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References [1] BRYANT A., MAWBY P., RAN L., TAVNER P., XIANG D., YANG S., Condition Monitoring for Device Reliability in Power Electronic Converters. A review, IEEE Trans. Power Electron., 2010, 25(11), 2734-2752. [2] WOLFGANG E., Examples for failures in power electronics systems, ECPE Tutorial Relative Power Electronic Systems, Nuremberg, Germany, April 2007, 154-160. [3] EDELMOSER K., ERTL H., KOLAR J.W., ZACH F.C., A Novel Method for On-Line Monitoring and Managing of Electrolytic Capacitors of DC Voltage Link PWM Converters, Power Electronics, Intelligent

experimental validation of a grid-connected MMC with pulsed DC load , IEEE Trans. Ind. Electron., 2017, 64(12), 9180–9190. [22] Q uan Z., L i Y., Harmonic analysis of interleaved voltage source converters and tri-carrier PWM strategies for three-level converters , 18th Workshop on Control and Modeling for Power Electronics (COMPEL), IEEE, Stanford, CA, USA, 2017, 1–7. [23] L iu H., Z hang D., W ang D., Design considerations for output capacitance under inductance mismatches in multiphase buck converters , IEEE Trans. Power Electron., 2017, 32(7), 5004–5015. [24] A

Power Electronics and Drives Power Electronics and Drives Volume 4(39), 2019 DOI: 10.2478/pead-2019-0016 * E-mail: malin@ee.pw.edu.pl Review Article 1 Institute of Control and Industrial Electronics, Warsaw University of Technology, Poland 2 Department of Electronics and Electrical Engineering, Liverpool John Moores University, United Kingdom 3 Department of Electrical Machines, Drives and Measurements, Wroclaw University of Science and Technology, Poland Mariusz Malinowski1,*, Emil Levi2, Teresa Orlowska-Kowalska3 Introduction to the Special Section on

REFERENCES siemens.com, (2017). The guide of Marine Frequency Converters, Siemens AG, Automation and Drives, Large Drives, Marine Equipment, Postfach 4743, 90441 NÜRNBERG, FEDERAL REPUBLIC OF GERMANY, www.siemens.com/ [Accessed 5 March 2017]. Kouro S., Malinowski M., Gopakumar K., Pou J., Franquelo L. G., Wu B., Rodríguez J., Pérez M. A., Leon J. I. (2010): Recent Advances and Industrial Applications of Multilevel Converters, IEEE Transactions on Industrial Electronics (Vol.: 57, Issue: 8, Aug. 2010) pp. 2553-2580, DOI: 10.1109/TIE.2010.2049719, ISSN: 0278

References [1] ORŁOWSKA-KOWALSKA T., State of the Art and Future Development of Electrical Drives, Przegląd Elektrotechniczny, 2004, Vol. 80, No 3, 185-190, (in Polish). [2] FINCH J.W., GIAOURIS D., Controlled AC Electrical Drives, IEEE Trans. Industrial Electronics, Vol. 55, No. 2, 481-491, 2008. [3] HERMANN, PENTEK, OTTO, Design Principles for Industrie 4.0 Scenarios, 2015. [4] CIENIAK I., Polish market of electric drives and servodrives, Control Engineering Polska, 2011, (in Polish). [5] SCHWAB K., The Fourth Industrial Revolution, 2016. [6] ORŁOWSKA

References Abdeltawab, H. H. and Mohamed, Y. A. R. I. (2016). Robust Energy Management of a Hybrid Wind and Flywheel Energy Storage System Considering Flywheel Power Losses Minimization and Grid-Code Constraints. IEEE Transactions on Industrial Electronics , 63(7), pp. 4242–4254. Abdel-Khalik, A. S., Hamad, M. S., Massoud, A. M. and Ahmed, S. (2018). Postfault Operation of a Nine-Phase Six-Terminal Induction Machine Under Single Open-Line Fault. IEEE Transactions on Industrial Electronics , 2, pp. 1084–1096. Afshari, E., Moradi, G. R., Rahimi, R., Farhangi, B

REFERENCES [1] P atel P., Where the jobs are: 2012 , IEEE Spectrum, 2012, 49(9), 26–32. [2] A gelidis V.G., The future of power electronics-power engineering education. Challenges and opportunities , IEEE Workshop on Power Electronics Education, Brazil, 2005, 1–8. [3] O rłowska -K owalska T., Application of training education systems in specialized education of electrical engineers , Przegl. Elektrotechn., 1998, 6, 202–205 (in Polish). [4] A lsmadi Y., T sai K., S cott M.J., X u L., W ang A., New Trends and Technologies in Power Electronics and Motor

Abstract

The aim of this paper is to give a preliminary insight regarding the current work in the field of mobile interaction in industrial environments by using established interaction technologies and metaphors from the consumer goods industry. The major objective is the development and implementation of a holistic app-framework, which enables dynamic feature deployment and extension by using mobile apps on industrial field devices. As a result, field device functionalities can be updated and adapted effectively in accordance with well-known appconcepts from consumer electronics to comply with the urgent requirements of more flexible and changeable factory systems of the future. In addition, a much more user-friendly and utilizable interaction with field devices can be realized. Proprietary software solutions and device-stationary user interfaces can be overcome and replaced by uniform, cross-vendor solutions

References Reznikov, B. and Ruderman, A. (2009). Four-level single-leg flying capacitor converter voltage balance dynamics analysis. In: Proceedings of 13th European Conference on Power Electronics and Applications , Barcelona (Spain), September 2009, pp. 1–10. Reznikov, B., Ruderman, A. and Galanina, V. (2019). Analysis of Transients in a Three-Level DC-DC Flying Capacitor Converter. Time Domain Approach. Power Electronics and Drives , 4(39), pp. 33–45. Reznikov, B., Ruderman, A. and Galanina, V. (2020). Analysis of Transients in a 4-Level Flying Capacitor