Locating electric vehicle charging stations under uncertain battery energy status and power consumption

Abstract Fostering the adoption of electric vehicles (EVs) by private drivers requires the development of a wide network of fast charging stations in which drivers traveling long-distance trips will be able to easily recharge their battery within a few minutes. However, due to their high installation costs, the number of stations that can actually be deployed with the available investment budget is strongly limited. It is thus necessary to carefully choose their location so that the charging demand satisfaction is maximized. This leads to the formulation of a facility location problem known as the flow refueling location problem (FRLP). In this paper, we study the FRLP and seek to take into account uncertainties on the vehicle driving range in the problem modeling. We propose to relax several modeling assumptions previously used in the literature to handle this problem. First, we allow the power consumption on a road segment to depend on the crossing direction. Second, we take into account uncertainties related to the energy available in the battery after recharging at a station as well as uncertainties related to the power consumption on each portion of the road network. Finally, we consider statistical dependencies between the stochastic power consumption on different arcs of the network. We focus on the chance-constrained flow refueling location model, which seeks to maximize the number of drivers for whom the probability of running out of fuel when carrying out their trip is below a certain threshold. To solve the resulting stochastic optimization problem, we propose to use a solution approach based on a partial sample approximation of the stochastic parameters and compare its performance with the one of a previously published approach based on Bonferroni’s inequality. We carry out numerical experiments on a set of medium-size randomly generated and real life instances. Our results show that the proposed partial sample approximation approach outperforms the Bonferroni approach in terms of solution quality and gives station locations which provide a significantly improved demand coverage in practice.

[1]  R. Rockafellar,et al.  Optimization of conditional value-at risk , 2000 .

[2]  Hanif D. Sherali,et al.  An Integrated Approach for Airline Flight Selection and Timing, Fleet Assignment, and Aircraft Routing , 2013, Transp. Sci..

[3]  A. Nemirovski,et al.  Scenario Approximations of Chance Constraints , 2006 .

[4]  Sreten Davidov,et al.  Impact of stochastic driving range on the optimal charging infrastructure expansion planning , 2017 .

[5]  Barış Yıldız,et al.  The urban recharging infrastructure design problem with stochastic demands and capacitated charging stations , 2019, Transportation Research Part B: Methodological.

[6]  Alexander Shapiro,et al.  Convex Approximations of Chance Constrained Programs , 2006, SIAM J. Optim..

[7]  Michael Kuby,et al.  Optimization of hydrogen stations in Florida using the Flow-Refueling Location Model , 2009 .

[8]  Morton E. O'Kelly,et al.  Spatial Interaction Models:Formulations and Applications , 1988 .

[9]  Giuseppe Carlo Calafiore,et al.  Uncertain convex programs: randomized solutions and confidence levels , 2005, Math. Program..

[10]  Michael Kuby,et al.  The flow-refueling location problem for alternative-fuel vehicles , 2005 .

[11]  V. Jorge Leon,et al.  An arc cover-path-cover formulation and strategic analysis of alternative-fuel station locations , 2013, Eur. J. Oper. Res..

[12]  S. A. MirHassani,et al.  A Flexible Reformulation of the Refueling Station Location Problem , 2013, Transp. Sci..

[13]  Harwin de Vries,et al.  Incorporating Driving Range Variability in Network Design for Refueling Facilities , 2016 .

[14]  Joseph Ying Jun Chow,et al.  Stochastic Dynamic Itinerary Interception Refueling Location Problem with Queue Delay for Electric Taxi Charging Stations , 2014 .

[15]  Zuo-Jun Max Shen,et al.  Infrastructure Planning for Electric Vehicles with Battery Swapping , 2012 .

[16]  James R. Luedtke,et al.  A Sample Approximation Approach for Optimization with Probabilistic Constraints , 2008, SIAM J. Optim..

[17]  Barış Yıldız,et al.  A branch and price approach for routing and refueling station location model , 2016, Eur. J. Oper. Res..

[18]  Abdel Lisser,et al.  Partial sample average approximation method for chance constrained problems , 2018, Optimization Letters.

[19]  Jong-Geun Kim,et al.  A network transformation heuristic approach for the deviation flow refueling location model , 2013, Comput. Oper. Res..

[20]  Fei Wu,et al.  A stochastic flow-capturing model to optimize the location of fast-charging stations with uncertain electric vehicle flows , 2017 .

[21]  Mouna Kchaou Boujelben,et al.  Efficient solution approaches for locating electric vehicle fast charging stations under driving range uncertainty , 2019, Comput. Oper. Res..

[22]  Mohsen Ramezani,et al.  Location Design of Electric Vehicle Charging Facilities: A Path-Distance Constrained Stochastic User Equilibrium Approach , 2017 .

[23]  M. J. Hodgson A Flow-Capturing Location-Allocation Model , 2010 .

[24]  Fritz Busch,et al.  Optimal location of wireless charging facilities for electric vehicles: Flow-capturing location model with stochastic user equilibrium , 2015 .

[25]  S. A. MirHassani,et al.  Refueling-station location problem under uncertainty , 2015 .

[26]  Chungmok Lee,et al.  Benders-and-Price approach for electric vehicle charging station location problem under probabilistic travel range , 2017 .

[27]  Ying-Wei Wang,et al.  Locating Road-Vehicle Refueling Stations , 2009 .

[28]  Maximilian Schiffer,et al.  Strategic planning of electric logistics fleet networks: A robust location-routing approach , 2017, Omega.

[29]  António Pais Antunes,et al.  Optimal Location of Charging Stations for Electric Vehicles in a Neighborhood in Lisbon, Portugal , 2011 .