Fair Energy Scheduling for Vehicle-to-Grid Networks Using Adaptive Dynamic Programming

Research on the smart grid is being given enormous supports worldwide due to its great significance in solving environmental and energy crises. Electric vehicles (EVs), which are powered by clean energy, are adopted increasingly year by year. It is predictable that the huge charge load caused by hig...

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Veröffentlicht in:	IEEE transaction on neural networks and learning systems 2016-08, Vol.27 (8), p.1697-1707
Hauptverfasser:	Xie, Shengli, Zhong, Weifeng, Xie, Kan, Yu, Rong, Zhang, Yan
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptive dynamic programming (ADP) Batteries Charge Charge (electric) contribution-based fairness Discharge Discharges (electric) Distribution management Dynamic programming Dynamic scheduling Electric vehicles Energy management Load Markov analysis Networks residential distribution network Resource management Scheduling smart grid Smart grids vehicle-to-grid (V2G)
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container_title	IEEE transaction on neural networks and learning systems
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creator	Xie, Shengli Zhong, Weifeng Xie, Kan Yu, Rong Zhang, Yan
description	Research on the smart grid is being given enormous supports worldwide due to its great significance in solving environmental and energy crises. Electric vehicles (EVs), which are powered by clean energy, are adopted increasingly year by year. It is predictable that the huge charge load caused by high EV penetration will have a considerable impact on the reliability of the smart grid. Therefore, fair energy scheduling for EV charge and discharge is proposed in this paper. By using the vehicle-to-grid technology, the scheduler controls the electricity loads of EVs considering fairness in the residential distribution network. We propose contribution-based fairness, in which EVs with high contributions have high priorities to obtain charge energy. The contribution value is defined by both the charge/discharge energy and the timing of the action. EVs can achieve higher contribution values when discharging during the load peak hours. However, charging during this time will decrease the contribution values seriously. We formulate the fair energy scheduling problem as an infinite-horizon Markov decision process. The methodology of adaptive dynamic programming is employed to maximize the long-term fairness by processing online network training. The numerical results illustrate that the proposed EV energy scheduling is able to mitigate and flatten the peak load in the distribution network. Furthermore, contribution-based fairness achieves a fast recovery of EV batteries that have deeply discharged and guarantee fairness in the full charge time of all EVs.
doi_str_mv	10.1109/TNNLS.2016.2526615
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Electric vehicles (EVs), which are powered by clean energy, are adopted increasingly year by year. It is predictable that the huge charge load caused by high EV penetration will have a considerable impact on the reliability of the smart grid. Therefore, fair energy scheduling for EV charge and discharge is proposed in this paper. By using the vehicle-to-grid technology, the scheduler controls the electricity loads of EVs considering fairness in the residential distribution network. We propose contribution-based fairness, in which EVs with high contributions have high priorities to obtain charge energy. The contribution value is defined by both the charge/discharge energy and the timing of the action. EVs can achieve higher contribution values when discharging during the load peak hours. However, charging during this time will decrease the contribution values seriously. We formulate the fair energy scheduling problem as an infinite-horizon Markov decision process. 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Electric vehicles (EVs), which are powered by clean energy, are adopted increasingly year by year. It is predictable that the huge charge load caused by high EV penetration will have a considerable impact on the reliability of the smart grid. Therefore, fair energy scheduling for EV charge and discharge is proposed in this paper. By using the vehicle-to-grid technology, the scheduler controls the electricity loads of EVs considering fairness in the residential distribution network. We propose contribution-based fairness, in which EVs with high contributions have high priorities to obtain charge energy. The contribution value is defined by both the charge/discharge energy and the timing of the action. EVs can achieve higher contribution values when discharging during the load peak hours. However, charging during this time will decrease the contribution values seriously. We formulate the fair energy scheduling problem as an infinite-horizon Markov decision process. 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subjects	Adaptive dynamic programming (ADP) Batteries Charge Charge (electric) contribution-based fairness Discharge Discharges (electric) Distribution management Dynamic programming Dynamic scheduling Electric vehicles Energy management Load Markov analysis Networks residential distribution network Resource management Scheduling smart grid Smart grids vehicle-to-grid (V2G)
title	Fair Energy Scheduling for Vehicle-to-Grid Networks Using Adaptive Dynamic Programming
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