Short-Term Load Forecasting for Electric Vehicle Charging Stations Based on Deep Learning Approaches

Zhu, Juncheng; Yang, Zhile; Guo, Yuanjun; Zhang, Jiankang; Yang, Huikun

doi:10.3390/app9091723

Cited by 98 publications

(46 citation statements)

References 25 publications

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“…However, these traditional methods are difficult for quantifying the external factors that affect the charging load of PEVs, and it is impossible to establish a deterministic model. In our previous study [43], the deep learning method is used for hourly level PEV load forecasting and obtained well performance. However, the minute level super-short-term forecasting is more challenging.…”

Section: Literature Studymentioning

confidence: 96%

Electric Vehicle Charging Load Forecasting: A Comparative Study of Deep Learning Approaches

et al. 2019

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Load forecasting is one of the major challenges of power system operation and is crucial to the effective scheduling for economic dispatch at multiple time scales. Numerous load forecasting methods have been proposed for household and commercial demand, as well as for loads at various nodes in a power grid. However, compared with conventional loads, the uncoordinated charging of the large penetration of plug-in electric vehicles is different in terms of periodicity and fluctuation, which renders current load forecasting techniques ineffective. Deep learning methods, empowered by unprecedented learning ability from extensive data, provide novel approaches for solving challenging forecasting tasks. This research proposes a comparative study of deep learning approaches to forecast the super-short-term stochastic charging load of plug-in electric vehicles. Several popular and novel deep-learning based methods have been utilized in establishing the forecasting models using minute-level real-world data of a plug-in electric vehicle charging station to compare the forecasting performance. Numerical results of twelve cases on various time steps show that deep learning methods obtain high accuracy in super-short-term plug-in electric load forecasting. Among the various deep learning approaches, the long-short-term memory method performs the best by reducing over 30% forecasting error compared with the conventional artificial neural network model.

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Section: Literature Studymentioning

confidence: 96%

Electric Vehicle Charging Load Forecasting: A Comparative Study of Deep Learning Approaches

et al. 2019

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“…Electric load forecasting (LF) is an indispensable task for electric utilities in the long term [1]. As a fundamental business problem, LF is associated with decision-making processes in power system plannings, operations, energy trading and so forth [2,3]. Prediction of future load demand is a tendency forecasting subject based on actual load data.…”

Section: Introductionmentioning

confidence: 99%

Probabilistic Forecasting of Short-Term Electric Load Demand: An Integration Scheme Based on Correlation Analysis and Improved Weighted Extreme Learning Machine

et al. 2019

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Precise prediction of short-term electric load demand is the key for developing power market strategies. Due to the dynamic environment of short-term load forecasting, probabilistic forecasting has become the center of attention for its ability of representing uncertainty. In this paper, an integration scheme mainly composed of correlation analysis and improved weighted extreme learning machine is proposed for probabilistic load forecasting. In this scheme, a novel cooperation of wavelet packet transform and correlation analysis is developed to deal with the data noise. Meanwhile, an improved weighted extreme learning machine with a new switch algorithm is provided to effectively obtain stable forecasting results. The probabilistic forecasting task is then accomplished by generating the confidence intervals with the Gaussian process. The proposed integration scheme, tested by actual data from Global Energy Forecasting Competition, is proved to have a better performance in graphic and numerical results than the other available methods.

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“…Particularly, charging stations are always equipped with a large number of batteries, which means they possess high frequency regulation capacity through making full use of retired batteries [20]. Consequently, the charging stations can be regarded as independent EV agents to participate in the frequency regulation service [21], which is crucial for power quality adjustment [22], while the power quality parameters can be estimated by the curve fitting algorithm [23]. When multiple charging stations participate in the secondary power system frequency regulation, there are typically two critical steps: (a) assigning the total power command ∆P EV of EV centralized control center to each charging station and (b) assigning the power command of the charging station to each battery in the station.…”

Section: Introductionmentioning

confidence: 99%

“…Hence, this paper applies the consensus algorithm to the AGC power allocation for each EV charging station. In order to avoid battery over-charging or over-discharging and to prolong the lifespan of the battery, a proportional allocation method based on SOC [21] is adopted to solve the AGC power redistribution. Finally, the model of the Hainan power grid in south China is utilized to evaluate the specific performance of the proposed method.…”

Section: Introductionmentioning

confidence: 99%

Cost Consensus Algorithm Applications for EV Charging Station Participating in AGC of Interconnected Power Grid

Tang

Ren

et al. 2019

Applied Sciences

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In order to more effectively reduce the regulation costs of power grids and to improve the automatic generation control (AGC) performance, an optimization mathematical model of generation command dispatch for AGC with an electric vehicle (EV) charging station is proposed in this paper, in which a cost consensus algorithm for AGC is adopted. Particularly, virtual consensus variables are applied to exchange information among different AGC units. At the same time, the actual consensus variables are utilized to determine the generation command, upon which the flexibility of the proposed algorithm can be significantly enhanced. Furthermore, the implement feasibility of such an algorithm is verified through a series simulation experiments on the Hainan power grid in southern China, where the results demonstrate that the proposed algorithm can effectively realize an autonomous frequency regulation of EVs participating in AGC.

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Short-Term Load Forecasting for Electric Vehicle Charging Stations Based on Deep Learning Approaches

Cited by 98 publications

References 25 publications

Electric Vehicle Charging Load Forecasting: A Comparative Study of Deep Learning Approaches

Electric Vehicle Charging Load Forecasting: A Comparative Study of Deep Learning Approaches

Probabilistic Forecasting of Short-Term Electric Load Demand: An Integration Scheme Based on Correlation Analysis and Improved Weighted Extreme Learning Machine

Cost Consensus Algorithm Applications for EV Charging Station Participating in AGC of Interconnected Power Grid

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