Enhanced approaches for non-intrusive load disaggregation
The modern urban life and increasing demands of energy are calling toward energy conservation and energy efficient strategies. Energy saving and energy management in the residential sectors are of great interests for obvious economic and environmental reasons, with increasing energy consumptions...
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Format: | Theses and Dissertations |
Language: | English |
Published: |
2018
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Online Access: | https://hdl.handle.net/10356/90196 http://hdl.handle.net/10220/47182 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | The modern urban life and increasing demands of energy are calling toward energy
conservation and energy efficient strategies. Energy saving and energy management in
the residential sectors are of great interests for obvious economic and environmental
reasons, with increasing energy consumptions by the consumers. An efficient energy
conservation and monitoring program requires some means of monitoring the power
consumed by individual appliances within the households. The deployment of smart
meters in smart grids in many countries has generated an increase in research interests
in the areas of non-intrusive load monitoring (NILM) in recent years. Non-intrusive load
monitoring, or load disaggregation, are sets of techniques and methods that decompose
the total aggregate consumptions, measured at a single point by smart meters, into the
respective appliance-specific consumptions in the household. Studies conducted have
shown that information of the energy consumed by individual appliances in the homes
can influence the behavior of the household occupants in a way that can achieve
noticeable energy savings. There are several challenges in the domain of unsupervised
load disaggregation approaches that do not require human intervention for learning or
installation of additional measuring instruments for each appliance, apart from the smart
meters, allowing a feasible economic adoption of NILM techniques.
In this thesis, a detailed literature review on methods and techniques applied to NILM
and common challenges is presented. Enhanced approaches that tackle three essential
challenges in the domain of NILM were proposed. Firstly, with the aim to achieve an
improved disaggregation accuracy, an unsupervised approach for load disaggregation
that embeds the mutual devices interactions information into the factorial hidden
Markov model (FHMM) representation of the total aggregate signal was introduced. The method was further extended with adaptive estimations of the devices main power
consumptions effects and their two-way interactions. Secondly, the modeling of
continuously varying loads was proposed using a quantized continuous-state hidden
Markov model (CS-HMM). A method to estimate the transition matrix that mitigates
the both extreme cases of too frequent and never occurred transitions was introduced
and the Viterbi algorithm was used to estimate the power consumption profile of the
variable loads. Thereafter, the proposed model for the continuously varying loads was
integrated with the standard FHMM to produce a hybrid continuous/discrete state
HMM, which is capable of modeling and disaggregating energy consumptions from a
wider range of home appliances types. Thirdly, to tackle the problem of overlapping
clusters that represent devices power consumptions resulting when applying a
clustering-based disaggregation, a method to analyze the cohesion of devices’ clusters
to determine if a cluster should be split into two small clusters was proposed. The
analysis of clusters cohesion was investigated based on normality tests performed
against two confidence levels.
The proposed approaches and techniques were applied and tested on real houses from
the Reference Energy Disaggregation Data Set (REDD). The proposed approaches, in
general, enhanced the overall performance and accuracy of disaggregation. The work
presented in thesis represents an advancement in the state-of-art in the domain of NILM
and contributes toward achieving energy savings in residential homes. |
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