Robust Control of Frequency Variations for a Multi-Area Power System in Smart Grid Using a Newly Wild Horse Optimized Combination of PIDD2 and PD Controllers

Khudhair, Mohammed; Ragab, Muhammad; AboRas, Kareem M.; Abbasy, Nabil H.

doi:10.3390/su14138223

Cited by 19 publications

(17 citation statements)

References 43 publications

(78 reference statements)

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“…Encouraged by their success, the authors continued along this path, proposing the PD-PIDA controller, which has better performance in the LFC problem [36] in order to improve STATCOM's ability to keep the frequency within acceptable ranges. The Artificial Rabbits Optimization (ARO) method, which is a novel bio-inspired meta-heuristic approach, is used to fine-tune the suggested PD-PIDA parameters.…”

Section: B Motivation and Contributionsmentioning

confidence: 99%

“…The purpose of the control strategy is to boost the performance of frequency for the linked generators of the kundur system. The PD-PIDA regulator that has been developed has nine parameters that have to be their values optimized, and the transfer function of this regulator may be described as follows [36]:…”

Section: Problem Formulation and The Proposed Controller Strategymentioning

confidence: 99%

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Improvement of Frequency Regulation of a Wind-Integrated Power System Based on a PD-PIDA Controlled STATCOM Tuned by the Artificial Rabbits Optimizer

Neamah,

AbuHussein,

Hossam-Eldin

et al. 2023

IEEE Access

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In this research, a novel optimized Proportional-Derivative with Proportional-Integral-Derivative-Acceleration (PD-PIDA) driven static synchronous compensator (STATCOM) is proposed with the goal of improving the frequency performance of power systems through the manipulation of reactive power. When there is a variation in load or when there is a failure of generation, the presented controller is able to maintain the frequency of the system within the allowable limits (±2% as per IEC 60034-1 standard). A recently developed metaheuristic optimization strategy known as the Artificial Rabbits Optimizer, or ARO, is used to do the fine-tuning the PD-PIDA controller's gain settings. In addition to this, the functionality of the ARO-based PD-PIDA-controlled STATCOM is evaluated in the context of two IEEE standard systems: the two-area four-machine system (Kundur system) and the New England IEEE 39-bus system. According to the outcomes, the ARO-based PD-PIDA controller can give a superior frequency response than the PIDA controller whose parameters are optimized by Marine Predator Algorithm (MPA) that was published in the prior literature. This was determined by comparing the two controllers. In addition, the proposed controller's resiliency is tested by integrating case studies with wind generation. This helps to ensure that the controller is fit for purpose. In every single one of the examples that were researched, the application of the ARO-based PD-PIDA-controlled STATCOM resulted in a remarkable boost in the frequency performance. Additionally, the outputs are introduced in the form of time domain simulations that were carried out with MATLAB/SIMULINK.

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Section: B Motivation and Contributionsmentioning

confidence: 99%

Section: Problem Formulation and The Proposed Controller Strategymentioning

confidence: 99%

Improvement of Frequency Regulation of a Wind-Integrated Power System Based on a PD-PIDA Controlled STATCOM Tuned by the Artificial Rabbits Optimizer

Neamah,

AbuHussein,

Hossam-Eldin

et al. 2023

IEEE Access

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“…several structures of power systems are considered with LFC, such as single area, multiple interconnected areas, nonlinear power system considerations, deregulated power grids, etc. [7]. In which, several control schemes from traditional to advanced ones have been proposed for LFC in the literature [8].…”

Section: A Literature Reviewmentioning

confidence: 99%

“…In which, several control schemes from traditional to advanced ones have been proposed for LFC in the literature [8]. The widely-presented LFC schemes are integer order (IO) controls [7], fractional order (FO) controls [2], model predictive controls (MPCs) [9], artificial intelligence (AI) controls [10], fuzzy logic (FL) controls [11], deep learning controls [3], etc. Several papers have been introduced for reviewing, comparing, and investigating the performance of various LFC schemes [12], [13].…”

Section: A Literature Reviewmentioning

confidence: 99%

“…However, tuning processes based on trial-and-error methods require long time for the parameters adjustments. Therefore, great efforts are made by researchers for properly adjusting the control parameters of IO based PI and PID control methods [7]. Among various widely-employed design methodologies for LFC applications, optimization algorithms based tuning schemes have shown improved performance and easier tuning processes [17].…”

Section: A Literature Reviewmentioning

confidence: 99%

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Enhancement the Frequency Stability and Protection of Interconnected Microgrid Systems Using Advanced Hybrid Fractional Order Controller

Mohamed

Aly²,

Elmelegi

et al. 2022

IEEE Access

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Substituting conventional energy sources with new renewable sources is crucial issue nowadays in energy generation systems to face climate changes and increased load demands. Due to the increased penetration levels of renewable sources in power systems, the benefits of the high-inertia of conventional sources are being insufficient. The resulting low-inertia power systems introduce several stability, reliability, and coordination problems for power system operation and control. Therefore, this paper tackles the coordination assessment and enhancement between digital frequency relays using a new fractional order load frequency controller equipped with superconducting magnetic energy storage (SMES) virtual inertia system. The improved coordination method is established using optimized fractional order controller based on slime mould optimization algorithm (SMA). The proposed SMA-based design method benefits the adaptive weights of SMA algorithm. The proposed design is generalized to be applied on single area and multi-area interconnected power systems as well. Compared to existing literature, this paper presents an advanced fractional order controller with coordinated operation with existing protection relays. The obtained results show the coordination shortcomings of renewable energy based microgrids with traditional control systems. However, improved design and coordination are obtained using the proposed SMA-optimized fractional order controllers. The superiority and feasibility of the proposed analysis and methods are verified on different case studies using single and multiple interconnected areas.INDEX TERMS Coordination, digital frequency relay, fraction order control, load frequency controllers, slime mould algorithm (SMA), renewable energy microgrids.

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Voltage and frequency regulation in smart grids via a unique Fuzzy PIDD2 controller optimized by Gradient-Based Optimization algorithm

et al. 2023

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Robust Control of Frequency Variations for a Multi-Area Power System in Smart Grid Using a Newly Wild Horse Optimized Combination of PIDD2 and PD Controllers

Cited by 19 publications

References 43 publications

Improvement of Frequency Regulation of a Wind-Integrated Power System Based on a PD-PIDA Controlled STATCOM Tuned by the Artificial Rabbits Optimizer

Improvement of Frequency Regulation of a Wind-Integrated Power System Based on a PD-PIDA Controlled STATCOM Tuned by the Artificial Rabbits Optimizer

Enhancement the Frequency Stability and Protection of Interconnected Microgrid Systems Using Advanced Hybrid Fractional Order Controller

Voltage and frequency regulation in smart grids via a unique Fuzzy PIDD2 controller optimized by Gradient-Based Optimization algorithm

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