Internal Model Control for a Light-Weight Active Noise-Reducing Casing

Mazur, K.; Pawełczyk, M.

doi:10.1515/aoa-2016-0032

Artykuł - szczegóły

Tytuł artykułu

Internal Model Control for a Light-Weight Active Noise-Reducing Casing

Autorzy

Mazur K. , Pawełczyk M.

Treść / Zawartość

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DOI

10.1515/aoa-2016-0032

Warianty tytułu

Języki publikacji

Abstrakty

The active noise-reducing casing developed and promoted by the authors in recent publications have multiple advantages over other active noise control methods. When compared to classical solutions, it allows for obtaining global reduction of noise generated by a device enclosed in the casing. Moreover, the system does not require loudspeakers, and much smaller actuators attached to the casing walls are used instead. In turn, when compared to passive casings, the walls can be made thinner, lighter and with much better thermal transfer than sound-absorbing materials. For active noise control a feedforward structure is usually used. However, it requires an in-advance reference signal, which can be difficult to be acquired for some applications. Fortunately, usually the dominant noise components are due to rotational operations of the enclosed device parts, and thus they are tonal and multitonal. Therefore, it can be adequately predicted and the Internal Model Control structure can be used to benefit from algorithms well developed for feedforward systems. The authors have already tested that approach for a rigid casing, where interaction of the walls was significantly reduced. In this paper the idea is further explored and applied for a light-weight casing, more frequently met in practice, where each vibrating wall of the casing influences all the other walls. The system is verified in laboratory experiments.

Słowa kluczowe

active noise-vibration control active structural acoustic control active casing Internal Model Control

Wydawca

Instytut Podstawowych Problemów Techniki PAN
Komitet Akustyki PAN
Polskie Towarzystwo Akustyczne

Czasopismo

Archives of Acoustics

Rocznik

2016

Tom

Vol. 41, No. 2

Strony

315--322

Opis fizyczny

Bibliogr. 26 poz., rys., tab., wykr., fot.

Twórcy

autor

Mazur K.

Krzysztof.Jan.Mazur@polsl.pl

Institute of Automatic Control, Silesian University of Technology, Akademicka 16, 44-100 Gliwice, Poland

autor

Pawełczyk M.

Marek.Pawelczyk@polsl.pl

Institute of Automatic Control, Silesian University of Technology, Akademicka 16, 44-100 Gliwice, Poland

Bibliografia

1. Bismor D. (2014), Partial Update LMS Algorithms in Active Noise Control, [in:] Proceedings of the Forum Acusticum 2014, Kraków.
2. Bismor D., Czyż K., Ogonowski Z. (2016), Review and Comparison of Variable Step-Size LMS Algorithms, International Journal of Acoustics and Vibration, 21, 1.
3. Elliott S. E., Stothers I. M., Nelson P. A. (1987), A Multiple Error LMS Algorithm and Its Application to the Active Control of Sound and Vibration, IEEE Transations on Acoustics, Speech and Signal Processing, ASSP-35, 10, 1423–1434.
4. Elliott S. J. (2001), Signal Processing for Active Control, Academic Press, London.
5. Fuller C., Mcloughlin M., Hildebrand S. (1994) (Apr. 28), Active acoustic transmission loss box, WO Patent App. PCT/US1992/008,401.
6. Górski P., Kozupa M. (2012), Variable Sound Insulation Structure with MFC Elements, Archives of Acoustics, 37, 1, 115–120.
7. Hasheminejad S. M., Rabbani V. (2015), Active Transient Sound Radiation Control from a Smart Piezocomposite Hollow Cylinder, Archives of Acoustics, 40, 3, 359–381.
8. Haykin S. S. (1996), Adaptive Filter Theory, Prentice- Hall information and system sciences series, Prentice Hall.
9. Leniowska L., Kos P. (2009), Self-tuning control with regularized RLS algorithm for vibration cancellation of a circular plate, Archives of Acoustics, 34, 4, 613–624.
10. Leniowska L., Mazan D. (2015), MFC Sensors and Actuators in Active Vibration Control of the Circular Plate, Archives of Acoustics, 40, 2, 257–265.
11. Mazur K. (2013), Active control of sound with a vibrating plate, Ph.D. thesis, Silesian University of Technology, Gliwice, Poland.
12. Mazur K., Pawełczyk M. (2011), Active noise-vibration control using the filtered-reference LMS algorithm with compensation of vibrating plate temperature variation, Archives of Acoustics, 36, 1, 65–76.
13. Mazur K., Pawełczyk M. (2013a), Active Noise Control with a single nonlinear control filter for a vibrating plate with multiple actuators., Archives of Acoustics, 38, 4.
14. Mazur K., Pawełczyk M. (2013b), Hammerstein nonlinear active noise control with the Filtered-Error LMS algorithm, Archives of Acoustics, 38, 2, 197–203.
15. Mazur K., Pawełczyk M. (2015a), Active control of noise emitted from a device casing, [in:] Proceedings of the 22nd International Congress of Sound and Vibration, Florence, Italy.
16. Mazur K., Pawełczyk M. (2015b), Multiple-error adaptive control of an active noise-reducing casing, [in:] Progress of Acoustics, pp. 701–712, Polish Acoustical Society, Wrocław.
17. Michalczyk M., Wieczorek M. (2011), Parameterization of adaptive control algorithms for multi-channel active noise control system, [in:] 58th Open Seminar on Acoustics joint with 2nd Polish-German Structured Conference on Acoustics, Jurata, Poland 13–16.09.2011, pp. 73–78, vol. 2.
18. Pietrzko S. J. (2009), Contributions to Noise and Vibration Control Technology, AGH – University of Science and Technology Press, Kraków.
19. Shehap A. M., Shawky H. A., El-Basheer T. M. (2016), Study and Assessment of Low Frequency Noise in Occupational Settings, Archives of Acoustics, 41, 1, 151–160.
20. Sibielak M., Raczka W., Konieczny J., Kowal J. (2015), Optimal control based on a modified quadratic performance index for systems disturbed by sinusoidal signals, Mechanical Systems and Signal Processing, 64, 498–519.
21. Szemela K. (2015), Sound Radiation from a Surface Source Located at the Bottom of the Wedge Region, Archives of Acoustics, 40, 2, 223–234.
22. Wiora J., Kozyra A., Wiora A. (2016), A weighted method for reducing measurement uncertainty below that which results from maximum permissible error, Measurement Science and Technology, 27.
23. Wrona S., Pawełczyk M. (2014), Active reduction of device multi-tonal noise by controlling vibration of multiple walls of the device casing, [in:] Proceedings of the 19th International Conference on Methods and Models in Automation and Robotics (MMAR), Międzyzdroje, Poland, pp. 687–692.
24. Wrona S., Pawełczyk M. (2016), Optimal placement of actuators for Active Structural Acoustic Control of a light-weight device casing, [in:] Proceedings of the 23nd International Congress of Sound and Vibration, Athens, Greece.
25. Wrona S., Pawełczyk M., Wyrwał J. (2014), Optimal placement of elastically mounted vibration actuators on a plate, for active noise-vibration control, [in:] Proceedings of 18th National Conference on Automatic Control, 8–10 September, Wrocław, Poland.
26. Zawieska W. M., Rdzanek W. P., Rdzanek W. J., Engel Z. (2007), Low frequency estimation for the sound radiation efficiency of some simply supported flat plates, Acta Acustica United with Acustica, 93, 3, 353–363.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.

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Bibliografia

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