Application of stochastic fractal search algorithm in novel harmonic blocking filter design for optimizing harmonic mitigation and hosting capacity in electric distribution systems

Power networks are being transformed by the incorporation of renewable energy sources (RES), such as photovoltaic systems and wind turbines, which also promote sustainability and lower carbon emissions. However, the widespread use of inverter-based RES threatens power quality and grid stability, with harmonic distortion being a key issue. System performance is compromised by harmonic distortion, elevating the risk of resonance and overheating equipment and increasing power losses. In this study, the Stochastic Fractal Search (SFS) algorithm is used to develop Harmonic Blocking Filters (HBF), an optimized passive power filter for reducing harmonic distortion and minimizing the system active power losses (P_LOSS) in electric distribution systems. Two multi-objective optimization algorithms: Multi-Objective Artificial Hummingbird (MOAHA) and Multi-Objective Atomic Orbital Search (MOAOS) efficiently determine the ideal HBF design to maximize the system’s Harmonic-Constrained Hosting Capacity (HC_HC) and minimize P_LOSS to support RES while minimizing voltage and current total demand distortion (THD_V and TDD_I). Three test systems (TS) are used to validate the HBF’s superiority in mitigating the harmonics, minimizing PLOSS, and maximizing HCHC. In TS1, the SFS-optimized HBF decreases THD_V by 78% and TDD_I by 90% while maintaining P_LOSS almost the same as compared to the previously obtained results in the literature. In TS2, the SFS-optimized HBF decreases THD_V by 16.2%, TDD_I by 99.96%, and P_LOSS by 27.6% compared to the uncompensated case with no filter connected. In TS3, the SFS-optimized HBF decreases THD_V by 45.71%, TDD_I by 99.96%, and P_LOSS by 33.26% compared to the uncompensated case. For the HC_HC enhancement application, MOAOS has proven superior to MOAHA and the MOAOS-optimized HBF increases the system’s HC_HC by 4.18% and in TS3, this value is increased by 16.4% compared to the literature.