An Optimization Model for Demand-Responsive Feeder Transit Services Based on Ride-Sharing Car

Sun, Bo; Wei, Ming; Wu, Wei

doi:10.3390/info10120370

Cited by 10 publications

(18 citation statements)

References 34 publications

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“…People at demand points, where passengers live or work, can walk to one of the nearest stops to get on and off the bus. In such a case, an operation of integrated pedestrian guidance (from demand points to selected stops) and transit routing (from pick-up places to transportation hubs) can find an optimal relation between the walking and riding time of residents and the operation efficiency of vehicles [1,6,7,34]. (3) Such integration of stop selection, transit routing, and frequency setting was a new research problem extending from an NP-hard vehicle route problem, and a novel heuristic algorithm was needed to efficiently resolve large-scale instances [8].…”

Section: Literature Reviewmentioning

confidence: 99%

“…In the real world, passengers at the demand point may walk to one of the nearby stops to get on and off the bus, and their choice behaviors are decided by routes with empty seats and shorter driving time. Selecting optimal stops in candidate routes as pick-up locations with an assignment of demand points is also key to designing FTS routes [6,7]. erefore, the integrated operation of transit route design and frequency setting with stop selection is now widely regarded as an effective tool to improve service efficiency and financial status.…”

Section: Introductionmentioning

confidence: 99%

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Optimal Integrated Model for Feeder Transit Route Design and Frequency-Setting Problem with Stop Selection

Wei

Liu

Sun

et al. 2020

Journal of Advanced Transportation

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This study proposed a mathematical model for designing a feeder transit service for improving the service quality and accessibility of transportation hubs (such as airport and rail station). The proposed model featured an integrated framework, which simultaneously guided passengers to reach their nearest stops to get on and off the bus, designed routes to transport passengers from these selected pick-up stops to the transportation hubs, and calculated their departure frequencies. In particular, the maximum walking distance, the upper and lower limits of route frequencies, and the load factor rate of each route were fully accounted for in this study. The main objective of the proposed model was to simultaneously minimize the total walking, riding time, and waiting time of all passengers. As this study explored an NP-hard problem, a two-stage genetic algorithm combining the Dijkstra search method was further developed to yield metaoptimal solutions to the model within an acceptable time. Finally, a test instance in Chongqing City, China, demonstrated that the proposed model was an effective tool to generate a pedestrian, route, and operation plan; it reduced the total travel time, compared with the traditional model.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal Integrated Model for Feeder Transit Route Design and Frequency-Setting Problem with Stop Selection

Wei

Liu

Sun

et al. 2020

Journal of Advanced Transportation

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“…Both DRT and DRASS are extensions of the vehicle routing problem (VRP) and the pick-up and delivery problem (PDP), which aim at assigning all customers in demand points to vehicles located at different bus depots and designing routes to transport them from their home or workplace to destinations [1,2,5,8]. e only difference between them is that DRT strengthens the connectivity between residential areas and rail stations, while DRASS transports air passengers to airports [1,7]. ey have similar objective functions (i.e., operating cost, carbon emissions, and passenger satisfaction) and constraints (i.e., time windows, vehicle capacity, and mileage).…”

Section: Literaturementioning

confidence: 99%

“…In general, DRT and DRASS often involve customers being picked up within specific time windows, which is related to the customers' satisfaction level in the airport shuttle service [9]. A variant of vehicle routing with time windows has been studied by researchers and can be divided into hard time windows [3,4,7,9] and soft time windows [12][13][14]. In the former, time windows cannot be violated, where the vehicles must arrive at the earliest arrival time and leave the customers before the latest departure time.…”

Section: Literaturementioning

confidence: 99%

“…Recent research on minimizing emissions in DRASS models can be divided into two main categories. e first is the set of models where vehicle speed is assumed to be constant [1,2,7], and the second set includes models where the vehicle speed is timevarying based on different road conditions [5,8]. Although the first models are not accurate, they are suitable where there is a lack of traffic data.…”

Section: Introductionmentioning

confidence: 99%

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A Green Demand-Responsive Airport Shuttle Service Problem with Time-Varying Speeds

Wei

Jing

Yin

et al. 2020

Journal of Advanced Transportation

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This study proposes a multiobjective mixed integer linear programming (MOMILP) model for a demand-responsive airport shuttle service. The approach aims to assign a set of alternative fuel vehicles (AFVs) located at different depots to visit each demand point within the specified time and transport all of them to the airport. The proposed model effectively captures the interactions between path selection and environmental protection. Moreover, users with flexible pick-up time windows, the time-varying speed of vehicles on the road network, and the limited fuel for the route duration are also fully considered in this model. The work aims at simultaneously minimizing the operating cost, vehicle fuel consumption, and CO2 emissions. Since this task is an NP-hard problem, a heuristic-based nondominated sorting genetic algorithm (NSGA-II) is also presented to find Pareto optimal solutions in a reasonable amount of time. Finally, a real-world example is provided to illustrate the proposed methodology. The results demonstrate that the model not only selects an optimal depot for each AFV but also determines its route and timetable plan. A sensitivity analysis is also given to assess the effect of early/late arrival penalty weights and the number of AFVs on the model performance, and the difference in quality between the proposed and traditional models is compared.

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A survey on demand-responsive public bus systems

Vansteenwegen

Melis

Aktaş

et al. 2022

Transportation Research Part C: Emerging Technologies

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An Optimization Model for Demand-Responsive Feeder Transit Services Based on Ride-Sharing Car

Cited by 10 publications

References 34 publications

Optimal Integrated Model for Feeder Transit Route Design and Frequency-Setting Problem with Stop Selection

Optimal Integrated Model for Feeder Transit Route Design and Frequency-Setting Problem with Stop Selection

A Green Demand-Responsive Airport Shuttle Service Problem with Time-Varying Speeds

A survey on demand-responsive public bus systems

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