TY - GEN
T1 - Beyond the Vehicle Routing Problem
T2 - 15th International Conference on Operations Research and Enterprise Systems, ICORES 2026
AU - Wu, Xiaoyi
AU - Seshadri, Ravi
AU - Rodrigues, Filipe
AU - Azevedo, Carlos Lima
AU - Araldo, Andrea
N1 - Publisher Copyright:
© 2026 by SCITEPRESS-Science and Technology Publications, Lda.
PY - 2026/1/1
Y1 - 2026/1/1
N2 - Conventional public transportation (CPT) is composed of fixed routes and fixed timetables, usually determined via long-term planning, based on nominal demand. However, during operations, demand may greatly deviate from the nominal one, causing a mismatch between demand and supply, leading to an inefficient service. On the other hand, flexible mobility services, such as Demand-Responsive Transport (DRT), adapt bus routes to the actual user demand. However, routes are calculated by solving a Vehicle Routing Problems (VRPs), which are not as effective as CPT in terms of demand consolidation, resulting in cost inefficiency. While in CPT, consolidation is obtained by forcing users to adapt to CPT by lines, VRP adapts instead to bus routes to user demand. This work introduces an alternative approach to DRT operations: different from VRP, we design a structured network describing bus routes, allowing for complex user trips, including transfers and walking legs. This enables greater consolidation and efficiency. While network design problems are limited to static networks, we propose here an original formulation to design temporal networks, which allows structured bus routes to adapt to the observed demand. We provide a proof-of-concept of the proposed approach, and show in small-scale numerical experiments that it reduces operator cost, without excessively penalizing users, compared to the classic VRP-based solution (Code available at https://github.com/XiaoyiWu21/TN4DRT).
AB - Conventional public transportation (CPT) is composed of fixed routes and fixed timetables, usually determined via long-term planning, based on nominal demand. However, during operations, demand may greatly deviate from the nominal one, causing a mismatch between demand and supply, leading to an inefficient service. On the other hand, flexible mobility services, such as Demand-Responsive Transport (DRT), adapt bus routes to the actual user demand. However, routes are calculated by solving a Vehicle Routing Problems (VRPs), which are not as effective as CPT in terms of demand consolidation, resulting in cost inefficiency. While in CPT, consolidation is obtained by forcing users to adapt to CPT by lines, VRP adapts instead to bus routes to user demand. This work introduces an alternative approach to DRT operations: different from VRP, we design a structured network describing bus routes, allowing for complex user trips, including transfers and walking legs. This enables greater consolidation and efficiency. While network design problems are limited to static networks, we propose here an original formulation to design temporal networks, which allows structured bus routes to adapt to the observed demand. We provide a proof-of-concept of the proposed approach, and show in small-scale numerical experiments that it reduces operator cost, without excessively penalizing users, compared to the classic VRP-based solution (Code available at https://github.com/XiaoyiWu21/TN4DRT).
KW - Demand-Responsive Transport
KW - Mobility on Demand
KW - Network Optimization
UR - https://www.scopus.com/pages/publications/105035602059
U2 - 10.5220/0014330400004055
DO - 10.5220/0014330400004055
M3 - Conference contribution
AN - SCOPUS:105035602059
SN - 9789897587993
T3 - International Conference on Operations Research and Enterprise Systems
SP - 339
EP - 350
BT - Proceedings of the 15th International Conference on Operations Research and Enterprise Systems
A2 - Schlosser, Rainer
A2 - Bruni, Maria Elena
A2 - Parlier, Greg
PB - Science and Technology Publications, Lda
Y2 - 9 March 2026 through 11 March 2026
ER -