Non-Intrusive Load Monitoring of Residential Water-Heating Circuit Using Ensemble Machine Learning Techniques

Rehman, Attique Ur; Lie, Tek Tjing; Vallès, Brice; Tito, Shafiqur Rahman

doi:10.3390/inventions5040057

Cited by 9 publications

(7 citation statements)

References 53 publications

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“…The key is the effective design of the ensemble strategy, where the reliability and variability of individual classifiers matter. Researchers from New Zealand have conducted some preliminary explorations by using ensemble machine learning techniques in NILM [31]. Although only water heating is considered and the ensemble design is constrained to the problem scenario, which highly limits the potentials for widespread applications, such an attempt is an encouraging exploration.…”

Section: Research Gapmentioning

confidence: 99%

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Toward Robust Non-Intrusive Load Monitoring via Probability Model Framed Ensemble Method

Liu

Wang

Hong

et al. 2021

Sensors

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As a pivotal technological foundation for smart home implementation, non-intrusive load monitoring is emerging as a widely recognized and popular technology to replace the sensors or sockets networks for the detailed household appliance monitoring. In this paper, a probability model framed ensemble method is proposed for the target of robust appliance monitoring. Firstly, the non-intrusive load disaggregation-oriented ensemble architecture is presented. Then, dictionary learning model is utilized to formulate the individual classifier, while the sparse coding-based approach is capable of providing multiple solutions under greedy mechanism. Furthermore, a fully probabilistic model is established for combined classifier, where the candidate solutions are all labelled with probability scores and evaluated via two-stage decision-making. The proposed method is tested on both low-voltage network simulator platform and field measurement datasets, and the results show that the proposed ensemble method always guarantees an enhancement on the performance of non-intrusive load disaggregation. Besides, the proposed approach shows high flexibility and scalability in classification model selection. Therefore, by initializing the architecture and approach of ensemble method-based NILM, this work plays a pioneer role in using ensemble method to improve the robustness and reliability of non-intrusive appliance monitoring.

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Section: Research Gapmentioning

confidence: 99%

“…Such attempts are with high difficulty and failure rates. So, although ensemble method has been demonstrated to be effective in NILM problem [31], the explorations of related studies are limited.…”

Section: New Contributionsmentioning

confidence: 99%

Toward Robust Non-Intrusive Load Monitoring via Probability Model Framed Ensemble Method

Liu

Wang

Hong

et al. 2021

Sensors

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“…Half of the TCLs are switched on at the beginning of a simulation, while the other half is off. This corresponds to values of switch = 1 for TCLs 1-10 and switch = 0 for TCLs 11-20 in the 20 TCL setup, where the switch value changes according to Equation (9). If the temperature crosses upper threshold θ max , the TCL changes the state to switched off, whereas if the temperature crosses the lower threshold θ min , the TCL state is changed to switched on.…”

Section: Power System Modelmentioning

confidence: 99%

“…Together with the contribution of the renewable energy sources to the smart grid transformation, a distributed smart grid is changed by the wide adoption of technologies related to the IoT paradigm [5,6]. Therefore, new solutions are necessary to solve the highlighted challenges [7][8][9]. To tackle the needs of grid improvement, one of the proposed advances in this paper is an approach to utilize a deep reinforcement method for the design of a controller considering the stochastic behavior of the thermostatically controlled loads and comfort of consumers without load disconnection.…”

Section: Introductionmentioning

confidence: 99%

Voltage Control-Based Ancillary Service Using Deep Reinforcement Learning

Lukianykhin

Bogodorova

2021

Energies

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Ancillary services rely on operating reserves to support an uninterrupted electricity supply that meets demand. One of the hidden reserves of the grid is in thermostatically controlled loads. To efficiently exploit these reserves, a new realization of control of voltage in the allowable range to follow the set power reference is proposed. The proposed approach is based on the deep reinforcement learning (RL) algorithm. Double DQN is utilized because of the proven state-of-the-art level of performance in complex control tasks, native handling of continuous environment state variables, and model-free application of the trained DDQN to the real grid. To evaluate the deep RL control performance, the proposed method was compared with a classic proportional control of the voltage change according to the power reference setup. The solution was validated in setups with a different number of thermostatically controlled loads (TCLs) in a feeder to show its generalization capabilities. In this article, the particularities of deep reinforcement learning application in the power system domain are discussed along with the results achieved by such an RL-powered demand response solution. The tuning of hyperparameters for the RL algorithm was performed to achieve the best performance of the double deep Q-network (DDQN) algorithm. In particular, the influence of a learning rate, a target network update step, network hidden layer size, batch size, and replay buffer size were assessed. The achieved performance is roughly two times better than the competing approach of optimal control selection within the considered time interval of the simulation. The decrease in deviation of the actual power consumption from the reference power profile is demonstrated. The benefit in costs is estimated for the presented voltage control-based ancillary service to show the potential impact.

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“…In [34], a multiscale wavelet packet tree is applied to collect comprehensive energy consumption features, and an ensemble bagging tree is adopted as a classifier, where the performance is compared with various machine learning schemes. In [35], an event detection and disaggregation framework based on an ensemble approach is proposed, whose disaggregation target is the water heating operation. Both of the above works focus on event-based load monitoring.…”

Section: Introductionmentioning

confidence: 99%

An Enhanced Ensemble Approach for Non-Intrusive Energy Use Monitoring Based on Multidimensional Heterogeneity

Liu

Shi

Wang

et al. 2021

Sensors

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Acting as a virtual sensor network for household appliance energy use monitoring, non-intrusive load monitoring is emerging as the technical basis for refined electricity analysis as well as home energy management. Aiming for robust and reliable monitoring, the ensemble approach has been expected in load disaggregation, but the obstacles of design difficulty and computational inefficiency still exist. To address this, an ensemble design integrated with multi-heterogeneity is proposed for non-intrusive energy use disaggregation in this paper. Firstly, the idea of utilizing a heterogeneous design is presented, and the corresponding ensemble framework for load disaggregation is established. Then, a sparse coding model is allocated for individual classifiers, and the combined classifier is diversified by introducing different distance and similarity measures without consideration of sparsity, forming mutually heterogeneous classifiers. Lastly, a multiple-evaluations-based decision process is fine-tuned following the interactions of multi-heterogeneous committees, and finally deployed as the decision maker. Through verifications on both a low-voltage network simulator and a field measurement dataset, the proposed approach is demonstrated to be effective in enhancing load disaggregation performance robustly. By appropriately introducing the heterogeneous design into the ensemble approach, load monitoring improvements are observed with reduced computational burden, which stimulates research enthusiasm in investigating valid ensemble strategies for practical non-intrusive load monitoring implementations.

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Non-Intrusive Load Monitoring of Residential Water-Heating Circuit Using Ensemble Machine Learning Techniques

Cited by 9 publications

References 53 publications

Toward Robust Non-Intrusive Load Monitoring via Probability Model Framed Ensemble Method

Toward Robust Non-Intrusive Load Monitoring via Probability Model Framed Ensemble Method

Voltage Control-Based Ancillary Service Using Deep Reinforcement Learning

An Enhanced Ensemble Approach for Non-Intrusive Energy Use Monitoring Based on Multidimensional Heterogeneity

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