Abstract
In this paper, three main approaches (univariate, multivariate and multistep) for electricity consumption forecasting have been investigated. In fact, three major algorithms (XGBOOST, LSTM and SARIMA) have been evaluated in each approach with the main aim to figure out which one performs the best in forecasting electricity consumption. The motivation behind this work is to assess the forecasting accuracy and the computational time/complexity for an embedded forecasting and model training at the smart meter level. Moreover, we investigate the deployment of the most efficient model in our platform for an online electricity consumption forecasting. This solution will serve for deploying predictive control solutions for efficient energy management in buildings. As a proof of concept, an already existing public dataset has been used. These data were mainly collected thanks to the usage of already deployed sensors. These provide accurate data related to occupancy (e.g., presence) as well as contextual data (e.g., disaggregated electricity consumption of equipment). Experiments have been conducted and the results showed the effectiveness of these algorithms, used in each approach, for short-term electricity consumption forecasting. This has been proved by performance evaluation and error calculations. The obtained results mainly shed light on the challenging trade-off between embedded forecasting model training and processing for being deployed in smart meters for electricity consumption forecasting.
Highlights
During the last few decades, big importance has been given to electric load prediction and forecasting
The work presented in this paper investigates three major algorithms from three categories, XGBOOST, long shortterm memory (LSTM) (AI based) and SARIMA, for load forecasting
This latter can be calculated by dividing the computational time necessary to accomplish the forecast by the relative time necessary for a naïve method (e.g., autoregressive integrated moving average (ARIMA))
Summary
During the last few decades, big importance has been given to electric load prediction and forecasting. It represents an important parameter used by many electric utilities for optimal planning and operational decisions. It was noticed that the level of management of these utilities has shifted from large-scale management of the entire grid to a small household level scale. This is mainly due to: (i) an energy market transition from centralized electricity production to decentralized or distributed production, and (ii) the load control, which is required for demand-side management [1]. The non-linearity of household consumption data and rapid fluctuations are caused by many exogenous factors, such as occupants’ behavior, the impact of calendar periods and the uncertainty of weather information [3,4]
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