Power system stabilizer based on a self-learning adaptive network fuzzy inference system

Abstract: Application of a self-learning adaptive network-based fuzzy inference system as a power system stabilizer (PSS) is described in this paper. A multilayer adaptive network is employed to design the fuzzy logic controller with self-learning capability that does not require another controller to tune the fuzzy inference rules and membership functions. Details of the design process are given. Behaviour of the proposed PSS, investigated under different operating conditions and disturbances in both simulation and rea… Show more

“…The constraints of the Equation 12 are the PSS and IPFC damping controller parameter limits. Table 2 shows the parameters of the KH algorithm which are used for solving the optimization problem of Equation 12.…”

“…Note that in the real‐world applications, tuning of the multi‐band PSS is a very challenging task, and thus the CPSS has gained a major role in the existing power system oscillation damping controllers. The complexity of power system stability studies reveals the necessity for development of intelligent algorithms in order to accurately damp the LFOs . Farahani replaced AVR and PSS with an intelligent controller based on neural networks and artificial intelligence.…”

“…The complexity of power system stability studies reveals the necessity for development of intelligent algorithms in order to accurately damp the LFOs. 1,[11][12][13] Farahani 11 replaced AVR and PSS with an intelligent controller based on neural networks and artificial intelligence. Although this control method is robust and adaptive, its application in practice needs complex hardware which makes it unusable in the real-world usages.…”

“…Although this control method is robust and adaptive, its application in practice needs complex hardware which makes it unusable in the real‐world usages. Authors in Malik and Hariri proposed a new intelligent PSS based on merging characteristics of neural networks and fuzzy logic. In Shayeghi et al, it is shown that PSS cannot provide appropriate damping for all power system modes.…”

Application of reinforcement learning for generating optimal control signal to the IPFC for damping of low-frequency oscillations

“…The constraints of the Equation 12 are the PSS and IPFC damping controller parameter limits. Table 2 shows the parameters of the KH algorithm which are used for solving the optimization problem of Equation 12.…”

“…Note that in the real‐world applications, tuning of the multi‐band PSS is a very challenging task, and thus the CPSS has gained a major role in the existing power system oscillation damping controllers. The complexity of power system stability studies reveals the necessity for development of intelligent algorithms in order to accurately damp the LFOs . Farahani replaced AVR and PSS with an intelligent controller based on neural networks and artificial intelligence.…”

“…The complexity of power system stability studies reveals the necessity for development of intelligent algorithms in order to accurately damp the LFOs. 1,[11][12][13] Farahani 11 replaced AVR and PSS with an intelligent controller based on neural networks and artificial intelligence. Although this control method is robust and adaptive, its application in practice needs complex hardware which makes it unusable in the real-world usages.…”

“…Although this control method is robust and adaptive, its application in practice needs complex hardware which makes it unusable in the real‐world usages. Authors in Malik and Hariri proposed a new intelligent PSS based on merging characteristics of neural networks and fuzzy logic. In Shayeghi et al, it is shown that PSS cannot provide appropriate damping for all power system modes.…”

Application of reinforcement learning for generating optimal control signal to the IPFC for damping of low-frequency oscillations

Power System Stabilizers Based On Adaptive Control and Artificial Intelligence Techniques