A deep spatial-temporal data-driven approach considering microclimates for power system security assessment

With the integration of renewable energy and microclimate-sensitive loads, secure and economic power system operation is becoming an increasingly important and complex problem. Therefore, based on big data from power systems and meteorological systems, a deep spatial-temporal data-driven model is proposed to predict and detect power system security weak spots during a future period. First, microclimates are considered in the proposed model. Then, a deep neural network structure is designed to extract deep features layer by layer for security weak spot detection. Furthermore, model simplification and parallelism as well as data parallelism are applied. Finally, the proposed model is evaluated based on the Guangdong Power Grid in China. The simulation results demonstrate that (1) power system security weak spots have spatial-temporal and microclimate-sensitive characteristics; (2) the deep model considering microclimates can greatly improve the task accuracy of online applications; and (3) simplification and parallelism can significantly enhance the training efficiency.

[1]  Canbing Li,et al.  Interaction between urban microclimate and electric air-conditioning energy consumption during high temperature season , 2014 .

[2]  Christopher Tull,et al.  A data-driven predictive model of city-scale energy use in buildings , 2017 .

[3]  Weiwei Miao,et al.  Online voltage security assessment considering comfort-constrained demand response control of distributed heat pump systems , 2012 .

[4]  Júlia Seixas,et al.  Effects of renewables penetration on the security of Portuguese electricity supply , 2014 .

[5]  Sijie Chen,et al.  Deep learning hybrid method for islanding detection in distributed generation , 2018 .

[6]  Sumit Saroha,et al.  Wind power forecasting using wavelet transforms and neural networks with tapped delay , 2018 .

[7]  Tatiana Filatova,et al.  Trade-offs between electrification and climate change mitigation: An analysis of the Java-Bali power system in Indonesia , 2017 .

[8]  Vivek Srikumar,et al.  Predicting electricity consumption for commercial and residential buildings using deep recurrent neural networks , 2018 .

[9]  Fu Xiao,et al.  Analytical investigation of autoencoder-based methods for unsupervised anomaly detection in building energy data , 2018 .

[10]  Nitish Srivastava,et al.  Dropout: a simple way to prevent neural networks from overfitting , 2014, J. Mach. Learn. Res..

[11]  Brantley Liddle,et al.  How Much Does Increasing Non-fossil Fuels in Electricity Generation Reduce Carbon Dioxide Emissions? , 2016 .

[12]  Geoffrey E. Hinton,et al.  Reducing the Dimensionality of Data with Neural Networks , 2006, Science.

[13]  S. Chou,et al.  Clean, efficient and affordable energy for a sustainable future , 2017 .

[14]  Yitao Liu,et al.  Deep belief network based deterministic and probabilistic wind speed forecasting approach , 2016 .

[15]  Hongbin Sun,et al.  A Distributed Computing Platform Supporting Power System Security Knowledge Discovery Based on Online Simulation , 2017, IEEE Transactions on Smart Grid.

[16]  Yitao Liu,et al.  Deep learning based ensemble approach for probabilistic wind power forecasting , 2017 .

[17]  Amanda D. Smith,et al.  Predicting heating demand and sizing a stratified thermal storage tank using deep learning algorithms , 2018, Applied Energy.

[18]  Zhi Wu,et al.  A bi-level planning approach for hybrid AC-DC distribution system considering N-1 security criterion , 2018 .

[19]  Linni Jian,et al.  A novel real-time scheduling strategy with near-linear complexity for integrating large-scale electric vehicles into smart grid , 2018 .

[20]  Bart De Schutter,et al.  Forecasting spot electricity prices Deep learning approaches and empirical comparison of traditional algorithms , 2018 .

[21]  Zhinong Wei,et al.  Probabilistic available transfer capability calculation considering static security constraints and uncertainties of electricity–gas integrated energy systems , 2016 .

[22]  Tanveer Ahmad,et al.  Deep learning-based fault diagnosis of variable refrigerant flow air-conditioning system for building energy saving , 2018, Applied Energy.

[23]  Tetsuo Tezuka,et al.  Prioritizing mitigation efforts considering co-benefits, equity and energy justice: Fossil fuel to renewable energy transition pathways , 2018, Applied Energy.

[24]  Fu Xiao,et al.  A short-term building cooling load prediction method using deep learning algorithms , 2017 .

[25]  Jie Zhang,et al.  A data-driven multi-model methodology with deep feature selection for short-term wind forecasting , 2017 .

[26]  R. Sunitha,et al.  Online Static Security Assessment Module Using Artificial Neural Networks , 2013, IEEE Transactions on Power Systems.

[27]  S. Krauter,et al.  Photovoltaic yield prediction using an irradiance forecast model based on multiple neural networks , 2018 .

[28]  Luis Olmos,et al.  Security of supply in a carbon-free electric power system: The case of Iceland , 2018 .

[29]  Gang Liu,et al.  Modeling of district load forecasting for distributed energy system , 2017 .

[30]  K. Morison,et al.  Power system security assessment , 2004, IEEE Power and Energy Magazine.

[31]  Tianshu Bi,et al.  Decision tree based online stability assessment scheme for power systems with renewable generations , 2015 .

[32]  Subhash Kumar Assessment of renewables for energy security and carbon mitigation in Southeast Asia: The case of Indonesia and Thailand , 2016 .