, like other network design problems is difficult to solve for large scale networks. In this study, a mixed-integer mathematical model that addresses the Transit Network Design Problem (TNDP) is presented. The objective function of the model is maximization of trip coverage. To solve the model, an algorithm is proposed and implemented in C# environment. The main modules of the algorithm are the following: (1) routes generation, (2) search tree, (3) solution evaluation, and (4) inference. In Route Generation module, the candidate transit route set is determined. Afterwards, the Search Tree module provides a strategy which guarantees that all feasible combinations can be considered in the search process. To evaluate the performance of each transit route combination, a transit assignment algorithm is used in the Solution Evaluation part. Finally, the intelligence core of the search process, that is called Inference, helps the algorithm to find parts of the search space which cannot contain the optimal solution. The algorithm is tested on a real size network, i.e., the extension of the Greater Isfahan rapid transit network with BRT routes. The output of the algorithm is the set of BRT routes that maximizes the daily trip coverage index while satisfying the budget constraint. By solving the case study problem, it is shown that our proposed model and algorithm are capable of tackling real size rapid transit network design problems.

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A quantitative approach for the long-term assessment of Railway Rapid Transit network construction or expansion projects

European Journal of Operational Research ◽

10.1016/j.ejor.2021.02.018 ◽

2021 ◽

Author(s):

David Canca ◽

José Luis Andrade-Pineda ◽

Alicia De-Los-Santos ◽

Pedro Luis González-R

Keyword(s):

Quantitative Approach ◽

Rapid Transit ◽

Network Construction ◽

Transit Network

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Multi-project scheduling: a new categorization for heuristic scheduling rules in construction scheduling problems

Construction Management and Economics ◽

10.1080/01446198800000010 ◽

1988 ◽

Vol 6 (2) ◽

pp. 93-115 ◽

Cited By ~ 12

Author(s):

Samir I. G. Allam

Keyword(s):

Project Scheduling ◽

Scheduling Problems ◽

Construction Scheduling ◽

Heuristic Scheduling

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Recoverable Robustness in Rapid Transit Network Design

Procedia - Social and Behavioral Sciences ◽

10.1016/j.sbspro.2012.09.843 ◽

2012 ◽

Vol 54 ◽

pp. 1288-1297 ◽

Cited By ~ 4

Author(s):

Luis Cadarso ◽

Ángel Marín

Keyword(s):

Network Design ◽

Rapid Transit ◽

Transit Network ◽

Recoverable Robustness ◽

Transit Network Design

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The new BRT system has led to an overall increase in transit-based accessibility to essential services during the COVID-19 pandemic: Empirical evidence from Winnipeg, Canada

10.31219/osf.io/anjd7 ◽

2021 ◽

Author(s):

Suraj Shirodkar Singh ◽

Reyhane Javanmard ◽

Jinhyung Lee ◽

Junghwan Kim ◽

Ehab Diab

Keyword(s):

Low Income ◽

Urban Areas ◽

Bus Rapid Transit ◽

Time Budgets ◽

Rapid Transit ◽

Transit Network ◽

Essential Services ◽

Before And After ◽

In Transit ◽

Different Parts

Recently, in Winnipeg, the implementation of new bus rapid transit (BRT) system in the middle of the COVID-19 pandemic has raised many concerns, challenging the rationale behind the untimely release. However, the new BRT service can benefit low-income, socio-economically vulnerable, and transit captive passengers who must travel to essential services and work opportunities during the pandemic. This study evaluates whether the new BRT system has positive impacts on accessibility to such essential services during the pandemic. Isochrones with different time budgets as well as times of a day are generated based on high-resolution public transit network via the General Transit Feed Specification (GTFS) data and used for evaluating accessibility benefits before and after the BRT construction. The new BRT service in Winnipeg demonstrates varying accessibility impacts across different parts of the BRT corridor. Areas near dedicated lane-section show a significant increase, whereas areas near non-dedicated lane sections show a decrease in accessibility. Nevertheless, across the whole BRT corridor, the new BRT service presents an overall increase in accessibility to essential services. This demonstrates the positive accessibility benefits of the new BRT service to residents seeking essential services during the COVID-19 pandemic. A decrease in accessibility along some parts suggests the necessity of using local transit improvement strategies (e.g., dedicated lanes) to improve service speed when planning BRT services within urban areas.

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