Your search keyword '"Mohamed Khamies"' showing total 22 results

1. Frequency regulation in a hybrid renewable power grid: an effective strategy utilizing load frequency control and redox flow batteries

Author

Ahmed H. A. Elkasem, Salah Kamel, Mohamed Khamies, and Loai Nasrat

Subjects

Fuzzy-PID + (T $${I}^{\lambda }{D}^{\mu }$$ I λ D μ ) controller, Crayfish optimization algorithm, Load frequency control, Renewable energy resources, Controlled redox flow batteries, Communication delay time, Medicine, Science

Abstract

Abstract Renewable energy sources (RESs) have become integral components of power grids, yet their integration presents challenges such as system inertia losses and mismatches between load demand and generation capacity. These issues jeopardize grid stability. To address this, an effective approach is proposed, combining enhanced load frequency control (LFC) (i.e., fuzzy PID- T $${I}^{\lambda }{D}^{\mu }$$ I λ D μ ) with controlled energy storage systems, specifically controlled redox flow batteries (CRFBs), to mitigate uncertainties arising from RES integration. The optimization of this strategy's parameters is achieved using the crayfish optimization algorithm (COA), known for its global optimization capabilities and balance between exploration and exploitation. Performance evaluation against conventional controllers (PID, FO-PID, FO-(PD-PI)) confirms the superiority of the proposed approach in LFC. Extensive testing under various load disturbances, high renewables penetration, and communication delays ensures its effectiveness in minimizing disruptions. Validation using a standardized IEEE 39-bus system further demonstrates its efficiency in power networks grappling with significant renewables penetration. In summary, this integrated strategy presents a robust solution for modern power systems adapting to increasing renewable energy utilization.

Published

2024

2. Feasibility Study and Economic Analysis of PV/Wind-Powered Hydrogen Production Plant

Author

Khairy Sayed, Mohamed Khamies, Ahmed G. Abokhalil, Mahmoud Aref, Mahmoud A. Mossa, Mishari Metab Almalki, and Thamer A. H. Alghamdi

Subjects

Cost-effective, DC/AC microgrid, green hydrogen, PV/wind, RES integration, sustainable energy, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In Egypt, the production of power and the associated environmental problems are starting to take the stage. One environmentally responsible way to lessen the power crisis is to employ renewable energy sources effectively and efficiently. This paper proposes to develop a hydrogen energy storage-based green (or environmentally friendly) power plant on many Egyptian cities such as Sohag city. To produce green hydrogen, the proposed power station uses energy storage, solar, and wind power. Energy storage systems are used to store extra energy produced by wind turbines and solar panels and to supply energy when the output of renewable energy is low. An optimized design of the proposed power plant uses hydrogen energy to satisfy peak load requirements and reduce GHG (greenhouse gas) emissions. Electrolysis is the method used in the proposed solar/wind power plant to create hydrogen. Water can be split into hydrogen and oxygen via electrolysis, a process that uses electricity. Renewable energy sources can be used to power this procedure, ensuring that the hydrogen produced is “green” and does not contribute to greenhouse gas emissions. The design of the power plant incorporates advanced electrolysis technology, such as proton exchange membrane (PEM) electrolyzers, which are efficient and well-suited for integrating with renewable energy sources.

Published

2024

3. Application of Tilt Integral Derivative for Efficient Speed Control and Operation of BLDC Motor Drive for Electric Vehicles

Author

Khairy Sayed, Hebatallah H. El-Zohri, Adel Ahmed, and Mohamed Khamies

Subjects

brushless direct current motors, current control, pulse width modulation, speed control of BLDC motors, electric vehicle, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

This study presents the tilt integral derivative (TID) controller technique for controlling the speed of BLDC motors in order to improve the real-time control of brushless direct current motors in electric vehicles. The TID controller is applied to the considered model to enhance its performance, e.g., torque and speed. This control system manages the torque output, speed, and position of the motor to ensure precise and efficient operation in EV applications. Brushless direct current motors are becoming more and more popular due to their excellent torque, power factor, efficiency, and controllability. The differences between PID, TID, and PI controllers are compared. The outcomes demonstrated that the TID control enhanced the torque and current stability in addition to the BLDC system’s capacity to regulate speed. TID controllers provide better input power for BLDC (brushless DC) drives than PI and PID controllers do. Better transient responsiveness and robustness to disturbances are features of TID controller design, which can lead to more effective use of input power. TID controllers are an advantageous choice for BLDC drive applications because of their increased performance, which can result in increased system responsiveness and overall efficiency. In an experimental lab, a BLDC motor drive prototype is implemented in this study. To fully enhance the power electronic subsystem and the brushless DC motor’s real-time performance, a test bench was also built.

Published

2024

4. Optimized Multiloop Fractional-Order Controller for Regulating Frequency in Diverse-Sourced Vehicle-to-Grid Power Systems

Author

Amira Hassan, Mohamed M. Aly, Mohammed A. Alharbi, Ali Selim, Basem Alamri, Mokhtar Aly, Ahmed Elmelegi, Mohamed Khamies, and Emad A. Mohamed

Subjects

electrical grid, electric vehicle application, fractional order control theory, load frequency controller (LFC), marine predator optimizer (MPA), multisourced power systems, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

A reduced power system’s inertia represents a big issue for high penetration levels of renewable generation sources. Recently, load frequency controllers (LFCs) and their design have become crucial factors for stability and supply reliability. Thence, a new optimized multiloop fractional LFC scheme is provided in this paper. The proposed multiloop LFC scheme presents a two-degree-of-freedom (2DOF) structure using the tilt–integral–derivatives with filter (TIDN) in the first stage and the tilt–derivative with filter (TDN) in the second stage. The employment of two different loops achieves better disturbance rejection capability using the proposed 2DOF TIDN-TDN controller. The proposed 2DOF TIDN-TDN method is optimally designed using the recent powerful marine predator optimizer algorithm (MPA). The proposed design method eliminates the need for precise modeling of power systems, complex control design theories, and complex disturbance observers and filter circuits. A multisourced two-area interlinked power grid is employed as a case study in this paper by incorporating renewable generation with multifunctionality electric vehicle (EV) control and contribution within the vehicle-to-grid (V2G) concept. The proposed 2DOF TIDN-TDN LFC is compared with feature-related LFCs from the literature, such as TID, FOTID, and TID-FOPIDN controllers. Better mitigated frequency and tie-line power fluctuations, faster response, lower overshot/undershot values, and shorter settling time are the proven features of the proposed 2DOF TIDN-TDN LFC method.

Published

2023

5. Optimal Model Predictive and Linear Quadratic Gaussian Control for Frequency Stability of Power Systems Considering Wind Energy

Author

Mohamed Khamies, Gaber Magdy, Salah Kamel, and Baseem Khan

Subjects

Frequency control (LFC), model predictive control (MPC), linear quadratic gaussian (LQG), wind energy, chimp optimization algorithm, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This work presents a new robust control technique which combines a model predictive control (MPC) and linear quadratic gaussian (LQG) approach to support the frequency stability of modern power systems. Moreover, the constraints of the proposed robust controller (MPC-LQG) are fine-tuned based on a new technique titled Chimp optimization algorithm (ChOA). The effectiveness of the proposed robust controller is tested and verified through a multi-area power system (i.e., single-area and two-area power systems). Each area contains a thermal power plant as a conventional generation source considering physical constraints (i.e. generation rate constraint, and governor dead band) in addition to a wind power plant as a renewable resource. The superiority of the proposed robust controller is confirmed by contrasting its performance to that of other controllers which were used in load frequency control studies (e.g., conventional integral and MPC). Also, the ChOA’s ingenuity is verified over several other powerful optimization techniques; particle swarm optimization, gray wolf optimization, and ant lion optimizer). The simulation outcomes reveal the effectiveness as well as the robustness of the proposed MPC-LQG controller based on the ChOA under different operating conditions considering different load disturbances and several penetration levels of the wind power.

Published

2021

6. An Efficient Control Strategy for Enhancing Frequency Stability of Multi-Area Power System Considering High Wind Energy Penetration

Author

Mohamed Khamies, Gaber Magdy, Mohamed Ebeed Hussein, Fahd A. Banakhr, and Salah Kamel

Subjects

Frequency stability, interconnected power systems, linear quadratic Gaussian (LQG), lightning attachment procedure optimization (LAPO), high penetration of wind energy, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes an efficient control strategy to enhance frequency stability of three-area power system considering a high penetration level of wind energy. The proposed strategy is based on a combination of a Proportional Integral Derivative (PID) controller with a Linear Quadratic Gaussian (LQG) approach. The parameters of the proposed controller (i.e., PID-LQG) are optimally designed by a novel natural physical based-algorithm called Lightning Attachment Procedure Optimization (LAPO). The main objective is to keep the frequency fluctuation at its acceptable value in the presence of high penetration of wind energy, high load disturbance and system uncertainties. The superiority of the proposed PID-LQG controller is validated by comparing its performance with optimal Coefficient Diagram Method (CDM) controller, conventional CDM controller, optimal PID controller-based LAPO, and integral controller. Moreover, the exhaustive results completely demonstrate that the proposed controller gives better performance in terms of overshoot, undershoot, and settling time as well as provides reliable frequency stability for interconnected power systems considering high wind penetration and system uncertainties.

Published

2020

7. A Developed Frequency Control Strategy for Hybrid Two-Area Power System with Renewable Energy Sources Based on an Improved Social Network Search Algorithm

Author

Mohamed Khamies, Salah Kamel, Mohamed H. Hassan, and Mohamed F. Elnaggar

Subjects

frequency stability, virtual inertia control, superconducting magnetic energy storage, renewable power penetration, Mathematics, QA1-939

Abstract

In this paper, an effective frequency control strategy is proposed for emulating sufficient inertia power and improving frequency stability. The developed technique is based on applying virtual inertia control (VIC) with superconducting magnetic energy storage (SMES) instead of a traditional energy storage system (ESS) to compensate for the system inertia during the high penetration of renewable energy sources, taking into account the role of the controller in the secondary control loop (SCL). Unlike previous studies that depended on the designer experience in selecting the parameters of the inertia gain or the parameters of the SMES technology, the parameters of the proposed strategy are selected using optimization techniques. Moreover, an improved optimization algorithm called Improved Social Network Search algorithm (ISNS) is proposed to select the optimal parameters of the proposed control strategy. Moreover, the ISNS is improved to overcome the demerits of the traditional SNS algorithm, such as low speed convergence and global search capability. Accordingly, the ISNS algorithm is applied to a hybrid two-area power grid to determine the optimal parameters of the proposed control technique as follows: the proportional-integral derivative (PID) controller in the SCL. Additionally, the ISNS is applied to select the optimal control gains of the VIC-based SMES technology (e.g., the inertia gain, the proportional gain of the SMES, and the negative feedback gain of the SMES). Furthermore, the effectiveness of the proposed ISNS algorithm is validated by comparing its performance with that of the traditional SNS algorithm and other well-known algorithms (i.e., PSO, TSA, GWO, and WHO) considering different standard benchmark functions. Formerly, the effectiveness of the proposed frequency control technique was confirmed by comparing its performance with the system performance based on optimal VIC with ESS as well as without VIC considering different operating situations. The simulation results demonstrated the superiority of the proposed technique over other considered techniques, especially during high penetration of renewable power and lack of system inertia. As a result, the proposed technique is credible for modern power systems that take into account RESs.

Published

2022

8. Optimal Design of TD-TI Controller for LFC Considering Renewables Penetration by an Improved Chaos Game Optimizer

Author

Ahmed H. A. Elkasem, Mohamed Khamies, Mohamed H. Hassan, Ahmed M. Agwa, and Salah Kamel

Subjects

improved chaos game optimization, TD-TI controller, load frequency control, renewable energy sources, electrical vehicles, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

This study presents an innovative strategy for load frequency control (LFC) using a combination structure of tilt-derivative and tilt-integral gains to form a TD-TI controller. Furthermore, a new improved optimization technique, namely the quantum chaos game optimizer (QCGO) is applied to tune the gains of the proposed combination TD-TI controller in two-area interconnected hybrid power systems, while the effectiveness of the proposed QCGO is validated via a comparison of its performance with the traditional CGO and other optimizers when considering 23 bench functions. Correspondingly, the effectiveness of the proposed controller is validated by comparing its performance with other controllers, such as the proportional-integral-derivative (PID) controller based on different optimizers, the tilt-integral-derivative (TID) controller based on a CGO algorithm, and the TID controller based on a QCGO algorithm, where the effectiveness of the proposed TD-TI controller based on the QCGO algorithm is ensured using different load patterns (i.e., step load perturbation (SLP), series SLP, and random load variation (RLV)). Furthermore, the challenges of renewable energy penetration and communication time delay are considered to test the robustness of the proposed controller in achieving more system stability. In addition, the integration of electric vehicles as dispersed energy storage units in both areas has been considered to test their effectiveness in achieving power grid stability. The simulation results elucidate that the proposed TD-TI controller based on the QCGO controller can achieve more system stability under the different aforementioned challenges.

Published

2022

9. An Eagle Strategy Arithmetic Optimization Algorithm for Frequency Stability Enhancement Considering High Renewable Power Penetration and Time-Varying Load

Author

Ahmed. H. A. Elkasem, Salah Kamel, Mohamed H. Hassan, Mohamed Khamies, and Emad M. Ahmed

Subjects

load frequency control (LFC), arithmetic optimization algorithm (AOA), eagle strategy arithmetic optimization algorithm (ESAOA), proportional-integral-derivative (PID), fractional-order proportional-integral-derivative (FOPID), renewable energy sources (RESs), Mathematics, QA1-939

Abstract

This study proposes a new optimization technique, known as the eagle strategy arithmetic optimization algorithm (ESAOA), to address the limitations of the original algorithm called arithmetic optimization algorithm (AOA). ESAOA is suggested to enhance the implementation of the original AOA. It includes an eagle strategy to avoid premature convergence and increase the populations’ efficacy to reach the optimum solution. The improved algorithm is utilized to fine-tune the parameters of the fractional-order proportional-integral-derivative (FOPID) and the PID controllers for supporting the frequency stability of a hybrid two-area multi-sources power system. Here, each area composites a combination of conventional power plants (i.e., thermal-hydro-gas) and renewable energy sources (i.e., wind farm and solar farm). Furthermore, the superiority of the proposed algorithm has been validated based on 23 benchmark functions. Then, the superiority of the proposed FOPID-based ESAOA algorithm is verified through a comparison of its performance with other controller performances (i.e., PID-based AOA, PID-based ESAOA, and PID-based teaching learning-based optimization TLBO) under different operating conditions. Furthermore, the system nonlinearities, system uncertainties, high renewable power penetration, and control time delay has been considered to ensure the effectiveness of the proposed FOPID based on the ES-AOA algorithm. All simulation results elucidate that the domination in favor of the proposed FOPID-based ES-AOA algorithm in enhancing the frequency stability effectually will guarantee a reliable performance.

Published

2022

10. A modified controller scheme for frequency stability enhancement of hybrid two‐area power grid with renewable energy sources

Author

Mohamed Ahmed, Mohamed Khamies, Mohamed H. Hassan, José Luis Domínguez‐García, and Salah Kamel

Subjects

Renewable Energy, Sustainability and the Environment

Published

2022

11. An improved Rao algorithm for frequency stability enhancement of nonlinear power system interconnected by AC/DC links with high renewables penetration

Author

Salah Kamel, Ali Selim, Gaber Magdy, and Mohamed Khamies

Subjects

Wind power, Computer science, business.industry, Automatic frequency control, Stability (learning theory), PID controller, Electric power system, Artificial Intelligence, Control theory, Benchmark (computing), Hybrid power, business, Algorithm, Software

Abstract

In this paper, an improved optimization algorithm is proposed to overcome the original Rao algorithm limitations (i.e., different characteristics in exploration and exploitation) and enhance the performance of the original Rao algorithm. In the improved algorithm, the self-adaptive multi-population and Levy flight methods are utilized in the original Rao algorithm. The improved algorithm is called I_Rao_3. The improved algorithm’s efficiency is confirmed by comparing it to the original Rao algorithm utilizing various standard benchmark test functions. Moreover, the proposed I_Rao_3 algorithm is utilized to improve the frequency response in a hybrid renewable power grid by fine-tuning the proportional-integral-derivative (PID) controller parameters. The targeted system used for this study is a hybrid power grid, which encompasses conventional generating stations (i.e., thermal power plants), renewable power stations (i.e., PV and wind power stations) for the analysis of the load frequency control (LFC) issue. Unlike other previously published works, this study considers the impact of DC links in parallel to AC links to interconnect the two-hybrid renewable power system area. In addition, the nonlinearities effects (i.e., generation rate constraint and a governor dead band) are applied to each area in order to achieve a more realistic study. The superiority of the proposed PID controller-based I_Rao_3 algorithm is endorsed by comparing its performance with many other optimization algorithms.

Published

2021

12. Frequency Stability Enhancement of Hybrid Multi-area Power Grid Considering High Renewable Energy Penetration Using TID Controller

Author

Ahmed. H. A. Elkasem, Salah Kamel, Mohamed Khamies, Ersan Kabalci, and Hossein Shahinzadeh

Published

2022

13. Artificial Gorilla Troops Optimizer for Optimum Tuning of TID Based Power System Stabilizer

Author

Mahmoud A. El-Dabah, Salah Kamel, Mohamed Khamies, Hossein Shahinzadeh, and Gevork B. Gharehpetian

Published

2022

14. An Efficient Control Strategy for Enhancing Frequency Stability of Multi-Area Power System Considering High Wind Energy Penetration

Author

Gaber Magdy, Fahd A. Banakhr, Salah Kamel, Mohamed Khamies, and Mohamed Ebeed Hussein

Subjects

Wind power, linear quadratic Gaussian (LQG), General Computer Science, Computer science, business.industry, Settling time, General Engineering, Frequency stability, PID controller, Linear-quadratic-Gaussian control, interconnected power systems, lightning attachment procedure optimization (LAPO), Electric power system, Control theory, Computer Science::Systems and Control, Overshoot (signal), Coefficient diagram method, General Materials Science, high penetration of wind energy, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971

Abstract

This paper proposes an efficient control strategy to enhance frequency stability of three-area power system considering a high penetration level of wind energy. The proposed strategy is based on a combination of a Proportional Integral Derivative (PID) controller with a Linear Quadratic Gaussian (LQG) approach. The parameters of the proposed controller (i.e., PID-LQG) are optimally designed by a novel natural physical based-algorithm called Lightning Attachment Procedure Optimization (LAPO). The main objective is to keep the frequency fluctuation at its acceptable value in the presence of high penetration of wind energy, high load disturbance and system uncertainties. The superiority of the proposed PID-LQG controller is validated by comparing its performance with optimal Coefficient Diagram Method (CDM) controller, conventional CDM controller, optimal PID controller-based LAPO, and integral controller. Moreover, the exhaustive results completely demonstrate that the proposed controller gives better performance in terms of overshoot, undershoot, and settling time as well as provides reliable frequency stability for interconnected power systems considering high wind penetration and system uncertainties.

Published

2020

15. Optimal Parameter Design of MPC for Performance Enhancement of a Two-Area Interconnected Power Grid

Author

Mohamed Khamies, Gaber Magdy, Salah Kamel, and Salah K. Elsayed

Published

2021

16. Frequency Stability of AC/DC Interconnected Power Systems with Wind Energy Using Arithmetic Optimization Algorithm-Based Fuzzy-PID Controller

Author

Ibrahim B. M. Taha, Ahmed. H. A. Elkasem, Gaber Magdy, Salah Kamel, and Mohamed Khamies

Subjects

Wind power, Environmental effects of industries and plants, Renewable Energy, Sustainability and the Environment, Computer science, business.industry, load frequency control (LFC), Geography, Planning and Development, PID controller, TJ807-830, Management, Monitoring, Policy and Law, TD194-195, high wind energy penetration, Renewable energy sources, Environmental sciences, Electric power system, Control theory, Robustness (computer science), Differential evolution, multi-source power system, fuzzy logic control (FLC), High-voltage direct current, GE1-350, Arithmetic, Intelligent control, business

Abstract

This article proposes an intelligent control strategy to enhance the frequency dynamic performance of interconnected multi-source power systems composing of thermal, hydro, and gas power plants and the high penetration level of wind energy. The proposed control strategy is based on a combination of fuzzy logic control with a proportional-integral-derivative (PID) controller to overcome the PID limitations during abnormal conditions. Moreover, a newly adopted optimization technique namely Arithmetic optimization algorithm (AOA) is proposed to fine-tune the proposed fuzzy-PID controller to overcome the disadvantages of conventional and heuristic optimization techniques (i.e., long time in estimating controller parameters-slow convergence curves). Furthermore, the effect of the high voltage direct current link is taken into account in the studied interconnected power system to eliminate the AC transmission disadvantages (i.e., frequent tripping during oscillations in large power systems–high level of fault current). The dynamic performance analysis confirms the superiority of the proposed fuzzy-PID controller based on the AOA compared to the fuzzy-PID controller based on a hybrid local unimodal sampling and teaching learning-based optimization (TLBO) in terms of minimum objective function value and overshoots and undershoots oscillation measurement. Also, the AOA’s proficiency has been verified over several other powerful optimization techniques, differential evolution, TLBO using the PID controller. Moreover, the simulation results ensure the effectiveness and robustness of the proposed fuzzy-PID controller using the AOA in achieving better performance under several contingencies, different load variations, the high penetration level of the wind power, and system uncertainties compared to other literature controllers adjusting by various optimization techniques.

Published

2021

17. An efficient coordinated strategy for frequency stability in hybrid power systems with renewables considering interline power flow controller and redox flow battery

Author

Mohamed Ahmed, Gaber Magdy, Mohamed Khamies, and Salah Kamel

Subjects

Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Electrical and Electronic Engineering

Published

2022

18. Slime Mould Algorithm for Frequency Controller Design of a Two-area Thermal-PV Power System

Author

Mohamed Khamies, Salah Kamel, Gaber Magdy, and Salah K. Elsayed

Subjects

Electric power system, Settling time, Robustness (computer science), Control theory, Computer science, Photovoltaic system, Overshoot (signal), PID controller, Algorithm, Maximum power point tracking

Abstract

In this study, a new implementation of the slime mould algorithm (SMA) is proposed to find the optimal parameters of proportional-integral (PI) controller and enhance the frequency stability in a two-area interconnected power grid combining thermal generator unit and photovoltaic (PV) system. Moreover, the design process of the considered power system takes the maximum power point tracking (MPPT) of the PV into its consideration. Furthermore, a time-domain based on the integral of time multiply absolute error (ITAE) is recognized for the robust design of the PI controller parameters exploiting the proposed SMA. The comparative results demonstrate the robustness of the proposed SMA-PI controller among all control methods (e.g. WOA-PI controller, GA-PI controller, and FA-PI controller) in terms of maximum undershoot, maximum overshoot, and maximum settling time under different operating condition (system parameters variations, and load disturbance).

Published

2021

19. A robust PID controller based on linear quadratic gaussian approach for improving frequency stability of power systems considering renewables

Author

Gaber Magdy, Mohamed Khamies, Salah Kamel, and Mohamed Ebeed

Subjects

0209 industrial biotechnology, Computer science, business.industry, Applied Mathematics, 020208 electrical & electronic engineering, PID controller, 02 engineering and technology, Linear-quadratic-Gaussian control, Stability (probability), Computer Science Applications, Power (physics), Renewable energy, Electric power system, 020901 industrial engineering & automation, Control and Systems Engineering, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Frequency stabilization, Electrical and Electronic Engineering, business, Instrumentation

Abstract

This paper proposes a novel robust controller for frequency stabilization of electrical systems taken into consideration a high renewable energy sources (RESs) penetration. The suggested controller, robust PID (RPID) controller, is combination of a proportional-integral-derivative (PID) controller and a linear quadratic gaussian (LQG) controller. Furthermore, the Improved lightning attachment procedure optimization (ILAPO) technique is applied for determining the optimal setting of the parameters of the introduced RPID controller. A studied power system with RESs is used as a test system to justify the performance of the RPID controller. The superiority of the introduced robust controller is verified through a comparison of its performance under system uncertainties with those of other robust controllers presented in the literature. The results elucidate that the RPID controller can effectually enhance frequency stability and guarantee reliable performance for power grids supplied with high share of renewable energy for all studied scenarios. Consequently, the proposed RPID controller purveys creditable for modern power systems considering RESs.

Published

2020

20. Modified TID controller for load frequency control of a two-area interconnected diverse-unit power system

Author

Mohamed Khamies, Mohamed Ahmed, Salah Kamel, and Gaber Magdy

Subjects

Electric power system, business.industry, Control theory, Computer science, Automatic frequency control, Energy Engineering and Power Technology, PID controller, Particle swarm optimization, Deadband, Electrical and Electronic Engineering, Hydraulic machinery, business, Solar power

Abstract

In this work, a modified structure of the tilted integral derivative (TID) controller, i.e. an integral derivative-tilted (ID-T) controller, is developed for the load frequency control issue of a multi-area interconnected multi-source power system. Moreover, a new optimization algorithm known as Archimedes optimization algorithm (AOA) is used to fine-tune the proposed ID-T controller parameters. The performance of the proposed ID-T controller based on AOA is evaluated through a two-area interconnected power system, each area containing various conventional generation units (i.e., thermal, gas, and hydraulic power plants) and renewables (wind and solar power). Furthermore, system nonlinearities (i.e., generation rate constraints, governor deadband, and communication time delays), system uncertainties, and load/renewables fluctuations are considered in designing the proposed controller. The effectiveness of the proposed ID-T controller based on AOA is verified by comparing its performance with other control techniques in the literature (i.e. integral controller, proportional integral derivative (PID) controller, fractional-order PID controller, TID controller, and I-TD controller). The AOA's optimization superiority has also been verified against a variety of other sophisticated optimization methods, including particle swarm optimization and whale optimization algorithm. The simulation results exhibit that the proposed ID-T controller based on the AOA presents a great improvement in the system frequency stability under several contingencies of different load perturbations, system uncertainties, physical constraints, communication time delays, high renewables penetration.

Published

2022

21. UTILIZATION OF Ziziphus spina-christi LEAVES AS A NATURAL GROWTH PROMOTER IN RABBIT’S RATIONS.

Author

Basyony, Mohamed, primary, Elsheikh, Hanim, additional, Abdel Salam, Haiam, additional, Mohamed, Khamies, additional, and Zedan., Afaf, additional

Published

2017

22. Load Frequency Control in Single Area System Using Model Predictive Control and Linear Quadratic Gaussian Techniques

Author

Gaber Shabib, Tarek Hassan Mohamed, Mohamed Khamies, Esam H. Abdelhameed, and Yaser Qudaih

Subjects

Model predictive control, Single area, Control theory, Automatic frequency control, Linear-quadratic-Gaussian control, Mathematics

Published

2015