Non-Intrusive Load Identification of Residential Appliances Using Improved Dictionary Learning Technique
DOI:
https://doi.org/10.57041/xm49bx49Keywords:
Dictionary learning, non-intrusive load monitoring, residential load, sparse representationAbstract
With the advent of time, the demand for power in the residential sector is increasing. Along with supply-side management, the demand side is also used to balance electricity and supply demand. To apply different demand-side management techniques, the energy disaggregation on metered data is used to retrieve information related to available demand. Non-intrusive load monitoring is a technique that separates the total power consumption into appliance loads with minimum invasion of privacy. Non-intrusive load monitoring covers the methods of Stochastic finite state machines, Neural Networks and Sparse Coding. Developing an efficient algorithm for NILM is a key challenge in maximizing energy conservation. Recently, a new deep learning technique called dictionary learning has been developed for energy disaggregation. Smart meters provide the whole house data, and the Dictionary technique is trained to predict an appliance's power or ON/OFF based on its power consumption. This research proposes the event-based dictionary learning technique, which can disaggregate multiple appliances through orthogonal matching pursuit (OMP) and kernel-singular value decomposition (K-SVD). The sparse matrix is predicted through OMP, and K-SVD predicts the dictionary matrix. The training, testing and validation are done on the ECO dataset. The results of this research are noticeable and show the validity of the proposed methodology for energy disaggregation.Downloads
Published
2023-12-30
Issue
Section
Articles
License
Copyright (c) 2023 https://grsh.org/journal1/index.php/jaic/cr
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
How to Cite
Non-Intrusive Load Identification of Residential Appliances Using Improved Dictionary Learning Technique. (2023). Journal of Artificial Intelligence and Computing, 1(2), 30-36. https://doi.org/10.57041/xm49bx49
