Abstract
Due to increasing concern about the environmental impact of internal combustion engines, both companies and customers are inclined to much cleaner alternatives like electric vehicles. Moreover, to withstand the current competitive market, companies seek strategies like collaboration to reduce their operational costs and enhance their customer service level. In this regard, this paper investigates a collaborative capacitated electric vehicle routing problem (CoCEVRP). Two novel bi-objective mathematical models, including several real-world assumptions, are developed for the problem under collaborative and non-collaborative strategies. Since the problem is intractable, a matheuristic approach is devised based on the integration of the multi-objective Keshtel algorithm (MOKA) with a mathematical model. Finally, a comprehensive computational experiment is carried out to validate and assess the performance of the devised approach and examine the impact of collaboration among companies. According to the results, the MOKA demonstrates an auspicious performance to achieve high-quality solutions. Moreover, the collaborative strategy can lead to a significant reduction in the total cost and the total electrical energy consumption, as well as a considerable improvement in the customer service level and vehicle utilization.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Availability of data and material
Not applicable.
Code availability
Not applicable.
References
Adler JD, Mirchandani PB (2014) Online routing and battery reservations for electric vehicles with swappable batteries. Transp Res Part B Methodol 70:285–302
Ankersmit S, Rezaei J, Tavasszy L (2014) The potential of horizontal collaboration in airport ground freight services. J Air Transp Manag 40:169–181
Arbabi H, Nasiri MM, Bozorgi-Amiri A (2021) A hub-and-spoke architecture for a parcel delivery system using the cross-docking distribution strategy. Eng Optim 53:1593–1612
Basso R, Kulcsár B, Egardt B, Lindroth P, Sanchez-Diaz I (2019) Energy consumption estimation integrated into the electric vehicle routing problem. Transp Res Part D Transp Environ 69:141–167
Basso R, Kulcsár B, Sanchez-Diaz I (2021) Electric vehicle routing problem with machine learning for energy prediction. Transp Res Part B Methodol 145:24–55
Bektaş T, Laporte G (2011) The pollution-routing problem. Transp Res Part B Methodol 45:1232–1250
Cheraghalipour A, Paydar MM, Hajiaghaei-Keshteli M (2018) A bi-objective optimization for citrus closed-loop supply chain using Pareto-based algorithms. Appl Soft Comput 69:33–59
Conrad RG, Figliozzi MA (2011) The recharging vehicle routing problem. In: Proceedings of the 2011 industrial engineering research conference. IISE Norcross, GA, p 8
Dantzig GB, Ramser JH (1959) The truck dispatching problem. Manag Sci 6:80–91
Defryn C, Sörensen K, Cornelissens T (2016) The selective vehicle routing problem in a collaborative environment. Eur J Oper Res 250:400–411
Defryn C, Sörensen K, Dullaert W (2019) Integrating partner objectives in horizontal logistics optimisation models. Omega 82:1–12
Deng J, Li J, Li C, Han Y, Liu Q, Niu B, Liu L, Zhang B (2021) A hybrid algorithm for electric vehicle routing problem with nonlinear charging. J Intell Fuzzy Syst 40(3):5383–5402
Desaulniers G, Errico F, Irnich S, Schneider M (2016) Exact algorithms for electric vehicle-routing problems with time windows. Oper Res 64:1388–1405
Fatemi-Anaraki S, Tavakkoli-Moghaddam R, Abdolhamidi D, Vahedi-Nouri B (2021) Simultaneous waterway scheduling, berth allocation, and quay crane assignment: a novel matheuristic approach. Int J Prod Res 59(24):7576–7593
Feng W, Figliozzi M (2013) An economic and technological analysis of the key factors affecting the competitiveness of electric commercial vehicles: a case study from the USA market. Transp Res Part C Emerg Technol 26:135–145
Gansterer M, Hartl R (2018) Collaborative vehicle routing: a survey. Eur J Oper Res 268:1–12
GGES (2016) Greenhouse gas emission statistics-emission inventories. European Commission, Brussels
Ghobadi A, Tavakkoli-Moghaddam R, Fallah M, Kazemipour H (2021) Multi-depot electric vehicle routing problem with fuzzy time windows and pickup/delivery constraints. J Appl Res Ind Eng 8(1):1–18
Golabian H, Arkat J, Tavakkoli-Moghaddam R, Faroughi H (2021) A multi-verse optimizer algorithm for ambulance repositioning in emergency medical service systems. J Ambient Intell Human Comput. https://doi.org/10.1007/s12652-021-02918-2
Hajiaghaei-Keshteli M, Aminnayeri M (2014) Solving the integrated scheduling of production and rail transportation problem by Keshtel algorithm. Appl Soft Comput 25:184–203
Hiermann G, Hartl RF, Puchinger J, Vidal T (2019) Routing a mix of conventional, plug-in hybrid, and electric vehicles. Eur J Oper Res 272:235–248
Hof J, Schneider M, Goeke D (2017) Solving the battery swap station location-routing problem with capacitated electric vehicles using an AVNS algorithm for vehicle-routing problems with intermediate stops. Transp Res Part B Methodol 97:102–112
Huang J, Liu Y, Liu M, Cao M, Yan Q (2019) Multi-objective optimization control of distributed electric drive vehicles based on optimal torque distribution. IEEE Access 7:16377–16394
Jie W, Yang J, Zhang M, Huang Y (2019) The two-echelon capacitated electric vehicle routing problem with battery swapping stations: formulation and efficient methodology. Eur J Oper Res 272:879–904
Karakatič S (2021) Optimizing nonlinear charging times of electric vehicle routing with genetic algorithm. Expert Syst Appl 164:114039
Keskin M, Çatay B (2016) Partial recharge strategies for the electric vehicle routing problem with time windows. Transp Res Part C Emerg Technol 65:111–127
Keskin M, Çatay B (2018) A matheuristic method for the electric vehicle routing problem with time windows and fast chargers. Comput Oper Res 100:172–188
Keskin M, Çatay B, Laporte G (2021) A simulation-based heuristic for the electric vehicle routing problem with time windows and stochastic waiting times at recharging stations. Comput Oper Res 125:105060
Kumar SN, Panneerselvam R (2012) A survey on the vehicle routing problem and its variants. Intell Inf Manag 4(3):66–74
Mavrotas G, Florios K (2013) An improved version of the augmented ε-constraint method (AUGMECON2) for finding the exact pareto set in multi-objective integer programming problems. Appl Math Comput 219:9652–9669
Muñoz-Villamizar A, Montoya-Torres JR, Faulin J (2017) Impact of the use of electric vehicles in collaborative urban transport networks: a case study. Transp Res Part D Transp Environ 50:40–54
Murakami K (2017) A new model and approach to electric and diesel-powered vehicle routing. Transp Res Part E Logist Transp Rev 107:23–37
Nejad MM, Mashayekhy L, Grosu D, Chinnam RB (2017) Optimal routing for plug-in hybrid electric vehicles. Transp Sci 51:1304–1325
Npr (2021) From Amazon To FedEx, the delivery truck is going electric. https://www.npr.org/2021/03/17/976152350/from-amazon-to-fedex-the-delivery-truck-is-going-electric. Accessed 3 Jan 2022
Parsaeifar S, Bozorgi-Amiri A, Naimi-Sadigh A, Sangari MS (2019) A game theoretical for coordination of pricing, recycling, and green product decisions in the supply chain. J Clean Prod 226:37–49
Rohaninejad M, Kheirkhah A, Fattahi P, Vahedi-Nouri B (2015) A hybrid multi-objective genetic algorithm based on the ELECTRE method for a capacitated flexible job shop scheduling problem. Int J Adv Manuf Technol 77:51–66
Rohaninejad M, Sahraeian R, Nouri BV (2016) Multi-objective optimization of integrated lot-sizing and scheduling problem in flexible job shops. RAIRO Oper Res 50:587–609
Rohaninejad M, Navidi H, Vahedi-Nouri B, Kamranrad R (2017) A new approach to cooperative competition in facility location problems: mathematical formulations and an approximation algorithm. Comput Oper Res 83:45–53
Roshanaei V, Luong C, Aleman DM, Urbach DR (2017) Collaborative operating room planning and scheduling. INFORMS J Comput 29:558–580
Sangaiah AK, Suraki MY, Sadeghilalimi M, Bozorgi SM, Hosseinabadi AAR, Wang J (2019) A new meta-heuristic algorithm for solving the flexible dynamic job-shop problem with parallel machines. Symmetry 11:165
Sangaiah AK, Ramamoorthi JS, Rodrigues JJ, Rahman MA, Muhammad G, Alrashoud M (2021) LACCVoV: linear adaptive congestion control with optimization of data dissemination model in vehicle-to-vehicle communication. IEEE Trans Intell Transp Syst 22(8):5319–5328
Schneider M, Stenger A, Goeke D (2014) The electric vehicle-routing problem with time windows and recharging stations. Transp Sci 48:500–520
Solomon MM (1987) Algorithms for the vehicle routing and scheduling problems with time window constraints. Oper Res 35:254–265
Tang J, Yang Y, Hao W, Liu F, Wang Y (2020) A data-driven timetable optimization of urban bus line based on multi-objective genetic algorithm. IEEE Trans Intell Transp Syst 22:2417–2429
Tao N, Shishasha S, Peng Z, Tao G (2021) Disruption management decision model for VRPSDP under changes of customer distribution demand. J Ambient Intell Humaniz Comput 12:2053–2063
UNFCCC (2021) United Nations framework convention on climate change: the Paris agreement. https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement. Accessed 3 Jan 2022
USEPA (2019) United States environmental protection agency: sources of greenhouse gas emissions. https://www.epa.gov/ghgemissions/sources-greenhouse-gas-emissions. Accessed 3 Jan 2022
Vahedi-Nouri B, Tavakkoli-Moghaddam R, Hanzálek Z, Arbabi H, Rohaninejad M (2021) Incorporating order acceptance, pricing and equity considerations in the scheduling of cloud manufacturing systems: matheuristic methods. Int J Prod Res 59(7):2009–2027
Vincent FY, Jodiawan P, Gunawan A (2021) An adaptive large neighborhood search for the green mixed fleet vehicle routing problem with realistic energy consumption and partial recharges. Appl Soft Comput 105:107251
Wang Y, Ma X, Li Z, Liu Y, Xu M, Wang Y (2017) Profit distribution in collaborative multiple centers vehicle routing problem. J Clean Prod 144:203–219
Wang X, Ong S, Nee A (2018) A comprehensive survey of ubiquitous manufacturing research. Int J Prod Res 56:604–628
Wang R, Zhou J, Yi X, Pantelous AA (2019) Solving the green-fuzzy vehicle routing problem using a revised hybrid intelligent algorithm. J Ambient Intell Humaniz Comput 10:321–332
Wang X, Lin N, Li Y, Shi Y, Ruan J (2021a) An integrated modeling method for collaborative vehicle routing: facilitating the unmanned micro warehouse pattern in new retail. Expert Syst Appl 168:114307
Wang Y, Li Q, Guan X, Xu M, Liu Y, Wang H (2021b) Two-echelon collaborative multi-depot multi-period vehicle routing problem. Expert Syst Appl 167:114201
Yang J, Sun H (2015) Battery swap station location-routing problem with capacitated electric vehicles. Comput Oper Res 55:217–232
Yang H, Yang S, Xu Y, Cao E, Lai M, Dong Z (2015) Electric vehicle route optimization considering time-of-use electricity price by learnable partheno-genetic algorithm. IEEE Trans Smart Grid 6:657–666
Yin J-L, Chen B-H, Lai K-HR (2019) Driver danger-level monitoring system using multi-sourced big driving data. IEEE Trans Intell Transp Syst 21:5271–5282
Zhang S, Gajpal Y, Appadoo S, Abdulkader M (2018) Electric vehicle routing problem with recharging stations for minimizing energy consumption. Int J Prod Econ 203:404–413
Funding
Not applicable.
Author information
Authors and Affiliations
Contributions
The authors of this research entitled “Bi-objective collaborative electric vehicle routing problem: mathematical modeling and matheuristic approach” certify that all the co-authors have made substantial contributions to the reported work and had an active part in the subject matter or materials discussed in this manuscript. Furthermore, each author certifies that this material or similar material has not been and will not be submitted to or published in any other publication before its appearance in the “Journal of Ambient Intelligence and Humanized Computing”. Behdin Vahedi-Nouri: conceptualization, methodology, writing—original draft. Hamidreza Arbabi: methodology, software, visualization. Fariborz Jolai: supervision, project administration. Reza Tavakkoli-Moghaddam: resources, writing—review & editing. Ali Bozorgi-Amiri: data curation, validation.
Corresponding author
Ethics declarations
Conflict of interest
No potential conflict of interest was reported by the authors.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Vahedi-Nouri, B., Arbabi, H., Jolai, F. et al. Bi-objective collaborative electric vehicle routing problem: mathematical modeling and matheuristic approach. J Ambient Intell Human Comput 14, 10277–10297 (2023). https://doi.org/10.1007/s12652-021-03689-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12652-021-03689-6