Integration methods for distributed sound sources

Roberto Merino-Martínez; Pieter Sijtsma; Alejandro Rubio Carpio; Riccardo Zamponi; Salil Luesutthiviboon; Anwar M.N. Malgoezar; Mirjam Snellen; Christophe Schram; Dick G. Simons

doi:10.1177/1475472X19852945

Integration methods for distributed sound sources

Roberto Merino-Martínez^*, Pieter Sijtsma, Alejandro Rubio Carpio, Riccardo Zamponi, Salil Luesutthiviboon, Anwar M.N. Malgoezar, Mirjam Snellen, Christophe Schram, Dick G. Simons

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

36 Citations (Scopus)

102 Downloads (Pure)

Abstract

Most acoustic imaging methods assume the presence of point sound sources and, hence, may fail to correctly estimate the sound emissions of distributed sound sources, such as trailing-edge noise. In this contribution, three integration techniques are suggested to overcome this issue based on models considering a single point source, a line source, and several line sources, respectively. Two simulated benchmark cases featuring distributed sound sources are employed to compare the performance of these integration techniques with respect to other well-known acoustic imaging methods. The considered integration methods provide the best performance in retrieving the source levels and require short computation times. In addition, the negative effects of the presence of unwanted noise sources, such as corner sources in wind-tunnel measurements, can be eliminated. A sensitivity analysis shows that the integration technique based on a line source is robust with respect to the choice of the integration area (shape, position, and mesh fineness). This technique is applied to a trailing-edge-noise experiment in an open-jet wind tunnel featuring a NACA 0018 airfoil. The location and far-field noise emissions of the trailing-edge line source were calculated.

Original language	English
Pages (from-to)	444-469
Number of pages	26
Journal	International Journal of Aeroacoustics
Volume	18
Issue number	4-5
DOIs	https://doi.org/10.1177/1475472X19852945
Publication status	Published - 2019

Keywords

Acoustic imaging
integration methods
porous trailing edge
trailing-edge noise

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10.1177/1475472X19852945

1475472x19852945Final published version, 1.82 MBLicence: CC BY-NC

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title = "Integration methods for distributed sound sources",

abstract = "Most acoustic imaging methods assume the presence of point sound sources and, hence, may fail to correctly estimate the sound emissions of distributed sound sources, such as trailing-edge noise. In this contribution, three integration techniques are suggested to overcome this issue based on models considering a single point source, a line source, and several line sources, respectively. Two simulated benchmark cases featuring distributed sound sources are employed to compare the performance of these integration techniques with respect to other well-known acoustic imaging methods. The considered integration methods provide the best performance in retrieving the source levels and require short computation times. In addition, the negative effects of the presence of unwanted noise sources, such as corner sources in wind-tunnel measurements, can be eliminated. A sensitivity analysis shows that the integration technique based on a line source is robust with respect to the choice of the integration area (shape, position, and mesh fineness). This technique is applied to a trailing-edge-noise experiment in an open-jet wind tunnel featuring a NACA 0018 airfoil. The location and far-field noise emissions of the trailing-edge line source were calculated.",

keywords = "Acoustic imaging, integration methods, porous trailing edge, trailing-edge noise",

author = "Roberto Merino-Mart{\'i}nez and Pieter Sijtsma and Carpio, {Alejandro Rubio} and Riccardo Zamponi and Salil Luesutthiviboon and Malgoezar, {Anwar M.N.} and Mirjam Snellen and Christophe Schram and Simons, {Dick G.}",

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doi = "10.1177/1475472X19852945",

language = "English",

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AU - Merino-Martínez, Roberto

AU - Sijtsma, Pieter

AU - Carpio, Alejandro Rubio

AU - Zamponi, Riccardo

AU - Luesutthiviboon, Salil

AU - Malgoezar, Anwar M.N.

AU - Snellen, Mirjam

AU - Schram, Christophe

AU - Simons, Dick G.

PY - 2019

Y1 - 2019

N2 - Most acoustic imaging methods assume the presence of point sound sources and, hence, may fail to correctly estimate the sound emissions of distributed sound sources, such as trailing-edge noise. In this contribution, three integration techniques are suggested to overcome this issue based on models considering a single point source, a line source, and several line sources, respectively. Two simulated benchmark cases featuring distributed sound sources are employed to compare the performance of these integration techniques with respect to other well-known acoustic imaging methods. The considered integration methods provide the best performance in retrieving the source levels and require short computation times. In addition, the negative effects of the presence of unwanted noise sources, such as corner sources in wind-tunnel measurements, can be eliminated. A sensitivity analysis shows that the integration technique based on a line source is robust with respect to the choice of the integration area (shape, position, and mesh fineness). This technique is applied to a trailing-edge-noise experiment in an open-jet wind tunnel featuring a NACA 0018 airfoil. The location and far-field noise emissions of the trailing-edge line source were calculated.

AB - Most acoustic imaging methods assume the presence of point sound sources and, hence, may fail to correctly estimate the sound emissions of distributed sound sources, such as trailing-edge noise. In this contribution, three integration techniques are suggested to overcome this issue based on models considering a single point source, a line source, and several line sources, respectively. Two simulated benchmark cases featuring distributed sound sources are employed to compare the performance of these integration techniques with respect to other well-known acoustic imaging methods. The considered integration methods provide the best performance in retrieving the source levels and require short computation times. In addition, the negative effects of the presence of unwanted noise sources, such as corner sources in wind-tunnel measurements, can be eliminated. A sensitivity analysis shows that the integration technique based on a line source is robust with respect to the choice of the integration area (shape, position, and mesh fineness). This technique is applied to a trailing-edge-noise experiment in an open-jet wind tunnel featuring a NACA 0018 airfoil. The location and far-field noise emissions of the trailing-edge line source were calculated.

KW - Acoustic imaging

KW - integration methods

KW - porous trailing edge

KW - trailing-edge noise

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Integration methods for distributed sound sources

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Keywords

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