Active control of harmonic sound transmission into an acoustic enclosure using both structural and acoustic actuators

Kim, Sang-Myeong; Brennan, M.J.

doi:10.1121/1.428640

Cited by 67 publications

(42 citation statements)

References 14 publications

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“…Unexpected noise is often transmitted and radiated through these flexible boundaries into the interior cabin. Active noise and vibration control (ANVC) has been proven to be an efficient technique to control sound transmission (Pan and Hansen, 1990;Qiu, 1995;Banks, 1994;Koshigoe and Teagle, 1995;Koshigoe and Murdock, 1993b;Kim and Brennan, 2000;Al-Bassyiouni and Balachandran, 2005;Jin et al, 2009aJin et al, , 2009bJin et al, , 2009cLau and Tang, 2003;Tanak and Kobayashi, 2006;Kaizuka and Tanaka, 2007;Sun and Zhao, 2010). In analytical studies of active sound transmission control in such vibro-acoustic system, a rectangular cavity model with five rigid walls and one flexible thin plate cover was most frequently discussed, and has been of interest to many investigators with the aim of achieving physical insight so that an effective control system can be designed.…”

Section: Introductionmentioning

confidence: 98%

“…Banks (1994) and Koshigoe et al (1993bKoshigoe et al ( , 1995 also investigated the transmission of sound from an external source into a cavity and their controls, and Green's functions were used to model the equations for structural-acoustic coupling interaction. Kim and Brennan (2000) presented a theoretical and experimental investigation into the active control of sound transmission into a structural-acoustic coupled system using both structural and acoustic actuators, and the theoretical formulation was given using the impedance-mobility approach. Jin et al (2009b) presented a theoretical investigation on active control of sound transmission into a structural-acoustic coupled system using the radiation modes control approach.…”

Section: Introductionmentioning

confidence: 99%

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Control strategies and mechanisms for active control of sound transmission into a vibro-acoustic enclosure

Jin

Feng

Yang

2011

J. Marine. Sci. Appl.

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An analytical study was presented on active control of sound transmission into a vibro-acoustic enclosure comprising two flexible plates. Two types of actuators were used, i.e. acoustic actuator and distributed lead zirconate titanate piezoelectric (PZT) actuator instead of point force actuator. Using the modal acoustic transfer impedance-mobility matrices, the excitation and interaction in the coupled sound transmission system can be described with clear physical significance. With the control system designed to globally reduce the sound field, different control system configurations were considered, including the structural actuator on the incident plate, actuator on the receiving plate, acoustic actuator on the cavity, and their combinations. The effectiveness and performance of the control strategy corresponding to each system configuration were compared and discussed. The role and control mechanism of each type of actuator were of particular interest. It was shown that the incident plate actuator is effective in controlling the cavity-dominated modes and the structural modes dominated by the incident plate and receiving plate. Two main control mechanisms are involved in this control configuration, i.e., modal suppressing and modal rearrangement. For control system configuration with only acoustic actuator in the enclosure, the mechanism involved in this arrangement is purely modal suppression. Desirable placements of structural actuators in terms of total potential energy reduction were also discussed.

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Control strategies and mechanisms for active control of sound transmission into a vibro-acoustic enclosure

Jin

Feng

Yang

2011

J. Marine. Sci. Appl.

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“…One approach that has been investigated by other researchers is to place loudspeakers on the sides of the cavity of double-glazed windows as secondary sources [2]- [4]. However, this cavity control approach is not effective in controlling panel radiation-dominated sound [5]. The other approach is to use a small voice-coil actuator to vibrate the glass panel itself to generate the canceling sound [6].…”

Section: Introductionmentioning

confidence: 99%

Active Control of Sound Transmission Through Windows With Carbon Nanotube-Based Transparent Actuators

Rajamani

Stelson

et al. 2007

IEEE Trans. Contr. Syst. Technol.

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This paper explores the development of active sound transmission control systems for windows that can achieve a significant reduction in window noise transmission. Two major challenges need to be addressed in order to make the development of such noise blocking windows feasible. These are the need for a distributed actuation system that is optically transparent and the unavailability of a real-time reference signal that can be used by the active control system to provide advance information on the noise affecting the window. To address the first challenge, a transparent thin-film actuator (speaker) is first developed for the control system, which consists of a piezoelectric poly (vinylidene fluoride) (PVDF) thin film coated with compliant carbon nanotube-based transparent conductors on both sides. The developed thin-film speaker shows excellent acoustic response over a broadband frequency range, and has the advantages of being flexible, transparent, thin, and lightweight. To address the second challenge of providing a time-advanced reference signal from a moving noise source, a small microphone array distributed on the outside wall of the home is used. New noise source identification algorithms are employed, by which an appropriate microphone from the array can be chosen to provide a reference signal. Experimental results show that over 12 dB reduction in sound transmission is achieved globally in the case of broadband sound, which demonstrates the effectiveness of the control system in blocking sound transmission.Index Terms-Active noise control (ANC), carbon nanotubes, noise source identification, sound transmission, transparent thin-film actuator, windows.

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“…Part of the work focused on active control of structural sound radiation to a free field, while other on acoustic-structural coupled enclosures (such as Pan and Hansen, 1991;Snyder and Tanaka, 1993;Cazzolato, 1999;Kim and Brennan, 2000;Tanaka and Kobayashi, 2006;Hill et al, 2009;Li and Cheng, 2010 and references therein). Two active control strategies in this aspect are the global and local active controls, showing respective merits and limitations.…”

Section: Introductionmentioning

confidence: 99%

Virtual sensors for active noise control in acoustic–structural coupled enclosures using structural sensing: Robust virtual sensor design

Halim

2011

The Journal of the Acoustical Society of America

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The work was aimed to develop a robust virtual sensing design methodology for sensing and active control applications of vibro-acoustic systems. The proposed virtual sensor was designed to estimate a broadband acoustic interior sound pressure using structural sensors, with robustness against certain dynamic uncertainties occurring in an acoustic-structural coupled enclosure. A convex combination of Kalman sub-filters was used during the design, accommodating different sets of perturbed dynamic model of the vibro-acoustic enclosure. A minimax optimization problem was set up to determine an optimal convex combination of Kalman sub-filters, ensuring an optimal worst-case virtual sensing performance. The virtual sensing and active noise control performance was numerically investigated on a rectangular panel-cavity system. It was demonstrated that the proposed virtual sensor could accurately estimate the interior sound pressure, particularly the one dominated by cavitycontrolled modes, by using a structural sensor. With such a virtual sensing technique, effective active noise control performance was also obtained even for the worst-case dynamics.

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Active control of harmonic sound transmission into an acoustic enclosure using both structural and acoustic actuators

Cited by 67 publications

References 14 publications

Control strategies and mechanisms for active control of sound transmission into a vibro-acoustic enclosure

Control strategies and mechanisms for active control of sound transmission into a vibro-acoustic enclosure

Active Control of Sound Transmission Through Windows With Carbon Nanotube-Based Transparent Actuators

Virtual sensors for active noise control in acoustic–structural coupled enclosures using structural sensing: Robust virtual sensor design

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