Title

Evaluation of the Shunt Active Power Filter apparent power ratio using particle swarm optimization

Journal title

Archives of Control Sciences

Yearbook

2010

Issue

No 1

Authors

Kouzou, A. ; Mahmoudi, M. ; Boucherit, M.

Divisions of PAS

Nauki Techniczne

Publisher

Committee of Automatic Control and Robotics PAS

Date

2010

Identifier

DOI: 10.2478/v10170-010-0004-9 ; ISSN 1230-2384

Source

Archives of Control Sciences; 2010; No 1

References

Lee 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.