Dynamic stability assessment of interconnected thermal-SsGT-solar photovoltaic-EV power system with ARO optimized IDN-FOID amalgamated controller

To succeed over the sudden load-frequency variations in interlinked power systems, an equilibrium must be maintained between power generations and losses. The major problem associated to manifold interlinking arenas of power systems is load frequency control. In this paper, a multiple-arena scheme is examined which encompasses thermal and split shaft gas turbine plants. Here, artificial rabbit optimization (ARO) is applied to procure the premium standards of the supplementary controller. The projected controller is the amalgamation of integer order integral-derivative with filter (IDN) and fractional order integral-derivative (FOID). So, the amalgamation is IDN-FOID. Henceforth, the ARO augmented IDN-FOID controller is recognized. The ARO augmented IDN-FOID supplementary controller delivers enhanced outcomes related to additional secondary controllers like I, PI, and PIDN. Valuation articulates about the improved act of ARO over added algorithms using the IDN-FOID controller related to converging nature, transient profile, and steady-state assessment. Assessment is done in the presence of non-linearities in generation rate constraints and time delay. It is also detected that scheme potent outcomes with the IDN-FOID controller are superior when the scheme is instructed with solar photovoltaic, electric vehicles, solid oxide fuel cells, and ultra-capacitor. The ARO optimized IDN-FOID controller is the anticipated arrangement for the measured scheme.