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Active noise control - a review of control-related problems

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Active noise control is a research area, where both acoustic and control related problems influence success of applications. The aim of the paper is to address the control aspects. After introducing active noise control in general, the fundamental state of the art is presented. The possible control techniques are discussed. Premises for the choice of feedforward, feedback and combined architectures are summarised. Single-channel and multi-channel systems are confronted. Benefits and drawbacks of continuous-time and discrete-time approaches are emphasised. Fixed-parameter and adaptive control systems are referenced. General control system requirements are formulated. Fundamental performance limitations are explained. Various control problem formulations including cost functions and constraints are presented for an exemplary structure.
Rocznik
Strony
509--520
Opis fizyczny
Bibliogr. 38 poz., rys.
Twórcy
  • Silesian University of Technology, Institute of Automatic Control, Akademicka 16, 44-101 Gliwice, Poland, Marek.Pawelczyk@polsl.pl
Bibliografia
  • [1] NELSON P.A., ELLIOTT S.J., Active Control of Sound, Academic Press, Cambridge 1994.
  • [2] KUO S.M., MORGAN D.R., Active Noise Control Systems. Algorithms and DSP Implementations, J. Wiley & Sons, New Jersey 1996.
  • [3] TOKHI M.O., LEITCH R.R., Active Noise Control, Clarendon Press, Oxford 1992.
  • [4] COANDA H., Procédé de protection contre les bruits [in French], French Patent, FR 722.274, 1930.
  • [5] LUEG P., Process of silencing sound oscillations, U.S. Patent, No 2,043,416, 1936.
  • [6] OLSON H.F., MAY E.G., Electronic sound absorber. Journal of the Acoustical Society of America, 25, 1130–1136 (1953).
  • [7] RUBINOWICZ A., Die Beugungswelle in der Kirchoffschen Theorie der Beugungserscheinungen [in German], Ann. Phys., 53, 257–278 (1917).
  • [8] JESSEL M., Some evidences for a general theory of active sound absorption, Proc. Inter Noise, 1979.
  • [9] CZARNECKI S., Investigations of sound transmission properties of a medium resulting from sound wave compensation caused by other sources, Journal of Sound and Vibration, 11, 225–233 (1970).
  • [10] ENGEL Z., Aktywna redukcja drgań i hałasu [in Polish], Proc. XI Symp. Drgania w Układach Fizycznych, Poznań, Poland, 1984, 124–125.
  • [11] ENGEL Z., Aktywne metody redukcji drgań i hałasu (rys historyczny, zadania, problemy) [in Polish], Proc. I Szkoła Metody Aktywne Redukcji Drga´n i Hałasu, Rabka-Kraków, 1993, 5–18.
  • [12] ENGEL Z., KOWAL J., Sterowanie Procesami Wibroakustycznymi [in Polish], Univesity of Mining and Metalurgy Press, Kraków 1995.
  • [13] ZAWIESKA W.M., Analiza i Synteza Układu Aktywnej Redukcji Hałasu [in Polish], Ph.D. Dissertation, University of Mining and Metalurgy, Kraków 1991.
  • [14] MAKAREWICZ G.J., Problemy stabilności w układach aktywnej redukcji dźwięku [in Polish], Ph.D. Dissertation, University of Mining and Metalurgy, Kraków 1993.
  • [15] OGONOWSKI Z., Adaptive noise control using direct method,Mat. XXII Zimowa Szkoła Zwalczania Zagrożeń Wibroakustycznych, Wisła, Poland, 1994, 65–66.
  • [16] PAWEŁCZYK M., Active Noise Control for Compact Acoustic Plants, JSCS, Gliwice 1999.
  • [17] BISMOR D., Adaptive Algorithms for Active Noise Control in an Acoustic Duct, JSCS, Gliwice 1999.
  • [18] TAMMI K., Identification and Active Feedback-Feedforward Control of Rotor, International Journal of Acoustics and Vibration, 12, 1, 7–14 (2007).
  • [19] RAFAELY B., ELLIOTT S.J., GARCIA–BONITO J., Broadband performance of an active headrests, Journal of the Acoustical Society of America, 106, 2, 787–793 (1999).
  • [20] TSENG W.K., RAFAELY B., ELLIOTT S.J., Performance limits and real-time implementation of a virtual microphone active headrest, Proc. ACTIVE’02, Southampton, UK, 2002, 1231–1242.
  • [21] KESTELL C., CAZZOLATO B., HANSEN C., Active noise control in a free field with a virtual microphone and a virtual energy density sensor, J. Acoustical Society of America, 48, 4, 475–483 (1999).
  • [22] PAWEŁCZYK M., Feedback Control of Acoustic Noise at Desired Locations, Habilitation Dissertation, Gliwice, Silesian University of Technology Press, No. 1684, (141), (2005).
  • [23] PAWEŁCZYK M., Adaptive noise control algorithms for active headrest system, Control Engineering Practice, 12, 9, 1101–1112 (2004).
  • [24] PAWEŁCZYK M., Multiple input-multiple output adaptive feedback control strategies for the active headrest system: design and real-time implementation, International Journal of Adaptive Control and Signal Processing, 17, 10, 785–800 (2003).
  • [25] ELLIOTT S.J., Signal Processing for Active Control, Academic Press, London 2001.
  • [26] FIGWER J. , BLA˙ZEJ M., Chaos in active noise control, Proc. 10th Int. Congress on Sound and Vibration, Stockholm, Sweden, 2003, 203–209.
  • [27] SIMON A., FLOWERS G.T., Adaptive Disturbance Rejection and Stabilisation for Rotor Systems with Internal Damping, International Journal of Acoustics and Vibration, 13, 2, 73–81 (2008).
  • [28] SERON M.M., BRASLAVSKY J.H., GOODWIN G.C., Fundamental Limitations in Filtering and Control, Springer-Verlag, London 1997.
  • [29] CHEN L., HANSEN C.H., HE F., SAMMUT K., Active Nonlinear Vibration Absorber Design for Flexible Structures, International Journal of Acoustics and Vibration, 12, 2, 51–59 (2007).
  • [30] CZYŻ K., Active Noise Control Systems with Nonuniform Signal Sampling, Ph.D. Dissertation, Gliwice, Institute of Automatic Control, Silesian University of Technology, 2006.
  • [31] RAFAELY B., Feedback Control of Sound, Ph.D. Thesis, University of Southampton, 1997.
  • [32] PAWEŁCZYK M., Optimal active noise control for time-varying plants [in Polish], Mat. XXXIV Zimowej Szkoły Zwalczania Zagrożeń Wibroakustycznych, Ustroń 2006.
  • [33] AKESSON H., SMIRNOVA T., CLAESSON I., HAKANSSON L., On the Development of a Simple and Robust Active Control System for Boring Bar Vibration in Industry, International Journal of Acoustics and Vibration, 12, 4, 139–152 (2007).
  • [34] SIMON A., FLOWERS G.T., Non-singleton Fuzzy Sets for Disturbance Attenuation, International Journal of Acoustics and Vibration, 12, 4, 171–178 (2007).
  • [35] ALAM M.S., TOKHI M.O., Design of Command Shaper using Gain-delay Units and Particle Swarm Optimisation Algorithm for Vibration Control of Flexible Systems, International Journal of Acoustics and Vibration, 12, 3, 99–108 (2007).
  • [36] MICHALCZYK M.I., Adaptive control algorithms for three-dimensional zones of quiet, JSCS, Gliwice 2004
  • [37] ENGEL Z., MAKAREWICZ G., ZAWIESKA W.M., MORZYŃSKI L., Metody Aktywne Redukcji Hałasu [in Polish], CIOP Press, Warszawa 2001.
  • [38] ZAWIESKA W.M., Wybrane zagadnienia aktywnej redukcji hałasu na przykładzie transformatorów [in Polish], CIOP Press, Warszawa 2007.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BAT8-0014-0015
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