Abstract
Accurate forecasting of demand load is momentous for the efficient economic dispatch of generating units with enormous economic and reliability implications. However, with the high integration levels of grid-tie generations, the precariousness in demand load forecasts is unreliable. This paper proposes a data-driven stochastic ensemble model framework for short-term and long-term demand load forecasts. Our proposed framework reduces uncertainties in the load forecast by fusing homogenous models that capture the dynamics in load state characteristics and exploit model diversities for accurate prediction. The ensemble model caters for factors such as meteorological and exogenous variables that affect load prediction accuracy with adaptable, scalable algorithms that consider weather conditions, load features, and state characteristics of the load. We defined a heuristic trained combiner model and an error correction model to estimate the contributions and compensate for forecast errors of each prediction model, respectively. Acquired data from the Korean Electric Power Company (KEPCO), and building data from the Korea Research Institute, together with testbed datasets, were used to evaluate the developed framework. The results obtained prove the efficacy of the proposed model for demand load forecasting.
Highlights
Developments in the invasive use of grid-flexibility options, such as demand-side management (DSM), require pliability in load prediction mechanisms to match temporal and spatial differences between energy demand and supply [1]
Demand load forecasting complexities are influenced by the nature of the demand load, which is a result of consumer behavior changes, energy policies, and load type
With the same dataset for both training and validation, we estimated the demand load forecast with artificial neural network (ANN) and K-means separately without the ensemble effect
Summary
Developments in the invasive use of grid-flexibility options, such as demand-side management (DSM), require pliability in load prediction mechanisms to match temporal and spatial differences between energy demand and supply [1]. For non-routine energy consumption or generation loads, such as hotels and renewable power, respectively, the energy sequence is randomized, with many variabilities in the energy profile patterns. Such a situation can pose a challenge to predict with generalized prediction models. Wang et al proposed an ensemble forecasting method for the aggregated load with subprofile [23]. In [24], Wang et al proposed a combined probabilistic model for load forecast based on a constrained quantile regression averaging method. This paper focuses on a predictive ensemble with limited available historical datasets to develop a scalable online predictive model for demand load forecasting.
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