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Electric Vehicle Optimized Charge and Drive Management

Published: 01 August 2017 Publication History

Abstract

Electric vehicles (EVs) have been considered as a solution to the environmental issues caused by transportation, such as air pollution and greenhouse gas emission. However, limited energy capacity, scarce EV supercharging stations, and long recharging time have brought anxiety to drivers who use EVs as their main mean of transportation. Furthermore, EV owners need to deal with a huge battery replacement cost when the battery capacity degrades. Yet in-house EV chargers affect the pattern of the power grid load, which is not favorable to the utilities. The driving route, departure/arrival time of daily trips, and electricity price influence the EV energy consumption, battery lifetime, electricity cost, and EV charger load on the power grid. The EV driving range and battery lifetime issues have been addressed by battery management systems and route optimization methodologies. However, in this article, we are proposing an optimized charge and drive management (OCDM) methodology that selects the optimal driving route, schedules daily trips, and optimizes the EV charging process while considering the driver’s timing preference. Our methodology will improve the EV driving range, extend the battery lifetime, reduce the recharging cost, and diminish the influence of EV chargers on the power grid. The performance of our methodology compared to the state of the art have been analyzed by experimenting on three benchmark EVs and three drivers. Our methodology has decreased EV energy consumption by 27%, improved the battery lifetime by 24.8%, reduced the electricity cost by 35%, and diminished the power grid peak load by 17% while increasing less than 20 minutes of daily driving time. Moreover, the scalability of our OCDM methodology for different parameters (e.g., time resolution and multiday cycles) in terms of execution time and memory usage has been analyzed.

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Published In

cover image ACM Transactions on Design Automation of Electronic Systems
ACM Transactions on Design Automation of Electronic Systems  Volume 23, Issue 1
January 2018
279 pages
ISSN:1084-4309
EISSN:1557-7309
DOI:10.1145/3129756
  • Editor:
  • Naehyuck Chang
Issue’s Table of Contents
Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

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Publication History

Published: 01 August 2017
Accepted: 01 April 2017
Revised: 01 April 2017
Received: 01 September 2016
Published in TODAES Volume 23, Issue 1

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Author Tags

  1. Electric vehicle
  2. MILP
  3. battery
  4. power estimation
  5. smart grid

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Cited By

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  • (2023)A review of the factors and input parameters influencing the range of an Edison electric vehicle according to measurementsScientific Review Engineering and Environmental Studies (SREES)10.22630/srees.454431:4(270-282)Online publication date: 10-Jan-2023
  • (2021)Intelligent charge scheduling and eco-routing mechanism for electric vehicles: A multi-objective heuristic approachSustainable Cities and Society10.1016/j.scs.2021.10282069(102820)Online publication date: Jun-2021
  • (2019)Runtime Power Management of Battery Electric Vehicles for Extended Range With Consideration of Driving TimeIEEE Transactions on Very Large Scale Integration (VLSI) Systems10.1109/TVLSI.2018.288044127:3(549-559)Online publication date: Mar-2019
  • (2019)Grid-to-Vehicle Smart Charging Strategies for Electric Vehicles Aggregator: A Review and Outlook2019 8th International Conference on Power Systems (ICPS)10.1109/ICPS48983.2019.9067551(1-6)Online publication date: Dec-2019
  • (2018)Switching Predictive Control Using Reconfigurable State-Based ModelACM Transactions on Design Automation of Electronic Systems10.1145/326712624:1(1-21)Online publication date: 19-Nov-2018
  • (2018)Design and Analysis of Battery-Aware Automotive Climate Control for Electric VehiclesACM Transactions on Embedded Computing Systems10.1145/320340817:4(1-22)Online publication date: 5-Jul-2018
  • (2018)Extended Range Electric Vehicle with Driving Behavior Estimation in Energy ManagementIEEE Transactions on Smart Grid10.1109/TSG.2018.2815689(1-1)Online publication date: 2018
  • (2018)Survey of Low-Power Electric Vehicles: A Design Automation PerspectiveIEEE Design & Test10.1109/MDAT.2018.287347535:6(44-70)Online publication date: Dec-2018
  • (2017)ACQUAProceedings of the 36th International Conference on Computer-Aided Design10.5555/3199700.3199726(193-200)Online publication date: 13-Nov-2017
  • (2017)ACQUA: Adaptive and cooperative quality-aware control for automotive cyber-physical systems2017 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)10.1109/ICCAD.2017.8203778(193-200)Online publication date: Nov-2017

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