Kuangpu Liu scite author profile

Scenario generations for renewable energy sources and loads play an important role in the stable operation and risk assessment of integrated energy systems. This paper proposes a deep generative network based method to model timeseries curves, e.g., power generation curves and load curves, of renewable energy sources and loads based on implicit maximum likelihood estimations (IMLEs), which can generate realistic scenarios with similar patterns as real ones. After training the model, any number of new scenarios can be obtained by simply inputting Gaussian noises into the data generator of IM-LEs. The proposed approach does not require any model assumptions or prior knowledge of the form in the likelihood function being made during the training process, which leads to stronger applicability than explicit density model based methods. The extensive experiments show that the IMLEs accurately capture the complex shapes, frequency-domain characteristics, probability distributions, and correlations of renewable energy sources and loads. Moreover, the proposed approach can be easily generalized to scenario generation tasks of various renewable energy sources and loads by fine-tuning parameters and structures.

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A Double-Deck Deep Reinforcement Learning-Based Energy Dispatch Strategy for an Integrated Electricity and District Heating System Embedded with Thermal Inertial and Operational Flexibility

Zhang

Liu

2022

SSRN Journal

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Energy Management Strategy for Smart Homes Based on Deep Reinforcement Learning

Liu

Zhang

Liao³

et al. 2022

SSRN Journal

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Kuangpu Liu

Ultra-short-term Interval Prediction of Wind Power Based on Graph Neural Network and Improved Bootstrap Technique

Electricity Theft Detection Using Euclidean and Graph Convolutional Neural Networks

Scenario Generations for Renewable Energy Sources and Loads Based on Implicit Maximum Likelihood Estimations

A Double-Deck Deep Reinforcement Learning-Based Energy Dispatch Strategy for an Integrated Electricity and District Heating System Embedded with Thermal Inertial and Operational Flexibility

Energy Management Strategy for Smart Homes Based on Deep Reinforcement Learning

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