2022
DOI: 10.3390/su14052780
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Optimization for Feeder Bus Route Model Design with Station Transfer

Abstract: To fully take the advantages of conventional bus and subway, and to maximize the overall feeder efficiency of the public transport system, the topic of feeder bus route optimization is studied in this paper. Considering the origin destination demand of passenger flow between subway stations and bus stations and transfer characteristics, the objective function is established with the minimum sum of bus operation cost and passenger travel cost. Taking into account the integrity of the feeder bus route, the ratio… Show more

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Cited by 6 publications
(6 citation statements)
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“…To align feeder bus routes with prevailing conditions, Wei et al [8] utilized temporal and spatial data to construct a dual-layer planning model, employing an ant colony optimization algorithm to reduce total bus travel time for passengers significantly. Cao et al [9] considered passenger demand and transfer characteristics to refine feeder bus route optimization, devising a genetic algorithm to minimize operational and passenger travel expenses and achieve optimal outcomes. Cipriani et al [10] developed an algorithm to tailor route plans and frequencies to concentrated customer demands at a singular destination, while subsequent research [11] adapted this approach to cater to diverse origins and destinations, reflecting the unique demand patterns of feeder bus routes.…”
Section: In Terms Of Feeder Bus Route Optimizationmentioning
confidence: 99%
“…To align feeder bus routes with prevailing conditions, Wei et al [8] utilized temporal and spatial data to construct a dual-layer planning model, employing an ant colony optimization algorithm to reduce total bus travel time for passengers significantly. Cao et al [9] considered passenger demand and transfer characteristics to refine feeder bus route optimization, devising a genetic algorithm to minimize operational and passenger travel expenses and achieve optimal outcomes. Cipriani et al [10] developed an algorithm to tailor route plans and frequencies to concentrated customer demands at a singular destination, while subsequent research [11] adapted this approach to cater to diverse origins and destinations, reflecting the unique demand patterns of feeder bus routes.…”
Section: In Terms Of Feeder Bus Route Optimizationmentioning
confidence: 99%
“…Traveling through metro mass transit is 20% cheaper [4]. However, compared with the urban metro, although the conventional bus has a small capacity and slow speed, it has the advantages of low cost, vital accessibility, and comprehensive coverage [5]. Terefore, studying the design and operation optimization of the feeder bus routes can help build a perfect feeder bus service system, give full play to their advantages, expand cooperation with the urban metro, and reduce competition.…”
Section: Introductionmentioning
confidence: 99%
“…Though the fixed-route service offered by traditional transit may benefit stable demands, it could hardly adapt to the temporal and spatial variations in unstable demands [2][3][4][5]. As a result, the popularity of traditional transit is decreasing, while the usage of private transit is increasing [6][7][8][9][10][11], which leads to heavy traffic congestion and serious air pollution [12][13][14][15][16].…”
Section: Introductionmentioning
confidence: 99%
“…If the trip j accepts the real-time demand n * (z j,n * = 1), it must meet the requirement of station sequence, as constraints (2) to (7) show, maintain the service for reserved demands, as constraints ( 8) to (10) show, and build the temporal and spatial relationship with the real-time demand n * , as constraints (18) to (21) show.…”
mentioning
confidence: 99%