Improving load frequency controller tuning with rat swarm optimization and porpoising feature detection for enhanced power system stability

Load frequency control (LFC) plays a critical role in ensuring the reliable and stable operation of power plants and maintaining a quality power supply to consumers. In control engineering, an oscillatory behavior exhibited by a system in response to control actions is referred to as “Porpoising”. T...

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Bibliographic Details
Published in:Scientific reports 2024-07, Vol.14 (1), p.15209-15, Article 15209
Main Authors: Gopi, Pasala, Alluraiah, N. Chinna, Kumar, Pujari Harish, Bajaj, Mohit, Blazek, Vojtech, Prokop, Lukas
Format: Article
Language:English
Subjects:
639/166
639/4077
639/705
Automatic generation control (AGC)
Control systems
Firefly algorithm
Humanities and Social Sciences
Load frequency control
multidisciplinary
PID control schemes
Porpoising
Power plants
Rat swarm optimization
Science
Science (multidisciplinary)
Systems stability
Thermal power
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Summary:Load frequency control (LFC) plays a critical role in ensuring the reliable and stable operation of power plants and maintaining a quality power supply to consumers. In control engineering, an oscillatory behavior exhibited by a system in response to control actions is referred to as “Porpoising”. This article focused on investigating the causes of the porpoising phenomenon in the context of LFC. This paper introduces a novel methodology for enhancing the performance of load frequency controllers in power systems by employing rat swarm optimization (RSO) for tuning and detecting the porpoising feature to ensure stability. The study focuses on a single-area thermal power generating station (TPGS) subjected to a 1% load demand change, employing MATLAB simulations for analysis. The proposed RSO-based PID controller is compared against traditional methods such as the firefly algorithm (FFA) and Ziegler-Nichols (ZN) technique. Results indicate that the RSO-based PID controller exhibits superior performance, achieving zero frequency error, reduced negative peak overshoot, and faster settling time compared to other methods. Furthermore, the paper investigates the porpoising phenomenon in PID controllers, analyzing the location of poles in the s-plane, damping ratio, and control actions. The RSO-based PID controller demonstrates enhanced stability and resistance to porpoising, making it a promising solution for power system control. Future research will focus on real-time implementation and broader applications across different control systems.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-66007-y