TY - JOUR
T1 - The value of stochastic crowd resources and strategic location of mini-depots for last-mile delivery
T2 - A Benders decomposition approach
AU - Nieto-Isaza, Santiago
AU - Fontaine, Pirmin
AU - Minner, Stefan
N1 - Publisher Copyright:
© 2022 Elsevier Ltd
PY - 2022/3
Y1 - 2022/3
N2 - Crowd-shipping is an emergent solution to avoid the negative effects caused by the growing demand for last-mile delivery services. Previous research has studied crowd-shipping typically at an operational planning level. However, the study of support infrastructure within a city logistics framework has been neglected, especially from a strategic perspective. We investigate a crowd-sourced last-mile parcel delivery system supported by a network of strategically located mini-depots and present a two-stage stochastic network design problem with stochastic time-dependent arc capacity to fulfill stochastic express deliveries. The first-stage decision is the location of mini-depots used for decoupling flows allowing more flexibility for crowd–demand matching. The second stage of the problem is the demand allocation of crowd carriers or professional couriers for a finite set of scenarios. We propose an exact Benders decomposition algorithm embedded in a branch-and-cut framework. To enhance the algorithm, we use partial Benders decomposition, warm-start, and non-dominated cuts. We perform computational experiments on networks inspired by the public transportation network of Munich. The proposed solution method outperforms an off-the-shelf solver by solving instances 3.6 to 19 times faster. The results show the potential to exploit the stochastic crowd flows to deliver packages with deadlines of 3 or 8 h. The crowd can transport 8.3% to 32.5% of the total demand by using between 4% to 24% of the crowd capacity, and we observe average daily savings of 2.1% to 7.6% of the total expected operational cost. The results show values of the stochastic solution of at least 1% and up to 10%.
AB - Crowd-shipping is an emergent solution to avoid the negative effects caused by the growing demand for last-mile delivery services. Previous research has studied crowd-shipping typically at an operational planning level. However, the study of support infrastructure within a city logistics framework has been neglected, especially from a strategic perspective. We investigate a crowd-sourced last-mile parcel delivery system supported by a network of strategically located mini-depots and present a two-stage stochastic network design problem with stochastic time-dependent arc capacity to fulfill stochastic express deliveries. The first-stage decision is the location of mini-depots used for decoupling flows allowing more flexibility for crowd–demand matching. The second stage of the problem is the demand allocation of crowd carriers or professional couriers for a finite set of scenarios. We propose an exact Benders decomposition algorithm embedded in a branch-and-cut framework. To enhance the algorithm, we use partial Benders decomposition, warm-start, and non-dominated cuts. We perform computational experiments on networks inspired by the public transportation network of Munich. The proposed solution method outperforms an off-the-shelf solver by solving instances 3.6 to 19 times faster. The results show the potential to exploit the stochastic crowd flows to deliver packages with deadlines of 3 or 8 h. The crowd can transport 8.3% to 32.5% of the total demand by using between 4% to 24% of the crowd capacity, and we observe average daily savings of 2.1% to 7.6% of the total expected operational cost. The results show values of the stochastic solution of at least 1% and up to 10%.
KW - Benders decomposition
KW - Crowd-shipping
KW - Network design
KW - Two-stage stochastic programming
UR - http://www.scopus.com/inward/record.url?scp=85123724141&partnerID=8YFLogxK
U2 - 10.1016/j.trb.2021.12.014
DO - 10.1016/j.trb.2021.12.014
M3 - Article
AN - SCOPUS:85123724141
SN - 0191-2615
VL - 157
SP - 62
EP - 79
JO - Transportation Research Part B: Methodological
JF - Transportation Research Part B: Methodological
ER -