Household appliance usage recommendation based on demand forecasting and multi­objective optimization

Authors

DOI:

https://doi.org/10.33448/rsd-v11i1.24515

Keywords:

Time Series Forecasting; Multi­-objective optimization; Smart Home Systems; Recommendation systems.

Abstract

Accelerated population growth in the 21st century and increased demand for energy sources, associated with climate change, have resulted in two main challenges: the search for sustainable energy sources and the need to find more efficient ways to use extant sustainable sources. The forecasting module provides an estimate of the future usage of these appliances and it is the source of the recommended module’s suggestion. Time Series Forecasting techniques, such as Autoregressive Integrated Moving Average, Long­Short Term Memory (LSTM), Gated Recurrent Units, Echo State Networks (ESN), and Support Vector Regression, were tested for the predictive module. Multi­objective optimization techniques such as Non­Sorted Genetic Algorithm II (NSGA II), Multi­Objective Particle Swarm Optimization (MOPSO), Speed constrained Multi-­objective Particle Swarm Optimization (SMOPSO), and Strength Pareto Evolutionary Algorithm two (SPEA2), for example, were tested for the Recommendation Module. The Forecasting and Recommendation module experiments were performed independently. In the Forecasting Module, the results and statistical tests revealed LSTM as the best­ suited technique for forecasting the loads of the majority of the appliances tested (in this case seven) in terms of root mean square error. In the experiments performed for the recommendation module, NSGA II showed a higher overall performance compared to other metrics in terms of hyper volume of the Pareto Front generated. This work presents the potential of using both Predictive Models and Multi­Objective Optimization Techniques combined to reduce energy usage in household environments.

Author Biographies

Allan Rivalles Souza Feitosa, Universidade Federal de Pernambuco

Researcher in Bio-inspired computational intelligence techniques and artificial intelligence developer in Research and Development projects. Doctoral candidate in Computer Science at the Federal University of Pernambuco, Master in Biomedical Engineering at UFPE and Biomedical Technician. He worked on the Master's with computational intelligence and bio-inspired algorithms applied to reconstruction of Electrical Impedance Tomography images, generating several publications with high citation levels. Currently working with computational intelligence algorithms, such as optimization algorithms (linear programming, genetic algorithms, differential evolution, particle swarm optimization and the dialectical method of optimization) as well as machine learning algorithms (Artificial Neural Networks, SVM, ELM, Deep Learning), applied to energy saving problems, smart cities, industrial process optimization, smart cars, smart grids and natural language processing aimed at legal problems.

Henrique Figuerôa Lacerda, Universidade Federal de Pernambuco

Henrique Figueroa Lacerda is a Computer Engineer with a Master's Degree in Computer Science from the Informatics Center of the Federal University of Pernambuco (2017). He specializes in computer networks, artificial intelligence and computer architecture design to reduce electrical energy consumption.

Abel Guilhermino da Silva Filho, Universidade Federal de Pernambuco

Abel Guilhermino da Silva Filho is currently a Productivity Scholarship in Technological Development and Innovative Extension at CNPq, Level 2 (DT 2), PhD in Computer Science from the Federal University of Pernambuco (UFPE) since 2006, and Associate Professor at UFPE, based at Centro de Informática (CIn), since 2008. He is the author and co-author of scientific articles published covering some research topics in the field of embedded systems in the field of optimization mechanisms for reducing energy consumption, computer architecture, reconfigurable architectures , high-performance applications, evolutionary algorithms for power reduction, cache memory and memory hierarchies, and health issues applied to embedded systems such as cancer segmentation and DNA sequencing, as well as innovative research in connectivity and automotive applications. At UFPE, he is part of the Computer Engineering Group (GRECO), the Radio Frequency Group and the High Performance Computing Group (HPCIn). Since 2007, I have coordinated 5 research projects (FACEPE PPP 2007, CNPq Universal 2008, CAPES Pro-Equipamentos 2009 and FACEPE APQ 2010, UFPE/PROACAD - Laboratory Improvement 2012, CNPq Universal 2013 and currently I coordinate 1 research project (FACEPE PRONEM 2014 ) and participates as a collaborator in some research projects (FINEP CT-Infra 2013 and CT-Infra 2018). He has also been a consultant for R&D Projects (CENPES/PETROBRAS Seismic since 2008, CTEEP/Informa Middleware 2012, SAMSUNG SMART_POWER 2012 and R&D MOTOROLA Mobile, 2015. He recently coordinated an extension project with FUCAPI/AM in 2016 to improve the efficient use of energy in mobile telephony and participates as a collaborator in the extension project NETBio (Nucleus for Social Technologies and Bioengineering). a strategic project for the State of Pernambuco and relevant for the country with Fiat Chrysler Automobiles (FCA) in the area of ​​Electrical Engineering, in particular Innovation in connectivity and IoT, a project that began o in 2015 and remains in force. In addition, does he also coordinate another project with FCA, in the Powertrain area? Vehicle Engines, developing innovative solutions and intelligent computing for problems related to the vehicle engine. He currently has 14 completed master's orientations, 4 completed doctoral orientations, and advises 3 master's students and 6 doctoral students. He is the research leader at the Vehicle Innovation Laboratory (LIVE), in which he develops innovative solutions in the context of smart cities, and has a team of 15 people in the laboratory.

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Published

03/01/2022

How to Cite

FEITOSA, A. R. S.; LACERDA, H. F.; SANTOS, W. P. dos .; SILVA FILHO, A. G. da. Household appliance usage recommendation based on demand forecasting and multi­objective optimization. Research, Society and Development, [S. l.], v. 11, n. 1, p. e13411124515, 2022. DOI: 10.33448/rsd-v11i1.24515. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/24515. Acesso em: 18 dec. 2024.

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Section

Engineerings