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Your search keyword '"Łach, Jan"' showing total 4 results
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4 results on '"Łach, Jan"'

2. Quantum multi-output Gaussian Processes based Machine Learning for Line Parameter Estimation in Electrical Grids

Author

Ganeshamurthy, Priyanka Arkalgud, Ghosh, Kumar, O'Meara, Corey, Cortiana, Giorgio, Schiefelbein-Lach, Jan, and Monti, Antonello

Subjects
Quantum Physics
Abstract

Gaussian process (GP) is a powerful modeling method with applications in machine learning for various engineering and non-engineering fields. Despite numerous benefits of modeling using GPs, the computational complexity associated with GPs demanding immense resources make their practical usage highly challenging. In this article, we develop a quantum version of multi-output Gaussian Process (QGP) by implementing a well-known quantum algorithm called HHL, to perform the Kernel matrix inversion within the Gaussian Process. To reduce the large circuit depth of HHL a circuit optimization technique called Approximate Quantum Compiling (AQC) has been implemented. We further showcase the application of QGP for a real-world problem to estimate line parameters of an electrical grid. Using AQC, up to 13-qubit HHL circuit has been implemented for a 32x32 kernel matrix inversion on IBM Quantum hardware for demonstrating QGP based line parameter estimation experimentally. Finally, we compare its performance against noise-less quantum simulators and classical computation results., Comment: 9 pages, 7 figures

Published
2024

3. Bridging the Gap to Next Generation Power System Planning and Operation with Quantum Computation

Author

Ganeshamurthy, Priyanka Arkalgud, Ghosh, Kumar, O'Meara, Corey, Cortiana, Giorgio, and Schiefelbein-Lach, Jan

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Innovative solutions and developments are being inspected to tackle rising electrical power demand to be supplied by clean forms of energy. The integration of renewable energy generations, varying nature loads, importance of active role of distribution system and consumer participation in grid operation has changed the landscape of classical power grids. Implementation of smarter applications to plan, monitor, operate the grid safely are deemed paramount for efficient, secure and reliable functioning of grid. Although sophisticated computations to process gigantic volume of data to produce useful information in a time critical manner is the paradigm of future grid operations, it brings along the burden of computational complexity. Advancements in quantum technologies holds promising solution for dealing with demanding computational complexity of power system related applications. In this article, we lay out clear motivations for seeking quantum solutions for solving computational burden challenges associated with power system applications. Next we present an overview of quantum solutions for various power system related applications available in current literature and suggest future topics for research. We further highlight challenges with existing quantum solutions for exploiting full quantum capabilities. Additionally, this paper serves as a bridge for power engineers to the quantum world by outlining essential quantum computation fundamentals for enabling smoother transition to future of power system computations.

Published
2024

4. End-to-End Reinforcement Learning of Curative Curtailment with Partial Measurement Availability

Author

Wolf, Hinrikus, Böttcher, Luis, Bouchkati, Sarra, Lutat, Philipp, Breitung, Jens, Jung, Bastian, Möllemann, Tina, Todosijević, Viktor, Schiefelbein-Lach, Jan, Pohl, Oliver, Ulbig, Andreas, and Grohe, Martin

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Systems and Control
Abstract

In the course of the energy transition, the expansion of generation and consumption will change, and many of these technologies, such as PV systems, electric cars and heat pumps, will influence the power flow, especially in the distribution grids. Scalable methods that can make decisions for each grid connection are needed to enable congestion-free grid operation in the distribution grids. This paper presents a novel end-to-end approach to resolving congestion in distribution grids with deep reinforcement learning. Our architecture learns to curtail power and set appropriate reactive power to determine a non-congested and, thus, feasible grid state. State-of-the-art methods such as the optimal power flow (OPF) demand high computational costs and detailed measurements of every bus in a grid. In contrast, the presented method enables decisions under sparse information with just some buses observable in the grid. Distribution grids are generally not yet fully digitized and observable, so this method can be used for decision-making on the majority of low-voltage grids. On a real low-voltage grid the approach resolves 100\% of violations in the voltage band and 98.8\% of asset overloads. The results show that decisions can also be made on real grids that guarantee sufficient quality for congestion-free grid operation.

Published
2024

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