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Autores principales: Baviera, Roberto, Manzoni, Pietro
Formato: Preprint
Publicado: 2022
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Acceso en línea:https://arxiv.org/abs/2209.01378
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author Baviera, Roberto
Manzoni, Pietro
author_facet Baviera, Roberto
Manzoni, Pietro
contents An elementary Recurrent Neural Network that operates on p time lags, called an RNN(p), is the natural generalisation of a linear autoregressive model ARX(p). It is a powerful forecasting tool for variables displaying inherent seasonal patterns across multiple time scales, as is often observed in energy, economic, and financial time series. The architecture of RNN(p) models, characterised by structured feedbacks across time lags, enables the design of efficient training strategies. We conduct a comparative study of learning algorithms for these models, providing a rigorous analysis of their computational complexity and training performance. We present two applications of RNN(p) models in power consumption forecasting, a key domain within the energy sector where accurate forecasts inform both operational and financial decisions. Experimental results show that RNN(p) models achieve excellent forecasting accuracy while maintaining a high degree of interpretability. These features make them well-suited for decision-making in energy markets and other fintech applications where reliable predictions play a significant economic role.
format Preprint
id arxiv_https___arxiv_org_abs_2209_01378
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle RNN(p) for Power Consumption Forecasting
Baviera, Roberto
Manzoni, Pietro
Machine Learning
Signal Processing
Statistical Finance
An elementary Recurrent Neural Network that operates on p time lags, called an RNN(p), is the natural generalisation of a linear autoregressive model ARX(p). It is a powerful forecasting tool for variables displaying inherent seasonal patterns across multiple time scales, as is often observed in energy, economic, and financial time series. The architecture of RNN(p) models, characterised by structured feedbacks across time lags, enables the design of efficient training strategies. We conduct a comparative study of learning algorithms for these models, providing a rigorous analysis of their computational complexity and training performance. We present two applications of RNN(p) models in power consumption forecasting, a key domain within the energy sector where accurate forecasts inform both operational and financial decisions. Experimental results show that RNN(p) models achieve excellent forecasting accuracy while maintaining a high degree of interpretability. These features make them well-suited for decision-making in energy markets and other fintech applications where reliable predictions play a significant economic role.
title RNN(p) for Power Consumption Forecasting
topic Machine Learning
Signal Processing
Statistical Finance
url https://arxiv.org/abs/2209.01378