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An Optimal Two-Stage Tuned PIDF + Fuzzy Controller for Enhanced LFC in Hybrid Power Systems

Saif H. Almutairi, Fatih Anayi, Michael Packianather, Mokhtar Shouran

2025Sustainability5 citationsDOIOpen Access PDF

Abstract

Ensuring reliable power system control demands innovative architectural solutions. This research introduces a fault-tolerant hybrid parallel compensator architecture for load frequency control (LFC), combining a Proportional–Integral–Derivative with Filter (PIDF) compensator with a Fuzzy Fractional-Order PI-PD (Fuzzy FOPI–FOPD) module. Particle Swarm Optimization (PSO) determines optimal PID gains, while the Catch Fish Optimization Algorithm (CFOA) tunes the Fuzzy FOPI–FOPD parameters—both minimizing the Integral Time Absolute Error (ITAE) index. The parallel compensator structure guarantees continuous operation during subsystem faults, substantially boosting grid reliability. Rigorous partial failure tests confirm uncompromised performance-controlled degradation. Benchmark comparisons against contemporary controllers reveal the proposed architecture’s superiority, quantifiable through transient metric enhancements: undershoot suppression (−9.57 × 10−5 p.u. to −1.17 × 10−7 p.u.), settling time improvement (8.8000 s to 3.1511 s), and ITAE reduction (0.0007891 to 0.0000001608), verifying precision and stability gains. Resilience analyses across parameter drift and step load scenarios, simulated in MATLAB/Simulink, demonstrate superior disturbance attenuation and operational stability. These outcomes confirm the solution’s robustness, dependability, and field readiness. Overall, this study introduces a transformative LFC strategy with high practical viability for modern power networks.

Topics & Concepts

Control theory (sociology)Electric power systemComputer scienceSettling timeParticle swarm optimizationBenchmark (surveying)Fuzzy logicRobustness (evolution)Fuzzy control systemController (irrigation)Transient (computer programming)CascadeControl engineeringPID controllerHybrid systemGridPower (physics)Stability (learning theory)Control systemEngineeringReduction (mathematics)Automatic frequency controlFilter (signal processing)Optimization problemMetric (unit)Transient responseApproximation errorPerformance metricConvex optimizationFrequency Control in Power SystemsMicrogrid Control and OptimizationPower System Optimization and Stability