Dai, Shuang (2023) A Distributed and Real-time Machine Learning Framework for Smart Meter Big Data. Doctoral thesis, University of Essex.
Dai, Shuang (2023) A Distributed and Real-time Machine Learning Framework for Smart Meter Big Data. Doctoral thesis, University of Essex.
Dai, Shuang (2023) A Distributed and Real-time Machine Learning Framework for Smart Meter Big Data. Doctoral thesis, University of Essex.
Abstract
The advanced metering infrastructure allows smart meters to collect high-resolution consumption data, thereby enabling consumers and utilities to understand their energy usage at different levels, which has led to numerous smart grid applications. Smart meter data, however, poses different challenges to developing machine learning frameworks than classic theoretical frameworks due to their big data features and privacy limitations. Therefore, in this work, we aim to address the challenges of building machine learning frameworks for smart meter big data. Specifically, our work includes three parts: 1) We first analyze and compare different learning algorithms for multi-level smart meter big data. A daily activity pattern recognition model has been developed based on non-intrusive load monitoring for appliance-level smart meter data. Then, a consensus-based load profiling and forecasting system has been proposed for individual building level and higher aggregated level smart meter data analysis; 2) Following discussion of multi-level smart meter data analysis from an offline perspective, a universal online functional analysis model has been proposed for multi-level real-time smart meter big data analysis. The proposed model consists of a multi-scale load dynamic profiling unit based on functional clustering and a multi-scale online load forecasting unit based on functional deep neural networks. The two units enable online tracking of the dynamic cluster trajectories and online forecasting of daily multi-scale demand; 3) To enable smart meter data analysis in the distributed environment, FederatedNILM was proposed, which is then combined with differential privacy to provide privacy guarantees for the appliance-level distributed machine learning framework. Based on federated deep learning enhanced with two schemes, namely the utility optimization scheme and the privacy-preserving scheme, the proposed distributed and privacy-preserving machine learning framework enables electric utilities and service providers to offer smart meter services on a large scale.
Item Type: | Thesis (Doctoral) |
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Subjects: | H Social Sciences > HA Statistics Q Science > QA Mathematics > QA75 Electronic computers. Computer science |
Divisions: | Faculty of Science and Health > Mathematical Sciences, Department of |
Depositing User: | Shuang Dai |
Date Deposited: | 03 Jul 2023 16:30 |
Last Modified: | 03 Jul 2023 16:30 |
URI: | http://repository.essex.ac.uk/id/eprint/35901 |
Available files
Filename: ShuangDai_DAISH64702_Thesis_FinalSubmitted.pdf