Open AccessA comparative study and experimental validation on single phase series active power filter control strategies using pi, flc and sliding mode controllers
Author(s) -
Abdallah Ben Abdelkader,
Othmane Abdelkhalek,
Ismaïl Khalil Bousserhane,
Mohamed Amine Hartani,
A. Omari
Publication year - 2019
Publication title -
international journal of power electronics and drive systems (ijpeds)
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.322
H-Index - 21
ISSN - 2088-8694
DOI - 10.11591/ijpeds.v10.i2.pp731-743
Subject(s) - control theory (sociology) , harmonics , voltage sag , total harmonic distortion , matlab , integrator , pid controller , swell , voltage , distortion (music) , three phase , power (physics) , active power filter , computer science , filter (signal processing) , mathematics , power quality , engineering , physics , control engineering , control (management) , telecommunications , temperature control , amplifier , thermodynamics , bandwidth (computing) , quantum mechanics , artificial intelligence , electrical engineering , operating system , computer vision
Sensitive loads are widely used in industrial, which is the main cause of sag-swell and harmonics voltages problems that can affect the power quality. Among the devices that solve such power quality perturbations, the series active power Filter APFS is considered in this paper. Thus, a single phase APFS is developed through an analytic analysis, supported by an experimental validation, where we applied classical proportional integrator PI, fuzzy logic FLC and sliding mode SM controllers to improve the dynamic response of the APFS. In addition, a comparative study between these control strategies has made in order to mitigate voltage sag-swell and especially harmonics, where the SMC has showed more effective and robust results compared to PI and FLC and proved by the Total harmonic distortion THD ratio. Results of the proposed controllers are simulated in MATLAB simulink® and validated through experimental tests applied on our system prototype.