Your search keyword '"Taher Niknam"' showing total 352 results

1. Concurrent PV production and consumption load forecasting using CT‐Transformer deep learning to estimate energy system flexibility

Author

Mohammad Zarghami, Taher Niknam, Jamshid Aghaei, and Azita Hatami Nezhad

Subjects

learning systems, load forecasting, neural nets, solar photovoltaic systems, Renewable energy sources, TJ807-830

Abstract

Abstract The integration of renewable energy sources (RESs) into power systems has increased significantly due to technical, economic, and environmental factors, necessitating greater flexibility to manage variable consumption loads and renewable energy generation. Accurate forecasting of solar energy production and consumption load is critical for enhancing power system flexibility. This study introduces a novel deep learning model, a spatial‐temporal hybrid convolutional‐transformer (CT‐Transformer) network with unique features and extended memory capacity. Additionally, a flexibility index (FI) is introduced to evaluate power system flexibility (PSF) based on the forecasting results. The CT‐Transformer forecasts PSF for the next 24 and 168 hours, using the FI to evaluate PSF based on forecasting results. The input data includes meteorological, solar energy production, load demand, and pricing data from France, comprising hourly data from 2015 and 2016 (about 17,520 entries). Data preprocessing involves correcting incomplete and irrelevant segments. The CT‐Transformer's performance is compared to other deep learning techniques, showing superior results with the lowest prediction error (2.5%) and a maximum error of 10.1% (MAE). It also achieved a prediction error of 0.08% for system flexibility, compared to the highest error of 0.96%. This research highlights the CT‐Transformer's potential for accurate RES and load forecasting and PSF evaluation.

Published

2024

2. A novel stochastic framework for optimal scheduling of smart cities as an energy hub

Author

Masoud Shokri, Taher Niknam, Mojtaba Mohammadi, Moslem Dehghani, Pierluigi Siano, Khmaies Ouahada, and Miad Sarvarizade‐Kouhpaye

Subjects

distribution planning and operation, energy management systems, micro grids, scheduling, smart power grids, Distribution or transmission of electric power, TK3001-3521, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Abstract Smart cities consist of various energy systems and services that must be optimally scheduled to improve energy efficiency and reduce operation costs. The smart city layout comprises a power distribution system, a thermal energy system, a water system, and the private and public transportation systems. Additionally, several new technologies such as reconfiguration, regenerative braking energy of the metro, etc. are considered. This study is one of the first to consider all these technologies together in a smart city. The proposed power distribution system is a grid‐connected hybrid AC–DC microgrid. The biogeography‐based optimization algorithm was utilized to seek the best solution for scheduling micro‐turbines, fuel cells, heat pumps, desalination units, energy storage systems, AC–DC converters, purchasing power from the upstream, distributed energy resources, and transferring power amongst electric vehicle parking stations and metro for the next day. Also, the reduced unscented transformation layout was used to capture the system's uncertainty. The suggested layout is implemented on an enhanced IEEE 33‐bus test system to show the efficiency of the suggested method. The results show that costs and environmental pollution are reduced. By comparing the proposed smart city with other studies, the efficiency and completeness of the proposed smart city are shown.

Published

2024

3. Cloud-fog architecture-based control of smart island microgrid in master-slave organization using disturbance observer-based hybrid backstepping sliding mode controller

Author

Mohammad Ali Azizi, Taher Niknam, Moslem Dehghani, and Hossein Jokar

Subjects

Smart island microgrid, Hybrid backstepping sliding mode control, Disturbance observer, Master-slave organization, Cloud-fog computing, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Distributed control is an effective method to coordinate the microgrid with various components, and also in a smart microgrid, communication graph layouts are essential since changing the topology unexpectedly could disrupt the operation of the distributed controllers, and also an imbalance may occur between the production and load. Hence, reducing the exchanged data between units and system operator is essential in order to reduce the transmitted data volume and computational burden. For this purpose, an islanded microgrid with multiple agents which is using cloud-fog computing is proposed here, in order to reduce the computing burden on the central control unit as well as reducing data exchange among units. To balance the production power and loads in a smart island with a stable voltage/frequency, a hybrid backstepping sliding mode controller (BSMC) with disturbance observer (DO) is suggested to control voltage/frequency and current in the MG-based master-slave organization. Therefore, this paper proposes a DO-driven BSMC for controlling voltage/frequency, and power of energy sources within a Master-Slave organization; in addition, the study proposes a clod-fog computing for enhancing performance, reducing transferred data volume, and processing information on time. In the extensive simulations, the suggested controller shows a reduction in steady-state error, a fast response, and a lower total harmonic distortion (THD) for nonlinear and linear loads less than 0.33 %. The fog layer serves as a local processing level, so it reduces the exchanged data between cloud and fog nodes.

Published

2024

4. Particle Swarm Optimization Based Sliding Mode Controller for Performance Improvement of Unified Power Quality Controllers Inverters

Author

Mohammad Amin Heidari, Mehdi Nafar, and Taher Niknam

Subjects

power quality, inverter control, upqc, pso, Telecommunication, TK5101-6720

Abstract

In this paper particle swarm optimasation algorithm (PSO) based sliding mode controller(SMC) introduced to control invrters of Uniefied power quality Controllers(UPQC) to control and improve the power quality in microgrids through controlling the output power of the distributed generation source. In the proposed control scheme, the standard sliding mode controller (SMC) is used as a robust nonlinear controller, with the addition of the particle swarm optimization (PSO) algorithm - to determine the optimal parameters of the SMC controller. Using PSO added extra advantages like reducing chattering problems and increasing accuracy and tracking capability to the commonly knowns SMC benefits. To confirm the accuracy of the proposed controller's performance, computer simulation is performed under different system load conditions in the MATLAB/Simulink software environment. The obtained results show the effectiveness of the proposed control compared to the standard sliding mode controller in reducing harmonics, reducing voltage imbalance and improving other power quality indicators.

Published

2024

5. Investigating Intelligent Forecasting and Optimization in Electrical Power Systems: A Comprehensive Review of Techniques and Applications

Author

Seyed Mohammad Sharifhosseini, Taher Niknam, Mohammad Hossein Taabodi, Habib Asadi Aghajari, Ehsan Sheybani, Giti Javidi, and Motahareh Pourbehzadi

Subjects

forecasting, machine learning, meta-heuristic algorithms, optimization, power systems, renewable energy sources, Technology

Abstract

Electrical power systems are the lifeblood of modern civilization, providing the essential energy infrastructure that powers our homes, industries, and technologies. As our world increasingly relies on electricity, and modern power systems incorporate renewable energy sources, the challenges have become more complex, necessitating advanced forecasting and optimization to ensure effective operation and sustainability. This review paper provides a comprehensive overview of electrical power systems and delves into the crucial roles that forecasting and optimization play in ensuring future sustainability. The paper examines various forecasting methodologies from traditional statistical approaches to advanced machine learning techniques, and it explores the challenges and importance of renewable energy forecasting. Additionally, the paper offers an in-depth look at various optimization problems in power systems including economic dispatch, unit commitment, optimal power flow, and network reconfiguration. Classical optimization methods and newer approaches such as meta-heuristic algorithms and artificial intelligence-based techniques are discussed. Furthermore, the review paper examines the integration of forecasting and optimization, demonstrating how accurate forecasts can enhance the effectiveness of optimization algorithms. This review serves as a reference for electrical engineers developing sophisticated forecasting and optimization techniques, leading to changing consumer behaviors, addressing environmental concerns, and ensuring a reliable, efficient, and sustainable energy future.

Published

2024

6. Public policies for cyber security of sustainable dominated renewable smart grids

Author

Moslem Dehghani, Taher Niknam, Mina GhasemiGarpachi, Hassan Haes Alhelou, Motahareh Pourbehzadi, Giti Javidi, and Ehsan Sheybani

Subjects

cyber‐physical systems, power system security, smart power grids, sustainable development, Distribution or transmission of electric power, TK3001-3521, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Abstract The purpose of this paper is to examine cyber security issues related to smart grids (SGs), such as prior cyber‐attacks, possible vulnerability issues, and enhanced cyber‐security procedures for SGs on a technical and management basis. When designing public policies for SGs, it is important to consider both the motivations and obstacles to cyber protection and socio‐economic conditions. Furthermore, the importance of suggested policies is viewed from various perspectives. The present paper provides an assessment of a group of policies specified by various stakeholders as having the potential for developing SG cyber security. The methodology for the formation of such a group of policies includes a perfect examination of global experience and meetings with experts from various fields. Subsequently, such policies are evaluated using a Delphi questionnaire aimed at assessing their advantages in pursuing investment goals for cyber security. The first result is that every policy is considered a positive effect of all goals, different in the priority assigned to each of them. The policies that received the most attention were: “regulatory changes policy to foster innovation in cyber security of SGs,” “regulation of new business models to improve cyber security and detect malicious attacks” and “establish a cyber‐security governance strategy.”

Published

2023

7. Resiliency enhancement of power system against intentional attacks

Author

Farshad Faramarzi, Taher Niknam, Jamshid Aghaei, and Mohammadrashid Rashidi

Subjects

Renewable energy sources, TJ807-830

Abstract

Abstract Natural disasters, man‐made attacks, and cyber‐attacks are some of the main hazards of power system which can interrupt the process of continuous power delivery to the end users. In this way, man‐made attacks characteristics’ are fundamentally different from other hazards due to its adaptive strategy that allows attackers to target the most vulnerable parts of the power system. By choosing appropriate time and place; attackers always have advantages over the defender to penetrate the system and launch malicious actions. Therefore, it is quite necessary to take into account the optimal policy for allocating resources in the defender's strategy. This research proposes a four‐level Defence–Defence–Attack–Defence (DDAD) approach to improve the power system resilience against the intentional human attacks. A new defence level, a planning level, is added to the common three‐level Defence–Attack–Defence (DAD) model in power system planning state in order to prevent cut off loads and voltage drop beyond standard with lower cost. In the proposed method, load priority is used to classify the vulnerable sections. The proposed model is performed on IEEE‐30 bus test system and the results indicate the feasibility of the proposed method. As the results indicate, in proposed method less than 10% budget is needed compared with the previous method while all critical loads will be remained. Furthermore, the new method needs no security guard to protect transmission lines for 30 years.

Published

2022

8. Decision model for cross-border electricity trade considering renewable energy sources

Author

Mehrdad Eghlimi, Taher Niknam, and Jamshid Aghaei

Subjects

Electricity trade, Exchange, Solar system, Wind turbines, Cost optimization, Beta/Weibull distribution, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Substantial benefits can be achieved from electricity trade through the interconnection of electricity networks of neighboring countries. In this study, we introduce a regional electricity exchange model to obtain an optimal power trade level between electrically-interconnected countries. In addition, producing clean electricity is one of the primary goals of many countries. Moreover, electricity production can be optimized in some areas using renewable sources and exported to regions with high demand. Thus, the power exchange using the proposed method and framework is investigated. Additionally, a decision model for planning an optimal configuration of hybrid wind/solar power systems and optimal electricity trade is presented. We analyze the economic, engineering, management, and policy issues to facilitate optimization of power generation and trade at the country level and quantify the gains from the increased trade. The proposed decision model is employed to plan electricity trade considering hybrid wind and solar energy resources. Furthermore, the effectiveness of reducing the variability of hourly power supply is evaluated by integrating the wind and solar power generation technologies. The main decision variables are the power trade value and number of installed wind turbines and solar systems. In case studies, the computational results using the proposed model yielded an optimal power trade between Iran and its neighboring countries, including Turkey, Turkmenistan, Afghanistan, Pakistan, Azerbaijan, Armenia, and Iraq. Consequently, Iran can export a maximum power capacity of 5,300 MW to its neighbors, where Iraq receives the highest share of 2,000 MW. When the electricity demand in Iran is high, Turkey, Turkmenistan, Azerbaijan, and Armenia can export 1,200, 1,000, 80, and 100 MW of electricity to Iran, respectively. Finally, various configurations of a hybrid wind/solar power generation system considering various cost and power supply variations are presented to partly supply the load requirements of the traded electricity. Consequently, Iran can supply 20% of the total demand of the electricity trade by wind and solar system installed capacities of 316.5 and 267 MW, respectively.

Published

2022

9. Efficient Microgrid Management with Meerkat Optimization for Energy Storage, Renewables, Hydrogen Storage, Demand Response, and EV Charging

Author

Hossein Jokar, Taher Niknam, Moslem Dehghani, Ehsan Sheybani, Motahareh Pourbehzadi, and Giti Javidi

Subjects

microgrid, energy management, plug-in hybrid electric vehicles, hydrogen storage, meerkat optimization algorithm, Technology

Abstract

Within microgrids (MGs), the integration of renewable energy resources (RERs), plug-in hybrid electric vehicles (PHEVs), combined heat and power (CHP) systems, demand response (DR) initiatives, and energy storage solutions poses intricate scheduling challenges. Coordinating these diverse components is pivotal for optimizing MG performance. This study presents an innovative stochastic framework to streamline energy management in MGs, covering proton exchange membrane fuel cell–CHP (PEMFC-CHP) units, RERs, PHEVs, and various storage methods. To tackle uncertainties in PHEV and RER models, we employ the robust Monte Carlo Simulation (MCS) technique. Challenges related to hydrogen storage strategies in PEMFC-CHP units are addressed through a customized mixed-integer nonlinear programming (MINLP) approach. The integration of intelligent charging protocols governing PHEV charging dynamics is emphasized. Our primary goal centers on maximizing market profits, serving as the foundation for our optimization endeavors. At the heart of our approach is the Meerkat Optimization Algorithm (MOA), unraveling optimal MG operation amidst the intermittent nature of uncertain parameters. To amplify its exploratory capabilities and expedite global optima discovery, we enhance the MOA algorithm. The revised summary commences by outlining the overall goal and core algorithm, followed by a detailed explanation of optimization points for each MG component. Rigorous validation is executed using a conventional test system across diverse planning horizons. A comprehensive comparative analysis spanning varied scenarios establishes our proposed method as a benchmark against existing alternatives.

Published

2023

10. A Novel Four-Level Approach for Improving Power System Resilience Against Intentional Attacks

Author

Farshad Faramarzi, Taher Niknam, Motahareh Pourbehzadi, Giti Javidi, and Ehsan Sheybani

Subjects

Four-level resilience model, intentional human attack, power system planning, resilience, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This study proposes a new four-level model to enhance the resilience of power systems against human attacks. The model considers human attacks such as intelligent attackers and power system planners as defenders. The attackers want to maximize the impact of actions, while the defender tries to avoid imposed costs and damages due to budget limitations. The classic resilience model is a three-level defense-attack-defense (DAD) model, which includes the hardening measure, human attack, and recovery levels. In this study, power system planning, as a new defensive layer, was added prior to the conventional DAD. The proposed method becomes a four-level defense-defense-attack-defense (DDAD) model. To this end, a new four-level defense-defense-attack-defense (DDAD) model is proposed, in which a new defense layer is added to the common three-level defense-attack-defense (DAD) model. Looking at the model more closely, new power plants and substations are added to the power system to improve its resilience, and the most important power plants and substations are determined. Subsequently, a conventional three-level model was applied. In this research, the defender and attacker have strategies with their own costs for every power system component, such as power plants and substations, and their own interactions. The power system model includes the load, power plant and substation, and substation priority, which are defined as a combination of the values of the load and network topology. The proposed model was applied to the IEEE-30 bus test system, and the results indicated the effectiveness of the proposed method.

Published

2022

11. Probabilistic and Deterministic Wind Speed Prediction: Ensemble Statistical Deep Regression Network

Author

Solmaz Farahbod, Taher Niknam, Mohammad Mohammadi, Jamshid Aghaei, and Sattar Shojaeiyan

Subjects

Wind speed prediction, probability density function (PDF), residual deep network, modified kernel density estimation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Wind energy as one of the most promising energy alternatives brings a set of serious challenges in the operation of power systems because of the uncertain nature of wind speed. To address this problem, it is essential to establish a framework to forecast a comprehensive form of information about the wind speed. To this end, an ensemble residual regression deep network is designed to understand fully time-variant and spatial features from the historical data including wind speed and corresponding meteorological data. Then, to enhance the accuracy, a modified error-based loss function is proposed. Consequently, to provide a comprehensive form of information, a modified kernel density estimator is proposed to extract a set of probability density functions (PDFs) with a high level of accuracy and reliability. The simulation results and a comparative analysis on an actual dataset in London, U.K. demonstrate the high capability of the proposed probabilistic wind speed approach.

Published

2022

12. Game Theory-Based Bidding Strategy in the Three-Level Optimal Operation of an Aggregated Microgrid in an Oligopoly Market

Author

Milad Jokar-Dehoie, Mohsen Zare, Taher Niknam, Jamshid Aghaei, Motahareh Pourbehzadi, Giti Javidi, and Ehsan Sheybani

Subjects

Game theory, microgrid operations, oligopoly, optimization, bidding, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes a new framework for the optimal operation of a microgrid aggregator (MGA) that participates in an oligopoly electricity market. This aggregator obtains an optimal bidding (power and price) strategy for a multigrid (MG) system, i.e., a community MG. Consequently, the granted quantity, i.e., power in the electricity market, is deployed to optimally schedule the MG’s resources to meet demand. As such, as per three-level optimization, the independent system operator (ISO) clears the market with the goal of maximizing the social welfare in the first stage and determining the hourly market price as well as players’ credited power. In the second-level optimization process, the players select the optimal coefficient supply function equilibrium according to the power granted from the market. In third-level optimization, an optimal scheduling for MGs’ resources and demand would be obtained according to the won power in the market to maximize the aggregator profit. In addition, a price-taker MGA is simulated for comparison with the price–maker MGA to highlight the advantage of the proposed technique. Furthermore, a bidding strategy based on game theory is proposed to obtain the optimal price and power of the oligopoly market players and maximize all players’ profits. Finally, a test system including three generators is created to evaluate the performance of the devised bidding strategy. The results show that the proposed bidding strategy can optimally calculate the focal point of the Nash equilibrium (NE) in the oligopoly electricity market.

Published

2022

13. Control of LPV Modeled AC-Microgrid Based on Mixed H2/H∞ Time-Varying Linear State Feedback and Robust Predictive Algorithm

Author

Moslem Dehghani, Mohammad Ghiasi, Taher Niknam, Kumars Rouzbehi, Zhanle Wang, Pierluigi Siano, and Hassan Haes Alhelou

Subjects

Microgrid, linear parameter varying system, distributed generation unit, H₂/H∞ control, robust model predictive control, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a robust model predictive control (RMPC) method with a new mixed H2/ $\text{H}\infty $ linear time-varying state feedback design. In addition, we propose a linear parameter-varying model for inverters in a microgrid (MG), in which disturbances and uncertainty are considered, where the inverters connect in parallel to renewable energy sources (RES). The proposed RMPC can use the gain-scheduled control law and satisfy both the H2 and $\text{H}\infty $ proficiency requirements under various conditions, such as disturbance and load variation. A multistep control method is proposed to reduce the conservativeness caused by the unique feedback control law, enhance the control proficiency, and strengthen the RMPC feasible area. Furthermore, a practical and efficient RMPC is designed to reduce the online computational burden. The presented controller can implement load sharing among distributed generators (DGs) to stabilize the frequency and voltage of an entire smart island. The proposed strategy is implemented and studied in a MG with two DG types and various load types. Specifically, through converters, one type of DGs is used to control frequency and voltage, and the other type is used to control current. These two types of DGs operate in a parallel mode. Simulation results show that the proposed RMPCs are input-to-state practically stable (ISpS). Compared with other controllers in the literature, the proposed strategy can lead to minor total harmonic distortion (THD), lower steady-state error, and faster response to system disturbance and load variation.

Published

2022

14. A Software Defined Networking Architecture for DDoS-Attack in the Storage of Multimicrogrids

Author

Elaheh Taherian-Fard, Taher Niknam, Ramin Sahebi, Mahshid Javidsharifi, Abdollah Kavousi-Fard, and Jamshid Aghaei

Subjects

Multi-microgrid, software defined networking, cloud-fog computing, distributed denial of service attack (DDoS), optimization algorithm, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Multi-microgrid systems can improve the resiliency and reliability of the power system network. Secure communication for multi-microgrid operation is a crucial issue that needs to be investigated. This paper proposes a multi-controller software defined networking (SDN) architecture based on fog servers in multi-microgrids to improve the electricity grid security, monitoring and controlling. The proposed architecture defines the support vector machine (SVM) to detect the distributed denial of service (DDoS) attack in the storage of microgrids. The information of local SDN controllers on fog servers is managed and supervised by the master controller placed in the application plane properly. Based on the results of attack detection, the power scheduling problem is solved and send a command to change the status of tie and sectionalize switches. The optimization application on the cloud server implements the modified imperialist competitive algorithm (MICA) to solve this stochastic mixed-integer nonlinear problem. The effective performance of the proposed approach using an SDN-based architecture is evaluated through applying it on a multi-microgrid based on IEEE 33-bus radial distribution system with three microgrids in simulation results.

Published

2022

15. Golf Optimization Algorithm: A New Game-Based Metaheuristic Algorithm and Its Application to Energy Commitment Problem Considering Resilience

Author

Zeinab Montazeri, Taher Niknam, Jamshid Aghaei, Om Parkash Malik, Mohammad Dehghani, and Gaurav Dhiman

Subjects

energy, energy carriers, exploitation, exploration, game-based, golf, Technology

Abstract

In this research article, we uphold the principles of the No Free Lunch theorem and employ it as a driving force to introduce an innovative game-based metaheuristic technique named Golf Optimization Algorithm (GOA). The GOA is meticulously structured with two distinctive phases, namely, exploration and exploitation, drawing inspiration from the strategic dynamics and player conduct observed in the sport of golf. Through comprehensive assessments encompassing fifty-two objective functions and four real-world engineering applications, the efficacy of the GOA is rigorously examined. The results of the optimization process reveal GOA’s exceptional proficiency in both exploration and exploitation strategies, effectively striking a harmonious equilibrium between the two. Comparative analyses against ten competing algorithms demonstrate a clear and statistically significant superiority of the GOA across a spectrum of performance metrics. Furthermore, the successful application of the GOA to the intricate energy commitment problem, considering network resilience, underscores its prowess in addressing complex engineering challenges. For the convenience of the research community, we provide the MATLAB implementation codes for the proposed GOA methodology, ensuring accessibility and facilitating further exploration.

Published

2023

16. Multi‐objective operation of distributed generations and thermal blocks in microgrids based on energy management system

Author

Rohollah Homayoun, Bahman Bahmani‐Firouzi, and Taher Niknam

Subjects

Optimisation techniques, Power system management, operation and economics, Optimisation, Distributed power generation, Distribution or transmission of electric power, TK3001-3521, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Abstract The optimal multi‐objective operation of microgrids with distributed generations and thermal block based on the energy management system is presented. In the thermal block, the combined heat and power system and boiler and thermal storage system supply the load of the block thermal. Therefore, the proposed strategy minimises three objectives of an microgrid's operation, that is, cost, energy loss and voltage deviation functions. Also, it is subject to AC power flow equations, system operation limits and distributed generations and thermal block constraints. The problem is modelled as a multi‐objective optimisation method; then is converted to a single‐objective problem model using the ε‐constraint‐based Pareto optimisation. Moreover, the proposed strategy includes uncertainties of the load, energy price and active power of renewable distributed generations; hence, a stochastic programming based on the hybrid Mont Carlo simulation and point estimate method is used to model these uncertain parameters. Then, the teaching–learning‐based optimisation and firefly algorithm are utilised to solve the problem to achieve a reliable optimal solution. Finally, the proposed strategy is simulated on the IEEE 69‐bus microgrid, and thus, the capabilities of the proposed strategy are extracted.

Published

2021

17. Cyber-Attack Detection and Cyber-Security Enhancement in Smart DC-Microgrid Based on Blockchain Technology and Hilbert Huang Transform

Author

Mohammad Ghiasi, Moslem Dehghani, Taher Niknam, Abdollah Kavousi-Fard, Pierluigi Siano, and Hassan Haes Alhelou

Subjects

Smart DC-microgrid, Hilbert-Huang Transform, false data injection attack, data exchanging, blockchain, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Due to the simultaneous development of DC-microgrids (DC-MGs) and the use of intelligent control, monitoring and operation methods, as well as their structure, these networks can be threatened by various cyber-attacks. Overall, a typical smart DC-MG includes battery, supercapacitors and power electronic devices, fuel cell, solar Photovoltaic (PV) systems, and loads such as smart homes, plug-in hybrid electrical vehicle (PHEV), smart sensors and network communication like fiber cable or wireless to send and receive data. Given these issues, cyber-attack detection and securing data exchanged in smart DC-MGs like CPS has been considered by experts as a significant subject in recent years. In this study, in order to detect false data injection attacks (FDIAs) in a MG system, Hilbert-Huang transform methodology along with blockchain-based ledger technology is used for enhancing the security in the smart DC-MGs with analyzing the voltage and current signals in smart sensors and controllers by extracting the signal details. Results of simulation on the different cases are considered with the objective of verifying the efficacy of the proposed model. The results offer that the suggested model can provide a more precise and robust detection mechanism against FDIA and improve the security of data exchanging in a smart DC-MG.

Published

2021

18. Short-Term Scheduling of a Renewable-Based Microgrid: Stochastic/Economic Battery Modeling

Author

Motahareh Pourbehzadi, Taher Niknam, Jamshid Aghaei, Abdollah Kavousi-Fard, Ali Dehghan, Giti Javidi, and Ehsan Sheybani

Subjects

Battery management systems, optimization, scheduling, stochastic systems, uncertainty, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper endeavors a probabilistic framework to ascertain optimal operation of a microgrid with a special focus on challenges that storage systems bring about. The objective function optimizes the operation of renewable energy resources and startup/shutdown costs of nonrenewable energy resources along with the main grid and storage units’ costs as a mixed-integer nonlinear programming (MINLP) problem. The optimization problem is solved based on a modified bird mating optimization (MBMO) algorithm and a novel cumulative mutation process. In order to capture the high uncertainties associated with the market price, Photovoltaic, Wind Turbine output powers, and load demands, a reduced unscented transformation (RUT) method has been exploited. The RUT method can effectively model the correlation of variables using (m+2) sampling points. The framework presented in this paper has considered five case studies with multiple seasonal and property features. Implementing the proposed framework on a typical test microgrid and a real large-scale microgrid proves its effectiveness and accuracy through various operational conditions, changing the storage units’ structure and characteristics, RESs’ correlation modeling, and avoiding convergence to local minimums by adopting a newly mutated population. This extensive analysis provides options for MG operation by studying compound cases and providing solutions for every scenario. Promising results regarding the execution time, cost function and its SD values as well as head-to-head points for battery investment costs have been found.

Published

2021

19. Resiliency/Cost-Based Optimal Design of Distribution Network to Maintain Power System Stability Against Physical Attacks: A Practical Study Case

Author

Mohammad Ghiasi, Moslem Dehghani, Taher Niknam, Hamid Reza Baghaee, Sanjeevikumar Padmanaban, Gevork B. Gharehpetian, and Hamdulah Aliev

Subjects

Power distribution network, grey wolf optimization, high-impact low-probability event, optimal design, resilience, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Unexpected natural disasters or physical attacks can have various consequences, including extensive and prolonged blackouts on power systems. Energy systems should be resistant to unwanted events, and their performance is not easily affected by such conditions. The power system should also have sufficient flexibility to adapt to severe disturbances without losing its full version; it should restore itself immediately after resolving the disturbance. This critical feature of the behavior of infrastructure systems in power grids is called resilience. In this paper, the concepts related to resilience in the power system against severe disturbance are explained. The resilience and evaluation process components are introduced; then, an optimal design of resilient substations in the Noorabad city distribution grid against physical attack is presented. This research proposes an optimal solution for simultaneously allocating the feeder routing issue and substation facilities and finding the models of installed conductors and economic hardening of power lines due to unexpected physical attacks on vital urban operational infrastructure. The values of distribution networks are calculated using the grey wolf optimization (GWO) algorithm to solve the problem of designing an optimal distribution network scheme (ODNS) and optimal resilient distribution network scheme (ORDNS). Obtained results confirm the effectiveness of the proposed resiliency-cost-based optimization approach.

Published

2021

20. Cyber Attack Detection Based on Wavelet Singular Entropy in AC Smart Islands: False Data Injection Attack

Author

Moslem Dehghani, Mohammad Ghiasi, Taher Niknam, Abdollah Kavousi-Fard, Elham Tajik, Sanjeevikumar Padmanaban, and Hamdulah Aliev

Subjects

Cyber-attack detection, wavelet transform, wavelet singular entropy, smart-island, false data injection attack, AC state, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Since Smart-Islands (SIs) with advanced cyber-infrastructure are incredibly vulnerable to cyber-attacks, increasing attention needs to be applied to their cyber-security. False data injection attacks (FDIAs) by manipulating measurements may cause wrong state estimation (SE) solutions or interfere with the central control system performance. There is a possibility that conventional attack detection methods do not detect many cyber-attacks; hence, system operation can interfere. Research works are more focused on detecting cyber-attacks that target DC-SE; however, due to more widely uses of AC SIs, investigation on cyber-attack detection in AC systems is more crucial. In these regards, a new mechanism to detect injection of any false data in AC-SE based on signal processing technique is proposed in this paper. Malicious data injection in the state vectors may cause deviation of their temporal and spatial data correlations from their ordinary operation. The suggested detection method is based on analyzing temporally consecutive system states via wavelet singular entropy (WSE). In this method, to adjust singular value matrices and wavelet transforms' detailed coefficients, switching surface based on sliding mode controller are decomposed; then, by applying the stochastic process, expected entropy values are calculated. Indices are characterized based on the WSE in switching level of current and voltage for cyber-attack detection. The proposed detection method is applied to different case studies to detect cyber-attacks with various types of false data injection, such as amplitude, and vector deviation signals. The simulation results confirm the high-performance capability of the proposed FDIA detection method. This detection method's significant characteristic is its ability in fast detection (10 ms from the attack initiation); besides, this technique can achieve an accuracy rate of over 96.5%.

Published

2021

21. Automated Distribution Networks Reliability Optimization in the Presence of DG Units Considering Probability Customer Interruption: A Practical Case Study

Author

Hassan Karimi, Taher Niknam, Moslem Dehghani, Mohammad Ghiasi, Mina Ghasemigarpachi, Sanjeevikumar Padmanaban, Sajad Tabatabaee, and Hamdulah Aliev

Subjects

Automated distribution networks, genetic algorithm, sectionalizing switch placement, reliability, distributed generation, customer interruption cost model, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Automation in power distribution systems and supervisory control and data acquisition (SCADA), which perform network switching automatically and remotely, allows distribution companies to flexibly control distribution power grids. Cross-section switches also has a significant role in the automation in distribution systems, in that the operational optimization of these switches is able to enhance the supply power quality and reliability indicators, and can be a prosperous solution to increase the reliability, efficiency and overall service quality in services to customers. In this regard, in this work, the genetic optimization algorithm (GOA) approach which integrated the Steepest Descend Technique (SDT) is proposed and enhanced based on the features of the mentioned issue to sketch the optimal location and control of automatic and manual cross-section switches and protection relay systems in distribution power systems. The GOA is able to search globally that can prevent the result from locally convergence, also, GOA gives superior primary solutions for the SDT. Thus, the SDT can search locally with higher performance which increase the solutions’ accuracy. Therefore, an optimization formulation is proposed to improve the value-based reliability of the suggested layout considering the cost of customer downtime and the costs related to segmentation of switches and relay protection devices. Also, a distributed generation (DG) system in distribution networks is considered based on the islanded state of generation units. The effectiveness of the optimal suggested procedure is evaluated and represented via performing a practical test system in the distribution network of Ahvaz city in Iran. The results show that using proposed method and by optimally allocating switches maneuver, energy losses without switches are reduced from 310.17 (MWh) to 254.2 (MWh), and also by using DG, losses are reduced from 554.01 to 533.61 which confirms the ability and higher accuracy of the proposed method to improve reliability indices.

Published

2021

22. Robustness Improvement of Computationally Efficient Cooperative Fuzzy Model Predictive-Integral Sliding Mode Control of Nonlinear Systems

Author

Mohsen Farbood, Mohammad Veysi, Mokhtar Shasadeghi, Afshin Izadian, Taher Niknam, and Jamshid Aghaei

Subjects

T-S fuzzy models (TSFMs), model predictive control (MPC), integral sliding mode control (ISMC), DC-DC buck converter, flexible joint robot, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper introduces a systematic and comprehensive method to design a constrained fuzzy model predictive control (MPC) cooperated with integral sliding mode control (ISMC) based on the Takagi-Sugeno (T-S) fuzzy model for uncertain continuous-time nonlinear systems subject to external disturbances. The proposed controller benefits from the robustness, optimality, and practical constraints considerations. The robustness against the uncertainties and matched external disturbances is achieved by the proposed ISMC without iterative calculation for obtaining the robust invariant set. The MPC schemes are designed separately based on the both quadratic and non-quadratic Lyapunov functions. By the proposed MPC, the states of the system reach the desired values in the optimal, constrained, and robust manner against the unmatched external disturbances. New linear matrix inequalities (LMIs) conditions are proposed to design both the proposed MPC schemes. Also, the practical constraints on the control signals are guaranteed in the design procedure based on the invariant ellipsoid set. To evaluate the effectiveness of the suggested strategy, some simulation and experimental tests were run.

Published

2021

23. Reduction of Ripple Toothed Torque in the Internal Permanent Magnet Electric Motor by Creating Optimal Combination of Holes in the Rotor Surface Considering Harmonic Effects

Author

Alireza Ramezani, Mohammad Ghiasi, Moslem Dehghani, Taher Niknam, Pierluigi Siano, and Hassan Haes Alhelou

Subjects

Permanent magnet synchronous motor, sensitivity analysis, ripple toothed torque, harmonic effects, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Due to the widespread use of electric motors in various industries, it is very important to have optimally designed motors in that they have high efficiency and lower negative effects on the quality of the power grid. Therefore, in this paper, the effects of winding type (wide and concentrated) on ripple torque in internal permanent magnet motor (IPMM) are investigated. In order to reduce the ripple torque and to increase the average torque, by making optimal holes in the rotor surface and using the sensitivity analysis method, the structure of the IPMM is improved. In this method, the number, dimensions and location of holes are optimized using the sensitivity analysis approach, which reduces the ripple torque of the motor. Using a concentrated winding instead of a wide winding, the toothed ripple torque is reduced by approximately 75% while maintaining the average torque value. Also, by making holes in the rotor surface and optimizing them using the finite element technique and sensitivity analysis, it is demonstrated that the amount of ripple torque by 20%. In the proposed approach, it is proved that in the concentrated winding, in addition to reducing the spatial harmonics, the average amount of torque can also be improved. Obtained results of the simulation confirm the effectiveness of the proposed method.

Published

2020

24. False Data Injection Attack Detection based on Hilbert-Huang Transform in AC Smart Islands

Author

Moslem Dehghani, Mohammad Ghiasi, Taher Niknam, Abdollah Kavousi-Fard, and Sanjeevikumar Padmanaban

Subjects

False data injection attack, Hilbert-Huang transform, smart island, AC system, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In Smart Island (SI) systems, operators of power distribution system usually utilize actual-time measurement information as the Advanced Metering Infrastructure (AMI) to have an accurate, efficient, advanced control and monitor of whole their system. SI system can be vulnerable to complicated information integrity attacks such as False Data Injection Attack (FDIA) on some equipment including sensors and controllers, which can generate misleading operational decision in the system. Hence, lack of detailed research in the evaluation of power system that links the FDIAs with system stability is felt, and it will be important for both assessment of the effect of cyber-attack and taking preventive protection measures. In this regards, time-frequency-based differential approach is proposed for SI cyber-attack detection according to non-stationary signal assessment. In this paper, non-stationary signal processing approach of Hilbert-Huang Transform (HHT) is performed for the FDIA detection in several case studies. Since various critical case studies with a small FDIA in data where accurate and efficient detection can be a challenge, the simulation results confirm the efficiency of HHT approach and the proposed detection frame is compared with shallow model. In this research, the configuration of the SI test case is developed in the MATLAB software with several Distributed Generations (DGs). As a result, it is found that the HHT approach is completely efficient and reliable for FDIA detection target in AC-SI. The simulation results verify that the proposed model is able to achieve accuracy rate of 93.17% and can detect FDIAs less than 50 ms from cyber-attack starting in different kind of scenarios.

Published

2020

25. A TLBO-BASED ENERGY EFFICIENT BASE STATION SWITCH OFF AND USER SUBCARRIER ALLOCATION ALGORITHM FOR OFDMA CELLULAR NETWORKS

Author

Danial Davarpanah, Mohammad Reza Zamani, Mohsen Eslami, and Taher Niknam

Subjects

Energy Efficiency, Green Cellular Network, Base Station Switching, Optimization, TLBO Algorithm, Computer engineering. Computer hardware, TK7885-7895, Information technology, T58.5-58.64

Abstract

Downlink of a cellular network with orthogonal frequency-division multiple access (OFDMA) is considered. Joint base station switch OFF and user subcarrier-allocation with guaranteed user quality of service, is shown to be a promising approach for reducing network’s total power consumption. However, solving the aforementioned mix-integer and nonlinear optimization problem requires robust and powerful optimization techniques. In this paper, teaching-learning based optimization algorithm has been adopted to lower cellular network’s total power consumption. The results show that the proposed technique is able to reduce network’s total power consumption by determining a near optimum set of base stations to be switched OFF and near optimum subcarrier-user assignments. It is shown that the proposed scheme is superior to existing base station switch OFF schemes. Robustness of the proposed TLBO-based technique is verified.

Published

2018

26. OPTIMAL UTILIZATION OF ELECTRICAL ENERGY FROM POWER PLANTS BASED ON FINAL ENERGY CONSUMPTION USING GRAVITATIONAL SEARCH ALGORITHM

Author

Zeinab Montazeri and Taher Niknam

Subjects

gravitational search algorithm, energy, electrical energy, economic distribution, final energy consumption, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Purpose. Energy consumption is a standard measure to evaluate the progress and quality of life in a country. When used properly and logically it could be cause of progress in science, technology and welfare of the people in any country and otherwise irreparable economic losses and economic gross recession would happen. And finally, the quantity of energy consumption per GDP will increase day by day. Electrical energy, as the most prominent type of energy, is very important. In this article based on a different approach, according to the final consumption of electric energy, a proper economic planning in order to supply electrical energy is submitted. In this programming, the details of final energy consumption, will replace with the information of power network, by considering the network efficiency and power plants. Operation of power plants is based on the energy optimization entranced to a plant. By using the proposed method and gravitational search algorithm, the total cost of electrical energy can be minimized. The results of simulation and numerical studies show better convergence of gravitational search algorithm in comparison with other existing methods in this area.

Published

2018

27. Fourier Singular Values-Based False Data Injection Attack Detection in AC Smart-Grids

Author

Moslem Dehghani, Taher Niknam, Mohammad Ghiasi, Pierluigi Siano, Hassan Haes Alhelou, and Amer Al-Hinai

Subjects

cyber-physical system, cyber-attack detection, fast Fourier transform, singular value decomposition, smart island, false data injection attack, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Cyber-physical threats as false data injection attacks (FDIAs) in islanded smart microgrids (ISMGs) are typical accretion attacks, which need urgent consideration. In this regard, this paper proposes a novel cyber-attack detection model to detect FDIAs based on singular value decomposition (SVD) and fast Fourier transform (FFT). Since new research are mostly focusing on FDIAs detection in DC systems, paying attention to AC systems attack detection is also necessary; hence, AC state estimation (SE) have been used in SI analysis and in considering renewable energy sources effect. Whenever malicious data are added into the system state vectors, vectors’ temporal and spatial datum relations might drift from usual operating conditions. In this approach, switching surface based on sliding mode controllers is dialyzed to regulate detailed FFT’s coefficients to calculate singular values. Indexes are determined according to the composition of FFT and SVD in voltage/current switching surface to distinguish the potential cyber-attack. This protection layout is presented for cyber-attack detection and is studied in various types of FDIA forms like amplitude and vector derivation of signals, which exchanged between agents such as smart sensor, control units, smart loads, etc. The prominent advantage of the proposed detection layout is to reduce the time (less than 10 milliseconds from the attack outset) in several kinds of case studies. The proposed method can detect more than 96% accuracy from 2967 sample tests. The performances of the method are carried out on AC-ISMG in MATLAB/Simulink environment.

Published

2021

28. Optimal Multi-Operation Energy Management in Smart Microgrids in the Presence of RESs Based on Multi-Objective Improved DE Algorithm: Cost-Emission Based Optimization

Author

Mohammad Ghiasi, Taher Niknam, Moslem Dehghani, Pierluigi Siano, Hassan Haes Alhelou, and Amer Al-Hinai

Subjects

multi-operational energy management, IDE, RES, smart microgrid, optimization, cost effective, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Today, in various leading power utilities in developing countries, achieving optimal operational energy management and planning, taking into account the costs reduction of generation, transmission and distribution of electricity, and also reducing the emission of an environmental pollutant becomes more and more important. Optimal use of renewable energy sources (RESs) is an effective way to achieve these goals. In this regard, in this research article, an improved multi-objective differential evolutionary (IMODE) optimization algorithm is suggested and performed to dispatch electricity generations in a smart microgrid (MG) system, taking into account economy and emission as competitive issues. In this paper, a nonlinear equation of multi-objective optimization issue with various equality and inequality limitations is formulated in order to lower the total operational costs of the MG considering environmental pollution effects simultaneously. In order to address the issue of optimal operation of the MG in single-objective and multi-objective forms, an intelligent method according to the improved differential evolutionary (IDE) optimization is utilized and performed and the proposed algorithm is implemented on different problems. First, it is assumed that there is no limit to the exchange of power overhead, and secondly, the limitation of power exchange with the upstream grid is considered. In multi-objective mode, these two modes are also considered. In order to show the impact of renewable energy on the cost, in the third part of the simulations, the operation is solved with maximum participation of renewable energy sources. In the final section, the sensitivity analysis on the number of populations in this problem is performed. The obtained results of the simulation are compared to differential evolutionary (DE) and particle swarm optimization (PSO) techniques. The effectiveness of the suggested multi-operational energy management method is confirmed by applying a study case system.

Published

2021

29. Placement of Combined Heat, Power and Hydrogen Production Fuel Cell Power Plants in a Distribution Network

Author

Bahman Bahmanifirouzi, Taher Niknam, Mosayeb Bornapour, and Ebrahim Farjah

Subjects

Fuzzy Adaptive Modified Particle Swarm Optimization algorithm (FAMPSO), Fuel Cell Power Plant (FCPP), Combined Heat, Power and Hydrogen (CHPH), multi-objective optimization, Distributed Generation (DG), Technology

Abstract

This paper presents a new Fuzzy Adaptive Modified Particle Swarm Optimization algorithm (FAMPSO) for the placement of Fuel Cell Power Plants (FCPPs) in distribution systems. FCPPs, as Distributed Generation (DG) units, can be considered as Combined sources of Heat, Power, and Hydrogen (CHPH). CHPH operation of FCPPs can improve overall system efficiency, as well as produce hydrogen which can be stored for the future use of FCPPs or can be sold for profit. The objective functions investigated are minimizing the operating costs of electrical energy generation of distribution substations and FCPPs, minimizing the voltage deviation and minimizing the total emission. In this regard, this paper just considers the placement of CHPH FCPPs while investment cost of devices is not considered. Considering the fact that the objectives are different, non-commensurable and nonlinear, it is difficult to solve the problem using conventional approaches that may optimize a single objective. Moreover, the placement of FCPPs in distribution systems is a mixed integer problem. Therefore, this paper uses the FAMPSO algorithm to overcome these problems. For solving the proposed multi-objective problem, this paper utilizes the Pareto Optimality idea to obtain a set of solution in the multi-objective problem instead of only one. Also, a fuzzy system is used to tune parameters of FAMPSO algorithm such as inertia weight. The efficacy of the proposed approach is validated on a 69-bus distribution system.

Published

2012

30. Voltage Security Constrained Optimal Power Flow considering Smart Transmission Switching Maneuvers.

Author

Mohammad Zarghami, Morteza Sheikh, Jamshid Aghaei, Taher Niknam, Ramin Sadooghi, Navid Javidtash, Seyed Shahriari, Fei Wang 0020, and João P. S. Catalão

Published

2021

31. Big Data Compression in Smart Grids via Optimal Singular Value Decomposition.

Author

Seyed Naser Hashemipour, Jamshid Aghaei, Abdollah Kavousi-Fard, Taher Niknam, Ladan Salimi, Pedro Crespo Del Granado, Miadreza Shafie-khah, Fei Wang 0020, and João P. S. Catalão

Published

2020

32. IoT in Smart Grid: Energy Management Opportunities and Security Challenges.

Author

Motahareh Pourbehzadi, Taher Niknam, Abdollah Kavousi-Fard, and Yasin Yilmaz

Published

2019

33. Uncertainty Modeling for Participation of Electric Vehicles in Collaborative Energy Consumption

Author

Naser Hashemipour, Jamshid Aghaei, Pedro Crespo Del Granado, Abdollah Kavousi-Fard, Taher Niknam, Miadreza Shafie-khah, and Joao P. S. Catalao

Subjects

Computer Networks and Communications, Automotive Engineering, Aerospace Engineering, Electrical and Electronic Engineering

Published

2022

34. Synergies Between Transportation Systems, Energy Hub and the Grid in Smart Cities

Author

Mahmoud Roustaei, Morteza Sheikh, Miadreza Shafie-khah, Taher Niknam, Hossein Chabok, Jamshid Aghaei, Abdollah Kavousi-Fard, and Joao P. S. Catalao

Subjects

050210 logistics & transportation, Network architecture, business.industry, Computer science, Mechanical Engineering, 05 social sciences, Hash function, Encryption, Computer security, computer.software_genre, Directed acyclic graph, Grid, Computer Science Applications, Electric power system, Smart city, 0502 economics and business, Automotive Engineering, business, computer, Database transaction

Abstract

The concept of smart cities has emerged as an ongoing research in recent years. In this case, there is a proven association between the smart cities and the smart devices, which have caused the power systems to become more flexible, controllable and detectable. Along with these promising results, many disputes have been generated over the cyber-attacks as unpredictable destructive threats, if not properly repelled, which could seriously endanger the power system. With this in mind, this paper explores a novel stochastic virtual assignment (SVA) method based on a directed acyclic graph (DAG) approach, where the essential data of the system sections are broadcasted decentralized through the data blocks, as a worthwhile step to deal with the cyber attacks' risk. To do so, an additional security layer is added to the data blocks aiming to enhance the security of the data against the long lasting data sampling by virtually assigning the hash addresses (HAs) to the data blocks, which are randomly changed based on a stochastic process. The basic network architecture is based on a Provchain structure as a new framework to constantly monitor data operation. Two pivotal strategies also represented to deal with the energy and time needed for the HAs generation process, which have improved the proposed method. In this paper, the proposed security framework is implemented in a smart city environment to provide a secure energy transaction platform. Results show the authenticity of this model and demonstrate the effectiveness of the SVA method in decreasing the successful probability of cyber threat, increasing the time needed for the cyber attacker to decrypt and manipulate the data block.

Published

2022

35. An Effective Non-Square Matrix Converter Based Approach for Active Power Control of Multiple DGs in Microgrids: Experimental Implementation

Author

Alireza chabok, Taher Niknam, Jamshid Aghaei, Mohammad Askarpour, Mahmoud Roustaei, Ramin Sadooghi, and Morteza Sheikh

Subjects

Computer science, Control theory, Active power control, Energy Engineering and Power Technology, Electrical and Electronic Engineering, Square matrix

Published

2022

36. Fuzzy Lyapunov-Based Model Predictive Sliding-Mode Control of Nonlinear Systems: An Ellipsoid Recursive Feasibility Approach

Author

Mokhtar Shasadeghi, Mohsen Farbood, Taher Niknam, and Behrouz Safarinejadian

Subjects

Lyapunov function, Computer science, Applied Mathematics, Linear matrix inequality, Sliding mode control, Fuzzy logic, Integral sliding mode, symbols.namesake, Model predictive control, Computational Theory and Mathematics, Exponential stability, Artificial Intelligence, Control and Systems Engineering, Control theory, Robustness (computer science), symbols

Abstract

This paper introduces the design of an artificial fuzzy Lyapunov-based model predictive integral sliding mode control (MPISMC) to achieve the stability of the closed-loop Takagi-Sugeno (T-S) fuzzy model-based nonlinear systems. First, to reach proper performance against the model uncertainties, a fuzzy integral sliding mode controller (FISMC) is designed. Then, the fuzzy model predictive control is developed based on a fuzzy Lyapunov function (FLF) by considering a contractive constraint and an ellipsoidal terminal constraint. A systematic method is developed to reach the recursive feasibility of the model predictive control (MPC) optimization problem based on an ellipsoidal terminal set. Also, a contractive fuzzy Lyapunov condition is imposed on the fuzzy model predictive control problem to guarantee the stability of closed-loop systems which is led to a linear matrix inequality (LMI)-based generalized eigenvalue minimization problem. In the proposed approach, FISMC greatly improves the robustness property of the fuzzy Lyapunov-based model predictive control (FLMPC) and asymptotic stability of the closed-loop system is achieved in comparison with tube-based MPC. In addition, the proposed robust MPC has less computational burden and improves the equilibrium point attractivity compared with the max-min MPC and the equality terminal constraint-based MPC. To illustrate the superiority of the proposed strategy, the suggested robust MPC is applied to a truck-trailer system and a numerical example. The simulation results show the capabilities of the proposed robust MPC.

Published

2022

37. Towards a Coefficient Secure IoT Energy Framework within the Smart City: Advanced Encryption Standard

Author

Maryam Shahmanesh, Razieh Malekhosseini, Taher Niknam, Karamollah BagheriFard, and S.Hadi Yaghoubyan

Abstract

The concept of a smart city is intertwined with a kind of great data management, and through which, reaching optimal management. The data transaction and the issue of communication between different equipment are all defined on the IoT platform. The concept of IoT is a general keyword referring to the widespread communication between equipment. Nevertheless, the idea that metropolitan management can be implemented with the targeted data processing faces challenges. On the other hand, multicarrier energy management, in which various types of energy generating structures like microgrids, smart grid, energy hub systems, transportation sector, etc. converge together in an optimal energy management program, is of great difficulty. Considering these challenges, the processes of encryption, dispatching data, decryption with the algorithm of the energy management plan should be intertwined and all solved together as a general problem. The current paper has presented a modified IoT architecture along with a multi-carrier energy management application through integrating two distributed and integrated management approaches. In the presented model, each energy-generating agent in the first layer initially controls its own internal supply and demand rate implementing distributed management, and then in the second layer, each agent participates in a macro-competitive market to achieve the optimal work point. Thus, in the presented model, the data blockchain building protocol based on The Advanced Encryption Standard (AES) in IOT platform is synchronized with the cloud-computing center and an integrated energy and data security management program is run, having the nature of the competitive market according to the block building time by each agent. According to the results, in this approach, while achieving the desired answer, the volume of data transaction and consequently, the time to gain the final consensus may be considerably reduced.

Published

2023

38. New optimal planning strategy for plug‐in electric vehicles charging stations in a coupled power and transportation network

Author

Sobhan Farjam Keleshteri, Taher Niknam, Mohammad Ghiasi, and Hossein Chabok

Subjects

General Engineering, Energy Engineering and Power Technology, Software

Published

2023

39. Constrained Robust Control by a Novel Dynamic Sliding Mode Surface

Author

Kazem Zare, Mokhtar Shasadeghi, Taher Niknam, Mohammad Hassan Asemani, and Saleh Mobayen

Subjects

Control and Systems Engineering, Computer Science Applications

Published

2022

40. Cyber-Physical Security in Smart Power Systems from a Resilience Perspective: Concepts and Possible Solutions

Author

Mohammad Ghiasi, Zhanle Wang, Taher Niknam, Moslem Dehghani, and Hamid Reza Ansari

Published

2023

41. Multipurpose FCS Model Predictive Control of VSC-Based Microgrids for Islanded and Grid-Connected Operation Modes

Author

Mohammad Ghiasi, Taher Niknam, Moslem Dehghani, Hamid Reza Baghaee, Zhanle Wang, Mohammad Mehdi Ghanbarian, Frede Blaabjerg, and Tomislav Dragicevic

Subjects

Control systems, Load modeling, Computer Networks and Communications, Inverters, Power system stability, Power conversion, Computer Science Applications, Control and Systems Engineering, Voltage control, SDG 7 - Affordable and Clean Energy, Electrical and Electronic Engineering, Switches, Information Systems

Abstract

This article presents an enhanced control strategy for renewable energy resources connected to the grid through voltage-sourced converters (VSCs) in microgrids. The proposed scheme contains a voltage control loop with the minimum inverter switching, a power-sharing controller with the minimum inverter switching, a negative-sequence current controller, and a loop to identify the control system operation mode. All the controllers are designed using the multipurpose finite control set-model predictive control (FCS-MPC) strategy. Since these controllers use the dynamic current and VSC voltage, they can be applied in grid-connected and island operation modes and transferred between them. The method uses voltage–frequency control instead of power control for VSCs. One inverter controls voltage, and the other controls current. The conventional FCS-MPC is enhanced to reduce the computation power by eightfold. This improvement is significant because the maximum switching frequency is limited in practical implementations. Also, the superiority of the proposed multipurpose control scheme is proved theoretically. Simulation is implemented using MATLAB software and compared with methods in the literature. The simulation demonstrates that the presented control strategy is efficient, authentic, and compatible. The proposed method is also tested and validated in hardware experiments.

Published

2023

42. Coordinated energy management strategy in scheme of flexible grid-connected hubs participating in energy and reserve markets

Author

Mohsen Kazemi, Bahman Bahmani-Firouzi, Mehdi Nafar, and Taher Niknam

Subjects

Statistics and Probability, Scheme (programming language), Computer science, Energy management, 020209 energy, Distributed computing, 020208 electrical & electronic engineering, General Engineering, 02 engineering and technology, Grid, Artificial Intelligence, 0202 electrical engineering, electronic engineering, information engineering, computer, Energy (signal processing), computer.programming_language

Abstract

This paper uses the coordinated energy management strategy for different sources and storages in the framework of flexible grid-connected energy hubs that participate in the day-ahead (DA) energy and reserve markets. In the base problem, this method maximizes the difference between the expected revenue of hubs gained by selling energy and reserve power in the proposed markets and the expected cost of lost flexibility (COLF). Also, it is subject to linearized optimal power flow (LOPF) equations in the electricity, gas and district heating systems, as well as hub constraints including different sources, storages and reserve models. This problem contains uncertainties of load, market price, reserve requirement, renewable power and hub mobile storages parameters. Therefore, the hybrid stochastic/robust optimization (HSRO) is suitable to model these uncertain parameters and obtain robust capability for the hub to improve the system flexibility. Accordingly, the bounded uncertainty-based robust optimization (BURO) is used in this paper to model the uncertainty of hub mobile storages to achieve the hub robust potential in improving the system flexibility, and other uncertain parameters are modeled according to scenario-based stochastic programming (SBSP). Finally, the proposed strategy is implemented on a standard test system. The obtained numerical results confirm the capability of the suggested scheme in improving the economic status of sources and storages using the coordinated energy management strategy in the form of an energy hub, as well as enhancing economic conditions, operation, and flexibility of energy networks thanks to hubs for having access to optimal scheduling.

Published

2021

43. A Novel Sliding Mode Based UPQC Controller for Power Quality Improvement in Micro-Grids

Author

Taher Niknam, Mohammad Heidari, and Mehdi Nafar

Subjects

Reduction (complexity), Control theory, Computer science, Harmonics, Voltage sag, Inverter, State observer, Electrical and Electronic Engineering, AC power, Sliding mode control

Abstract

This paper presents a novel State Observer Based Sliding Mode controller for UPQC inverters to enhance the power quality in microgrids. In the proposed control scheme, Enhanced extended state observer was applied on a standard sliding mode controller to boost its disturbance rejection capability. The controller was designed to be robust against parameteric and external uncertainties. Further, affordable UPQC-grid integration scheme suggested where the photovoltaeek system could be connected to the network via UPQC inverters. Using the suggested configuration the active and reactive power injection capability was added to UPQC along with its commonly known advantages. Extensive MATLAB Simulink-based theoretical and experimental studies were conducted in different scenarios to verify the efficiency of the proposed method in improving the power quality indices. Using UPQC with the proposed control scheme shows the better performance than the current traditional UPQC controllers in voltage sag reduction and Harmonics minimization. The main feature of the proposed controller included its accuracy and fast tracking response.

Published

2021

44. Bi-level fuzzy stochastic-robust model for flexibility valorizing of renewable networked microgrids

Author

Mohammadali Norouzi, Jamshid Aghaei, Taher Niknam, Sasan Pirouzi, Matti Lehtonen, Shiraz University of Technology, Islamic Azad University, Department of Electrical Engineering and Automation, Aalto-yliopisto, and Aalto University

Subjects

Flexibility valorizing, Renewable Energy, Sustainability and the Environment, Control and Systems Engineering, Energy Engineering and Power Technology, Fuzzy decision-making, Electrical and Electronic Engineering, Hybrid stochastic-robust programming, Microgrid flexibility, Renewable networked microgrids

Abstract

Publisher Copyright: © 2022 The Author(s) This paper presents a new bi-level multi-objective model to valorize the microgrid (MG) flexibility based on flexible power management system. It considers the presence of renewable and flexibility resources including demand response program (DRP), energy storage system and integrated unit of electric spring with electric vehicles (EVs) parking (IUEE). The proposed bi-level model in the upper-level maximizes expected flexibility resources profit subject to flexibility constraints. Also, in the lower level, minimizing MG energy cost and voltage deviation function based on the Pareto optimization technique is considered as the objective functions; it is bounded by the linearized AC optimal power flow constraints, renewable and flexibility resources limits, and the MG flexibility restrictions. In the following, the proposed bi-level model using Karush–Kuhn–Tucker (KKT) technique is converted to a single-level counterpart, and the fuzzy decision-making method is employed to achieve the best compromise solution. Further, hybrid stochastic-robust programming models uncertain parameters of the proposed model, so that stochastic programming models uncertainties associated with demand, energy price, and the maximum renewables active generation. Also, to capture the flexible potential capabilities of the IUEE, robust optimization models the EVs’ parameters uncertainty. Finally, numerical results confirm the proposed model could jointly improve operation, economic and flexibility conditions of the MG and turned it to a flexi-optimized-renewable MG.

Published

2022

45. Multi‐objective operation of distributed generations and thermal blocks in microgrids based on energy management system

Author

Bahman Bahmani-Firouzi, Taher Niknam, and Rohollah Homayoun

Subjects

Energy management system, TK1001-1841, Production of electric energy or power. Powerplants. Central stations, Distribution or transmission of electric power, Control and Systems Engineering, Computer science, Thermal, Energy Engineering and Power Technology, TK3001-3521, Electrical and Electronic Engineering, Reliability engineering

Abstract

The optimal multi‐objective operation of microgrids with distributed generations and thermal block based on the energy management system is presented. In the thermal block, the combined heat and power system and boiler and thermal storage system supply the load of the block thermal. Therefore, the proposed strategy minimises three objectives of an microgrid's operation, that is, cost, energy loss and voltage deviation functions. Also, it is subject to AC power flow equations, system operation limits and distributed generations and thermal block constraints. The problem is modelled as a multi‐objective optimisation method; then is converted to a single‐objective problem model using the ε‐constraint‐based Pareto optimisation. Moreover, the proposed strategy includes uncertainties of the load, energy price and active power of renewable distributed generations; hence, a stochastic programming based on the hybrid Mont Carlo simulation and point estimate method is used to model these uncertain parameters. Then, the teaching–learning‐based optimisation and firefly algorithm are utilised to solve the problem to achieve a reliable optimal solution. Finally, the proposed strategy is simulated on the IEEE 69‐bus microgrid, and thus, the capabilities of the proposed strategy are extracted.

Published

2021

46. Fuzzy modeling and control of a class of non‐differentiable multi‐input multi‐output nonlinear systems

Author

Taher Niknam, Mokhtar Shasadeghi, Kazem Zare, Mohammad Hassan Asemani, and Afshin Izadian

Subjects

Nonlinear system, Control and Systems Engineering, Control theory, Computer science, Multi input, Multi output, Differentiable function, Control (linguistics), Sliding mode control, Class (biology), Fuzzy logic

Published

2021

47. Extended Kalman Filter-Based Approach for Nodal Pricing in Active Distribution Networks

Author

Sajjad Sharifinia, Mohsen Tajdinian, Mehdi Allahbakhshi, Taher Niknam, Joao P. S. Catalao, Mohammad Mehdi Arefi, and Miadreza Shafie-khah

Subjects

State variable, Mathematical optimization, 021103 operations research, Computer Networks and Communications, business.industry, Computer science, 0211 other engineering and technologies, 02 engineering and technology, Kalman filter, AC power, Computer Science Applications, Power (physics), Reduction (complexity), Extended Kalman filter, Control and Systems Engineering, Distributed generation, Range (statistics), Electrical and Electronic Engineering, business, Information Systems

Abstract

This article presents an analytical approach based on Extended Kalman Filter (EKF) for nodal pricing in distribution networks containing private distributed generation (DG). An appropriate nodal pricing policy can direct active distribution network (ADN) to optimal operation mode with minimum loss. However, there are several crucial challenges in nodal pricing model such as: equitable loss allocation between DGs, obtain minimum merchandising surplus (MS), and equitable distribution of remuneration between DGs, which is difficult to achieve these goals simultaneously. However, in the proposed method, the issue was embedded in the form of the EKF updates. The measurement update reduces the MS, and in the time update, DG's nodal prices as state variables are modified based on their contribution to the loss reduction. Therefore, all aspects of the problem are considered and modeled simultaneously, which will prepare a realistic state estimation tool for distribution companies in the next step of operation. The proposed method also has the ability to determine the nodal prices for distribution network buses in a wide range of power supply point prices (PSP), which other methods have been failed, especially at very low or high PSP prices. Eventually, using the new method will move system towards to the minimum possible losses with the equitable condition. The application of the proposed nodal pricing method is illustrated on 17-bus radial distribution test systems, and the results are compared with other methods.

Published

2021

48. Electrical and thermal power management in an energy hub system considering hybrid renewables

Author

B. Bahmani Firouzi, J. Ebrahimi, and Taher Niknam

Subjects

Consumption (economics), business.industry, 020209 energy, Applied Mathematics, 020208 electrical & electronic engineering, Thermal power station, 02 engineering and technology, Solver, Automotive engineering, Power (physics), Renewable energy, Demand response, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Electricity, Electrical and Electronic Engineering, business, Physics::Atmospheric and Oceanic Physics, Thermal energy

Abstract

This paper proposes a multi-carrier energy system or energy hub in which natural gas and electricity resources are used as inputs. The output demand profile includes electrical, heating and cooling energy, which is evaluated in four seasons. The significant differences in simulations and evaluation of the considered energy hub in different seasons have led to climate variation, resulting in higher electrical energy consumption in warmer seasons than thermal energy, while it is contrariwise in the cold season. When the customers are willing to participate in the demand response programs, total energy consumption decreases, and this can only change the pattern of customer consumption in the warmer seasons. A mixed-integer linear programing (MILP) formulation for this optimization problem is proposed and solved using the CPLEX solver in general algebraic modeling system (GAMS). Simulations of the energy hub system, including renewable wind and solar sources, will confirm and verify that the model provided represents a growth in energy hub profit, reducing the cost of purchased power from electricity grid as well as decreasing cost of social welfare.

Published

2021

49. Automated Distribution Networks Reliability Optimization in the Presence of DG Units Considering Probability Customer Interruption: A Practical Case Study

Author

Mohammad Ghiasi, Sanjeevikumar Padmanaban, Hassan Karimi, Sajad Tabatabaee, Hamdulah Aliev, Moslem Dehghani, Mina GhasemiGarpachi, and Taher Niknam

Subjects

Service quality, Downtime, reliability, distributed generation, business.product_category, General Computer Science, business.industry, Computer science, Reliability (computer networking), customer interruption cost model, General Engineering, sectionalizing switch placement, Automation, Automated distribution networks, TK1-9971, Reliability engineering, Electric power system, SCADA, Distributed generation, genetic algorithm, General Materials Science, Network switch, Electrical engineering. Electronics. Nuclear engineering, business

Abstract

Automation in power distribution systems and supervisory control and data acquisition (SCADA), which perform network switching automatically and remotely, allows distribution companies to flexibly control distribution power grids. Cross-section switches also has a significant role in the automation in distribution systems, in that the operational optimization of these switches is able to enhance the supply power quality and reliability indicators, and can be a prosperous solution to increase the reliability, efficiency and overall service quality in services to customers. In this regard, in this work, the genetic optimization algorithm (GOA) approach which integrated the Steepest Descend Technique (SDT) is proposed and enhanced based on the features of the mentioned issue to sketch the optimal location and control of automatic and manual cross-section switches and protection relay systems in distribution power systems. The GOA is able to search globally that can prevent the result from locally convergence, also, GOA gives superior primary solutions for the SDT. Thus, the SDT can search locally with higher performance which increase the solutions' accuracy. Therefore, an optimization formulation is proposed to improve the value-based reliability of the suggested layout considering the cost of customer downtime and the costs related to segmentation of switches and relay protection devices. Also, a distributed generation (DG) system in distribution networks is considered based on the islanded state of generation units. The effectiveness of the optimal suggested procedure is evaluated and represented via performing a practical test system in the distribution network of Ahvaz city in Iran. The results show that using proposed method and by optimally allocating switches maneuver, energy losses without switches are reduced from 310.17 (MWh) to 254.2 (MWh), and also by using DG, losses are reduced from 554.01 to 533.61 which confirms the ability and higher accuracy of the proposed method to improve reliability indices.

Published

2021

50. Short-Term Scheduling of a Renewable-Based Microgrid: Stochastic/Economic Battery Modeling

Author

Abdollah Kavousi-Fard, Ehsan Sheybani, Jamshid Aghaei, Giti Javidi, Ali Dehghan, Motahareh Pourbehzadi, and Taher Niknam

Subjects

education.field_of_study, Mathematical optimization, Optimization problem, General Computer Science, business.industry, stochastic systems, Photovoltaic system, Population, General Engineering, Scheduling (production processes), Battery management systems, Grid, TK1-9971, Renewable energy, Nonlinear programming, General Materials Science, scheduling, Electrical engineering. Electronics. Nuclear engineering, Microgrid, uncertainty, business, education, optimization

Abstract

This paper endeavors a probabilistic framework to ascertain optimal operation of a microgrid with a special focus on challenges that storage systems bring about. The objective function optimizes the operation of renewable energy resources and startup/shutdown costs of nonrenewable energy resources along with the main grid and storage units’ costs as a mixed-integer nonlinear programming (MINLP) problem. The optimization problem is solved based on a modified bird mating optimization (MBMO) algorithm and a novel cumulative mutation process. In order to capture the high uncertainties associated with the market price, Photovoltaic, Wind Turbine output powers, and load demands, a reduced unscented transformation (RUT) method has been exploited. The RUT method can effectively model the correlation of variables using (m+2) sampling points. The framework presented in this paper has considered five case studies with multiple seasonal and property features. Implementing the proposed framework on a typical test microgrid and a real large-scale microgrid proves its effectiveness and accuracy through various operational conditions, changing the storage units’ structure and characteristics, RESs’ correlation modeling, and avoiding convergence to local minimums by adopting a newly mutated population. This extensive analysis provides options for MG operation by studying compound cases and providing solutions for every scenario. Promising results regarding the execution time, cost function and its SD values as well as head-to-head points for battery investment costs have been found.

Published

2021