Abstract
Energy disaggregation (ED), with minimal infrastructure, can create energy awareness and thus promote energy efficiency by providing appliance-level consumption information. However, ED is highly ill-posed and gets complicated with increase in number and type of devices, similarity between devices, measurement errors, etc. To design, test, and benchmark ED algorithms, the availability of open-access energy consumption datasets is crucial. Most datasets in the literature suit data-intensive pattern-based ED algorithms. Recently, optimization-based ED algorithms that only require information regarding the operational states of the devices are being developed. However, the lack of standard datasets and appropriate evaluation metrics is hindering the development of reproducible state-of-the-art optimization-based ED algorithms. Therefore, in this paper, we propose a dataset with multiple instances that are representative of the different challenges posed by ED in practice. Performance indicators to empirically evaluate different optimization-based ED algorithms are summarized. In addition, baseline simulation results of the state-of-the-art optimization-based ED algorithms are presented. The developed dataset, summarization of different metrics, and baseline results are expected to provide a platform for researchers to develop novel optimization-based frameworks, in general, and evolutionary computation-based frameworks in particular to solve ED.
Highlights
In the residential sector, which accounts for 30% of global energy consumption [1], providing appliance-level consumption feedback is expected to result in 12% annual energy savings [2] compared to the traditional indirect feedback such as monthly bills
To provide the baseline results, the existing optimization-based energy disaggregation (ED) algorithms are simulated on all 18 instances and the results are summarized with respect to the performance metrics described
The codes for IP, ALIP, and MONILM are obtained from the authors of the original publications, while Sparse Switching Event Recovering (SSER) and Sparse optimization (Sopt) are reproduced with the help of the information presented in the respective publications
Summary
In the residential sector, which accounts for 30% of global energy consumption [1], providing appliance-level consumption feedback is expected to result in 12% annual energy savings [2] compared to the traditional indirect feedback such as monthly bills. The simultaneous advancements in artificial intelligence and smart meters have provided the much necessary impetus to the exponential growth of ALM, which can be intrusive (IALM) or non-intrusive (NIALM) [1]. IALM is more accurate but expensive since it requires that one or more sensors be installed per appliance. In NIALM or energy disaggregation (ED) measurements corresponding to the whole house are made through a single sensor, and appliance-level information is obtained through artificial intelligence-based techniques. ED garnered huge attention from both the research community as well as the industry [2,8,9] because of its capability to promote energy awareness with minimal infrastructure
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