A COMPARATIVE ANALYSIS OF PREDICTIVE MODELS FOR HOUSEHOLD ENERGY CONSUMPTION IN LAGOS

Authors

  • Raheem, W. A.,

    University of Lagos, Lagos State, Nigeria

  • Omiyale, A. D

    University of Lagos, Lagos State, Nigeria

  • Odeyinka, O. F.

    Corona College of Education, Lagos, Lagos State, Nigeria

  • Folorunso, C

    Corona College of Education, Lagos, Lagos State, Nigeria

DOI:
https://doi.org/10.51459/futajeet.2025.19.2.497
Keywords:
Artificial neural networks, autoregressive integrated moving average, energy consumption, linear regression, machine learning
Abstract

Rapid urbanisation, unreliable electricity supply, and increasing reliance on electrical appliances have heightened residential energy demand and created the need for accurate prediction of household energy usage. While deep learning and hybrid predictive models have been increasingly applied to energy forecasting globally, their use in African contexts remains comparatively limited, with relatively few studies addressing the added complexities of infrastructural fragility and diverse user behaviours. In Nigeria, there has been limited effort in comparative modelling research, particularly at the household level, where energy behaviour is shaped by a complex interplay of socio-economic and infrastructural factors. This study examines household energy consumption patterns in Lagos, Nigeria, using a comparative, multi-model approach. Data from 350 households, including socio-economic status, appliance usage, billing methods, and conservation practices were collected and analyzed. The results of four predictive models, Linear Regression, Artificial Neural Networks (ANN), AutoRegressive Integrated Moving Average (ARIMA), and a hybrid ARIMA–Long Short-Term Memory (LSTM) model, were compared. Findings indicate that household income, dwelling type, and appliance usage are significant predictors of electricity consumption. Among the models, the hybrid ARIMA–LSTM achieved the best performance (RMSE of 580, MAE of 400, R² of 0.85), combining the strengths of both linear and non-linear modeling. The ANN model also demonstrated strong predictive accuracy (R² of 0.79), while linear regression was limited by its inability to capture complex relationships. The results highlight the potential of integrating machine learning into urban energy planning. Policymakers could use these insights to support targeted interventions such as smart metering, appliance subsidies, and behaviour-based demand management.

 

Author Biographies
  1. Raheem, W. A., , University of Lagos, Lagos State, Nigeria

            Department of Systems Engineering, University of Lagos, Lagos State, Nigeria

  2. Omiyale, A. D, University of Lagos, Lagos State, Nigeria

    Department of Systems Engineering

  3. Odeyinka, O. F. , Corona College of Education, Lagos, Lagos State, Nigeria

    Department of Computer Science Education

  4. Folorunso, C, Corona College of Education, Lagos, Lagos State, Nigeria

    Department of Computer Science Education

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Published
2025-11-28
Issue
Vol. 19 No. 2 (2025): FUTA Journal of Engineering and Engineering Technology
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How to Cite

A COMPARATIVE ANALYSIS OF PREDICTIVE MODELS FOR HOUSEHOLD ENERGY CONSUMPTION IN LAGOS. (2025). FUTA JOURNAL OF ENGINEERING AND ENGINEERING TECHNOLOGY, 19(2), 63-73. https://doi.org/10.51459/futajeet.2025.19.2.497

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