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Ali ArzaniM.Sc. Graduate KTH- The Royal Institute of Technology School of Electrical Engineering SE-100 44 Stockholm, Sweden Email: arzani@kth.se |
Biography Education Thesis Publications Projects Photo Gallery
I received my B.Sc. degree in Electrical Engineering from Semnan University, Semnan, Iran, in 2008 and the M.Sc. degree in Electric Power Engineering from the Royal Institute of Technology (KTH), Stockholm, Sweden, in 2010, respectively. During my bachelor studies I was an invited guest student at the University of Tehran for three semesters.
From January to September 2010, I was a Researcher at ABB Corporate Research Ltd., Västerås, Sweden. My main research interests include power electronics, applications of power electronics in power systems, and power system dynamics.M.Sc., School of Electrical Engineering, Royal Institute of Technology (KTH), Sweden, November 2010.
Design and Control of a Novel Dynamic Hybrid VAR Compensator, M.Sc. Thesis, KTH Press, November 2010. [BibTeX]
Available Transfer Capability Enhancement Using Series FACTS Devices, B.Sc. Thesis, Semnan University Press, January 2008.
A. Arzani, S. Boshoff, P. Arunagirinathan, Maigha, and J.H. Enslin, "System Design, Economic Analysis and Operation Strategy of a Campus Microgrid", IEEE 9th International Symposium on Power Electronics for Distributed Generation Systems (PEDG), Charlotte, North Carolina, USA, June 2018. [IEEEXplore] [pdf] [pdf]
A. Arzani, I. Jayawardene, P. Arunagirinathan, and G.K. Venayagamoorthy, "Impact of Solar Eclipse on Utility Grid Operations", in Proc. IEEE PES/IAS Power Africa Conference (PowerAfrica), Cape Town, South Africa, June 2018. [IEEEXplore] [pdf]
A. Arzani and G.K. Venayagamoorthy, "Integration of SmartParks in a Power System with Utility-Scale PV Plant", IEEE PES Transmission and Distribution Conference and Exposition (T&D), Denver, Colorado, USA, April 2018. [IEEEXplore] [pdf] [pdf]
A. Arzani and G.K. Venayagamoorthy, "Computational Approach to Enhance Performance of Photovoltaic System Inverters Interfaced to Utility Grids", IET Renewable Power Generation, vol. 12, no. 1, pp. 112-124, August 2017. [IET] [IEEEXplore] [pdf]
A. Arzani, P. Arunagirinathan, I. Jayawardene, and G.K. Venayagamoorthy, "Dynamic Performance Enhancement of a Utility-Scale Solar PV Plant", in Proc. IEEE PES Power Africa Conference (PowerAfrica), Livingstone, Zambia, June 2016. [IEEEXplore] [pdf]
A. Arzani, P. Arunagirinathan, and G.K. Venayagamoorthy, "Development of Optimal PI Controllers for a Grid-Tied Photovoltaic Inverter", in Proc. IEEE Computational Intelligence Applications in Smart Grid (CIASG), Cape Town, South Africa, December 2015. [IEEEXplore] [pdf]
A. Arzani, M. Jazaeri, and Y. Alinejad-Beromi, "Available Transfer Capability Enhancement Using Series FACTS Devices in a Designed Multi-Machine Power System", in Proc. Of the 43rd International Universities Power Engineering Conference (UPEC), Padova, Italy, September 2008. [IEEEXplore] [pdf]
*Chosen for publication in the Int. Journal of Innovations in Energy System and Power (IJESP), November 2009. [journal] [acceptance letter]E. Dabbagh, A. Arzani, and Z. Moravej, "Loss Evaluation of Distribution Transformers in Iran's Electric Power System", the IEEE International Conference on Sustainable Energy Technologies (ICSET), Singapore, full paper accepted in August 2008. [conference] [acceptance letter] [pdf]
A. Arzani, "The Position of Electric Energy Industry in Iran: The Current and Future Importance of Using Wind, Solar, Hydro-power and Other Sustainable Green Sources of Energy", in Proc. of the 3rd International Student Conference at Ibaraki University (ISCIU3), Ibaraki, Japan, October 2007, pp. 201-208.
Case Study: Impact of TCSC and UPFC on Transient Stability and Power Oscillation Damping in a Multi-Machine Power System, FACTS & HVDC Course Project, October 2009. [Report] MATLAB code by H. Latorre and A. Arzani. [Download code]
Laboratory pre-study and work on FACTS & HVDC classical thyristor-based technology to illustrate the use of power electronic devices based on thyristor technology in the power transmission system, FACTS & HVDC Course.
Laboratory pre-study and work on FACTS & HVDC based on VSC technology to illustrate the use of power electronic devices based on Voltage Source Converter (VSC) technology in the power transmission system, FACTS & HVDC Course.
A. Arzani, et al., Pre-feasibility Study and Design of a 120MW Mountain Wind Farm, Wind Power Systems Course Project, April 2009. [Report] [ppt]
Design and study of small scale wind turbine systems; Comprehensive analysis of wind turbine design concepts; Literature review and analysis of various power generation technologies utilized in wind turbines. Performing comprehensive wind data analysis, using Excel and MATLAB, Wind Power Systems Course.
Integration of wind power systems to the power grid, using MATLAB programming, Wind Power Systems Course.
Load flow study and sensitivity analysis of the KTH 6-bus test system, using MATLAB, Power Systems Advanced Course.
Performing frequency control on a multi-machine test system, using MATLAB and its SimPowerSystems toolbox, Power Systems Advanced Course.
Creating mathematical model for dynamic and stability analysis of a multi-machine power system, including load flow and small signal analysis describing its electromechanical modes under various cases, using MATLAB programming, Power Systems Advanced Course.
Comprehensive design and study of the impact of AVR installations in the multi-machine power system on small-signal stability, using MATLAB programming, Power Systems Advanced Course.
Comprehensive design and study on the impact of PSS installation in the multi-machine power system containing AVR in order to enhance small-signal stability, using MATLAB programming, Power Systems Advanced Course.
Analyze and Study the transient stability of a single-machine system connected to an infinite bus in various fault cases, using MATLAB programming, Power Systems Basic Course.
Writing a Load flow program utilizing the Newton-Raphson algorithm for the KTH 6-bus test system and analyzing the results obtained in the computations, using MATLAB, Power Systems Basic Course.
Creating computational models suitable for analysis of symmetrical as well as unsymmetrical conditions in a power system and analyzing their results, using MATLAB programming, Power Systems Basic Course.
Analyze and Study the transient stability of a single-machine system connected to an infinite bus in various fault cases, using MATLAB programming, Power Systems Basic Course.
Study of an electricity market and its simulation based on probabilistic production cost simulation method and Monte Carlo simulation method respectively, using MATLAB, System Planning Course.
Short-term planning of a small power company consisting of three hydro power plants and a thermal power plant, using GAMS software, using MATLAB programming, System Planning Course.
Study electricity pricing in the Nordic power market using MATLAB program Nordicprice, carried out in a group of two members, System Planning Course.
Implementing frequency control in a small four area power system, System Planning Course.
Performing power system state estimation on test networks with Weighted Least Square algorithm, using Power Education Toolbox (P.E.T.) software, Power System Control & Operation Course.
Creating an information model of a small power system using the Common Information Model (CIM), Power System Control & Operation Course.
Creating a simple SCADA system from scratch, using Intellution FIX software package, Power System Control & Operation Course.
Creating an architecture for the wide area communications network and central systems used at a specified power company, carried out in a group of two members, Power System Control & Operation Course.
Creating a substation architecture and protection scheme for a simple substation, carried out in a group of two members, Power System Control & Operation Course.
Power system instrumentation: creating a measurement set up and switching schemes for a substation in the power company's grid, carried out in a group of two members, Power System Control & Operation Course.
Analysis and simulation of converter modulation methods i.e. single-phase leg modulation, single-phase full-bridge modulation, and three-phase modulation, using MATLAB programming, Modulation of Power Electronics Course.
Vector Control of an induction machine by flux estimation to have field oriented reference frame, closed-loop speed control, PWM inverter instead of direct supply by using measured values from real machine, using MATLAB programming and Simulink, Electrical Machines & Drives Course.
Design of a step-down dc-dc converter, using PSpice and MATLAB and Simulink, Power Electronics Course.
Modeling and analysis of ionospheric radio wave reflection, using MATLAB, Electrotechnical Modeling Course.
Modeling of a microwave oven project, using MATLAB, Electrotechnical Modeling Course.
Analysis of energy balance in a compact fusion reactor, using MATLAB, Electrotechnical Modeling Course.
Modeling of an electric ignition system for combustion engines, using MATLAB, Electrotechnical Modeling Course.
Cauer-modeling of windings and magnetic cores, using PSpice, Electrotechnical Modeling Course.
Loudspeaker modeling, using MATLAB and PSpice, Electrotechnical Modeling Course.
Last update: March 1, 2011
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