WSEAS Transactions on Environment and Development


Print ISSN: 1790-5079
E-ISSN: 2224-3496

Volume 14, 2018

Notice: As of 2014 and for the forthcoming years, the publication frequency/periodicity of WSEAS Journals is adapted to the 'continuously updated' model. What this means is that instead of being separated into issues, new papers will be added on a continuous basis, allowing a more regular flow and shorter publication times. The papers will appear in reverse order, therefore the most recent one will be on top.


Volume 14, 2018



Study and Analysis of Performance of 3-Phase Shunt Active Filter in Grid-tied PV-Fuel Cell System Employing Sinusoidal Current Control Strategy

AUTHORS: Rudranarayan Senapati, Rajendra Narayan Senapati, Sonakshi Pradhan, Manoj Kumar Maharana

Download as PDF

ABSTRACT: This paper describes about mitigation of power quality issues using Shunt active filter in a Grid connected hybrid energy system consisting of PV-Battery-Fuel Cell. The Shunt active filter control is based on Sinusoidal Current Control Strategy. Shunt Active Power Filters (ShAPF) is implemented in the hybrid systems to mitigate the harmonic current component as well as to recompense the imaginary or reactive power owing to their exact and reckless operation. Sinusoidal current based controller used in a ShAPF has been focused over here. Sinusoidal current control strategy is utilized to extricate sinusoidal current commencing from the source. The sinusoidal Currents in addition with a stout synchronizing circuit (Phase Locked Loop or PLL circuit), custom a brief controller meant for ShAPF which is precise by a sinusoidal current control based controller in order to perform like a harmonic isolator amid supply and load. Action of the ShAPF under passive load conditions using non-linear load, the performance of the sinusoidal current control technique is evaluated using MATLAB R2016a. MATLAB simulation results validate the efficiency of the power filter system to mitigate harmonic, it also offered to validate the control strategy. Total Harmonic Distortion (THD) of voltage as well as of current determines the practical feasibility of controller designed for ShAPF to deliver a harmonic separation of passive loads.

KEYWORDS: Active Filters, Custom Power Devices, Distributed Generators, Harmonic Current Compensation, Power Quality, Shunt Active Power Filter, Sinusoidal Current Control Strategy

REFERENCES:

[1] Mauricio Aredes, Jurgen Hafner, Klemens Heumann, 'Three-Phase FourWire Shunt Active Filter Control Strategies,' IEEE Transactions on Power Electronics, Vol. 12, No. 2, pp. 311-318, March 1997J. Clerk Maxwell, A Treatise on Electricity and Magnetism, 3rd ed., vol. 2. Oxford: Clarendon, 1892, pp.68-73.

[2] Koteswara Rao Uyyuru, Mahesh K. Mishra, and Arindam Ghosh, “An Optimization-Based Algorithm for Shunt Active,” IEEE Transactions on Power Electronics, Vol. 24, No. 5, pp. 1223-1232, May 2009.

[3] Habi, M. Bouguerra, D. Ouahdi, and H. Meglouli, “Using the Schunt Active Power Filter for Compensation of the Distorted and Unbalanced Power System Voltage,” World Academy of Science, Engineering and Technology, Vol. 24, pp. 152-156, 2006.

[4] T.Sopapirm, K-N.Areerak, K-L.Areerak, A.Srikaew, “The Application of Adaptive Tabu Search Algorithm and Averaging Model to the Optimal Controller Design of Buck Converters,” World Academy of Science, Engineering and Technology, Volume 60, pp. 477-483, 2011.

[5] K.Chaijarurnudomrung, K-N.Areerak, KL.Areerak, and A.Srikaew, “The Controller Design of Three-Phase Controlled Rectifier Using an Adaptive Tabu Search Algorithm,” Proceedings of 8th Electrical Engineering/ Electronics, Computer, Telecommunications and Information Technology (ECTI), Thailand, 2011, pp.605- 608.

[6] K-N.Areerak, S.V.Bozhko, G.M.Asher, and D.W. P.Thomas, 'DQTransformation Approach for Modelling and Stability Analysis of AC-DC Power System with Controlled PWM Rectifier and Constant Power Loads,” Proceedings of 13th International Power Electronics and Motion Control Conference (EPE-PEMC 2008), 2008,pp. 2049-2054.

[7] T.Kulworawanichpong, K-L.Areerak, KN.Areerak, and S.Sujitjorn, 'Harmonic Identification for Active Power Filters Via Adaptive Tabu Search Method,” LNCS (Lecture Notes in Computer Science), SpringerVerlag Heidelberg, Volume 3215, 2004, pp. 687-694.

[8] D.Puangdownreong, K-N.Areerak, A.Srikaew, S.Sujijorn, and P.Totarong, 'System Identification via Adaptive Tabu Search,” Proceedings of IEEE International Conference on Industrial Technology (ICIT02), 2002, pp. 915-920.

[9] Ghosh, Arindam, and Gerard Ledwich. Power quality enhancement using custom power devices. Springer Science & Business Media, 2012.

[10] Bialasiewicz, Jan T. 'Renewable energy systems with photovoltaic power generators: Operation and modeling.' IEEE Transactions on industrial Electronics 55.7 (2008): 2752- 2758.

[11] Mohan, N., T. Ananthapadmanabha, and A. D. Kulkarni. 'A weighted multi-objective index based optimal distributed generation planning in distribution system.' Procedia Technology 21 (2015): 279-286.

[12] Mostafa, Haytham A., Ramadan El-Shatshat, and Magdy MA Salama. 'Multi-objective optimization for the operation of an electric distribution system with a large number of single phase solar generators.' IEEE Transactions on Smart Grid 4.2 (2013): 1038- 1047.

[13] van de Ven, Peter M., et al. 'Optimal control of end-user energy storage.' IEEE Transactions on Smart Grid 4.2 (2013): 789-797.

[14] Sahai, Yogeshwar, and Jia Ma. 'Advances in producing cost-effective direct borohydride fuel cells and road to its commercialization.' Energy Procedia 14 (2012): 358-363

[15] Joglekar, Jayesh, N. Gopalakrishnan, and Y. P. Nerkar. 'A Novel Power Grid Restoration Scheme Using Active PFC.' Procedia Technology 21 (2015): 256-263.

[16] Igba, Joel, et al. 'A systems approach towards reliability-centred maintenance (RCM) of wind turbines.' Procedia Computer Science 16 (2013): 814-823.

[17] Jain, Anjana, et al. 'Battery Charging Using Doubly Fed Induction Generator Connected to Variable Speed Wind Turbine.' Procedia Technology 21 (2015): 619-624.

[18] Kumar, Nallapaneni Manoj, M. S. P. Subathra, and Orville Damaso Cota. 'Design and Wind Tunnel Testing of Funnel Based Wind Energy Harvesting System.' Procedia Technology 21 (2015): 33-40.

[19] Gaviano, Antonello, Karl Weber, and Christian Dirmeier. 'Challenges and integration of PV and wind energy facilities from a smart grid point of view.' Energy Procedia 25 (2012): 118-125.

[20] Sulaiman, Shahril Irwan, et al. 'An artificial immune-based hybrid multi-layer feedforward neural network for predicting grid-connected photovoltaic system output.' Energy Procedia 14 (2012): 260-264.

[21] Peng, Li, and Gao-Shi Yan. 'Clean energy grid-connected technology based on smart grid.' Energy Procedia 12 (2011): 213-218.

[22] Kappagantu, Ramakrishna, S. Arul Daniel, and M. Venkatesh. 'Analysis of rooftop solar PV system implementation barrier in Puducherry Smart Grid Pilot Project.' Procedia Technology 21 (2015): 490-497.

[23] Potter, Cameron W., Allison Archambault, and Kenneth Westrick. 'Building a smarter smart grid through better renewable energy information.' Power Systems Conference and Exposition, 2009. PSCE'09. IEEE/PES. IEEE, 2009

[24] Priya, T. M., et al. 'Design and Analysis of a Sustainable LV Residential Microgrid.' Procedia Technology 21 (2015): 139-146.

[25] Sechilariu, Manuela, Baochao Wang, and Fabrice Locment. 'Building integrated photovoltaic system with energy storage and smart grid communication.' IEEE Transactions on Industrial Electronics 60.4 (2013): 1607-1618.

[26] Gaurav, Sonal, et al. 'Energy Management of PV–Battery Based Microgrid System.' Procedia Technology 21 (2015): 103- 111.

[27] Cirrincione, Maurizio, Marcello Pucci, and Gianpaolo Vitale. 'A single-phase DG generation unit with shunt active power filter capability by adaptive neural filtering.' IEEE Transactions on Industrial Electronics 55.5 (2008): 2093-2110.

[28] Hashempour, Mohammad M., et al. 'A control architecture to coordinate distributed generators and active power filters coexisting in a microgrid.' IEEE Transactions on Smart Grid 7.5 (2016): 2325-2336.

[29] Blaabjerg, Frede, et al. 'Overview of control and grid synchronization for distributed power generation systems.' IEEE Transactions on industrial electronics 53.5 (2006): 1398-1409.

[30] H. L. Willis and W. G. Scott, Distributed Power Generation Planning and Evaluation,Marcel Dekker, New York, 2000.

[31] Dugan, R. C., McGranaghan, M. F., & Beaty, H. W. (1996). Electrical power systems quality. New York, NY: McGraw-Hill,| c1996.

[32] Akagi, Hirofumi. 'New trends in active filters for power conditioning.' IEEE transactions on industry applications 32.6 (1996): 1312-1322.

[33] Athira, S., et al. 'An Optimization Algorithm for Voltage Flicker Analysis.' Procedia Technology 21 (2015): 589-595.

[34] IEEE Standard P1547, Distributed Resources Interconnected with Electric Power Systems, Draft 8, P1547 Working Group of IEEE SCC 21, T. Basso, Secretary.

[35] W. E. Feero, W. B. Gish, “Overvoltages Caused by DSG Operation: Synchronous and Induction Generators,” IEEE Transactions on Power Delivery, January 1986, pp.258–264.

[36] Saadat, Nima, S. S. Choi, and D. Mahinda Vilathgamuwa. 'A series-connected photovoltaic distributed generator capable of enhancing power quality.' IEEE Transactions on Energy Conversion 28.4 (2013): 1026-1035.

[37] Singh, Bhim, Kamal Al-Haddad, and Ambrish Chandra. 'A review of active filters for power quality improvement.' IEEE transactions on industrial electronics 46.5 (1999): 960-971.

[38] Hariri, Ali, and M. Omar Faruque. 'Impacts of distributed generation on power quality.' North American Power Symposium (NAPS), 2014. IEEE, 2014.

[39] Quiroga, G. A., et al. 'Study of the Distributed Generation impact on distributed networks, focused on quality of power.' Harmonics and Quality of Power (ICHQP), 2016 17th International Conference on. IEEE, 2016.

[40] Long, Zhao, et al. 'Harmonic current detection and suppression based on neural network.' Advanced Information Management, Communicates, Electronic and Automation Control Conference (IMCEC), 2016 IEEE. IEEE, 2016.

[41] Senthilkumar, A., et al. 'Mitigation of Harmonic Distortion in Microgrid System Using Adaptive Neural Learning Algorithm Based Shunt Active Power Filter.' Procedia Technology 21 (2015): 147-154.

[42] Ganesan, K., et al. 'Selective Harmonic Elimination of Cascaded Multilevel Inverter Using BAT Algorithm.' Procedia Technology 21 (2015): 651-657

[43] Jou, H-L., J-C. Wu, and K-D. Wu. 'Parallel operation of passive power filter and hybrid power filter for harmonic suppression.' IEE Proceedings-Generation, Transmission and Distribution 148.1 (2001): 8-14.

[44] Wu, Jinn-Chang, et al. 'A new hybrid power conditioner for suppressing harmonics and neutral-line current in three-phase four-wire distribution power systems.' IEEE Transactions on Power Delivery 29.4 (2014): 1525-1532

[45] Lee, Tzung-Lin, et al. 'Hybrid active filter with variable conductance for harmonic resonance suppression in industrial power systems.' IEEE Transactions on Industrial Electronics 62.2 (2015): 746-756.

[46] Herman, Leopold, Igor Papic, and Bostjan Blazic. 'A proportional-resonant current controller for selective harmonic compensation in a hybrid active power filter.' IEEE Transactions on Power Delivery 29.5 (2014): 2055-2065.

[47] Domijan, Alexander, et al. 'Custom power devices: An interaction study.' IEEE transactions on Power Systems 20.2 (2005): 1111-1118.

[48] Roldán-Pérez, Javier, et al. 'On the Power Flow Limits and Control in Series-Connected Custom Power Devices.' IEEE Transactions on Power Electronics 31.10 (2016): 7328- 7338.

[49] Ghosh, Arindam, and Gerard Ledwich. Power quality enhancement using custom power devices. Springer Science & Business Media, 2012.

[50] Ghosh, Arindam, and Avinash Joshi. 'The concept and operating principles of a mini custom power park.' IEEE transactions on power delivery 19.4 (2004): 1766-1774.

[51] Ghosh, Arindam. 'Performance study of two different compensating devices in a custom power park.' IEE Proceedings-Generation, Transmission and Distribution 152.4 (2005): 521-528.

[52] Domijan, Alexander, et al. 'Simulation study of the world's first distributed premium power quality park.' IEEE Transactions on Power Delivery 20.2 (2005): 1483-1492.

[53] Nielsen, John Godsk, and Frede Blaabjerg. 'A detailed comparison of system topologies for dynamic voltage restorers.' IEEE Transactions on Industry Applications 41.5 (2005): 1272- 1280

[54] Çetin, Alper, and Muammer Ermis. 'VSCbased D-STATCOM with selective harmonic elimination.' IEEE Transactions on Industry Applications 45.3 (2009): 1000-1015.

[55] Srivatchan, N. S., P. Rangarajan, and S. Rajalakshmi. 'Control Scheme for Power Quality Improvement in Islanded Microgrid Operation.' Procedia Technology 21 (2015): 212-215.

[56] Blazic, Bostjan, and Igor Papic. 'Improved DStatCom control for operation with unbalanced currents and voltages.' IEEE Transactions on Power Delivery 21.1 (2006): 225-233.

[57] Masand, Titiksha Jain1 Deepika. 'Zig-Zag Transformer and Three-Leg VSC based DSTATCOM for a Diesel Generator based Microgrid.' International Journal of Engineering Science 2537 (2016).

[58] Dinavahi, Venkata, Reza Iravani, and Richard Bonert. 'Design of a real-time digital simulator for a D-STATCOM system.' IEEE Transactions on Industrial Electronics 51.5 (2004): 1001-1008.

[59] Ghosh, Arindam, and Gerard Ledwich. 'Compensation of distribution system voltage using DVR.' IEEE Transactions on power delivery 17.4 (2002): 1030-1036.

[60] Zhan, Changjiang, et al. 'Dynamic voltage restorer based on voltage-space-vector PWM control.' IEEE transactions on Industry applications 37.6 (2001): 1855-1863.

[61] Ghosh, Arindam, and Gerard Ledwich. 'Compensation of distribution system voltage using DVR.' IEEE Transactions on power delivery 17.4 (2002): 1030-1036.

[62] Barros, J. Dionísio, and J. Fernando Silva. 'Multilevel optimal predictive dynamic voltage restorer.' IEEE Transactions on Industrial Electronics 57.8 (2010): 2747-2760.

[63] Benachaiba, C., et al. 'Power quality enhancement using DVR based on ant colony controller.' Power and Electrical Engineering of Riga Technical University (RTUCON), 2016 57th International Scientific Conference on. IEEE, 2016.

[64] Yao, Wenli, et al. 'Design and Analysis of Robust Active Damping for LCL Filters using Digital Notch Filters.' IEEE Transactions on Power Electronics 32.3 (2017): 2360-2375.

[65] Illindala, Mahesh, and Giri Venkataramanan. 'Frequency/sequence selective filters for power quality improvement in a microgrid.' IEEE Transactions on Smart Grid 3.4 (2012): 2039- 2047.

[66] Alhafadhi, Liqaa, Johnson Asumadu, and Amean Alsafi. 'Total harmonics distortion reduction using adaptive, Weiner, and Kalman filters.' Computing and Communication Workshop and Conference (CCWC), 2017 IEEE 7th Annual. IEEE, 2017.

[67] Dash, P. K., A. K. Pradhan, and G. Panda. 'Frequency estimation of distorted power system signals using extended complex Kalman filter.' IEEE Transactions on Power Delivery 14.3 (1999): 761-766.

[68] Sirjani, Reza, and Mehmet Kusaf. 'Optimal design of passive harmonic filters using Bee Colony Optimization.' HONET-ICT, 2016. IEEE, 2016.

[69] Darvishi, A., A. Alimardani, and S. H. Hosseinian. 'Fuzzy multi-objective technique integrated with differential evolution method to optimise power factor and total harmonic distortion.' IET generation, transmission & distribution 5.9 (2011): 921-929.

[70] Reddy, J. B. V., et al. 'Fast tracking of power quality disturbance signals using an optimized unscented filter.' IEEE Transactions on Instrumentation and Measurement 58.12 (2009): 3943-3952.

[71] Vural, Revna Acar, et al. 'Performance evaluation of evolutionary algorithms for optimal filter design.' IEEE Transactions on Evolutionary Computation 16.1 (2012): 135- 147.

[72] Akagi, Hirofumi, Edson Hirokazu Watanabe, and Mauricio Aredes. Instantaneous power theory and applications to power conditioning. Vol. 31. John Wiley & Sons, 2007.

[73] Akagi, Hirofumi, et al. 'Generalized theory of instantaneous reactive power and its application.' Electrical engineering in Japan 103.4 (1983): 58-66.

[74] Rahmani, Salem, et al. 'A new control technique for three-phase shunt hybrid power filter.' IEEE Transactions on industrial electronics 56.8 (2009): 2904-2915.

[75] Rahmani, Salem, Abdelhamid Hamadi, and Kamal Al-Haddad. 'A Lyapunov-functionbased control for a three-phase shunt hybrid active filter.' IEEE Transactions on Industrial Electro boosting.' Power Systems Conference, 2006. MEPCON 2006. Eleventh International Middle East. Vol. 1. IEEE, 2006.

[80] Aredes, Mauricio, and Edson H. Watanabe. 'New control algorithms for series and shunt three-phase four-wire active power filters.' IEEE Transactions on Power Delivery 10.3 (1995): 1649-1656.

[81] Buticchi, Giampaolo, et al. 'Single-phase series active power filter with transformercoupled matrix converter.' IET Power Electronics 9.6 (2016): 1279-1289.

[82] Swain, Sushree, Pravat Ray, and Kanungo Mohanty. 'Improvement of power quality using a robust hybrid series active power filter.' IEEE Transactions on Power Electronics (2016).

[83] Inoue, Shigenori, Toshihisa Shimizu, and Keiji Wada. 'Control methods and compensation characteristics of a series active filter for a neutral conductor.' IEEE Transactions on Industrial Electronics 54.1 (2007): 433-440.

[84] Dixon, Juan W., Gustavo Venegas, and Luis A. Moran. 'A series active power filter based on a sinusoidal current-controlled voltage-source inverter.' IEEE Transactions on Industrial Electronics 44.5 (1997): 612-620.

[85] Peng F.Z., Akagi H., Nabae A., ―A new approach to harmonic compensation in power systems—a combined system of shunt passive, series active filters‖, IEEE Trans. Ind. Appl. 26 (6), pp.983–990, 1990.

[86] Detjen, Dirk, et al. 'A new hybrid filter to dampen resonances and compensate harmonic currents in industrial power systems with power factor correction equipment.' IEEE Transactions on Power Electronics 16.6 (2001): 821-827.

[87] Singh, Bhim, et al. 'Hybrid filters for power quality improvement.' IEE ProceedingsGeneration, Transmission and Distribution 152.3 (2005): 365-378.

[88] Singh, Bhim, and Vishal Verma. 'An indirect current control of hybrid power filter for varying loads.' IEEE Transactions on power delivery 21.1 (2006): 178-184.

[89] Jou, H-L., et al. 'Novel power converter topology for three-phase four-wire hybrid power filter.' IET Power Electronics 1.1 (2008): 164-173.

[90] Hasan, Khairul Nisak Binti Md, et al. 'Harmonic compensation analysis in offshore wind power plants using hybrid filters.' IEEE Transactions on industry applications 50.3 (2014): 2050-2060

[91] Huang, Jin, and Haixia Shi. 'A hybrid filter for the suppression of common-mode voltage and differential-mode harmonics in three-phase inverters with CPPM.' IEEE Transactions on Industrial Electronics 62.7 (2015): 3991-4000.

[92] Gonzatti, Robson B., et al. 'Smart impedance: A new way to look at hybrid filters.' IEEE Transactions on Smart Grid 7.2 (2016): 837- 846.

[93] Lima, Francisco Kleber A., et al. 'A new proposal for DFIG grid-side converter as double-tuned hybrid filter to improve the power quality.' Industrial Electronics Society, IECON 2013-39th Annual Conference of the IEEE. IEEE, 2013.

[94] Ostroznik, Simon, Primoz Bajec, and Peter Zajec. 'A study of a hybrid filter.' IEEE Transactions on Industrial Electronics 57.3 (2010): 935-942.

[95] Jianben, Liu, et al. 'Modelling and industrial application of series hybrid active power filter.' IET Power Electronics 6.8 (2013): 1707-1714.

[96] Corasaniti, Victor Fabián, et al. 'Hybrid active filter for reactive and harmonics compensation in a distribution network.' IEEE Transactions on Industrial Electronics 56.3 (2009): 670-677.

[97] Nguyen, Trung Nhan, et al. 'Generalised design method for improving control quality of hybrid active power filter with injection circuit.' IET Power Electronics 7.5 (2014): 1204-1215.

[98] Inzunza, Rubén, and Hirofumi Akagi. 'A 6.6- kV transformerless shunt hybrid active filter for installation on a power distribution system.' IEEE Transactions on power electronics 20.4 (2005): 893-900.

[99] Swain, Sushree, Pravat Ray, and Kanungo Mohanty. 'Improvement of power quality using a robust hybrid series active power filter.' IEEE Transactions on Power Electronics (2016).

[100] Lam, C-S., M-C. Wong, and Y-D. Han. 'Hysteresis current control of hybrid active power filters.' IET Power Electronics 5.7 (2012): 1175-1187.

[101] Dey, Papan, and Saad Mekhilef. 'Current harmonics compensation with three-phase four-wire shunt hybrid active power filter based on modified D–Q theory.' IET Power Electronics 8.11 (2015): 2265-2280.

[102] Zobaa, Ahmed Faheem. 'Optimal multiobjective design of hybrid active power filters considering a distorted environment.' IEEE Transactions on Industrial Electronics 61.1 (2014): 107-114

[103] Wang, Lei, Chi-Seng Lam, and Man-Chung Wong. 'Unbalanced Control Strategy for A Thyristor-Controlled LC-Coupling Hybrid Active Power Filter in Three-Phase Three-Wire Systems.' IEEE Transactions on Power Electronics 32.2 (2017): 1056-1069

[104] Akagi, Hirofumi, and Takaaki Hatada. 'Voltage balancing control for a three-level diode-clamped converter in a medium-voltage transformerless hybrid active filter.' IEEE Transactions on Power Electronics 24.3 (2009): 571-579.

[105] Wang, Lei, et al. 'Non-linear adaptive hysteresis band pulse-width modulation control for hybrid active power filters to reduce switching loss.' IET Power Electronics 8.11 (2015): 2156-2167.

[106] Lam, Chi-Seng, et al. 'Adaptive DC-link voltage-controlled hybrid active power filters for reactive power compensation.' IEEE Transactions on power electronics 27.4 (2012): 1758-1772.

[107] Salmeron, Patricio, and Salvador P. Litran. 'A control strategy for hybrid power filters to compensate four-wires three-phase systems.' IEEE Transactions on Power Electronics 25.7 (2010): 1923-1931.

[108] Rahmani, Salem, et al. 'A combination of shunt hybrid power filter and thyristorcontrolled reactor for power quality.' IEEE Transactions on Industrial Electronics 61.5 (2014): 2152-2164.

[109] Hamadi, Abdelhamid, Salem Rahmani, and Kamal Al-Haddad. 'Digital control of a shunt hybrid power filter adopting a nonlinear control approach.' IEEE Transactions on Industrial Informatics 9.4 (2013): 2092-2104.

[110] Singh, Bhim, et al. 'Hybrid filters for power quality improvement.' IEEProceedingsGeneration, Transmission and Distribution 152.3 (2005): 365-378.

[111] Hamadi, Abdelhamid, Salem Rahmani, and Kamal Al-Haddad. 'Digital control of a shunt hybrid power filter adopting a nonlinear control approach.' IEEE Transactions on Industrial Informatics 9.4 (2013): 2092-2104.

[112] Bauer, Peter H., Michael A. Sartori, and Timothy M. Bryden. 'An IIR median hybrid filters.' IEEE Transactions on signal processing 40.5 (1992): 1068-1078.

[113] Campbell, M. R., R. E. Crochiere, and L. R. Rabiner. 'An algorithmic procedure for designing hybrid FIR/IIR digital filters.' Bell System Technical Journal 55.1 (1976): 89-108.

[114] Ferro, Humberto F., Luiz FO Chamon, and Cassio G. Lopes. 'FIR–IIR adaptive filters hybrid combination.' Electronics Letters 50.7 (2014): 501-503.

[115] Garanayak, Priyabrat, and Gayadhar Panda. 'Fast and accurate measurement of harmonic parameters employing hybrid adaptive linear neural network and filtered-x least mean square algorithm.' IET Generation, Transmission & Distribution 10.2 (2016): 421-436.

[116] van Schoor, George, Jacobus Daniel van Wyk, and Ian S. Shaw. 'Training and optimization of an artificial neural network controlling a hybrid power filter.' IEEE Transactions on Industrial Electronics 50.3 (2003): 546-553.

[117] He, Na, Dianguo Xu, and Lina Huang. 'The application of particle swarm optimization to passive and hybrid active power filter design.' IEEE transactions on industrial electronics 56.8 (2009): 2841-2851

[118] Luo, An, et al. 'Development of hybrid active power filter based on the adaptive fuzzy dividing frequency-control method.' IEEE transactions on power delivery 24.1 (2009): 424-432.

[119] Solanki, Jitendra, Norbert Fröhleke, and Joachim Böcker. 'Implementation of hybrid filter for 12-pulse thyristor rectifier supplying high-current variable-voltage DC load.' IEEE Transactions on Industrial Electronics 62.8 (2015): 4691-4701.

[120] Verma, Vishal, and Bhim Singh. 'Design and implementation of a current-controlled parallel hybrid power filter.' IEEE Transactions on Industry Applications 45.5 (2009): 1910-1917.

[121] Mulla, Mahmadasraf Abdulhamid, Chudamani Rajagopalan, and Anandita Chowdhury. 'Hardware implementation of series hybrid active power filter using a novel control strategy based on generalised instantaneous power theory.' IET Power Electronics 6.3 (2013): 592-600.

[122] Kesler, M.; Ozdemir, E., 'SynchronousReference-Frame-Based Control Method for UPQC under Unbalanced and Distorted Load Conditions', IEEE Transactions on Industrial Electronics, vol.58, no.9, pp.3967-3975, Sept. 2011.

[123] Fujita, Hideaki, and Hirofumi Akagi. 'The unified power quality conditioner: The integration of series active filters and shunt active filters.' Power Electronics Specialists Conference, 1996. PESC'96 Record., 27th Annual IEEE. Vol. 1. IEEE, 1996.

[124] Fujita, Hideaki, and Hirofumi Akagi. 'The unified power quality conditioner: the integration of series and shunt-active filters.' IEEE transactions on power electronics 13.2 (1998): 315-322.

[125] Sindhu, S., M. R. Sindhu, and T. N. P. Nambiar. 'An Exponential Composition Algorithm Based UPQC for Power Quality Enhancement.' Procedia Technology 21 (2015): 415-422.

[126] Kumar, A. Senthil, S. Rajasekar, and P. Ajay-D-Vimal Raj. 'Power quality profile enhancement of utility connected microgrid system using ANFIS-UPQC.' Procedia Technology 21 (2015): 112-119.

[127] Karelia, Nirav D., and Vivek J. Pandya. 'Distributed Generation and Role of UPQC– DG in Meeting Power Quality Criteria–A Review.' Procedia Technology 21 (2015): 520- 525.

[128] S. Ganguly, “Impact of Uni fi ed PowerQuality Conditioner Allocation on Line Loading , Losses , and Voltage Stability of Radial Distribution Systems,” IEEE Trans. Power Deliv., vol. 29, no. 4, pp. 1859–1867, 2014.

[129] Rajabi-Ghahnavieh, Abbas, et al. 'UPFC for enhancing power system reliability.' IEEE Transactions on Power Delivery 25.4 (2010): 2881-2890.

[130] Singh, Shiv P. 'Congestion mitigation using UPFC.' IET Generation, Transmission & Distribution 10.10 (2016): 2433-2442.

[131] Yang, Shuitao, et al. 'Modulation and control of transformerless UPFC.' IEEE Transactions on Power Electronics 31.2 (2016): 1050-1063.

[132] Guo, Jianjun, Mariesa L. Crow, and Jagannathan Sarangapani. 'An improved UPFC control for oscillation damping.' IEEE Transactions on Power Systems 24.1 (2009): 288-296.

[133] Wang, Keyou, et al. 'A novel real-time approach to unified power flow controller validation.' IEEE Transactions on Power Systems 25.4 (2010): 1892-1901.

[134] Aredes, Mauricio, Klemens Heumann, and Edson H. Watanabe. 'An universal active power line conditioner.' IEEE Transactions on Power Delivery 13.2 (1998): 545-551.

[135] Chakraborty, Sudipta, Manoja D. Weiss, and M. Godoy Simoes. 'Distributed intelligent energy management system for a single-phase high-frequency AC microgrid.' IEEE Transactions on Industrial electronics 54.1 (2007): 97-109.

[136] Chakraborty, Sudipta, and Marcelo G. Simoes. 'Experimental evaluation of active filtering in a single-phase high-frequency AC microgrid.' IEEE Transactions on energy conversion 24.3 (2009): 673-682

[137] Akagi, Hirofumi, Edson Hirokazu Watanabe, and Mauricio Aredes. Instantaneous power theory and applications to power conditioning. Vol. 31. John Wiley & Sons, 2007.

[138] Cavallini, A., Montanari, G. C., & Member, S. (1994). “Compensation Strategies for Shunt Active-Filter Control”, IEEE Transactions on Power Electronics, Vol. 9, issue.6, pp. 587 – 593,1994.

[139] Member, S. (1995). “New control algorithms for series and shunt three- phase four-wire active power filters”, ”, IEEE Transactions on Power Delivery, 10(3), 1649– 1656.

[140] Aredes, Mauricio, and Edson H. Watanabe. 'New control algorithms for series and shunt three-phase four-wire active power filters.' IEEE Transactions on Power Delivery 10.3 (1995): 1649-1656.

[141] Vodyakho, Oleg, and Chris C. Mi. 'Threelevel inverter-based shunt active power filter in three-phase three-wire and four-wire systems.' IEEE transactions on power electronics 24.5 (2009): 1350-1363.

[142] Akagi, Hirofumi. 'Control strategy and site selection of a shunt active filter for damping of harmonic propagation in power distribution systems.' IEEE Transactions on Power Delivery 12.1 (1997): 354-363.

[143] Benchaita, L., and S. Saadate. 'A comparison of voltage source and current source shunt active filter by simulation and experimentation.' IEEE transactions on power systems 14.2 (1999): 642-647.

[144] Routimo, Mikko, Mika Salo, and Heikki Tuusa. 'Comparison of voltage-source and current-source shunt active power filters.' IEEE Transactions on Power Electronics 22.2 (2007): 636-643.

[145] Jain, S. K., P. Agrawal, and H. O. Gupta. 'Fuzzy logic controlled shunt active power filter for power quality improvement.' IEE Proceedings-Electric Power Applications 149.5 (2002): 317-328.

[146] Akagi, Hirofumi, Sunt Srianthumrong, and Yasuhiro Tamai. 'Comparisons in circuit configuration and filtering performance between hybrid and pure shunt active filters.' Industry Applications Conference, 2003. 38th IAS Annual Meeting. Conference Record of the. Vol. 2. IEEE, 2003.

[147] Kale, Murat, and Engin Ozdemir. 'An adaptive hysteresis band current controller for shunt active power filter.' Electric Power Systems Research 73.2 (2005): 113-119.

[148] Tey, L. H., P. L. So, and Y. C. Chu. 'Improvement of power quality using adaptive shunt active filter.' IEEE transactions on power delivery 20.2 (2005): 1558-1568.

[149] Bhuvaneswari, G., and Manjula G. Nair. 'Design, simulation, and analog circuit implementation of a three-phase shunt active filter using the I cosθ algorithm.' IEEE transactions on power delivery 23.2 (2008): 1222-1235.

[150] Rahmani, Salem, Nassar Mendalek, and Kamal Al-Haddad. 'Experimental design of a nonlinear control technique for three-phase shunt active power filter.' IEEE Transactions on Industrial Electronics 57.10 (2010): 3364- 3375.

[151] Tang, Yi, et al. 'Generalized design of high performance shunt active power filter with output LCL filter.' IEEE Transactions on Industrial Electronics 59.3 (2012): 1443-1452.

[152] H. Akagi, E.H. Watanabe and M. Aredes, 'Instantaneous Power Theory and Applications to Power Conditioning,' John Wiley & Sons, Inc., New Jersey, 2007

WSEAS Transactions on Environment and Development, ISSN / E-ISSN: 1790-5079 / 2224-3496, Volume 14, 2018, Art. #3, pp. 24-47


Copyright © 2018 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution License 4.0

Bulletin Board

Currently:

The editorial board is accepting papers.


WSEAS Main Site