Knacks of Fractional Order Swarming Intelligence for Parameter Estimation of Harmonics in Electrical Systems

The efficient parameter estimation of harmonics is required to effectively design filters to mitigate their adverse effects on the power quality of electrical systems. In this study, a fractional order swarming optimization technique is proposed for the parameter estimation of harmonics normally present in industrial loads. The proposed fractional order particle swarm optimization (FOPSO) effectively estimates the amplitude and phase parameters corresponding to the first, third, fifth, seventh and eleventh harmonics. The performance of the FOPSO was evaluated for ten fractional orders with noiseless and noisy scenarios. The robustness efficiency of the proposed FOPSO was analyzed by considering different levels of additive white Gaussian noise in the harmonic signal. Monte Carlo simulations confirmed the reliability of the FOPSO for a lower fractional order (lambda = 0.1) with a faster convergence rate and no divergent run compared to other fractional orders as well as to standard PSO (lambda = 1).

Automated summary

This study proposes a fractional order swarming optimization technique (FOPSO) for the efficient parameter estimation of harmonics in industrial loads. FOPSO effectively estimates the amplitude and phase parameters of harmonics and is robust to noise. Evaluation and analysis were conducted for different fractional orders and noise scenarios.