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Q. T. Tran

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Journal article (2018) - Thomas I. Strasser, F. Pröstl Andrén, E. C.W. De Jong, J. E. Rodriguez, A. van der Meer, R. Bhandia, G. Arnold, Q. T. Tran, V. H. Nguyen, More Authors...
A driving force for the realization of a sustainable energy supply in Europe is the integration of distributed, renewable energy resources. Due to their dynamic and stochastic generation behaviour, utilities and network operators are confronted with a more complex operation of the underlying distribution grids. Additionally, due to the higher flexibility on the consumer side through partly controllable loads, ongoing changes of regulatory rules, technology developments, and the liberalization of energy markets, the system’s operation needs adaptation. Sophisticated design approaches together with proper operational concepts and intelligent automation provide the basis to turn the existing power system into an intelligent entity, a so-called smart grid. While reaping the benefits that come along with those intelligent behaviours, it is expected that the system-level testing will play a significantly larger role in the development of future solutions and technologies. Proper validation approaches, concepts, and corresponding tools are partly missing until now. This paper addresses these issues by discussing the progress in the integrated Pan-European research infrastructure project ERIGrid where proper validation methods and tools are currently being developed for validating smart grid systems and solutions. ...
Report (2017) - Edmund Widl, Michael Spiegel, D. E. Morales Bondy, C Steinbrink, M. Blank, A. Stathakis, T. Sarris, Panos Kotsampopoulos, N. Akroud, I. O. Sagarduy, V. H. Nguyen, D. Moneta, Cyndi Moyo, C. Sandroni, S. Corti, S. Uski, L. Matti, P. Chodura, R. Brandl, Q. T. Tran, B. Lazpita, T. Delaplagne, Thomas Strasser, Arjen van der Meer, Peter Palensky, Rishabh Bhandia, A. Emhemed, M. Syed, Oliver Gehrke
Work package JRA2 focuses on the development of advanced simulation-based methods to checkand validate smart grid scenarios, configurations and corresponding applications. The main aim isto employ offline simulation of scenarios where a combination of parallel processing, advanced optimization techniques, and design-of-experiments is used to master the system complexity. Secondary targets include the development of methods for HIL application as well as for the assessment of cyber-security concepts. This assessment will cover the following smart grid properties:system stability, system scalability, component interoperability, and information security. Eventuallyit is the goal to explore the operational limits and the sensitivity of these system properties towardssystem parameters. ...
Conference paper (2017) - V. H. Nguyen, Y. Besanger, E. Guillo-Sansano, Georg Lauss, Thomas Strasser, K. Heussen, Q. T. Tran, T.L. Nguyen, C. Boudinet, R. Brandl, F. Marten, A. Markou, Panos Kotsampopoulos, Arjen van der Meer
Conference paper (2017) - C Steinbrink, S Lehnhoff, A. A. van der Meer, K. Heussen, Oliver Gehrke, E. Guillo-Sansano, M. H. Syed, A. Emhemed, R. Brandl, V. H. Nguyen, A. Khavari, Q. T. Tran, Sebastian Rohjans, Panos Kotsampopoulos, Nikos Hatziargyriou, N. Akroud, E. Rikos, M. Z. Degefa, T. I. Strasser, Edmund Widl, Cyndi Moyo, Georg Lauss, F. Lehfuss, M. Faschang, P. Palensky
Smart grid systems are characterized by high complexity due to interactions between a traditional passive network and active power electronic components, coupled using communication links. Additionally, automation and information technology plays an important role in order to operate and optimize such cyber-physical energy systems with a high(er) penetration of fluctuating renewable generation and controllable loads. As a result of these developments the validation on the system level becomes much more important during the whole engineering and deployment process, today. In earlier development stages and for larger system configurations laboratory-based testing is not always an option. Due to recent developments, simulation-based approaches are now an appropriate tool to support the development, implementation, and roll-out of smart grid solutions. This paper discusses the current state of simulation-based approaches and outlines the necessary future research and development directions in the domain of power and energy systems. ...