Deep learning-driven hybrid model for short-term load forecasting and smart grid information management

Wen, Xinyu; Liao, Jiacheng; Niu, Qingyi; Shen, Nachuan; Bao, Yingxu

doi:10.1038/s41598-024-63262-x

Cited by 2 publications

References 37 publications

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Short-Term Load Forecasting for Smart Grid based on Bidirectional-LSTM Recurrent Neural Network

Zafar,

Hashmi,

Ayub

et al. 2024

Preprint

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The traditional power grid is evolving into a smart grid, integrating advanced two-way communication technologies and a greater proportion of renewable energy sources, resulting in a more dynamic and flexible network. Accurate load forecasting is crucial for effective operation, planning, and management of the smart grid. Short-term load forecasting (STLF) is particularly challenging due to the high variability and unpredictability in individual consumer behavior, which can impact forecasting accuracy and complicate daily operations and scheduling. Advanced deep learning techniques offer a promising solution to this problem by improving the accuracy of STLF. In this paper, we introduce an ensemble forecasting framework that combines the convolutional neural network (CNN) with a bidirectional long short-term memory (BiLSTM) recurrent neural network with dynamic weight adjustment (DWA). The CNN layers extract features from the data, the DWA layer multiplies the extracted features by their respective dynamic weights before passing them to the BiLSTM model which enhances the forecasting accuracy by capturing both past and future temporal dependencies. We evaluate this framework using a high-resolution real residential smart meter readings dataset and compare its performance against standalone and hybrid models. Our results demonstrate that the BiLSTM-based framework outperforms LSTM-based and traditional approaches in key metrics, including mean absolute percentage error (MAPE) with an improvement of MAPE by 1.99% against the benchmark CNN-LSTM model. This underscores our model's superior accuracy and reliability for STLF, marking a significant advancement over traditional methods. Our model effectively enhances forecasting accuracy in smart grid applications.

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Short-Term Load Forecasting for Smart Grid based on Bidirectional-LSTM Recurrent Neural Network

Zafar,

Hashmi,

Ayub

et al. 2024

Preprint

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Radian Scaling and Its Application to Enhance Electricity Load Forecasting in Smart Cities Against Concept Drift

Bin Kamilin,

Yamaguchi,

Bin Ahmadon

2024

Smart Cities

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In a real-world implementation, machine learning models frequently experience concept drift when forecasting the electricity load. This is due to seasonal changes influencing the scale, mean, and median values found in the input data, changing their distribution. Several methods have been proposed to solve this, such as implementing automated model retraining, feature engineering, and ensemble learning. The biggest drawback, however, is that they are too complex for simple implementation in existing projects. Since the drifted data follow the same pattern as the training dataset in terms of having different scale, mean, and median values, radian scaling was proposed as a new way to scale without relying on these values. It works by converting the difference between the two sequential values into a radian for the model to compute, removing the bounding, and allowing the model to forecast beyond the training dataset scale. In the experiment, not only does the constrained gated recurrent unit model with radian scaling have shorter average training epochs, but it also lowers the average root mean square error from 158.63 to 43.375, outperforming the best existing normalization method by 72.657%.

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Deep learning-driven hybrid model for short-term load forecasting and smart grid information management

Cited by 2 publications

References 37 publications

Short-Term Load Forecasting for Smart Grid based on Bidirectional-LSTM Recurrent Neural Network

Short-Term Load Forecasting for Smart Grid based on Bidirectional-LSTM Recurrent Neural Network

Radian Scaling and Its Application to Enhance Electricity Load Forecasting in Smart Cities Against Concept Drift

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