Minimum Viable Product for Smart Monitoring in Smart Homes
Abstract
Smart Home Energy Management Systems are powerful tools for efficient energy management. In this scenario, monitoring is done by reading information generated by intelligent home appliances. However, it is not every home that owns such equipment, which makes management difficult. In this work, we present a minimum viable product (MVP) of a residential electrical monitoring system capable of extracting information about the energy consumption of common household appliances, through a single point of collection and through consumer signatures to identify these appliances when they are connected to the electrical network.
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Andreoli, A. L. (2005). Controlador de demanda e fator de potˆencia de baixo custo para unidades consumidoras de energia elétrica.
Jaffey, T. (2014). Mqtt and coap, iot protocols. Feb-2014.[Online]. Available: http://www.eclipse. org/community/eclipse newsletter/2014/february/article2. php.[Accessed: 24-Mar-2016].
Khan, I., Mahmood, A., Javaid, N., Razzaq, S., Khan, R., and Ilahi, M. (2013). Home energy management systems in future smart grids. J Basic Appl Sci Res, 3.
Lin, C. M. and Chen, M. T. (2017). Design and implementation of a smart home energy saving system with active loading feature identification and power management. In Proc. IEEE 3rd Int. Future Energy Electronics Conf. and ECCE Asia (IFEEC 2017 - ECCE Asia), pages 739–742.
Nilsson, A., Wester, M., Lazarevic, D., and Brandt, N. (2018). Smart homes, home energy management systems and real-time feedback: Lessons for influencing household energy consumption from a swedish field study. Energy and Buildings, 179:15– 25.
Nyquist, H. (1928). Certain topics in telegraph transmission theory. Transactions of the American Institute of Electrical Engineers, 47(2):617–644.
Pau, G., Collotta, M., Ruano, A., and Qin, J. (2017). Smart home energy management.
Pilloni, V., Floris, A., Meloni, A., and Atzori, L. (2018). Smart home energy management including renewable sources: A qoe-driven approach. IEEE Transactions on Smart Grid, 9(3):2006–2018.
Ramos, M. and Andrade, V. S. (2015). Desenvolvimento, construção e calibração de uma central de monitoramento de consumo de energia elétrica e de água utilizando o microcontrolador arduino. Anais do ENEDS.
Santos, B. P., Silva, L., Celes, C., Borges, J. B., Neto, B. S. P., Vieira, M. A. M., Vieira, L. F. M., Goussevskaia, O. N., and Loureiro, A. (2016). Internet das coisas: da teoria à prática. Minicursos SBRC-Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos.
Siqueira, W. V. B. (2014). O microcontrolador arduino como uma central de monitoramento de consumo de energia elétrica. Monografia de conclusão de curso de bacharelado, Instituto Federal de Educação, Ciência e Tecnologia de Minas Gerais, Governador Valadares, MG, Brasil.
Published
2019-07-19
How to Cite
SEVERINO, Valdenir; VASCONCELOS, Danilo; MILFONT, Ronaldo; ANDRADE, Rossana; SANTOS, Ismayle; ANDRADE, Cassio; FILHO, Jose.
Minimum Viable Product for Smart Monitoring in Smart Homes. In: BRAZILIAN WORKSHOP ON INTELLIGENT CITIES (WBCI), 2. , 2019, Belém.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2019
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DOI: https://doi.org/10.5753/wbci.2019.6745.
