Accurate Prediction of Hourly Energy Consumption in a Residential Building Based on the Occupancy Rate Using Machine Learning Approaches

Le Hoai My Truong,Ka Ho Karl Chow,Ben Horan,Alex Stojcevski,Gokul Sidarth Thirunavukkarasu,Mehdi Seyedmahmoudian,Rungsimun Luevisadpaibul,Saad Mekhilef

doi:10.3390/app11052229

Le Hoai My Truong, Ka Ho Karl Chow + Show 6 more

Open Access

https://doi.org/10.3390/app11052229

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Abstract

In this paper, a novel deep neural network-based energy prediction algorithm for accurately forecasting the day-ahead hourly energy consumption profile of a residential building considering occupancy rate is proposed. Accurate estimation of residential load profiles helps energy providers and utility companies develop an optimal generation schedule to address the demand. Initially, a comprehensive multi-criteria analysis of different machine learning approaches used in energy consumption predictions was carried out. Later, a predictive micro-grid model was formulated to synthetically generate the stochastic load profiles considering occupancy rate as the critical input. Finally, the synthetically generated data were used to train the proposed eight-layer deep neural network-based model and evaluated using root mean square error and coefficient of determination as metrics. Observations from the results indicated that the proposed energy prediction algorithm yielded a coefficient of determination of 97.5% and a significantly low root mean square error of 111 Watts, thereby outperforming the other baseline approaches, such as extreme gradient boost, multiple linear regression, and simple/shallow artificial neural network.

Highlights

The Australian energy market has been operating on a centralised generation model with state-owned power plants situated closest to fossil fuel resources such as coal, hydro, wind, and natural gas for many years
This study aims to develop a novel deep neural network-based energy prediction algorithm to synthesise hourly load profiles based on the occupancy rate
Root mean square error (RMSE) and coefficient of determination (R2 ) values are the metrics that the models are compared on the results indicated that the proposed deep neural network model outperformed the other models

Summary

Introduction

The Australian energy market has been operating on a centralised generation model with state-owned power plants situated closest to fossil fuel resources such as coal, hydro, wind, and natural gas for many years. The electricity price keeps going up due to the increased investment in distribution infrastructure required to connect households and businesses to a stabilised power supply [1]. The centralised model requires large power plants to meet the demand and significant transmission lines to connect households and businesses with their power source, resulting in colossal air pollutant emissions, wastage of generation, and land use. The fact that it requires a high integration level means that its system is extremely vulnerable to disturbances in the supply chain. Its attractiveness is reducing, and the penetration of small-scale decentralised systems or microgrids is emerging and increasingly invested

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