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10 results on '"Brucke, Karoline"'

1. e-Values for Real-Time Residential Electricity Demand Forecast Model Selection

Author

Backhaus, Fabian, Brucke, Karoline, Ruckdeschel, Peter, and Schlüters, Sunke

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

With the growing number of forecasting techniques and the increasing significance of forecast-based operation - particularly in the rapidly evolving energy sector - selecting the most effective forecasting model has become a critical task. Given the dynamic nature of energy forecasting, it is highly advantageous to assess the superiority of forecasting models not only retrospectively but continuously in real-time as new data and evidence becomes available, while simultaneously providing strong probabilistic guarantees for these decisions. In this work, we show that this can be achieved through the mathematical concept of e-values, which has recently gained massive attention in the field of statistics. It allows for unified construction principles for powerful tests and accurate statistical decisions, which can be evaluated at any chosen time points while maintaining an overall probabilistic error control. We extend the use of e-values by developing a simple persistence approach that dynamically combines input forecasts to generate new fused predictions. To demonstrate the performance of our method we apply it to electricity demand forecasts based on different artificial intelligence based models. Our results indicate that e-values are able to improve the accuracy and reliability of forecasts in a dynamic environment, offering a valuable tool for real-time decision-making in the energy sector., Comment: 25 pages, 9 figures

Published
2024

5. A Non-Intrusive Load Monitoring Approach for Very Short Term Power Predictions in Commercial Buildings

Author

Brucke, Karoline, Arens, Stefan, Telle, Jan-Simon, Steens, Thomas, Hanke, Benedikt, von Maydell, Karsten, and Agert, Carsten

Subjects
Electrical Engineering and Systems Science - Signal Processing, Statistics - Machine Learning, 37M10, 68T10, 68T07, I.5.0, I.2.8, I.2.1, G.3
Abstract

This paper presents a new algorithm to extract device profiles fully unsupervised from three phases reactive and active aggregate power measurements. The extracted device profiles are applied for the disaggregation of the aggregate power measurements using particle swarm optimization. Finally, this paper provides a new approach for short term power predictions using the disaggregation data. For this purpose, a state changes forecast for every device is carried out by an artificial neural network and converted into a power prediction afterwards by reconstructing the power regarding the state changes and the device profiles. The forecast horizon is 15 minutes. To demonstrate the developed approaches, three phase reactive and active aggregate power measurements of a multi-tenant commercial building are used. The granularity of data is 1 s. In this work, 52 device profiles are extracted from the aggregate power data. The disaggregation shows a very accurate reconstruction of the measured power with a percentage energy error of approximately 1 %. The developed indirect power prediction method applied to the measured power data outperforms two persistence forecasts and an artificial neural network, which is designed for 24h-day-ahead power predictions working in the power domain., Comment: 15 pages, 14 figures, 4 tables

Published
2020

6. Particle Swarm Optimization for Energy Disaggregation in Industrial and Commercial Buildings

Author

Brucke, Karoline, Arens, Stefan, Telle, Jan-Simon, Sunke~Schlüters, Hanke, Benedikt, von Maydell, Karsten, and Agert, Carsten

Subjects
Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing, 68W50, 68W15, 90C90
Abstract

This paper provides a formalization of the energy disaggregation problem for particle swarm optimization and shows the successful application of particle swarm optimization for disaggregation in a multi-tenant commercial building. The developed mathmatical description of the disaggregation problem using a state changes matrix belongs to the group of non-event based methods for energy disaggregation. This work includes the development of an objective function in the power domain and the description of position and velocity of each particle in a high dimensional state space. For the particle swarm optimization, four adaptions have been applied to improve the results of disaggregation, increase the robustness of the optimizer regarding local optima and reduce the computational time. The adaptions are varying movement constants, shaking of particles, framing and an early stopping criterion. In this work we use two unlabelled power datasets with a granularity of 1 s. Therefore, the results are validated in the power domain in which good results regarding multiple error measures like root mean squared error or the percentage energy error can be shown., Comment: 10 pages, 13 figures, 3 tables

Published
2020

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