Design of PI Controller for Automatic Generation Control of Multi Area Interconnected Power System using Bacterial Foraging Optimization
Naresh Kumari, Nitin Malik, A. N. Jha, Gaddam Mallesham

TL;DR
This paper presents an optimized PI controller design for multi-area interconnected power systems using bacterial foraging optimization, improving frequency response performance compared to traditional methods.
Contribution
The paper introduces the application of bacterial foraging optimization for tuning PI controllers in multi-area power systems, demonstrating superior performance over PSO and gradient descent methods.
Findings
BFO reduces peak overshoot and undershoot more effectively.
BFO achieves better frequency response performance.
Settling time increases marginally with BFO.
Abstract
The system comprises of three interconnected power system networks based on thermal, wind and hydro power generation. The load variation in any one of the network results in frequency deviation in all the connected systems.The PI controllers have been connected separately with each system for the frequency control and the gains (Kp and Ki) of all the controllers have been optimized along with frequency bias (Bi) and speed regulation parameter (Ri). The computationally intelligent techniques like bacterial foraging optimization (BFO) and particle swarm optimization (PSO) have been applied for the tuning of controller gains along with variable parameters Bi and Ri. The gradient descent (GD) based conventional method has also been applied for optimizing the parameters Kp, Ki,Bi and Ri.The frequency responses are obtained with all the methods. The performance index chosen is the integral…
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Taxonomy
MethodsBacterial Foraging Optimization · SPEED: Separable Pyramidal Pooling EncodEr-Decoder for Real-Time Monocular Depth Estimation on Low-Resource Settings
