Work place: Electrical Power Engineering Dept., Faculty of Engineering, Ain Shams University, Cairo, Egypt
E-mail: hossam.eldeen@fue.edu.eg
Website:
Research Interests: Computer systems and computational processes, Neural Networks, Computer Networks, Data Structures and Algorithms
Biography
Hossam E.A. Talaat received the B.Sc. and M.Sc. degrees from Ain Shams University, Cairo, Egypt in 1975 and 1980 respectively, and his Ph.D. degree from University of Grenoble, France in 1986. During 1999-2001. He is a reviewer of many international journals (IEEE, IET, Electric Power System Research, Electrical power and Energy systems, ...). He has supervised 40+ Ph.D. and M.Sc. theses in the field of power system operation, control, stability, and protection. He has taught tens of undergraduate and graduate courses in this field. He has authored and co-authored more than 70 technical papers and reports. He has accomplished several research projects as PI and as the investigator. He was the reviewer of a number of academic undergraduate and postgraduate programs for Egyptian and Arabic Universities. He is the Chairman of 2 IEC committees (49&93) and was a member of the Egyptian National board of Electricity and Energy Researches– Scientific Research and Technology Academy. He is the Chairman of the Middle East Conference on Power Systems MEPCON 2014 to be held on 23th-25th December 2014. He is interested in many research areas such as Distributed Generation and Microgrids, Application of artificial intelligence techniques (Neural Networks, Knowledge-Based Systems, Genetic Algorithms, and Fuzzy Logic) to Power System analysis, control, and protection; Real-time applications to electrical power systems and machines; Application of optimal and adaptive control techniques for the enhancement of power system stability. His email is hossam.eldeen@fue.edu.eg.
By Nader M.A. Ibrahim Basem E. Elnaghi Hamed A. Ibrahim Hossam E. A. Talaat
DOI: https://doi.org/10.5815/ijisa.2019.07.05, Pub. Date: 8 Jul. 2019
This paper describes the process of power system stabilizer (PSS) optimization by using bacterial foraging (BG) to improve the power system stability and damping out the oscillation during large and small disturbances in a multi-machine power system. The proposed PSS type is P. Kundur (Lead-Lag) with speed deviation as the input signal. BG used to optimize the PSS gains. The proposed BG based delta w lead-lag PSS (P. Kundur structure) (BG-PSS) evaluated in the well-known benchmark simulation problem P. Kundur 4-machines 11-buses 2-areas power system. The BG-PSS compared with MB-PSS with simplified settings: IEEE® type PSS4B according to IEEE Std. 421.5, Conventional Delta w PSS (as the proposed PSS without optimization) from P. Kundur, and Conventional Acceleration Power (Delta Pa) PSS to demonstrate its robustness and superiority versus the three PSSs types to damp out the inter-area oscillations in a multi-machine power system. The damping ratio and the real part of the eigenvalues used as the fitness function in the optimization process. The nonlinear simulation results obtained in the MATLAB / SIMULINK environment prove that the proposed PSS is highly effective, robust, & superior to the other used controllers in restrictive the inter-area oscillation in a large power system & to maintain the wide-area stability of the system. Also, the performance indices eigenvalue analysis, peak overshoot, settling time, and steady-state error used to validate the superior oscillation damping and fast recovered transient dynamic behavior over the three considered controllers.
[...] Read more.By Bassam A. Hemade Hamed A. Ibrahim Hossam E. A. Talaat
DOI: https://doi.org/10.5815/ijisa.2019.02.04, Pub. Date: 8 Feb. 2019
Power system contingency studies play a pivotal role in maintaining the security and integrity of modern power system operation. However, the number of possible contingencies is enormous and mostly vague. Therefore, in this paper, two well-known clustering techniques namely K-Means (KM) and Fuzzy C-Means (FCM) are used for contingency screening and ranking. The performance of both algorithms is comparatively investigated using IEEE 118-bus test system. Considering various loading conditions and multiple outages, the IEEE 118-bus contingencies have been generated using fast-decoupled power flow (FDPF). Silhouette analysis and fuzzy partition coefficient techniques have been profitably exploited to offer an insight view of the number of centroids. Moreover, the principal component analysis (PCA) has been used to extract the dominant features and ensure the consistency of passed data with artificial intelligence algorithms’ requirements. Although analysis of comparison results showed excellent compatibility between the two clustering algorithms, the FCM model was found more suitable for power system static security investigation.
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