A study of the position of the reference microphone of active noise control of feedforward type for MRI noise

Kenji Muto; Shohei Nakayama; Ryosuke Osada; Kazuo Yagi; Guoyue Chen

A study of the position of the reference microphone of active noise control of feedforward type for MRI noise

Kenji Muto, Shohei Nakayama, Ryosuke Osada, Kazuo Yagi, Guoyue Chen

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Magnetic resonance imaging (MRI) devices generate loud acoustical noise during operation. The sound pressure level of the MRI noise depends on the imaging sequence, but it is generally 100 dB or more. Our current study is aimed at the improvement of the acoustical environment for the MRI patient by means of an active noise control system. We propose using a feedforward system because acoustical MRI noise typically comprises unsteady pulse waves. It is important for a feedforward system that the reference microphone is located near the sound source. Here, we discuss the measurement of the sound source of MRI acoustical noise to position a reference microphone and show the effect of reference microphone position in an active noise control system by computer simulation. The apparent source of MRI acoustical noise was estimated from the delay time of the cross correlation between the signals of two microphones on the table in the MRI gantry. The result indicates that the apparent source lies between the center and edge of the gantry. Computer simulation shows that the proposed system produces substantial noise reduction when the reference microphone is attached in the vicinity of the apparent origin of the sound, such as in the wall of the scanner.

Original language	English
Title of host publication	INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering
Subtitle of host publication	Improving the World Through Noise Control
Editors	John Davy, Marion Burgess, Charles Don, Liz Dowsett, Terry McMinn, Norm Broner
Publisher	Australian Acoustical Society
ISBN (Electronic)	9780909882037
Publication status	Published - 2014 Jan 1
Event	43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, INTERNOISE 2014 - Melbourne, Australia Duration: 2014 Nov 16 → 2014 Nov 19

Publication series

Name	INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control

Conference

Conference	43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, INTERNOISE 2014
Country/Territory	Australia
City	Melbourne
Period	14/11/16 → 14/11/19

Keywords

MRI acoustical noise
Reference microphone
Sound source

ASJC Scopus subject areas

Acoustics and Ultrasonics

Cite this

Muto, K., Nakayama, S., Osada, R., Yagi, K., & Chen, G. (2014). A study of the position of the reference microphone of active noise control of feedforward type for MRI noise. In J. Davy, M. Burgess, C. Don, L. Dowsett, T. McMinn, & N. Broner (Eds.), INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control (INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control). Australian Acoustical Society.

A study of the position of the reference microphone of active noise control of feedforward type for MRI noise. / Muto, Kenji; Nakayama, Shohei; Osada, Ryosuke et al.
INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control. ed. / John Davy; Marion Burgess; Charles Don; Liz Dowsett; Terry McMinn; Norm Broner. Australian Acoustical Society, 2014. (INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Muto, K, Nakayama, S, Osada, R, Yagi, K & Chen, G 2014, A study of the position of the reference microphone of active noise control of feedforward type for MRI noise. in J Davy, M Burgess, C Don, L Dowsett, T McMinn & N Broner (eds), INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control. INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, Australian Acoustical Society, 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, INTERNOISE 2014, Melbourne, Australia, 14/11/16.

Muto K, Nakayama S, Osada R, Yagi K, Chen G. A study of the position of the reference microphone of active noise control of feedforward type for MRI noise. In Davy J, Burgess M, Don C, Dowsett L, McMinn T, Broner N, editors, INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control. Australian Acoustical Society. 2014. (INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control).

Muto, Kenji ; Nakayama, Shohei ; Osada, Ryosuke et al. / A study of the position of the reference microphone of active noise control of feedforward type for MRI noise. INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control. editor / John Davy ; Marion Burgess ; Charles Don ; Liz Dowsett ; Terry McMinn ; Norm Broner. Australian Acoustical Society, 2014. (INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control).

@inproceedings{44f10ced2e0340c6baea480e4e374011,

title = "A study of the position of the reference microphone of active noise control of feedforward type for MRI noise",

abstract = "Magnetic resonance imaging (MRI) devices generate loud acoustical noise during operation. The sound pressure level of the MRI noise depends on the imaging sequence, but it is generally 100 dB or more. Our current study is aimed at the improvement of the acoustical environment for the MRI patient by means of an active noise control system. We propose using a feedforward system because acoustical MRI noise typically comprises unsteady pulse waves. It is important for a feedforward system that the reference microphone is located near the sound source. Here, we discuss the measurement of the sound source of MRI acoustical noise to position a reference microphone and show the effect of reference microphone position in an active noise control system by computer simulation. The apparent source of MRI acoustical noise was estimated from the delay time of the cross correlation between the signals of two microphones on the table in the MRI gantry. The result indicates that the apparent source lies between the center and edge of the gantry. Computer simulation shows that the proposed system produces substantial noise reduction when the reference microphone is attached in the vicinity of the apparent origin of the sound, such as in the wall of the scanner.",

keywords = "MRI acoustical noise, Reference microphone, Sound source",

author = "Kenji Muto and Shohei Nakayama and Ryosuke Osada and Kazuo Yagi and Guoyue Chen",

year = "2014",

month = jan,

day = "1",

language = "English",

series = "INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control",

publisher = "Australian Acoustical Society",

editor = "John Davy and Marion Burgess and Charles Don and Liz Dowsett and Terry McMinn and Norm Broner",

booktitle = "INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering",

note = "43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, INTERNOISE 2014 ; Conference date: 16-11-2014 Through 19-11-2014",

}

TY - GEN

T1 - A study of the position of the reference microphone of active noise control of feedforward type for MRI noise

AU - Muto, Kenji

AU - Nakayama, Shohei

AU - Osada, Ryosuke

AU - Yagi, Kazuo

AU - Chen, Guoyue

PY - 2014/1/1

Y1 - 2014/1/1

N2 - Magnetic resonance imaging (MRI) devices generate loud acoustical noise during operation. The sound pressure level of the MRI noise depends on the imaging sequence, but it is generally 100 dB or more. Our current study is aimed at the improvement of the acoustical environment for the MRI patient by means of an active noise control system. We propose using a feedforward system because acoustical MRI noise typically comprises unsteady pulse waves. It is important for a feedforward system that the reference microphone is located near the sound source. Here, we discuss the measurement of the sound source of MRI acoustical noise to position a reference microphone and show the effect of reference microphone position in an active noise control system by computer simulation. The apparent source of MRI acoustical noise was estimated from the delay time of the cross correlation between the signals of two microphones on the table in the MRI gantry. The result indicates that the apparent source lies between the center and edge of the gantry. Computer simulation shows that the proposed system produces substantial noise reduction when the reference microphone is attached in the vicinity of the apparent origin of the sound, such as in the wall of the scanner.

AB - Magnetic resonance imaging (MRI) devices generate loud acoustical noise during operation. The sound pressure level of the MRI noise depends on the imaging sequence, but it is generally 100 dB or more. Our current study is aimed at the improvement of the acoustical environment for the MRI patient by means of an active noise control system. We propose using a feedforward system because acoustical MRI noise typically comprises unsteady pulse waves. It is important for a feedforward system that the reference microphone is located near the sound source. Here, we discuss the measurement of the sound source of MRI acoustical noise to position a reference microphone and show the effect of reference microphone position in an active noise control system by computer simulation. The apparent source of MRI acoustical noise was estimated from the delay time of the cross correlation between the signals of two microphones on the table in the MRI gantry. The result indicates that the apparent source lies between the center and edge of the gantry. Computer simulation shows that the proposed system produces substantial noise reduction when the reference microphone is attached in the vicinity of the apparent origin of the sound, such as in the wall of the scanner.

KW - MRI acoustical noise

KW - Reference microphone

KW - Sound source

UR - http://www.scopus.com/inward/record.url?scp=84923535127&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84923535127&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:84923535127

T3 - INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control

BT - INTERNOISE 2014 - 43rd International Congress on Noise Control Engineering

A2 - Davy, John

A2 - Burgess, Marion

A2 - Don, Charles

A2 - Dowsett, Liz

A2 - McMinn, Terry

A2 - Broner, Norm

PB - Australian Acoustical Society

T2 - 43rd International Congress on Noise Control Engineering: Improving the World Through Noise Control, INTERNOISE 2014

Y2 - 16 November 2014 through 19 November 2014

ER -

A study of the position of the reference microphone of active noise control of feedforward type for MRI noise

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Other files and links

Fingerprint

Cite this