TitleEvaluation of the Shunt Active Power Filter apparent power ratio using particle swarm optimization
Journal titleArchives of Control Sciences
Divisions of PASNauki Techniczne
PublisherCommittee of Automatic Control and Robotics PAS
ReferencesLee C. (1997), Effets of various unbalanced voltages on the operation performane of an induction motor under the same voltage unbalnce factor ondition, null, 51. ; Jindal A. (2005), The protection of sensitive loads from inter-harmonic currents using shunt/series active filters, Electric Power Systems Research, 73, 187. ; Chang G. (2005), Optimisation-based strategy for shunt active power filter control under non-ideal supply voltages, IEE Proceedings Electric Power Applications, 152, 2, 182. ; George S. (2007), A DSP based optimal algorithm for shunt active filter under nonsinusoidal supply and unbalanced load conditions, IEEE Trans. on Power Electronics, 22, 593. ; Montero M. (2007), Comparison of control strategies for shunt active power filters in three-phase four-wire systems, IEEE Trans. on Power Electronics, 22, 229. ; Green T. (2005), Control techniques for active power filters, IEE Proceedings Electric Power Applications, 152, 2, 369. ; M. Tavakoli Bina (2009), An efficient procedure to design passive LCL-filters for active power filters, Electric Power Systems Research, 79, 606. ; Conway G. (1993), Harmonic currents produced by variable speed drives with uncontrolled rectifier inputs, null. ; Grötzbach M. (1993), Noncharacteristic line current harmonics in diode rectifier bridges produced by network symmetries, null, 64. ; Bauta M. (2000), Noncharacteristic line harmonics of AC/DC converters with high DC current ripple, IEEE Trans. Power Delivery, 15, 1060. ; Jeong S.-G. (2002), Line current characteristics of three-phase uncontrolled rectifiers under line voltage unbalance condition, IEEE Trans. on Power electronics, 17, 6, 935. ; Souto C. (1998), Power quality impact on performance and associated osts of three-phase inction motors, Proc. Harmonis and Quality of Power, 2, 791. ; Svensson J. (2001), Ative filtering of supply voltage with series-connected voltage soure inverter. ; Akagi H. (1983), Generalized theory of the instantaneous reactive power in three-phase circuits, null, 1375. ; Akagi H. (1984), Istanteneous reactive power compensators comprising switching devices without energy storage components, IEEE Trans. Ind. Appl, I4-20. ; Moreno V. (2004), Reference current estimation under distorted line voltage for control of Shunt Active Power Filters, IEEE Trans. on Power Electronics, 19, 4. ; Longhui W. (2007), Study on the influence of supply-voltage fluctuation on Shunt Active Power Filter, IEEE Trans. on Power Delivery, 22, 3. ; Alali M. (2000), IEEE-IEP-2000, 80. ; Alali M. (2000), Control and analysis of series and Shunt Active Power Filters with SABER, 1467. ; Watanabe H. (1993), New concepts of instantaneous active and reactive powers in electrical systems with generic loads, IEEE Trans. on Power Delivery, 8, 2. ; Akagi H. (1994), Trend in active power line conditioners, IEEE Trans. Ind. Electron, 9, 3, 263. ; Akagi H. (1986), Control strategy of active power filters using multiple voltage source PWM converters, IEEE Trans. Ind. Appl, IA-22, 460. ; Omeiri A. (2006), A three-phase shunt active power filter for currents harmonics suppression and reactive power compensation, Asian J. Inform. Technol, 5, 12, 1454. ; Saad S. (2009), Fuzzy logic controller for three-level shunt active filter compensating harmonics and reactive power, Electric Power Systems Research, 79, 1337. ; Singh B. (1999), Review of active filters for power quality improvement, IEEE Trans. on Industrial Electronics, 46, 5, 960. ; Zanchetta P. (2009), Experimental modeling and control design of shunt active power filters, Control Engineering Practice, 17, 1126. ; Willems J. (2005), The apparent power concept and the IEEE standard 1459-2000, IEEE Trans. Power Delivery, 20, 2, 876. ; Definitions for the measurement of electric quantities under sinusoidal, nonsinusoidal, balanced or unbalanced conditions. <i>IEEE Std. 1459-2000</i>, 2000. ; Emanuel A. (2003), Reflections on the effective voltage concept, null, 1. ; Willems J. (2005), Addendum to the apparent power concept and the IEEE Standard 1459-2000, IEEE Trans. on Power Delivery, 20, 2. ; Pajic S. (2006), A comparison among apparent power definitions, null. ; Pajic S. (2006), Modern apparent power definitions: Theoretical versus practical approach - The general case, IEEE Trans. on Power Delivery, 21, 4, doi.org/10.1109/TPWRD.2006.876647 ; Kouzou A. (2008), TShunt Active Power Filter apparent power for design process, 1402. ; Kouzou A. (2008), The effect of the zero sequence component on the evaluation of the series APF apparent power. ; Kouzou A. (2008), Apparent power evaluation of series active power filter with recent definitions. ; Moleykutty G. (2008), Modeling and control of three-phase Shunt Active Power Filter, American Journal of Applied Sciences, 5, 8, 1064. ; Emanuel A. (2004), Summary of IEEE Standard 1459: Definitions for the measurement of Electric Power Quantities under sinusoidal, nonsinusoidal, balanced or unbalanced conditions, IEEE Trans. Ind. Appl, 40, 3, 869. ; Pajic S. (2006), Modern apparent power definitions: Theoretical versus practical approach - The general case, IEEE Trans. on Power Delivery, 21, 4, 1787. ; Pajic S. (2009), Effect of neutral path power losses on the apparent power definitions: A preliminary study, IEEE Trans. on Power Delivery, 24, 2, 517. ; Kennedy J. (1995), Particle swarm optimization, null, 1942. ; Eberhart R. (1995), A new optimizer using particle swarm theory, null, 39. ; Kennedy J. (1997), The particle swarm: social adaptation of knowledge, null, 303. ; Shi Y. (1998), A modified particle swarm optimizer, null, 69. ; Shi Y. (1999), Empirical study of particle swarm optimization, null. ; Eberhart R. (2000), Comparing inertia weights and constriction factors in particle swarm optimization, Proc. of the 2000 Congress on Evolutionary Computation, 1, 84, doi.org/10.1109/CEC.2000.870279 ; Hu X. (2002), Multiobjective optimization using dynamic neighborhood particle swarm optimization, Proc. of the 2002 Congress on Evolutionary Computation, 2, 16771681. ; Eberhart R. (2001), Tracking and optimizing dynamic systems with particle swarms, Proc. of the 2001 Congress on Evolutionary Computation, 1, 94, doi.org/10.1109/CEC.2001.934376 ; Kennedy J. (2001), Swarm intelligence. ; G. H. M. Omran: Particle swarm optimization methods for pattern recognition and image processing. PhD thesis, University of Pretoria, 2004. ; A. Geletu: Solving optimization problems using the Matlab Optimization Toolbox - a Tutorial. 2007. ; Wu X. (2008), Particle swarm optimization with normal cloud mutation, null, 2828. ; Wen J. (2008), Particle swarm algorithm based on normal cloud, null, 1492.