2023
DOI: 10.3390/fractalfract7080603
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Design Optimization of Improved Fractional-Order Cascaded Frequency Controllers for Electric Vehicles and Electrical Power Grids Utilizing Renewable Energy Sources

Abstract: Recent developments in electrical power grids have witnessed high utilization levels of renewable energy sources (RESs) and increased trends that benefit the batteries of electric vehicles (EVs). However, modern electrical power grids cause increased concerns due to their continuously reduced inertia resulting from RES characteristics. Therefore, this paper proposes an improved fractional-order frequency controller with a design optimization methodology. The proposed controller is represented by two cascaded c… Show more

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Cited by 9 publications
(4 citation statements)
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“…Furthermore, the control of an automatic voltage regulator using FOPID was achieved in [33,34]. Also, improved frequency controllers based on the FOPID strategy regulated the frequency of inter-connected power grids [35]. Moreover, a modified version of FOPID was used to regulate a hybrid inter-connected system formed of various renewable resources [36].…”
Section: Objectives and Contributionsmentioning
confidence: 99%
“…Furthermore, the control of an automatic voltage regulator using FOPID was achieved in [33,34]. Also, improved frequency controllers based on the FOPID strategy regulated the frequency of inter-connected power grids [35]. Moreover, a modified version of FOPID was used to regulate a hybrid inter-connected system formed of various renewable resources [36].…”
Section: Objectives and Contributionsmentioning
confidence: 99%
“…This approach introduces more adaptable weighting functions with a variety of adjustable parameters for mixed sensitivity problems, thereby offering increased flexibility [15]. Fractional-order Laplace operators are a term of fractional calculus which has gained substantial popularity within the control community [16][17][18][19][20][21]. In this context, this operator has been used in H ∞ controllers, either in design step or in controller structure.…”
Section: Introduction 1the Contex Of Researchmentioning
confidence: 99%
“…A cascaded FOPI-IDDF LFC scheme optimized with the crow search algorithm (CSA) has been presented in [47] with solarthermal generation-based grids. Another cascased 1+PD/FOPID LFC method has been proposed in [48] for EV-based power grids, whereas the MRFO has been applied for optimizing the various parameters of the presented controller. The 3DOF cascaded LFC using FOTPID-TIDF control has been presented in [49].…”
mentioning
confidence: 99%
“…The paper is concluded in Section 6. I JBO [25] PID - [28] PI, PID ARO [26] Nonlinear PI DO [27] I, PI PSO [30] Fuzzy PIDD2 GBO [40] iFOI GWO [35] FOPID SCA Have more parameters to tune [36] FOPID MDWA FO-based Possess higher flexibility compared to IO ones [37] FOPIDF ICA LFC with Have improved disturbance mitigation compared to IO [38] TFOID AEO single input Have reduced rejection of existing disturbances [50] TID MRFO [39] FOPIDA GWO [41] TFOID SMA [42] TFOID CMRFO, WCM-RFO [43] TFOID with PI SMA [31] PD-PI ESMOA Possess high number of parameters to tune [32] 2DOF PID TLBO Cascaded LFC Have more flexibilities (degree of freedom) in design [33] PD-PID BA with multiple Provide better disturbance mitigation due to using cascaded loops [34] PI-PDF DTBO inputs can mitigate high as well as low frequency disturbances [44] 3DOF TID SSA Have better performance than single input LFC methods [45] FO-IDF ICA [46] PI-TDF SSA [29] PD-PIDA (STATCOM) ARO [47] FOPI-IDDF CSA [48] 1+PD/FOPID MRFO [49] 3DOF…”
mentioning
confidence: 99%