Abstract
Short-term electricity load forecasting is key to the safe, reliable, and economical operation of power systems. An important challenge that arises with high-frequency load series, e.g., hourly load, is how to deal with the complex seasonal patterns that are present. Standard approaches suggest either removing seasonality prior to modeling or applying time series decomposition. This work proposes a hybrid approach that combines Singular Spectrum Analysis (SSA)-based decomposition and Artificial Neural Networks (ANNs) for day-ahead hourly load forecasting. First, the trajectory matrix of the time series is constructed and decomposed into trend, oscillating, and noise components. Next, the extracted components are employed as exogenous regressors in a global forecasting model, comprising either a Multilayer Perceptron (MLP) or a Long Short-Term Memory (LSTM) predictive layer. The model is further extended to include exogenous features, e.g., weather forecasts, transformed via parallel dense layers. The predictive performance is evaluated on two real-world datasets, controlling for the effect of exogenous features on predictive accuracy. The results showcase that the decomposition step improves the relative performance for ANN models, with the combination of LSTM and SAA providing the best overall performance.
Highlights
The Seasonal and Trend decomposition using Loess (STL) with exponential smoothing has a similar performance to the base Artificial Neural Networks (ANNs) model, i.e., the simple Multilayer Perceptron (MLP), which in turn outperforms the other statistical benchmarks
We proposed a hybrid methodology to combine Singular Spectrum Analysis (SSA)-based decomposition with ANNs and, in particular Long Short-Term Memory (LSTM), for predicting day-ahead hourly electricity load
The results on two real-world are consistent in showing that the decomposition step reduces the prediction error for both MLPs and LSTMs
Summary
Accurate electricity load forecasting is critical for the safe and reliable operation of power systems, as demand and supply need to be in constant equilibrium. The increased penetration of variable renewable energy sources (VREs) in the generation mix over recent years adds another dimension of complexity by introducing uncertainty on the supply side and by further reinforcing the effect of weather, e.g., solar radiation and wind, on the load profile. This leads to increased imbalance volumes, further affecting subsequent spot electricity prices [2]. Increased load uncertainty leads to an overall increase in production cost, further underlining the crucial role of accurate load forecasting in facilitating the ongoing transition towards an emissions-free electricity grid
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