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Year 2011, Volume: 24 Issue: 2, 283 - 289, 05.04.2011

Abstract

References

  • Khadkikar V., Chandra A., Singh B. N., “Generalised single-phase p-q theory for active power filtering: simulation and DSP-based experimental investigation”, Power Electronics, IET, 2: 67-78, (2009).
  • Luo A., Shuai Z., Zhu W., “Combined system for harmonic compensation”, Industrial Electronics, IEEE Transactions, 56: 418-428, (2009). power
  • Luo A., Shuai Z., Shen Z. J., Wenji Z., Xianyong X., “Design considerations for maintaining DC- side voltage of hybrid active power filter with injection circuit”, Power Electronics, IEEE Transactions., 24: 75-84, (2009).
  • Habrouk E., Darwish M., Mehta M.K., “Active power filters: A review”, Electric Power Applications, IEE Proceedings, 147: 403-413, (2000).
  • Fujita H., “A single-phase active filter using an H- bridge PWM converter with a sampling frequency quadruple of the switching frequency”, Power Electronics, IEEE Transactions., 24: 934-941, (2009).
  • Jou H. L., Wu K. D., Wu J. C., Chiang W., “A three-phase four-wire power filter comprising a three-phase three-wire active power filter and a zig–zag transformer”, Power Electronics, IEEE Transactions, 23: 252-259, (2008).
  • Vodyakho O., Kim T., “Shunt active filter based on three-level inverter for three-phase four-wire systems”, Power Electronics, IET, 2: 216-226, (2009).
  • Singh B., Al-Haddad K., Chandra A., “A review of active filters for power quality improvement”, IEEE Tran. Industrial Electronics, 46: 960–971, (1999).
  • Jain S. K., Agarwal P. H. O., “Design simulation and experimental investigations, on a shunt active power filter for harmonics and reactive power compensation”, Electric Power Components and Systems, 33: 671-692, (2003).
  • Singh G.K., Singh A.K., Mitra R., “A simple fuzzy logic based robust active power filter for harmonics minimization under random load variation”, Electric Power Systems Research, 77: 1101-1111, (2007).
  • Rahim N. A., Hew W. P., Lim S. H., “Simple control strategy for fuzzy logic controlled active power filter”, 10th Conference on Artificial Intelligence University of Kaohsiung, (2005). National
  • Brahim B., Chellali B., Rachid D., Brahim F., “Optimization of shunt active power filter system fuzzy logic controller based on ant colony algorithm”, Journal of Theoretical and Applied Information Technology, 14: 117-125, (2010).
  • Radzi M. A. M., Rahim N. A., “Neural network and bandless hysteresis approach to control switched capacitor active power filter for reduction of harmonics”, IEEE Transactions on Industrial Electronics, 56: 1477-1484, (2009).
  • Flores P., Dixon J., Ortuzar M., Carmi R., Barriuso P., Moran L., “Static VAr compensator and active power filter with power injection capability using 27-level Industrial Electronics, IEEE Transactions, 56: 130-138, (2009). photovoltaic cells”,
  • Uyyuru K. R., Mishra M., Ghosh K. A., “An optimization-based algorithm for shunt active filter under Electronics, IEEE Transactions., 24: 1223-1232, (2009). voltages”, Power
  • Senturk O.S., Hava A.M., “High performance harmonic isolation and load voltage regulation of the three-phase series active filter utilizing the waveform Transactions on Industry Applications, 45: 2030- 2038, (2009). method”, IEEE
  • Luo A., Shuai Z., Zhu W., Shen Z.J., Tu C., “Design and application of a hybrid active power filter with injection circuit”, Power Electronics, IET, 3: 54–64, (2010).
  • Salmeron P., Litran S.P., “Improvement of the electric power quality using series active and shunt passive Transactions, 25: 1058–1067, (2010). Delivery, IEEE
  • Massoud A.M., Finney S.J., Williams B.W., “Seven-level Harmonics and Quality of Power, International Conference, 11: 136-141, (2004). power filter”,
  • Xiao P., Venayagamoorthy G.K., K.A. Corzine, “Seven-level shunt active power filter for high- power drive systems”, Power Electronics, IEEE Transactions , 24: 6-13, (2009).
  • Dai N. Y., Wong M. C., Fan N., Han Y. D., “A FPGA-based generalized pulse width modulator for three-leg center-split and four-leg voltage source inverters”, Power Electronics, IEEE Transactions, 23: 1472-1484, (2008).
  • Henning P.H., Fuchs H.D., Roux A.D. L., Mouton H.A T., “1.5-MW seven-cell series-stacked converter as an active power filter and regeneration converter for a DC traction substation”, Power Electronics, IEEE Transactions, 23: 2230-2236, (2008).
  • Routimo M., Tuusa H., “LCL type supply filter for active power filter, comparison of an active and a passive method for resonance damping” IEEE Power Electronics Specialists Conference, 2939- 2945, (2007).
  • Internet: http://www.ablerex-ups.com.sg/note.pdf, (2010).
  • Vodyakho Mi O. C. C., “Three-level inverter- based shunt active power filter in three-phase three-wire transactions on power electronics, 24, (2009). systems”, IEEE
  • Fathi S.H., Pishvaei M., Gharehpetian G.B., “A frequency domain method for instantaneous determination of reference current in shunt active filter”, TENCON, IEEE Region 10 Conference, 1-4, (2006).
  • Salam Z., Tan P. C., Jusoh A., “Harmonics mitigation technological review”, Elektrika Journal of Electrical Engineering, 8: 17-26, (2006). A
  • Maurício A., Hirofumi A., Edson H. W., V. Eumir S., Lucas F. E., “Comparisons between the p-q and p-q-r theories in three-phase four-wire systems”, IEEE Trans. on Power Electronics, 24(4): (2009).
  • Silva S. A. O., Novochadlo R., Modesto R.A., “Single-phase PLL structure using modified p-q theory for utility connected systems”, IEEE Power Electronics Specialists Conf., 4706-4711, (2008).
  • Li D., Chen Q., Jia Z., Zhang C., “A high-power active filtering system with fundamental magnetic flux compensation”, Power Delivery, IEEE Transactions, 21: 823-830, (2006).
  • Mojiri M., Karimi M. G., Bakhshai A., “Processing of harmonics and interharmonics using an adaptive notch filter”, Power Delivery, IEEE Transactions., 25: 534–542, (2010).
  • Karimi H., Karimi-Ghartemani M., Reza Iravani M. Bakhshai A. R., “Adaptive filter for synchronous distortions”, delivery, 18(4): (2003). of transactions on power
  • Azevedo H. J., Ferreira J. M., Martins A. P., Carvalho A. S., “An active power filter with direct current control for power quality conditioning”, Electric Power Components and Systems, 36: 587-601, (2008).
  • Pucci M., Vitale M., Miraoui A. G., “Current harmonic compensation by a single-phase shunt active power filter controlled by adaptive neural filtering”, Transactions, 56: 3128-3143, (2009). Electronics, IEEE
  • Zhang H., Massoud A.M., Finney S.J., Williams B.W., Fletcher J.E., “Operation of an active power filter with line voltage SVM under non-ideal conditions”, Compatibility in Power Electronics, 1-7, (2007).
  • Matas J., Vicuna L.G., Miret J., Guerrero J.M., Castilla M., “Feedback linearization of a single- phase active power filter via sliding mode control”, Power Electronics, IEEE Transactions, 23: 116- 125, (2008).
  • Qu Y., Tan W., Yang Y., “A fuzzy adaptive detecting approach of harmonic currents for active power filter”, Power Electronics and Drive Systems, 7th International Conference, 1695- 1699, (2007).
  • Jiang M. C., “Analysis and design of a novel three- phase active power filter”, Aerospace and Electronic Systems, IEEE Transactions, 37: 824- 831, (2001).
  • Bhattacharya A., Chakraborty C., “ANN (Adaline) based harmonic compensation for shunt active power filter with capacitor voltage based predictive technique”, Industrial and Information Systems, IEEE 3rd international Conf., 1-6, (2008).
  • Kumar P., Mahajan A., “Soft computing techniques for the control of an active power filter”, IEEE Transactions on Power Delivery, 24: 452-461, (2009).
  • Zhang H., Finney J. S., Massoud A., Williams B.W., “An SVM algorithm to balance the capacitor voltages of the three-level NPC active power filter”, Power Electronics, IEEE Transactions, 23: 2694–2702, (2008).
  • Firlit A., “The active power filter operation under the distorted supply voltage”, Inst. of Electr. Drive & Electronics and Applications, 10, (2005). Control, Power [43] Kedjar B., Al-Haddad K., “DSP-based implementation of an LQR with integral action for a three-phase three-wire shunt active power filter”, IEEE Transactions on Industrial Electronics, 56: 2821-2828, (2009).
  • Shu Z., Guo Y., Lian J., “Steady-state and dynamic study of active power filter with efficient FPGA- based control algorithm”, Industrial Electronics, IEEE Transactions, 55: 1527-1536, (2008).
  • Akagi H., “Active filters and energy storage systems operated under non-periodic conditions”, IEEE Power Engineering Society Summer Meeting, 2: 965-970, (2000).
  • Akagi H., “Modern active filters and traditional passive filters”, Bulletin of the Polish Academy of Sciences, Technical Sciences, 54: 255-269, (2006).
  • Akagi, H., New Trends in Active Filters for Improving Power Quality, Power Electronics, Drives and Energy Systems for Industrial Growth, Proceedings of the 1996 International Conf., 1: 417 – 425, (1996).
  • Bae, C. H., Han, M. S., Kim, Y. K., Kwon, S. Y., Park, H. J., Determining the Capacity and Installation Positions of Regenerative Inverters at DC 1500V Electric Railway Substations, The transactions of the Korean Institute of Electrical Engineers. B, Society of electrical machinery & energy conversion systems, 55: 478-484, (2006).
  • Akagi, H., Large Static Converters for Industry and Utility Applications, Proceedings of the IEEE, 89:6, 976-983, (2001).

Active Power Filter: Review of Converter Topologies and Control Strategies

Year 2011, Volume: 24 Issue: 2, 283 - 289, 05.04.2011

Abstract

Decrease in the cost of power electronic devices and improvement in the efficiency of both power converters and energy storage components have increased the applicability of new technological solutions such as Custom Power (CP) and Flexible AC Transmission Systems (FACTS) Devices. Active Power Filter (APF) is one of the CP devices and can mitigate harmonics, reactive power and unbalanced load currents originating from load side. In this study, a comprehensive review of APF studies, the advantages and disadvantages of each presented techniques are presented. The study also helps the researchers to select the optimum control strategies and power circuit configuration for APF applications.

References

  • Khadkikar V., Chandra A., Singh B. N., “Generalised single-phase p-q theory for active power filtering: simulation and DSP-based experimental investigation”, Power Electronics, IET, 2: 67-78, (2009).
  • Luo A., Shuai Z., Zhu W., “Combined system for harmonic compensation”, Industrial Electronics, IEEE Transactions, 56: 418-428, (2009). power
  • Luo A., Shuai Z., Shen Z. J., Wenji Z., Xianyong X., “Design considerations for maintaining DC- side voltage of hybrid active power filter with injection circuit”, Power Electronics, IEEE Transactions., 24: 75-84, (2009).
  • Habrouk E., Darwish M., Mehta M.K., “Active power filters: A review”, Electric Power Applications, IEE Proceedings, 147: 403-413, (2000).
  • Fujita H., “A single-phase active filter using an H- bridge PWM converter with a sampling frequency quadruple of the switching frequency”, Power Electronics, IEEE Transactions., 24: 934-941, (2009).
  • Jou H. L., Wu K. D., Wu J. C., Chiang W., “A three-phase four-wire power filter comprising a three-phase three-wire active power filter and a zig–zag transformer”, Power Electronics, IEEE Transactions, 23: 252-259, (2008).
  • Vodyakho O., Kim T., “Shunt active filter based on three-level inverter for three-phase four-wire systems”, Power Electronics, IET, 2: 216-226, (2009).
  • Singh B., Al-Haddad K., Chandra A., “A review of active filters for power quality improvement”, IEEE Tran. Industrial Electronics, 46: 960–971, (1999).
  • Jain S. K., Agarwal P. H. O., “Design simulation and experimental investigations, on a shunt active power filter for harmonics and reactive power compensation”, Electric Power Components and Systems, 33: 671-692, (2003).
  • Singh G.K., Singh A.K., Mitra R., “A simple fuzzy logic based robust active power filter for harmonics minimization under random load variation”, Electric Power Systems Research, 77: 1101-1111, (2007).
  • Rahim N. A., Hew W. P., Lim S. H., “Simple control strategy for fuzzy logic controlled active power filter”, 10th Conference on Artificial Intelligence University of Kaohsiung, (2005). National
  • Brahim B., Chellali B., Rachid D., Brahim F., “Optimization of shunt active power filter system fuzzy logic controller based on ant colony algorithm”, Journal of Theoretical and Applied Information Technology, 14: 117-125, (2010).
  • Radzi M. A. M., Rahim N. A., “Neural network and bandless hysteresis approach to control switched capacitor active power filter for reduction of harmonics”, IEEE Transactions on Industrial Electronics, 56: 1477-1484, (2009).
  • Flores P., Dixon J., Ortuzar M., Carmi R., Barriuso P., Moran L., “Static VAr compensator and active power filter with power injection capability using 27-level Industrial Electronics, IEEE Transactions, 56: 130-138, (2009). photovoltaic cells”,
  • Uyyuru K. R., Mishra M., Ghosh K. A., “An optimization-based algorithm for shunt active filter under Electronics, IEEE Transactions., 24: 1223-1232, (2009). voltages”, Power
  • Senturk O.S., Hava A.M., “High performance harmonic isolation and load voltage regulation of the three-phase series active filter utilizing the waveform Transactions on Industry Applications, 45: 2030- 2038, (2009). method”, IEEE
  • Luo A., Shuai Z., Zhu W., Shen Z.J., Tu C., “Design and application of a hybrid active power filter with injection circuit”, Power Electronics, IET, 3: 54–64, (2010).
  • Salmeron P., Litran S.P., “Improvement of the electric power quality using series active and shunt passive Transactions, 25: 1058–1067, (2010). Delivery, IEEE
  • Massoud A.M., Finney S.J., Williams B.W., “Seven-level Harmonics and Quality of Power, International Conference, 11: 136-141, (2004). power filter”,
  • Xiao P., Venayagamoorthy G.K., K.A. Corzine, “Seven-level shunt active power filter for high- power drive systems”, Power Electronics, IEEE Transactions , 24: 6-13, (2009).
  • Dai N. Y., Wong M. C., Fan N., Han Y. D., “A FPGA-based generalized pulse width modulator for three-leg center-split and four-leg voltage source inverters”, Power Electronics, IEEE Transactions, 23: 1472-1484, (2008).
  • Henning P.H., Fuchs H.D., Roux A.D. L., Mouton H.A T., “1.5-MW seven-cell series-stacked converter as an active power filter and regeneration converter for a DC traction substation”, Power Electronics, IEEE Transactions, 23: 2230-2236, (2008).
  • Routimo M., Tuusa H., “LCL type supply filter for active power filter, comparison of an active and a passive method for resonance damping” IEEE Power Electronics Specialists Conference, 2939- 2945, (2007).
  • Internet: http://www.ablerex-ups.com.sg/note.pdf, (2010).
  • Vodyakho Mi O. C. C., “Three-level inverter- based shunt active power filter in three-phase three-wire transactions on power electronics, 24, (2009). systems”, IEEE
  • Fathi S.H., Pishvaei M., Gharehpetian G.B., “A frequency domain method for instantaneous determination of reference current in shunt active filter”, TENCON, IEEE Region 10 Conference, 1-4, (2006).
  • Salam Z., Tan P. C., Jusoh A., “Harmonics mitigation technological review”, Elektrika Journal of Electrical Engineering, 8: 17-26, (2006). A
  • Maurício A., Hirofumi A., Edson H. W., V. Eumir S., Lucas F. E., “Comparisons between the p-q and p-q-r theories in three-phase four-wire systems”, IEEE Trans. on Power Electronics, 24(4): (2009).
  • Silva S. A. O., Novochadlo R., Modesto R.A., “Single-phase PLL structure using modified p-q theory for utility connected systems”, IEEE Power Electronics Specialists Conf., 4706-4711, (2008).
  • Li D., Chen Q., Jia Z., Zhang C., “A high-power active filtering system with fundamental magnetic flux compensation”, Power Delivery, IEEE Transactions, 21: 823-830, (2006).
  • Mojiri M., Karimi M. G., Bakhshai A., “Processing of harmonics and interharmonics using an adaptive notch filter”, Power Delivery, IEEE Transactions., 25: 534–542, (2010).
  • Karimi H., Karimi-Ghartemani M., Reza Iravani M. Bakhshai A. R., “Adaptive filter for synchronous distortions”, delivery, 18(4): (2003). of transactions on power
  • Azevedo H. J., Ferreira J. M., Martins A. P., Carvalho A. S., “An active power filter with direct current control for power quality conditioning”, Electric Power Components and Systems, 36: 587-601, (2008).
  • Pucci M., Vitale M., Miraoui A. G., “Current harmonic compensation by a single-phase shunt active power filter controlled by adaptive neural filtering”, Transactions, 56: 3128-3143, (2009). Electronics, IEEE
  • Zhang H., Massoud A.M., Finney S.J., Williams B.W., Fletcher J.E., “Operation of an active power filter with line voltage SVM under non-ideal conditions”, Compatibility in Power Electronics, 1-7, (2007).
  • Matas J., Vicuna L.G., Miret J., Guerrero J.M., Castilla M., “Feedback linearization of a single- phase active power filter via sliding mode control”, Power Electronics, IEEE Transactions, 23: 116- 125, (2008).
  • Qu Y., Tan W., Yang Y., “A fuzzy adaptive detecting approach of harmonic currents for active power filter”, Power Electronics and Drive Systems, 7th International Conference, 1695- 1699, (2007).
  • Jiang M. C., “Analysis and design of a novel three- phase active power filter”, Aerospace and Electronic Systems, IEEE Transactions, 37: 824- 831, (2001).
  • Bhattacharya A., Chakraborty C., “ANN (Adaline) based harmonic compensation for shunt active power filter with capacitor voltage based predictive technique”, Industrial and Information Systems, IEEE 3rd international Conf., 1-6, (2008).
  • Kumar P., Mahajan A., “Soft computing techniques for the control of an active power filter”, IEEE Transactions on Power Delivery, 24: 452-461, (2009).
  • Zhang H., Finney J. S., Massoud A., Williams B.W., “An SVM algorithm to balance the capacitor voltages of the three-level NPC active power filter”, Power Electronics, IEEE Transactions, 23: 2694–2702, (2008).
  • Firlit A., “The active power filter operation under the distorted supply voltage”, Inst. of Electr. Drive & Electronics and Applications, 10, (2005). Control, Power [43] Kedjar B., Al-Haddad K., “DSP-based implementation of an LQR with integral action for a three-phase three-wire shunt active power filter”, IEEE Transactions on Industrial Electronics, 56: 2821-2828, (2009).
  • Shu Z., Guo Y., Lian J., “Steady-state and dynamic study of active power filter with efficient FPGA- based control algorithm”, Industrial Electronics, IEEE Transactions, 55: 1527-1536, (2008).
  • Akagi H., “Active filters and energy storage systems operated under non-periodic conditions”, IEEE Power Engineering Society Summer Meeting, 2: 965-970, (2000).
  • Akagi H., “Modern active filters and traditional passive filters”, Bulletin of the Polish Academy of Sciences, Technical Sciences, 54: 255-269, (2006).
  • Akagi, H., New Trends in Active Filters for Improving Power Quality, Power Electronics, Drives and Energy Systems for Industrial Growth, Proceedings of the 1996 International Conf., 1: 417 – 425, (1996).
  • Bae, C. H., Han, M. S., Kim, Y. K., Kwon, S. Y., Park, H. J., Determining the Capacity and Installation Positions of Regenerative Inverters at DC 1500V Electric Railway Substations, The transactions of the Korean Institute of Electrical Engineers. B, Society of electrical machinery & energy conversion systems, 55: 478-484, (2006).
  • Akagi, H., Large Static Converters for Industry and Utility Applications, Proceedings of the IEEE, 89:6, 976-983, (2001).
There are 48 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Electrical & Electronics Engineering
Authors

Lütfü Sarıbulut

Ahmet Teke This is me

M. Meral This is me

Mehmet Tumay This is me

Publication Date April 5, 2011
Published in Issue Year 2011 Volume: 24 Issue: 2

Cite

APA Sarıbulut, L., Teke, A., Meral, M., Tumay, M. (2011). Active Power Filter: Review of Converter Topologies and Control Strategies. Gazi University Journal of Science, 24(2), 283-289.
AMA Sarıbulut L, Teke A, Meral M, Tumay M. Active Power Filter: Review of Converter Topologies and Control Strategies. Gazi University Journal of Science. April 2011;24(2):283-289.
Chicago Sarıbulut, Lütfü, Ahmet Teke, M. Meral, and Mehmet Tumay. “Active Power Filter: Review of Converter Topologies and Control Strategies”. Gazi University Journal of Science 24, no. 2 (April 2011): 283-89.
EndNote Sarıbulut L, Teke A, Meral M, Tumay M (April 1, 2011) Active Power Filter: Review of Converter Topologies and Control Strategies. Gazi University Journal of Science 24 2 283–289.
IEEE L. Sarıbulut, A. Teke, M. Meral, and M. Tumay, “Active Power Filter: Review of Converter Topologies and Control Strategies”, Gazi University Journal of Science, vol. 24, no. 2, pp. 283–289, 2011.
ISNAD Sarıbulut, Lütfü et al. “Active Power Filter: Review of Converter Topologies and Control Strategies”. Gazi University Journal of Science 24/2 (April 2011), 283-289.
JAMA Sarıbulut L, Teke A, Meral M, Tumay M. Active Power Filter: Review of Converter Topologies and Control Strategies. Gazi University Journal of Science. 2011;24:283–289.
MLA Sarıbulut, Lütfü et al. “Active Power Filter: Review of Converter Topologies and Control Strategies”. Gazi University Journal of Science, vol. 24, no. 2, 2011, pp. 283-9.
Vancouver Sarıbulut L, Teke A, Meral M, Tumay M. Active Power Filter: Review of Converter Topologies and Control Strategies. Gazi University Journal of Science. 2011;24(2):283-9.