Journal Press India^®

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The stability of the SMIB system in the presence of tiny signals is the major focus of this study. The small signal stability of SMIB is shown first by graphing the eigenvalue associated with rotor oscillations against the gain of the voltage regulator and the machine loading. Second, the very low-level signals that are sent by the SMIB system will be more reliable as a result of the incorporation of the pole placement technique and the use of TCSC in the production of PSS. A comparison is made between the impacts of PSS and TCSC on the oscillations of the rotor's speed and angle. During this last stage of the design process, consideration was given to the selection of a feedback control signal for the PSS. The amount of time it takes to reply to messages is one of the factors that determines how effective they are.

Keywords

SSS; SMIB; FACTs Devices; Power System Stabilizer (PSS)

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