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Seamless Electromobility

Published: 16 May 2017 Publication History

Abstract

The existing electromobility (EM) is still in its fledgling stage and multiple challenges have to be overcome to make Electric Vehicles (EVs) as convenient as combustion engine vehicles. Users and Electric Vehicle Fleet Operators (EFOs) want their EVs to be charged and ready for use at all times. This straightforward goal, however, is counteracted from various sides:
The range of the EV depends on the status and depletion of the EV battery which is influenced by EV use and charging characteristics. Also, most convenient charging from the user's point of view, might unfortunately lead to problems in the power grid. As in the case of a power peak in the evening when EV users return from work and simultaneously plug in their EVs for charging. Last but not least, the mass of EV batteries are an untapped potential to store electricity from intermittent renewable energy sources.
In this paper, we propose a novel approach to tackle this multi-layered problem from different perspectives. Using on-board EV data and grid prediction models, we build up an information model as a foundation for a back end service containing EFO and Charging Station Provider (CSP) logic as well as a central Advanced Drivers Assistant System (ADAS). These components connect to both battery management and user interfaces suggesting various routing and driving behaviour alternatives customized and incentivized for the current user profile optimizing above mentioned goals.

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Cited By

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  • (2024)Predictability of electric vehicle charging: Explaining extensive user behavior-specific heterogeneityApplied Energy10.1016/j.apenergy.2024.123544370(123544)Online publication date: Sep-2024
  • (2023)System for Monitoring and Managing Electric Vehicles Charging Using IoTIntelligent Sustainable Systems10.1007/978-981-19-7663-6_39(417-427)Online publication date: 25-Jan-2023
  • (2022)Dynamic Pricing for Charging of EVs with Monte Carlo Tree SearchSmart Cities10.3390/smartcities50100145:1(223-240)Online publication date: 27-Feb-2022
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Published In

cover image ACM Conferences
e-Energy '17: Proceedings of the Eighth International Conference on Future Energy Systems
May 2017
388 pages
ISBN:9781450350365
DOI:10.1145/3077839
This work is licensed under a Creative Commons Attribution International 4.0 License.

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Publication History

Published: 16 May 2017

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Author Tags

  1. ADAS
  2. Battery Health
  3. Electric Vehicles
  4. Grid Prediction Models
  5. Incentives
  6. Range Modelling
  7. Routing
  8. Smart Charging
  9. User Guidance

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Overall Acceptance Rate 160 of 446 submissions, 36%

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  • (2024)Predictability of electric vehicle charging: Explaining extensive user behavior-specific heterogeneityApplied Energy10.1016/j.apenergy.2024.123544370(123544)Online publication date: Sep-2024
  • (2023)System for Monitoring and Managing Electric Vehicles Charging Using IoTIntelligent Sustainable Systems10.1007/978-981-19-7663-6_39(417-427)Online publication date: 25-Jan-2023
  • (2022)Dynamic Pricing for Charging of EVs with Monte Carlo Tree SearchSmart Cities10.3390/smartcities50100145:1(223-240)Online publication date: 27-Feb-2022
  • (2022)Using real mobility patterns to assess the impact of 100% electrified mobility in a German cityEnergy Informatics10.1186/s42162-022-00248-x5:1Online publication date: 17-Oct-2022
  • (2022)Impact of incentives for greener battery electric vehicle charging – A field experimentEnergy Policy10.1016/j.enpol.2021.112752161(112752)Online publication date: Feb-2022
  • (2022)Estimation of Range for Electric Vehicle Using Fuzzy Logic SystemAI and IoT for Smart City Applications10.1007/978-981-16-7498-3_3(31-46)Online publication date: 4-Jan-2022
  • (2021)Communication Vulnerabilities in Electric Mobility HCP Systems: A Semi-Quantitative AnalysisSmart Cities10.3390/smartcities40100234:1(405-428)Online publication date: 20-Mar-2021
  • (2021)When, What and How to Teach about Electric Mobility? An Innovative Teaching Concept for All Stages of Education: Lessons from PolandEnergies10.3390/en1419644014:19(6440)Online publication date: 8-Oct-2021
  • (2021)Framework for User-Centered Access to Electric Charging Facilities via Energy-Trading Blockchain2021 24th International Symposium on Wireless Personal Multimedia Communications (WPMC)10.1109/WPMC52694.2021.9700475(1-6)Online publication date: 14-Dec-2021
  • (2020)A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle ChargingSmart Cities10.3390/smartcities30400673:4(1405-1427)Online publication date: 21-Nov-2020
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