Abstract
Next-generation power systems aim at optimizing the energy consumption of household appliances by utilising computationally intelligent techniques, referred to as load monitoring. Non-intrusive load monitoring (NILM) is considered to be one of the most cost-effective methods for load classification. The objective is to segregate the energy consumption of individual appliances from their aggregated energy consumption. The extracted energy consumption of individual devices can then be used to achieve demand-side management and energy saving through optimal load management strategies. Machine learning (ML) has been popularly used to solve many complex problems including NILM. With the availability of the energy consumption datasets, various ML algorithms have been effectively trained and tested. However, most of the current methodologies for NILM employ neural networks only for a limited operational output level of appliances and their combinations (i.e., only for a small number of classes). On the contrary, this work depicts a more practical scenario where over a hundred different combinations were considered and labelled for the training and testing of various machine learning algorithms. Moreover, two novel concepts—i.e., thresholding/occurrence per million (OPM) along with power windowing—were utilised, which significantly improved the performance of the trained algorithms. All the trained algorithms were thoroughly evaluated using various performance parameters. The results shown demonstrate the effectiveness of thresholding and OPM concepts in classifying concurrently operating appliances using ML.
Highlights
There has been a greater focus on utilising renewable energy resources since the KyotoProtocol in order to reduce the effects of greenhouse gasses, global warming and reduce our carbon footprint
This paper focuses on the second technique, commonly known as non-intrusive load monitoring (NILM)
To improve the macro accuracy, we demonstrate the impact of utilising the concepts of occurrence per million (OPM)/thresholding and power windowing on the trained algorithms by reevaluating the macro accuracy on the Reference Energy Disaggregation Dataset (REDD) House 1 dataset
Summary
There has been a greater focus on utilising renewable energy resources since the KyotoProtocol in order to reduce the effects of greenhouse gasses, global warming and reduce our carbon footprint. The integration of unpredictable renewable energy into the power grid acts as the driving force towards the evolution of the existing grid system to smart grid— characterised by bi-directional power flow, control and two-way communication. This provides an opportunity to achieve enhanced energy efficiency through user participation. Next-generation power systems intend to exploit artificial intelligence and machine learning to design sustainable energy systems. These systems are likely to work with smart grids to optimise energy consumption [1].
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