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Electrical Engineering

Erschienen in:

01.09.2015 | Original Paper

Comparative analysis of swarm optimization-based control method for direct matrix converter

verfasst von: Haluk Gozde

Erschienen in: Electrical Engineering | Ausgabe 3/2015

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Abstract

Direct matrix converter (DMC) is an AC–AC converter which supplies power flow between AC power supply and the load for changing voltage and current requirements. Its relatively small power circuits and simple control structures provide considerable advantages to itself with respect to the classical AC–AC converter topologies. In this article, the new control method based on swarm optimization is suggested and analyzed comparatively for 3-phase DMC to improve the robustness of DMC control system. The switching generator designed with this control method generates optimal switching states using swarm intelligence-based optimization algorithm and also applies them to the DMC. To compare the control performance of the method for this type of operating conditions, chaotic-based particle swarm optimization and artificial bee colony algorithms are used since their relatively short program codes and superior optimization performances. The results of this study show that the proposed control method can be applied to the DMC control system successfully as a new control technique.

Vorheriger Artikel A geometric algebra reformulation and interpretation of Steinmetz’s symbolic method and his power expression in alternating current electrical circuits

Nächster Artikel Generalized predictive control robust for position control of induction motor using field-oriented control

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Yamamoto E, Kume T, Hara H, Uchino T, Kang J, Krug H (2009) Development of matrix converter and its applications in industry. In: Proceedings of the 35th IEEE IECON, Porto, Portugal, pp 4–12

Wheeler P, Rodriguez J, Clare J, Empringham L, Weinstein A (2002) Matrix converters: a technology review. IEEE Trans Ind Electron 49(2):276–288CrossRef

Hazeltine LA (1923) An improved method of an apparatus for converting electronic power. US Patent 218675

Friedli T, Kolar JW (2012) Milestones in matrix converter research. IEEJ J Ind Appl 1(1):2–14

Venturini M (1980) A new sine wave in sine wave out conversion technique which eliminates reactive elements. In: Proceedings of the Powercon 7:E3/1–E3/15

Venturini M, Alesina A (1980) The generalized transformer: a new bidirectional sinusoidal waveform frequency converter with continuously adjustable input power factor. In: Proceedings of the IEEE PESC’80, pp 242–252

Rodriguez J, Rivera M, Kolar J, Wheeler P (2012) A review of control and modulation methods for matrix converters. IEEE Trans Ind Electron 59(1)

Muller S, Ammann U, Rees S (2005) New time-discrete modulation scheme for matrix converters. IEEE Trans Ind Electron 52(6):1607–1615CrossRef

Gamboa P, Pinto SF, Silva JF, Margato E (2007) Predictive optimal control of input and output currents in matrix converters. In: Proceedings of the POWERENG 2007, April 12–14, Satubal, Portugal, pp 529–533

10.

Rivera M, Correa P, Rodriguez J, Lizama I, Espinoza J, Rojas C (2009) Predictive control with active damping in a Direct Matrix Converter. IEEE Energy Convers Congress Expos ECCE 2009:3057–3062CrossRef

11.

Rodriguez J, Espinoza J, Rivera M, Villarroel F, Rojas C (2010) Predictive control of source and load currents in a direct matrix converter. IEEE international conference on industrial technology (ICIT), pp 1826–1831

12.

Villarroel F, Espinoza J, Rojas C, Molina C, Espinosa E (2010) A multiobjective ranking based finite states model predictive control scheme applied to a direct matrix converter. IECON 2010–36th annual conference on IEEE Industrial Electronics Society, pp 2941–2946

13.

Rojas C, Rivera M, Rodriguez J, Wilson A, Espinoza J, Villarroel F, Wheeler P (2010) Predictive control of a direct matrix converter operating under an unbalanced AC source. IEEE international symposium on industrial electronics (ISIE), pp 3159–3164

14.

Rivera M, Rojas C, Rodríguez J, Wheeler P, Wu B, Espinoza JR (2011) Predictive current control with input filter resonance mitigation for a direct matrix converter. IEEE Trans Power Electron 26(10)

15.

Rivera M, Rodríguez J, Wheeler PW, Rojas CA, Wilson A, Espinoza JR (2012) Control of a matrix converter with imposed sinusoidal source currents. IEEE Trans Ind Electron 59(4):1939–1949CrossRef

16.

Hosseini SH, Babaei E (2003) A new control algorithm for matrix converters under distorted and unbalanced conditions. CCA2003 IEEE Conf Control Appl 2:1088–1093

17.

Zanchetta P, Sumner M, Clare JC, Wheeler PW (2004) Control of matrix converters for AC power supplies using genetic algorithms. IEEE Int Symp Ind Electron 2:1429–1433

18.

Villarroel F, Espinoza J, Rojas C, Molina C, Rodriguez J (2011) Application of fuzzy decision making to the switching state selection in the predictive control of a Direct Matrix Converter. IECON 2011–37th annual conference on IEEE Industrial Electronics Society, pp 4272–4277

19.

Sivarani TS, Jawhar SJ, Kumar CA (2012) Novel intelligent hybrid techniques for speed control of electric drives fed by matrix converter. International conference on computing, electronics and electrical technologies (ICCEET), pp 466–471

20.

Ghoni R, Abdalla AN, Ibrahim T, Rifai D, Lubis Z (2012) A ripple minimization strategy for matrix converter using hybrid PSO. Procedia Eng 38:111–124CrossRef

21.

Gözde H, Taplamacioglu MC (2013) A simulation study of crazy-PSO controller for direct matrix converter. ELECO2013 IEEE international conference on electrical and electronics engineering, Bursa, Turkey, pp 107–111

22.

Kennedy J, Eberhart RC (1995) Particles swarm optimization. In: IEEE international conference on neural networks, pp 1942–1948

23.

Eberhart RC, Shi Y (1998) A modified particle swarm optimizer. In: IEEE international conference on evolutionary computation, pp 69–73

24.

Yang B, Chen Y, Zhao Z (2007) Survey on applications of particle swarm optimization in electric power systems. In: IEEE international conference on control and automation—ICCA2007, pp 481–486

25.

Park JB, Jeong YW, Kim HH, Shin JR (2006) An improved particle swarm optimization for economic dispatch with valve-point effect. Int J Innov Energy Syst Power 1(1):1–7

26.

Caponetto R, Fortuna L, Fazzino S, Xibilia MG (2003) Chaotic sequences to improve the performance of evolutionary algorithms. IEEE Trans Evol Comput 7(3):289–304CrossRef

27.

Niknam T, Narimani MR, Aghaei J, Azizipanah-Abarghooee R (2012) Improved particle swarm optimization for multi-objective optimal power flow considering the cost, loss, emission and voltage stability index. IET Gener Transm Distrib 6(6):515–527CrossRef

28.

Karaboğa D (2005) An idea based on honey bee swarm for numerical optimization. Technical Report-TR06, Erciyes University of Engineering, Faculty of Computer Engineering Department

29.

Karaboga D, Basturk B (2007) A powerful and efficient algorithm for numeric optimization: artificial bee colony (ABC) algorithm. J Glob Optim 39(3):459–471

30.

Blooming TM, Carnovale DJ (2005) Application of IEEE STD 519–1992 harmonic limits. In: 2005 IEEE IAS pulp and paper industry conference

Titel: Comparative analysis of swarm optimization-based control method for direct matrix converter
verfasst von: Haluk Gozde
Publikationsdatum: 01.09.2015
Verlag: Springer Berlin Heidelberg
Erschienen in: Electrical Engineering / Ausgabe 3/2015
Print ISSN: 0948-7921
Elektronische ISSN: 1432-0487
DOI: https://doi.org/10.1007/s00202-014-0327-9

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