Normalized inverse characterization of sound absorbing rigid porous media

Zieliński, Tomasz G.

doi:10.1121/1.4919806

Cited by 34 publications

(22 citation statements)

References 39 publications

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“…Different inverse problems for parameter identifications have been attempted in the past regarding air-saturated porous media, mostly in the audio frequency regime [10,11,12,13,14]. The largest unaddressed issues of these studies are the modeling deficiency at these frequencies and the scarcity of uncertainty considerations.…”

Section: Introductionmentioning

confidence: 99%

Bayesian inference for the ultrasonic characterization of rigid porous materials using reflected waves by the first interface

Roncen

Fellah

Simon

et al. 2018

The Journal of the Acoustical Society of America

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The purpose of this paper is to present a method for the ultrasonic characterization of air-saturated porous media, by solving the inverse problem using only the reflected waves from the first interface to infer the porosity, the tortuosity, and the viscous and thermal characteristic lengths. The solution of the inverse problem relies on the use of different reflected pressure signals obtained under multiple obliquely incident waves, in the time domain. In this paper, the authors propose to solve the inverse problem numerically with a first level Bayesian inference method, summarizing the authors' knowledge on the inferred parameters in the form of posterior probability densities, exploring these densities using a Markov-Chain Monte-Carlo approach. Despite their low sensitivity to the reflection coefficient, it is still possible to extract the knowledge of the viscous and thermal characteristic lengths, allowing the simultaneous determination of all the physical parameters involved in the expression of the reflection operator. To further constrain the problem and guide the inference, the knowledge of a particular incident angle is used at one's advantage in order to more precisely define the thermal length, by effectively yielding a statistical relationship between tortuosity and characteristic length ratio.

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Section: Introductionmentioning

confidence: 99%

Bayesian inference for the ultrasonic characterization of rigid porous materials using reflected waves by the first interface

Roncen

Fellah

Simon

et al. 2018

The Journal of the Acoustical Society of America

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“…The relationship between the acoustic impedances does not only have to do with the modification of the amplitude of the incident wave: it is also related to the fraction of the incident energy that will be reflected or transmitted. Most of the acoustic properties of materials can be studied by the application of new laboratory and numerical methods as ultrasonic characterization [4], inverse characterization with basis on the acoustic impedance measurement [5], or ensemble averaged scattering [6].…”

Section: How Does Sound Insulation Occur?mentioning

confidence: 99%

How Do Acoustic Materials Work?

González¹

2019

Acoustics of Materials

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Acoustic quality of closed spaces is an increasing concern all around the world, since noise pollution is one of the main nowadays pollutants, but also one of the less considered when building designing and construction. In 2011, the World Health Organization stated that noise pollution should be treated as a public health concern: about 1 million years of human healthy life are lost yearly because of the environmental noise pollution, emphasizing on traffic noise in the cities. There are some physics phenomena that are the rule of thumb for room acoustic projects. This chapter introduces the main concepts about them: sound absorption, insulation, and diffusion. Their principles, main implementation, and computing are presented for each one.

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“…It suffices to invoke the general property that, because of the divergence-free nature of the fluid flow, the functions k 0 app (ω) and α 0 app (ω) necessarily are strictly decreasing functions of frequency: d dω k 0 app (ω) < 0 and d dω α 0 app (ω) < 0. Indeed, these are the inequalities (18) in Ref. [28], where the theory of asymptotic homogenization at two scales was used to derive the condition of incompressibility.…”

Section: A Extension Of the Acoustical Low Frequency Modeling For Rigmentioning

confidence: 99%

“…This model was later used in [17], where an inverse scattering problem was solved in the time domain to obtain both the static thermal permeability k 0 and the static viscous tortuosity α 0 simultaneously, using transmitted waves in the low-frequency range. Based on measurements of the surface impedance of a porous sample backed by different air gaps, the method developed by Zieliński [18] allowed the simultaneous retrieval of the 6 parameters of the Johnson-Champoux-Allard-Lafarge [4,19,7] JCAL model (φ, α ∞ , k 0 , Λ, Λ and k 0 ), using impedance tube experiments, in the frequency domain.…”

Section: Introductionmentioning

confidence: 99%

Acoustical modeling and Bayesian inference for rigid porous media in the low-mid frequency regime

Roncen

Fellah

Lafarge

et al. 2018

The Journal of the Acoustical Society of America

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In this paper, a modeling extension for the description of wave propagation in porous media at low-mid frequencies is introduced. To better characterize the viscous and inertial interactions between the fluid and the structure in this regime, two additional terms described by two parameters α1 and α2 are taken into account in the representation of the dynamic tortuosity in a Laurent-series on frequency. The model limitations are discussed. A sensitivity analysis is performed, showing that the influence of α1 and α2 on the acoustic response of porous media is significant. A general Bayesian inference is then conducted to infer simultaneously the posterior probability densities of the model parameters. The proposed method is based on the measurement of waves transmitted by a slab of rigid porous material, using a temporal model for the direct and inverse transmission problem. Bayesian inference results obtained on three different porous materials are presented, which suggest that the two additional parameters are accessible and help reducing systematic errors in the identification of other parameters: porosity, static viscous permeability, static viscous tortuosity, static thermal permeability and static thermal tortuosity.

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Normalized inverse characterization of sound absorbing rigid porous media

Cited by 34 publications

References 39 publications

Bayesian inference for the ultrasonic characterization of rigid porous materials using reflected waves by the first interface

Bayesian inference for the ultrasonic characterization of rigid porous materials using reflected waves by the first interface

How Do Acoustic Materials Work?

Acoustical modeling and Bayesian inference for rigid porous media in the low-mid frequency regime

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