Mario Paolone mainly focuses on Electronic engineering, Lightning, Emtp, Distributed generation and Grid. His studies in Electronic engineering integrate themes in fields like Electric power system, Electrical network, Electric power transmission, Fault indicator and Transient. His Lightning study contributes to a more complete understanding of Electrical engineering.
Mario Paolone has researched Emtp in several fields, including Distribution networks, Power quality and Simulation. His work deals with themes such as Photovoltaic system and Optimal control, which intersect with Distributed generation. His research in Grid intersects with topics in Real-time computing, Mathematical optimization and Observability.
Mario Paolone focuses on Lightning, Electronic engineering, Electrical engineering, Electric power system and Control theory. His Lightning research is multidisciplinary, incorporating elements of Tower, Overhead, Current and Voltage. The concepts of his Voltage study are interwoven with issues in Distribution networks and Distributed generation.
As part of one scientific family, Mario Paolone deals mainly with the area of Electronic engineering, narrowing it down to issues related to the Fault, and often Algorithm. His study on Phasor is often connected to Context as part of broader study in Electric power system. In his study, Reliability engineering is strongly linked to Grid, which falls under the umbrella field of Control theory.
His primary areas of study are Electric power system, Grid, Control theory, Phasor and Distributed generation. In his articles, Mario Paolone combines various disciplines, including Electric power system and Context. As a part of the same scientific study, he usually deals with the Grid, concentrating on Energy storage and frequently concerns with Mathematical optimization, Photovoltaic system and Renewable energy.
When carried out as part of a general Phasor research project, his work on Phasor measurement unit is frequently linked to work in Units of measurement, therefore connecting diverse disciplines of study. His work in Distributed generation addresses issues such as Voltage, which are connected to fields such as Automatic frequency control. His Harmonic research is multidisciplinary, relying on both Electronic engineering and Harmonic analysis.
Mario Paolone spends much of his time researching Electric power system, Phasor, AC power, Grid and Control theory. Mario Paolone interconnects Reliability engineering, Electronic engineering, State and Harmonic in the investigation of issues within Phasor. His work often combines Electronic engineering and National instrument studies.
His AC power study combines topics in areas such as Distributed generation, Optimal control, Voltage regulation, Torque and Operating point. As a member of one scientific family, he mostly works in the field of Grid, focusing on Model predictive control and, on occasion, Distributed computing, Scheduling and Microgrid. His Control theory research incorporates elements of Convergence and State.
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Optimal Allocation of Dispersed Energy Storage Systems in Active Distribution Networks for Energy Balance and Grid Support
Mostafa Nick;Rachid Cherkaoui;Mario Paolone.
IEEE Transactions on Power Systems (2014)
Continuous-Wavelet Transform for Fault Location in Distribution Power Networks: Definition of Mother Wavelets Inferred From Fault Originated Transients
A. Borghetti;M. Bosetti;M. Di Silvestro;C.A. Nucci.
IEEE Transactions on Power Systems (2008)
Real-Time Simulation Technologies for Power Systems Design, Testing, and Analysis
M. D. Omar Faruque;Thomas Strasser;Georg Lauss;Vahid Jalili-Marandi.
IEEE Power and Energy Technology Systems Journal (2015)
Short-Term Scheduling and Control of Active Distribution Systems With High Penetration of Renewable Resources
A Borghetti;M Bosetti;S Grillo;S Massucco.
IEEE Systems Journal (2010)
Enhanced Interpolated-DFT for Synchrophasor Estimation in FPGAs: Theory, Implementation, and Validation of a PMU Prototype
Paolo Romano;Mario Paolone.
IEEE Transactions on Instrumentation and Measurement (2014)
Mitigation of lightning-induced overvoltages in medium Voltage distribution lines by means of periodical grounding of shielding wires and of surge arresters: modeling and experimental validation
M. Paolone;C.A. Nucci;E. Petrache;F. Rachidi.
IEEE Transactions on Power Delivery (2004)
Integrated Use of Time-Frequency Wavelet Decompositions for Fault Location in Distribution Networks: Theory and Experimental Validation
A Borghetti;M Bosetti;C A Nucci;M Paolone.
IEEE Transactions on Power Delivery (2010)
Efficient Computation of Sensitivity Coefficients of Node Voltages and Line Currents in Unbalanced Radial Electrical Distribution Networks
K. Christakou;J. LeBoudec;M. Paolone;D-C Tomozei.
IEEE Transactions on Smart Grid (2013)
An Improved Procedure for the Assessment of Overhead Line Indirect Lightning Performance and Its Comparison with the IEEE Std. 1410 Method
A. Borghetti;C.A. Nucci;M. Paolone.
IEEE Transactions on Power Delivery (2007)
A Microcontroller-Based Power Management System for Standalone Microgrids With Hybrid Power Supply
B. Belvedere;M. Bianchi;A. Borghetti;C. A. Nucci.
IEEE Transactions on Sustainable Energy (2012)
École Polytechnique Fédérale de Lausanne
University of Bologna
University of Bologna
École Polytechnique Fédérale de Lausanne
University of Florida
University of Florida
Northeastern University
Kiel University
Uppsala University
École Polytechnique Fédérale de Lausanne
Profile was last updated on December 6th, 2021.
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