Smart Meters Big Data : Behavioral Analytics via Incremental Data Mining and Visualization

• Main Author: Singh, Shailendra
• Other Authors: Shirmohammadi, Shervin
• Language: en
• Published: Université d'Ottawa / University of Ottawa 2016
• Subjects: Smart Grid; Smart Meter; Behavioral Analytics; Data-Driven Approach; Energy Consumption Patterns; Frequent Pattern; Correlation Pattern; Cluster Analysis; Online Data Mining; Incremental Data Mining; Distributed Data Mining; Association Rules; Appliance Usage Prediction; Energy Consumption Prediction; Prediction; Visualization
• Online Access: http://hdl.handle.net/10393/35244; http://dx.doi.org/10.20381/ruor-202

The big data framework applied to smart meters offers an exception platform for data-driven forecasting and decision making to achieve sustainable energy efficiency. Buying-in consumer confidence through respecting occupants' energy consumption behavior and preferences towards improved participation in various energy programs is imperative but difficult to obtain. The key elements for understanding and predicting household energy consumption are activities occupants perform, appliances and the times that appliances are used, and inter-appliance dependencies. This information can be extracted from the context rich big data from smart meters, although this is challenging because: (1) it is not trivial to mine complex interdependencies between appliances from multiple concurrent data streams; (2) it is difficult to derive accurate relationships between interval based events, where multiple appliance usage persist; (3) continuous generation of the energy consumption data can trigger changes in appliance associations with time and appliances. To overcome these challenges, we propose an unsupervised progressive incremental data mining technique using frequent pattern mining (appliance-appliance associations) and cluster analysis (appliance-time associations) coupled with a Bayesian network based prediction model. The proposed technique addresses the need to analyze temporal energy consumption patterns at the appliance level, which directly reflect consumers' behaviors and provide a basis for generalizing household energy models. Extensive experiments were performed on the model with real-world datasets and strong associations were discovered. The accuracy of the proposed model for predicting multiple appliances usage outperformed support vector machine during every stage while attaining accuracy of 81.65\%, 85.90\%, 89.58\% for 25\%, 50\% and 75\% of the training dataset size respectively. Moreover, accuracy results of 81.89\%, 75.88\%, 79.23\%, 74.74\%, and 72.81\% were obtained for short-term (hours), and long-term (day, week, month, and season) energy consumption forecasts, respectively.