Publications and References

Publications

The following publications discuss SIMONA and implementation details as well as outcomes where SIMONA have been used:

SIMONA Publications

[1]

Johannes Hiry. Agent-based Discrete-Event Simulation Environment for Electric Power Distribution System Analysis. Volume 24 of Dortmunder Beiträge zu Energiesystemen, Energieeffizienz und Energiewirtschaft. Shaker, Düren, 1. auflage edition, 2022. ISBN 9783844084627.

[2]

Chris Kittl. Entwurf und Validierung eines individualitätszentrierten, interdisziplinären Energiesystemsimulators basierend auf ereignisdiskreter Simulation und Agententheorie. Shaker Verlag, Düren, 2022. ISBN 978-3-8440-8463-4. doi:10.17877/DE290R-22548.

[3]

Stephan Balduin, Eric Msp Veith, Alexander Berezin, Sebastian Lehnhoff, Thomas Oberließen, Chris Kittl, Johannes Hiry, Christian Rehtanz, Giancarlo Torres-Villarreal, Sasiphong Leksawat, and Marc-Aurel Frankenbach. Towards a universally applicable neural state estimation through transfer learning. In 2021 IEEE PES Innovative Smart Grid Technologies Europe (ISGT-Europe). 2021.

[4]

Kittl, Chris and Hiry, Johannes Hiry and Wagner, Christian and Pfeiffer, Christian and Rehtanz, Christian and Engels, Christoph. Large scale agent based simulation of distribution grid loading and its practical application. In 25th International Conference on Electricity Distribution (CIRED), number June. Madrid, 2019.

[5]

J. Hiry, C. Kittl, and C. Römer and C. Rehtanz and L. Willmes and S. Schimmeyer. Automated time series based grid extensions planning using a coupled agent based simulation and genetic algorithm approach. In 25th International Conference on Electricity Distribution (CIRED), number June. Madrid, 2019.

[6]

Jan Kays. Multi-agent Based Planning Considering the Behavior of Individual End-Users, pages 143–165. Springer Singapore, Singapore, 2018. URL: https://doi.org/10.1007/978-981-10-7056-3_5, doi:10.1007/978-981-10-7056-3_5.

[7]

Römer, Christian and Hiry, Johannes Hiry and Kittl, Chris and Liebig, Thomas and Rehtanz, Christian. Charging control of electric vehicles using contextual bandits considering the electrical distribution grid. In KNOWMe: 2nd International Workshop on Knowledge Discovery from Mobility and Transportation Systems. Dublin, 2018.

[8]

Johannes Hiry, Chris Kittl, Zita Hagemann, and Christian Rehtanz. Das Potential spannungsebenenübergreifender Zeitreihensimulationen für die Verteilnetzplanung. In Uwe Großmann, Ingo Kunold, and Christoph Engels, editors, Smart Energy Konferenz, 133–142. Dortmund, 2017. vwh Verlag Werner Hülsbusch.

[9]

Anton Shapovalov, Chris Kittl, Christian Rehtanz, Lars Jendernalik, Anna Carina Schneider, and Dominique Giavarra. Application fo time-resolved input data for smart grid simulation. In 24th International Conference on Electricity Distribution (CIRED), number June, 12–15. Glasgow, 2017.

[10]

Lars Jendernalik, Dominique Giavarra, Christoph Engels, Johannes Hiry, Chris Kittl, and Christian Rehtanz. A holistic network planning approach: enhacement of the grid expansion using the flexibility of network participants. In 24th International Conference on Electricity Distribution (CIRED), number June, 12–15. Glasgow, 2017.

[11]

Jan Kays and Christian Rehtanz. Planning process for distribution grids based on flexibly generated time series considering RES, DSM and storages. IET Generation, Transmission & Distribution, 10(14):3405–3412, 2016. doi:10.1049/iet-gtd.2015.0825.

[12]

André Seack. Time-series based distribution grid planning considering interaction of network participants with a multi-agent system. PhD Thesis, TU Dortmund University, 2016.

[13]

Jan Kays, André Seack, and Ulf Häger. Consideration of Innovative Distribution Grid Operation Concepts in the Planning Process. In 2016 IEEE PES Innovative Smart Grid Technologies Conference Europe (ISGT-Europe), 7. Ljubljana, 2016.

[14]

Jan Kays, André Seack, and Christian Rehtanz. Consideration of smart-meter measurements in a multi-agent simulation environment for improving distribution grid planning. In 2016 IEEE Power & Energy Society Innovative Smart Grid Technologies Conference (ISGT), 1–5. Minneapolis, 2016. doi:10.1109/ISGT.2016.7781168.

[15]

Dennis Kötter, André Seack, and Jan Kays. Analyse des Wärmepumpenverhaltens zur Erweiterung eines Verteilnetzplanungswerkzeugs. Eldorado, pages 6, 2015. URL: https://eldorado.tu-dortmund.de/bitstream/2003/33924/1/S01.2.pdf.

[16]

Christian Rehtanz, André Seack, Sebastian Lehnhoff, and Olav Krause. Plannung und Betrieb von Smart Grids. In Tagungsband der Konferenz für Nachhaltige Energieversorgung und Integration von Speichern (NEIS), 6. Hamburg, 2015. Springer Verlag.

[17]

Jan Kays, André Seack, Ulf Häger, and Christian Rehtanz. The potential of detailed time series of grid users in the distribution grid planning. In VDE ETG-Kongress, 6. Kassel, 2015.

[18]

André Seack, Jan Kays, and Christian Rehtanz. Multi-Level Distribution Grid Planning Process by Means of a Multi-Agent-System. In 23rd International Conference on Electricity Distribution (CIRED), 5. Lyon, 2015.

[19]

Jan Kays, Seack, and Ulf Häger. The potential of using generated time series in the distribution grid planning process. In 23rd International Conference on Electricity Distribution (CIRED), number June, 15–18. Lyon, 2015.

[20]

Jan Kays. Agent-based Simulation Environment for Improving the Planning of Distribution Grids. PhD Thesis, TU Dortmund University, 2014.

[21]

Jan Kays, André Seack, Christian Rehtanz, J Raasch, and Christoph Weber. Berücksichtigung preiselastischer Lasten und Einspeisungen in der Verteilnetzplanung Considering price dependent loads and generation in the distribution grid planning process Kurzfassung Einleitung Multiagentenbasiertes Simulationssystem Modellierung von. In Kongressbeiträge VDE-Kongress 2014 Smart Cities, 1–6. Frankfurt/Main, 2014.

[22]

André Seack, Jan Kays, and Christian Rehtanz. Time series based distribution grid planning approach with decentralised voltage regulation. In Proceedings - 2014 Power Systems Computation Conference, PSCC 2014, 1–7. Wroclaw, 2014.

[23]

Jan Kays, André Seack, Jonas Von Haebler, and Christian Rehtanz. Evaluation of storage systems in distribution networks by means of an agent-based simulation system. In Proceedings - 2014 Power Systems Computation Conference, PSCC 2014, 7. Wroclaw, 2014.

[24]

André Seack, Jan Kays, Lars Jendernalik, and Dominique Giavarra. Potentiale und Risiken bei der Verwendung innovativer Netzplanungsansätze. In Tagungsband 13. Symposium Energieinnovationen, 1–10. Graz, 2014.

[25]

Jan Kays, André Seack, Johannes Rolink, and Christian Rehtanz. Integration of electric vehicles in the distribution grid planning process by extending a multi agent environment. In Proceedings of the CIRED Workshop 2014: Challenges of Implementing Active Distribution System Management, number June, 5. Rome, 2014.

[26]

Jan Kays, André Seack, and Christian Rehtanz. Detaillierte Einspeiseprognosen für Wind- und Photovoltaikanlagen auf Basis eines Multiagentensystems - Detailed feed-in forecast for wind and photovoltaic power units with a multi-agent system. In Internationaler ETG-Kongress, 1–6. 2013.

[27]

André Seack, Jan Kays, and Lars Jendernalik. Agent based approach to model photovoltaic feed-in in distribution network planning. In Cigré Symposium Auckland, 8. Auckland, 2013.

[28]

Jan Kays, André Seack, and Christian Rehtanz. Accurate and realistic regional forecast of renewable infeed in power systems. In Cigré Symposium Auckland, 8. Auckland, 2013.

[29]

Anton Shapovalov, Jan Kays, André Seack, and Christian Rehtanz. Agentenbasierte Netzrekonfiguration für einen optimierten Verteilnetzbetrieb. In Tagungsband des Power and Energy Student Summit, number 2, 5. Ilmenau, 2012.

[30]

Jan Kays, André Seack, and Christian Rehtanz. Analyse der Verteilnetzbelastung durch Simulation in einem Multiagentensystem. In Internationaler ETG-Kongress 2011, volume 10, 9–14. Würzburg, 2011.

[31]

Jan Kays, André Seack, and Christian Rehtanz. Agent-based modelling of regenerative energy sources for an efficient distribution power system design. In CIGRE Symposium, 1–10. Bologna, 2011.

References

References of publications SIMONA referred on:

References

[Duffie.2013]

John A. Duffie. Solar engineering of thermal processes. Wiley, Hoboken, 4th ed. edition, 2013. ISBN 1118418123. URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781118671603, doi:10.1002/9781118671603.

[Iqbal.1983]

Muhammad Iqbal. An Introduction To Solar Radiation. Elsevier Science, Oxford, 1983. ISBN 9780123737502. URL: http://site.ebrary.com/lib/alltitles/docDetail.action?docID=10678925.

[Itaca_Sun]

Itacanet. The sun as a source of energy. https://www.itacanet.org/the-sun-as-a-source-of-energy/part-3-calculating-solar-angles/.

[Kittl_2022]

Chris Kittl. Entwurf und Validierung eines individualitätszentrierten, interdisziplinären Energiesystemsimulators basierend auf ereignisdiskreter Simulation und Agententheorie. Shaker Verlag, Düren, 2022. ISBN 978-3-8440-8463-4. doi:10.17877/DE290R-22548.

[Maleki.2017]

Seyed Abbas Mousavi Maleki, H. Hizam, and Chandima Gomes. Estimation of hourly, daily and monthly global solar radiation on inclined surfaces: models re-visited. Energies, 2017. URL: https://www.mdpi.com/1996-1073/10/1/134, doi:10.3390/en10010134.

[Myers.2017]

D.R. Myers. Solar Radiation: Practical Modeling for Renewable Energy Applications. Compact research: Energy and the environment. CRC Press, 2017. ISBN 9781466503274. URL: https://books.google.de/books?id=or3MBQAAQBAJ.

[Perez.1987]

R. Perez, R. Seals, Pierre Ineichen, R. Stewart, and D. Menicucci. A new simplified version of the perez diffuse irradiance model for tilted surfaces. Solar Energy, 39(3):221–231, 1987. ID: unige:17207. URL: https://archive-ouverte.unige.ch/unige:17207.

[Perez.1990]

Richard Perez, Pierre Ineichen, Robert Seals, Joseph Michalsky, and Ronald Stewart. Modeling daylight availability and irradiance components from direct and global irradiance. Solar Energy, 44(5):271–289, 1990. URL: http://www.cuepe.ch/html/biblio/pdf/perez-ineichen%201990%20-%20modelling%20daylight%20(se).pdf, doi:https://doi.org/10.1016/0038-092X(90)90055-H.

[Quaschning.2013]

Volker Quaschning. Regenerative Energiesysteme: Technologie; Berechnung; Simulation. Hanser, München, 8., aktualisierte und erw. aufl. edition, 2013. ISBN 3446435719. URL: http://ebooks.ciando.com/book/index.cfm/bok_id/471802.

[Schoenberg.1929]

E. Schoenberg. Theoretische Photometrie, pages 1–280. Springer Berlin Heidelberg, Berlin, Heidelberg, 1929. doi:10.1007/978-3.

[Spencer.1971]

J. W. Spencer. Fourier series representation of the position of the sun. Search, 2(5):172+, May 1971. URL: http://www.mail-archive.com/sundial@uni-koeln.de/msg01050.html.

[Wang.2019]

Zhifeng Wang. Chapter 2 - the solar resource and meteorological parameters. In Zhifeng Wang, editor, Design of Solar Thermal Power Plants, pages 47–115. Academic Press, 2019. URL: https://www.sciencedirect.com/science/article/pii/B978012815613100002X, doi:https://doi.org/10.1016/B978-0-12-815613-1.00002-X.

[Watter.2013]

Holger Watter. Regenerative Energiesysteme: Systemtechnik und Beispiele nachhaltiger Energiesysteme aus der Praxis ; mit 51 Tabellen. Lehrbuch. Springer Vieweg, Wiesbaden, 3., überarb. und erw. aufl. edition, 2013. ISBN 9783658014841.

[WikiAirMass]

Wikipedia. Air mass. https://en.wikipedia.org/wiki/Air_mass_(solar_energy)##Calculation.

[Zheng.2017]

Hongfei Zheng. Chapter 2 - solar energy utilization and its collection devices. In Hongfei Zheng, editor, Solar Energy Desalination Technology, pages 47–171. Elsevier, Amsterdam, 2017. URL: https://www.sciencedirect.com/science/article/pii/B9780128054116000026, doi:https://doi.org/10.1016/B978-0-12-805411-6.00002-6.