Robustness Generalizations of the Shortest Feasible Path Problem for Electric Vehicles

Electric Vehicle routing is often modeled as a Shortest Feasible Path Problem (SFPP), which minimizes total travel time while maintaining a non-zero State of Charge (SoC) along the route. However, the problem assumes perfect information about energy consumption and charging stations, which are difficult to even estimate in practice. Further, drivers might have varying risk tolerances for different trips. To overcome these limitations, we propose two generalizations to the SFPP; they compute the shortest feasible path for any initial SoC and, respectively, for every possible minimum SoC threshold. We present algorithmic solutions for each problem, and provide two constructs: Starting Charge Maps and Buffer Maps, which represent the tradeoffs between robustness of feasible routes and their travel times. The two constructs are useful in many ways, including presenting alternate routes or providing charging prompts to users. We evaluate the performance of our algorithms on realistic input instances. 2012 ACM Subject Classification Mathematics of computing → Graph algorithms; Mathematics of computing → Paths and connectivity problems

[1]  Dorothea Wagner,et al.  Time-Dependent Route Planning , 2009, Encyclopedia of GIS.

[2]  Chinya V. Ravishankar,et al.  The Phase Abstraction for Estimating Energy Consumption and Travel Times for Electric Vehicle Route Planning , 2019, SIGSPATIAL/GIS.

[3]  Dorothea Wagner,et al.  Energy-Optimal Routes for Battery Electric Vehicles , 2019, Algorithmica.

[4]  Sabine Storandt,et al.  Quick and energy-efficient routes: computing constrained shortest paths for electric vehicles , 2012, IWCTS '12.

[5]  Guoyuan Wu,et al.  Data-driven decomposition analysis and estimation of link-level electric vehicle energy consumption under real-world traffic conditions , 2017, Transportation Research Part D: Transport and Environment.

[6]  Martin Strehler,et al.  Routing of Electric Vehicles: Constrained Shortest Path Problems with Resource Recovering Nodes , 2015, ATMOS.

[7]  Shashi Shekhar,et al.  Physics-guided energy-efficient path selection: a summary of results , 2018, SIGSPATIAL/GIS.

[8]  Stefan Funke,et al.  Optimal Route Planning for Electric Vehicles in Large Networks , 2011, AAAI.

[9]  Andrew V. Goldberg,et al.  Customizable Route Planning in Road Networks , 2017, Transp. Sci..

[10]  Frank Gauterin,et al.  Influence of Measurement and Prediction Uncertainties on Range Estimation for Electric Vehicles , 2018, IEEE Transactions on Intelligent Transportation Systems.

[11]  Wolfgang Ketter,et al.  Electric Vehicle Range Anxiety: An Obstacle for the Personal Transportation (R)evolution? , 2019, 2019 4th International Conference on Smart and Sustainable Technologies (SpliTech).

[12]  S. Shekhar,et al.  Physics-guided Energy-efficient Path Selection Using On-board Diagnostics Data , 2020, Trans. Data Sci..

[13]  Martin Leucker,et al.  Efficient Energy-Optimal Routing for Electric Vehicles , 2011, AAAI.

[14]  I. Neumann,et al.  Experiencing Range in an Electric Vehicle: Understanding Psychological Barriers , 2012 .

[15]  Dorothea Wagner,et al.  Dynamic Time-Dependent Route Planning in Road Networks with User Preferences , 2015, SEA.

[16]  Martin Leucker,et al.  The Shortest Path Problem Revisited: Optimal Routing for Electric Vehicles , 2010, KI.

[17]  Dorothea Wagner,et al.  Shortest feasible paths with charging stops for battery electric vehicles , 2015, SIGSPATIAL/GIS.

[18]  Andrew V. Goldberg,et al.  Route Planning in Transportation Networks , 2015, Algorithm Engineering.

[19]  Hesham Rakha,et al.  Power-based electric vehicle energy consumption model: Model development and validation , 2016 .

[20]  Lutz M. Kolbe,et al.  Understanding the influence of in-vehicle information systems on range stress – Insights from an electric vehicle field experiment , 2016 .

[21]  Stefan Funke,et al.  Polynomial-Time Construction of Contraction Hierarchies for Multi-Criteria Objectives , 2013, SOCS.

[22]  Dorothea Wagner,et al.  Modeling and Engineering Constrained Shortest Path Algorithms for Battery Electric Vehicles , 2020, ESA.

[23]  Nadine Rauh,et al.  Which Factors Can Protect Against Range Stress in Everyday Usage of Battery Electric Vehicles? Toward Enhancing Sustainability of Electric Mobility Systems , 2016, Hum. Factors.

[24]  Thomas Franke,et al.  Interacting with limited mobility resources: Psychological range levels in electric vehicle use , 2013 .

[25]  Julian Dibbelt,et al.  Speed-Consumption Tradeoff for Electric Vehicle Route Planning , 2014, ATMOS.

[26]  Andrew V. Goldberg,et al.  Customizable Route Planning , 2011, SEA.

[27]  Peter Sanders,et al.  Exact Routing in Large Road Networks Using Contraction Hierarchies , 2012, Transp. Sci..

[28]  Martin Leucker,et al.  Abstract Routing Models and Abstractions in the Context of Vehicle Routing , 2015, IJCAI.

[29]  Stefan Funke,et al.  Cruising with a Battery-Powered Vehicle and Not Getting Stranded , 2012, AAAI.

[30]  Martin Steinert,et al.  Displayed Uncertainty Improves Driving Experience and Behavior: The Case of Range Anxiety in an Electric Car , 2015, CHI.

[31]  Peter Sanders,et al.  Combining hierarchical and goal-directed speed-up techniques for dijkstra's algorithm , 2008, JEAL.

[32]  E. Martins On a multicriteria shortest path problem , 1984 .

[33]  C. Fiori,et al.  Energy Consumption Modeling in Presence of Uncertainty , 2021, IEEE Transactions on Intelligent Transportation Systems.

[34]  Frederico G. Guimarães,et al.  A comparison of dominance criteria in many-objective optimization problems , 2011, 2011 IEEE Congress of Evolutionary Computation (CEC).

[35]  Dorothea Wagner,et al.  Consumption Profiles in Route Planning for Electric Vehicles: Theory and Applications , 2017, SEA.

[36]  K. Bogenberger,et al.  Optimization of Charging Strategies for Battery Electric Vehicles Under Uncertainty , 2020, IEEE Transactions on Intelligent Transportation Systems.

[37]  Nadine Rauh,et al.  User Experience with Electric Vehicles while Driving in a Critical Range Situation - A Qualitative Approach , 2015 .

[38]  Johannes Kester Security in transition(s): The low-level security politics of electric vehicle range anxiety , 2019, Security Dialogue.

[39]  Jessika E. Trancik,et al.  Potential for widespread electrification of personal vehicle travel in the United States , 2016, Nature Energy.

[40]  Joeri Van Mierlo,et al.  A Data-Driven Method for Energy Consumption Prediction and Energy-Efficient Routing of Electric Vehicles in Real-World Conditions , 2017 .

[41]  Michael T. Goodrich,et al.  Two-phase bicriterion search for finding fast and efficient electric vehicle routes , 2014, SIGSPATIAL/GIS.

[42]  Yazan Al-Wreikat,et al.  Driving behaviour and trip condition effects on the energy consumption of an electric vehicle under real-world driving , 2021 .

[43]  Martin Strehler,et al.  Energy-efficient shortest routes for electric and hybrid vehicles , 2017 .

[44]  Wolfgang Ketter,et al.  A survey-based assessment of how existing and potential electric vehicle owners perceive range anxiety , 2020 .

[45]  Michael E. Theologou,et al.  Energy-efficient routing based on vehicular consumption predictions of a mesoscopic learning model , 2015, Appl. Soft Comput..

[46]  Tomáš Juřík Optimal Route Planning for Electric Vehicles , 2013 .

[47]  Subhash Suri,et al.  On the Complexity of Time-Dependent Shortest Paths , 2011, Algorithmica.

[48]  Matthew William Fontana,et al.  Optimal routes for electric vehicles facing uncertainty, congestion, and energy constraints , 2013 .