A Data-Driven Scheduling Approach for Hydrogen Penetrated Energy System Using LSTM Network

Abstract: Intra-day control and scheduling of energy systems require high-speed computation and strong robustness. Conventional mathematical driven approaches usually require high computation resources and have difficulty handling system uncertainties. This paper proposes two data-driven scheduling approaches for hydrogen penetrated energy system (HPES) operational scheduling. The two data-driven approaches learn the historical optimization results calculated out using the mixed integer linear programing (MILP) and cond… Show more

“…Similarly, Alabi et al (2022b) combine deep learning for prediction and optimization methods for optimal scheduling of multi-energy systems. Zhou et al (2019) use a LSTM model trained on pre-solved MILP solutions to predict the operation of a hydrogen-penetrated energy system. However, the computation time of the operational optimization is not examined, and the optimization problem is relatively small (11 variables over 24 h).…”

Boosting operational optimization of multi-energy systems by artificial neural nets

“…Similarly, Alabi et al (2022b) combine deep learning for prediction and optimization methods for optimal scheduling of multi-energy systems. Zhou et al (2019) use a LSTM model trained on pre-solved MILP solutions to predict the operation of a hydrogen-penetrated energy system. However, the computation time of the operational optimization is not examined, and the optimization problem is relatively small (11 variables over 24 h).…”

Boosting operational optimization of multi-energy systems by artificial neural nets

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