Abstract
As the world's population grows and energy demand increases, it is necessary to increase the scale of the electrical system, which is more complicated. Consequently, adopting automatic generation control (AGC) scheme to meet the demand becomes inevitable. In this article, the fusion of flower pollinated algorithm (FPA) and pathfinder algorithm (PFA), named hereafter as hFPAPFA, is proposed to achieve maximum control efficiency by combining the exploitation of FPA with the exploration capacity of PFA. The proposed hFPAPFA is meant to regulate two unequal multi-area interconnected power system with different generating units such as thermal, hydro, wind power and diesel plants. The proposed control scheme aims to achieve this by using the new algorithm to optimize the fractional-order set-point weighted PID (FOSWPID) parameters under time domain-based fitness functions namely, integral time square error (ITSE) and integral time absolute error (ITAE) while simultaneously minimizing the power losses. Employing the same interconnected power systems, a comparative study with some recent approaches in renowned journals is conducted. The performance of the proposed method is observed under diverse load conditions scenarios. Moreover, three nonlinearities including boiler dynamics, the governor dead band (GDB) and generation rate constraints (GRC) are further integrated into the system from a pragmatic context. Finally, sensitivity tests involving various parameter changes and the introduction of random step load perturbations are carried out. From the results, the proposed approach outperformed other approaches under different load condition scenarios, incorporation of nonlinearities and random load perturbation, demonstrating the proposed technique's efficacy and reliability.
Highlights
This paper aims to present a hybrid of optimization-based algorithms which comprises the integration of flower pollinated algorithm (FPA) and pathfinder algorithm PFA for addressing the problems of load changes and frequency deviation in the automatic generation control (AGC) system
Boiler dynamics, the governor dead band (GDB) and the generation rate constraints (GRC) have been incorporated into the model to demonstrate the competence of the system towards nonlinearities
In this work, a new algorithm based on the merger of the flower pollinated algorithm and the pathfinder algorithm is used to optimize the setpoint weighted fractional-order PID (FOSWPID) controller for the automatic generation control of a multi-source interconnected power system with renewable energy sources
Summary
A. LITERATURE REVIEW The power system is a complex system that consists of interconnected active elements. The top priority of power system industries is to ensure adequate generation, transmission, and electric power distribution. The associate editor coordinating the review of this manuscript and approving it for publication was Siqi Bu. technology, the need for power supply has become essential for individuals and industries [1]. The power systems are becoming more and more complicated since they include multiple sources such as biomass, fossil fuels, solar thermal energy, wind, hydro etc. The renewable energy sources have significantly contributed to the supply of energy to the power grid sectors.
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