Development of an Energy-Based Nearfield Acoustic Holography System

Harris, Michael C.

23 May 2005

Acoustical-based imaging techniques have found merit in determining the behavior of vibrating structures. These techniques are commonly used in numerous applications to obtain detailed noise source information and energy distributions on source surfaces. This thesis focuses on the continued development of the nearfield acoustic holography (NAH) approach. Conventional NAH consists of first capturing pressure data on a two-dimensional conformal measurement contour in the nearfield of the radiating source. These data are then propagated back to the vibrating structure to obtain the normal velocity profile on the source surface. With the source surface velocity profile known, the acoustic pressure, particle velocity, and intensity generated by the source can be reconstructed anywhere in space. The precision of source reconstruction is reliant upon accurate measurement of the pressure field at the hologram surface. For complex acoustic fields this requires fine spatial resolution and therefore demands large microphone arrays. In this thesis, a technique is developed for performing NAH using energy-based measurements. Recent advancements in the area of acoustic sensing technology have made particle velocity field information more readily available. Because energy-based measurements provide directional information about the field, a more accurate measurement of the pressure field is obtained. It is proposed that an energy-based system will significantly reduce the number of measurements required to perform NAH without sacrificing accuracy. Significantly reducing the number of measurements required to perform NAH will reduce the time, and therefore the expense, of using NAH as an analysis tool. Many potential applications exist for an improved NAH measurement method in the automobile and aerospace industries. These industries provide numerous large-scale applications where employing time-consuming scanning methods is not cost-effective. This is especially the case for airplane in-flight passenger noise tests, where the expense of operating the airplane is extremely high. Therefore, even a small savings in data acquisition time would be very beneficial.

nearfield acoustic holography

NAH

energy-based NAH

Mechanical Engineering

Caracterização vibroacustica usando holografia acustica de campo proximo / Vibroacoustic vharacterization using nearfield acoustic holography

Colinas, Nilton Gilber

08 February 1999

Orientador: Jose Maria Campos dos Santos / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-07-25T04:25:40Z (GMT). No. of bitstreams: 1 Colinas_NiltonGilber_M.pdf: 6668829 bytes, checksum: 0f5fe00364a351d5d5859c9c042c161c (MD5) Previous issue date: 1999 / Resumo: Neste trabalho procurou-se explorar a técnica de Holografia Acústica de Campo Próximo (Nearfield Acoustic Holography - NAB), que tem se mostrado como uma forma de análise para problemas vibroacústicos. A holografia é um processo que permite determinar as características de um campo de ondas acústicas usando a Transformada de Fourier Discreta (Discrete Fourier Transform - DFT), a partir de uma grade de pontos de medições regularmente espaçados obtidos em um ambiente acústico onde a função de Green é conhecida. O presente trabalho apresenta uma breve revisão dos princípios desta técnica com uma aplicação na reconstrução de propriedades vibroacústicas de estruturas. O campo de pressão, campo de velocidade das partículas e intensidade acústica gerados por um elemento estrutural vibrante foram as grandezas reconstruídas através da técnica NAH em diferentes posições do espaço. A fim de minimizar os problemas de leakage oriundos do processamento dos sinais, a Série de Fourier Discreta Regressiva (Regressive Discrete Fourier Series - RDFS) foi utilizada como alternativa às técnicas de janelamento do sinal. Resultados obtidos para uma estrutura do tipo placa são analisados, validados e comparados com previsões teóricas / Abstract: In this work, the Nearfield Acoustic Holography technique - NAH was explored as an way to analyze vibroacoustic problems. Holography is a process that allows to determine acoustic fields characteristics using a Discrete Fourier Transform - DFT, from a regular grid of measurements obtained in an acoustic environment for which the Green' s function is known. This work presents a brief principle's review of this technique with an application on the reconstruction of the vibroacoustic properties of structures. The pressure field, particle velocity field and acoustical intensity generated by a vibrating structural element were reconstructed through the NAH technique in different spatial positions. ln order to minimize spatial leakage problems from signal processing a Regressive Discrete Fourier Series ¿ RDFS was utilized as an alternative to windowing techniques. Results obtained from a plate type structure were analyzed, validated and compared with theoretical predictions / Mestrado / Mecanica dos Solidos / Mestre em Engenharia Mecânica

Holografia acústica

Vibração

Fourier, Transformadas de

Fourier, Séries de

Acoustic holography

Nearfield acoustic holography

Structural vibrations

Vibroacoustic

Noise Source Evaluation of Misalignment and Elastomeric Couplings using Nearfield Acoustic Holography

Filyayev, Anton A.

January 2017

No description available.

Mechanical Engineering

nearfield acoustic holography

misalignment

elastomeric couplings

fault detection

acoustics

microphone array

Application de l'holographie acoustique en soufflerie par mesures LDV / Application of acoustic holography in wind tunnel by means of LDV measurements

Parisot-Dupuis, Hélène

05 December 2012

L’ Holographie acoustique de champ proche (NAH) est une méthode d’imagerie acoustique robuste, mais son application en écoulement peut être limitée par l’utilisation de mesures intrusives de pression ou de vitesse acoustique. Dans cette étude, une procédure holographique applicable en écoulement utilisant des mesures de vitesse non-intrusives est proposée. Cette méthode est basée sur le théorème intégral de Kirchhoff-Helmholtz convecté. La fonction de Green convectée est alors utilisée pour déterminer des propagateurs spatiaux convectés définis dans l’espace réel et incluant l’effet d’un écoulement subsonique uniforme. Les transformées de Fourier discrètes de ces propagateurs permettent alors d’évaluer les champs acoustiques à partir de la mesure du champ de pression ou de vitesse acoustique normale. Le but étant de développer une méthode de caractérisation de sources aéroacoustiques à partir de mesures de vitesse non-intrusives, cette étude se concentre essentiellement sur les propagateurs réels convectés basés sur la mesure de vitesse acoustique. Afin de valider cette procédure,des simulations ont été menées dans le cas de combinaisons de sources monopolaires et dipolaires convectées corrélées ou non. La procédure holographique développée donne de bons résultats par comparaison aux champs acoustiques théoriques. Une comparaison des résultats obtenus par les propagateurs convectés réels, développés dans cette thèse, avec ceux obtenus par leurs formes spectrales, développés par Kwon et al. fin 2010 pour des mesures de pression acoustique, montre l’intérêt d’utiliser la forme réelle pour la reconstruction de la pression acoustique à partir de la mesure de vitesse acoustique normale. L’efficacité de la procédure développée est confirmée par une campagne de mesure en soufflerie avec un haut-parleur affleurant rayonnant au sein d’un écoulement à Mach 0.22, et des mesures non-intrusives effectuées par Vélocimétrie Laser Doppler (LDV). Les champs de vitesse acoustique utilisés pour la procédure holographique sont dans ce cas extraits des mesures LDV par corrélation avec un microphone de référence. La faisabilité de prendre en compte des variations de l’écoulement dans la direction de reconstruction holographique est également vérifiée. / Nearfield Acoustic Holography (NAH) is a powerful acoustic imaging method but its application in flow can be limited by intrusive measurements of acoustic pressure or velocity. In this work, a moving fluid medium NAH procedure using non-intrusive velocity measurements is proposed. This method is based on the convective Kirchhoff-Helmholtz integral formula. The convective Green’s function is then used to derive convective realspace propagators including uniform subsonic airflow effects. Discrete Fourier transforms of these propagators allow then the assessment of acoustic fields from acoustic pressure or normal acoustic velocity measurements. As the aim is to derive an aeroacoustic sources characterisation method from non-inrusive velocity measurements, this study is especially focused on real convective velocity-based propagators. In order to validate this procedure, simulations in the case of combinations of monopolar and dipolar sources correlated or not, radiating invarious uniform subsonic flows, have been performed. NAH provides very favorable results when compared to the theoretical fields. A comparison of results obtained by real convective propagators, developed in this work, and those obtained by the spectral ones, developed by Kwon et al. at the end of 2010 for acoustic pressure measurements, shows the interest of using the real-form for NAH acoustic pressure reconstruction from normal acoustic velocity measurements. The efficiency of the developed procedure is confirmed by a wind tunnel campaign with a flush-mounted loudspeaker radiating in a flow at Mach 0.22 and non-intrusive Laser Doppler Velocimetry (LDV) measurements. Acoustic velocity fields used for the NAH procedure are in this case extracted from LDV measurements by correlation with a reference microphone. The feasibility of taking into account mean flow variations in the direction of NAH reconstruction is also checked.

Holographie acoustique de champ proche

Aéroacoustique

Soufflerie

Vélocimétrie laser Doppler

Nearfield acoustic holography

Aeroacoustic

Wind tunnel

Laser Doppler velocimetry

532

Intensidade acustica supersonica : implementação e verificação / Supersonic acoustic intensity : implementation and evaluation

Moraes, Elson Cesar, 1976-

24 February 2006

Orientador: Jose Maria Campos dos Santos / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-08-08T16:32:33Z (GMT). No. of bitstreams: 1 Moraes_ElsonCesar_M.pdf: 10024919 bytes, checksum: 5229531ae57fbedd477ddafcf581d5b2 (MD5) Previous issue date: 2006 / Resumo: Neste trabalho apresenta-se uma implementação e avaliação experimental da grandeza acustica denominada de Intensidade Acustica Supersonica (IAS), a qual permite determinar a parcela da intensidade acustica de uma fonte sonora que sera radiada para o campo distante. Tal grandeza permite quantificar de forma mais precisa a eficiencia de radiação ou não de radiadores acusticos na solução dos problemas de vibroacustica. A IAS origina-se da Holografia Acustica de Campo Proximo (Nearfield Acoustic Holography - NAH) e tem por objetivo identificar as regiões de uma fonte de ru?do que contribuem para a potencia sonora radiada para o campo distante (supersonica) filtrando, consequentemente, a parcela referente as ondas sonoras recirculantes e evanescentes (subsonicas). O trabalho apresenta uma breve revisão teorica dos fundamentos da holografia acustica plana usando a transformada de Fourier e sua extensão para obtenção da Intensidade Acustica Supersonica. Com base no NAH para sistemas em coordenadas Cartesiano (holografia plana) implementou-se em linguagem MatLab um algoritmo do calculo da IAS e simulações em estrutura plana do tipo placa foram realizadas. Os resultados simulados foram verificados atraves de medições experimentais em uma placa real com as mesmas propriedades, dimensões, condições iniciais e de contorno. Os resultados obtidos são analisados e discutidos / Abstract: This work presents an experimental implementation and evaluation of the acoustic parameter named Supersonic Acoustic Intensity (SAI) which permits determining the part of the acoustic intensity of sound source that will be radiate to farfield. This parameter permits quantify precisely the radiation efficiency or acoustic radiator to solve the vibroacoustic problems. SAI had origin from Nearfield Acoustic Holography (NAH) it has as objective identify the regions of the sound source that contribute to the sound power radiated to the far field (supersonic) filtered out as a result the part of the sound recirculating and evanescence waves (subsonic). The work presents a brief theoretical review of the planar acoustic holography fundaments using the Fourier Transformed and its extension to obtain the supersonic acoustic intensity. With base in the NAH for coordinates systems (planar holography) it was implemented in MatLab language an algorithm from the SAI calculus and simulation in planar structure type plate were achieved. The simulated results were verified through experimental measurements in a realistic plate with the same properties, dimension, initial conditions and boundaries. The results obtained are analyzed and discussed. / Mestrado / Mecanica dos Sólidos e Projeto Mecanico / Mestre em Engenharia Mecânica

Holografica acustica

Som - Intensidade

Ondas acústicas superficiais

Vibração

Vibração - Medição

Nearfield acoustic holography

Supersonic acoustic intensity

Vibroacoustic