Active noise control in a free field with virtual sensors

Kestell, Colin; Cazzolato, B.; Hansen, Colin H.

doi:10.1121/1.1326950

Cited by 46 publications

(34 citation statements)

References 4 publications

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“…This arrangement is based on the assumption that, at low frequencies, the spatial rate of change of the primary sound field is small at the physical and at the virtual microphone locations [7]. In the early 2000s, Kestell et al showed that the zone of quiet could be further extended using a virtual energy density sensor from the pressure and pressure gradient [22], considering that the weighted summation of pressure and velocity is much more spatially uniform than pressure only. It should also be noted that local control using phasedarray sensors was also suggested to achieve directionally sensitive detection through acoustic beam steering techniques [23], thereby producing acoustic beams which intersect to define a quiet area far away from the sensors.…”

Section: Introductionmentioning

confidence: 99%

Design of Remote Quiet Zones Using Spot-Type Sound Reducers

Boulandet¹,

Laurence²,

Lissek³

2017

Acta Acustica united with Acustica

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SummaryThis paper presents a local control approach to generate remote quiet zones. To deal with situations where global control can hardly be achieved, it is proposed to use an arrangement of spot-type sound reducers as originally suggested by Olson and May. Assuming that cross-coupling between control units is weak, each can be controlled independently and a decentralised feedback controller is implemented without the need for direct monitoring of the primary source. Active noise attenuation in the remote target region is achieved using a linear quadratic optimization based on prior knowledge of the transfer path of the system. The performance of a particular configuration comprising three control units is examined by numerical simulation and experimentally evaluated for a tonal noise source in a free-field environment. An average noise reduction of about 6 dB was measured in a target region of volume 0.25 × 0.25 × 0.25 m 3 for a 160 Hz tonal primary source distant more than one wavelength from the secondary sources. The performance of the control system in relation to changes in the primary field is also considered with a view to extending the concept to more realistic enclosed sound field conditions in future work.

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Section: Introductionmentioning

confidence: 99%

Design of Remote Quiet Zones Using Spot-Type Sound Reducers

Boulandet¹,

Laurence²,

Lissek³

2017

Acta Acustica united with Acustica

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“…With improvements in computer science, the application of complicated ANC algorithms has become feasible. Many researchers have attempted to improve the performance of ANC algorithms for real applications [2][3][4][5][6][7][8][9][10]. Among these ANC algorithms, the filtered-X least mean squares (FXLMS) algorithm is the most popular one.…”

Section: Introductionmentioning

confidence: 99%

“…Amongst many existing virtual microphone techniques, the remote microphone technique is widely used, which uses an additional filter to estimate virtual error signal from error signal of the physical microphone. There are some successful cases of applying this virtual microphone technique in the lab [4][5][6][7][8]. Pawelczyk proposed a prototype of an active headrest system by using FXLMS and the filtered-X least mean squares virtual microphone (FXLMS-VM) algorithm [7].…”

Section: Introductionmentioning

confidence: 99%

A Study of the Virtual Microphone Algorithm for ANC System Working in Audio Interference Environment

Wang

Lee

Qiu

2014

Journal of Low Frequency Noise, Vibration and Active Control

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Two kinds of anti-audio interference active noise control (ANC) algorithms are proposed based on a conventional filtered-X least mean squares virtual microphone (FXLMS-VM) algorithm. The proposed filtered-X least mean squares virtual microphone and anti-audio interference (FXLMS-VM-AI) algorithm employs an extra audio path to compensate for the influence of the audio interference phenomenon on the ANC adaptive filter. The proposed time frequency mixed filtered-X least mean squares virtual microphone and antiaudio interference (TFM-FXLMS-VM-AI) algorithm can overcomes this audio interference effect by calculating the coefficients of the ANC adaptive filter in the frequency domain. The time domain acoustic wave field simulation method is adopted to test the performance of the proposed ANC algorithms in an audio interference environment. By analyzing the simulation results, both proposed algorithms show better convergence accuracy in terms of the adaptive filter coefficients and better audio signal performance than the conventional algorithm. The proposed FXLMS-VM-AI algorithm has a faster convergence speed for the ANC adaptive filter than the proposed TFM-FXLMS-VM-AI algorithm. The proposed TFM-FXLMS-VM-AI algorithm has a lower computational complexity than the conventional algorithm and the proposed TFM-FXLMS-VM-AI algorithm.

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“…Kestell et al, University of Adelaide (Australia) describe active noise control under that employs virtual sensors [10]. Summarizing the pros and cons of the approach, authors report "in general the 'virtual energy density sensor' outperforms the actual energy density sensor, the actual microphone and the virtual microphone in terms of centering a practically sized zone of local control around an observer who is remotely located from any physical sensors; the virtual sensor algorithms however, are shown to be sensitive (by varying degrees) to short wavelength spatial pressure variations of the primary and secondary sound fields".…”

Section: Previous Workmentioning

confidence: 99%

“…Reference source not found., in which "virtual sensors" are discussed [2]- [10], the virtual sensors described in these references are either agents that reformat (perhaps taking into account some noise and error issues) data from real sensors, or they are ad hoc efforts that were handcrafted to meet the momentary needs of a specific narrow application.…”

Section: Introductionmentioning

confidence: 99%

Sensor modeling and simulation: can it pass the Turing test?

Siegel

VIMS 2001. 2001 IEEE International Workshop on Virtual and Intelligent Measurement Systems (IEEE Cat. No.01EX447)

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-The VIMS workshop encompasses both virtual instruments and "virtual sensors", but historically the latter are hardly represented in the program. This paper is not so much a research report as a friendly challenge to the VIMS community to begin thinking actively and creatively about this complementary aspect of our theme. In particular, it raises the question of what and how much we need to build into a virtual sensor agent for it to pass something analogous to the Turing Test, i.e., for a virtual sensor, as a "black-box", to be indistinguishable from a real sensor.

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Active noise control in a free field with virtual sensors

Cited by 46 publications

References 4 publications

Design of Remote Quiet Zones Using Spot-Type Sound Reducers

Design of Remote Quiet Zones Using Spot-Type Sound Reducers

A Study of the Virtual Microphone Algorithm for ANC System Working in Audio Interference Environment

Sensor modeling and simulation: can it pass the Turing test?

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