Your search keyword '"Gooi, Hoay Beng"' showing total 2 results

1. Subsynchronous Oscillation Analysis Using Multisynchrosqueezing Transform and Dissipating Energy Flow Method.

Author

Ma, Yue, Huang, Qi, Gooi, Hoay Beng, Zhang, Zhenyuan, Yang, Xiaomei, and Wang, Yang

Subjects

PHASOR measurement, OSCILLATIONS, ELECTRIC transients, TIME-frequency analysis, ELECTRONIC equipment

Abstract

With a high proportion of new energy and power electronic equipment connected to the modern power system, a new type of subsynchronous oscillation (SSO) is triggered, which affects the safe and stable operation of the system. Accurate analysis and identification of the SSO source becomes the key to studying this problem. This article presents a novel method to analyze SSOs. First, multisynchrosqueezing transform is applied to the signal to get the concentrated time–frequency analysis results. Then, the ridge tracking method is utilized to identify and reconstruct the subsynchronous component signals. The method of dissipating energy flow is applied to locate the source and sink of the SSO in the subsynchronous component signals. The performances of the proposed method are verified using electromagnetic transient simulations in a three-wind farms system and a modified IEEE 10-generator 39-bus New England power system. [ABSTRACT FROM AUTHOR]

Published

2022

2. A Hybrid Firefly-Swarm Optimized Fractional Order Interval Type-2 Fuzzy PID-PSS for Transient Stability Improvement.

Author

Ray, Prakash K., Paital, Shiba R., Mohanty, Asit, Foo, Y. S. Eddy, Krishnan, Ashok, Gooi, Hoay Beng, and Amaratunga, Gehan A. J.

Subjects

DIFFERENTIAL evolution, PID controllers, FUZZY integrals, GENETIC algorithms, PARTICLE swarm optimization

Abstract

This article focuses on the implementation of a hybrid firefly algorithm-particle swarm optimization (FAPSO) scheme for optimizing the parameters of an interval type-2 fractional order fuzzy proportional integral derivative (IT2FOFPID)-based power system stabilizer (PSS) to minimize the low-frequency oscillations in a power system. Here, the IT2FOFPID-based PSS is designed by considering speed deviation and acceleration as input signals. In this article, a single machine infinite bus system and the New England 10 machine 39-bus power system are used for testing and comparing the approaches. Stability studies are also performed using OPAL-RT's OP5600, a real-time digital simulator. The comparative studies demonstrate that the hybrid FAPSO optimized IT2FOFPID-PSS provides better damping and stability performance when compared with the PSSs based on the FA/PSO/ hybrid genetic algorithm and bacterial foraging optimization and hybrid differential evolution and pattern search optimized IT2FOFPID approaches under various operating scenarios. [ABSTRACT FROM AUTHOR]

Published

2019