Evolutionary algorithm based performance enhancement of automatic generation control in Multi Source interconnected power systems

Abstract

The increasing demand for electricity and global attention to the environment newlinehas led energy planners and developers to explore developing control techniques for newlineenergy stability. The main objective function of this research in an interconnected newlineelectrical power system to increase the stability of the system with the proposed newlineResilience Random Variance Reduction Technique is evaluated in terms of the different newlineconstraints like THD (%), steady-state error (%), settling time (sec), Overshoot (%), newlineefficiency (%) and to maintain the Frequency at a predetermined value, and controlling newlinethe change of the power flow of control between the areas renewable energy generation newline(Solar, wind, and fuel cell with battery management system) based smart grid system. newlineIn this work, a Fractional High-Order Differential Feedback Controller (FHODFC) is newlineproposed for the LFC problems in a multi-area power system. The gains of FHODFC newlineare best adjusted by RRVR designed to minimize the overall weighted absolute error newlineperformance exponential time. newlineIn the current situation of the power system, with the need to increase power newlineto meet the availability of all types of loads, the quality of power is equal to the demand. newlineOn this day, there is no change, and a demanding power supply with a stable and reliable newlinepower supply at all times. Therefore, in order to maintain the quality and power to meet newlinethe current reforms in the power sector and to adapt to the changes in the demands of newlinethe industrial sector thus changing in frequency, an advanced controller is necessary. newlineThis work presents a Revolutionary Energy Balance Control (REBC) controller newlineapproach for automatic generation controller. This AGC technique seeks to balance the newlinewhole producing system while maintaining a constant system frequency per tie-lie newlinepower flow, with no power losses or load fluctuations. To decrease the maximum newlinedeviation and oscillation duration, modeling error is taken into consideration. The newlinefundamental goal of FOPID based AGC is to ensure that power sys