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Bayesian Approach for the In Situ Estimation of the Acoustic Boundary Admittance

Chair of Vibroacoustics of Vehicles and Machines, School of Engineering and Design, Technical University of Munich, Boltzmannstraβe 15, 85748 Garching, Germany

E-mail Address: jonas.m.schmid@tum.de

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Martin Eser

https://orcid.org/0000-0001-8839-9826

Chair of Vibroacoustics of Vehicles and Machines, School of Engineering and Design, Technical University of Munich, Boltzmannstraβe 15, 85748 Garching, Germany

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, and

Steffen Marburg

https://orcid.org/0000-0001-6464-8015

Chair of Vibroacoustics of Vehicles and Machines, School of Engineering and Design, Technical University of Munich, Boltzmannstraβe 15, 85748 Garching, Germany

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https://doi.org/10.1142/S2591728523500135Cited by:1 (Source: Crossref)

Abstract

Interior acoustic problems require accurately representing the boundary conditions of all acoustically interacting surfaces to achieve precise acoustic predictions. The complex-valued boundary admittance fully characterizes these properties. Yet, conventional approaches to determine boundary admittances, such as the impedance tube, have limitations which do not accurately represent real-world conditions. This motivates in situ methods, where the acoustic boundary admittance is estimated in the actual mounting condition based on sound pressure measurements at certain observation points within the domain. In contrast to existing deterministic methods, a Bayesian approach is employed in this work, which provides probability distributions for the boundary admittances rather than point estimates. This offers valuable insights into the uncertainty associated with the estimation, proving beneficial for applications where a comprehensive understanding of uncertainty is desired. A finite element model is utilized to generate sound pressure data and serves as the forward model during the inference process. This makes it particularly suited for applications that involve pre-existing geometrical models, such as digital twin applications and model updating. The proposed method is applied to a two-dimensional car cabin model, demonstrating the framework’s efficacy in accurately inferring the acoustic boundary admittance using just ten observation points.

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References

1. M. Aretz and M. Vorländer , Efficient modelling of absorbing boundaries in room acoustic FE simulations, Acta Acust. United Acust. 96 (2010) 1042–1050. Crossref, Google Scholar
2. M. Aretz and M. Vorländer , Combined wave and ray based room acoustic simulations of audio systems in car passenger compartments, Part I: Boundary and source data, Appl. Acoust. 76 (2014) 82–99. Crossref, Google Scholar
3. M. Aretz and M. Vorländer , Combined wave and ray based room acoustic simulations of audio systems in car passenger compartments, Part II: Comparison of simulations and measurements, Appl. Acoust. 76 (2014) 52–65. Crossref, Google Scholar
4. M. Vorländer , Computer simulations in room acoustics: Concepts and uncertainties, J. Acoust. Soc. Am. 133 (2013) 1203–1213. Crossref, Google Scholar
5. S. Marburg and B. Nolte , Computational Acoustics of Noise Propagation in Fluids - Finite and Boundary Element Methods (Springer-Verlag, Berlin, 2008). Crossref, Google Scholar
6. S. Preuss, C. Gurbuz, C. Jelich, S. K. Baydoun and S. Marburg , Recent advances in acoustic boundary element methods, J. Theor. Comput. Acoust. 30 (2022) 2240002. Link, Google Scholar
7. C. Gurbuz and S. Marburg , Efficient analysis of energy-based surface contributions for an entire acoustic cavity, J. Theor. Comput. Acoust. 31 (2023) 2350002. Link, Google Scholar
8. ISO 354, Acoustics — measurement of sound absorption in a reverberation room (2003). Google Scholar
9. ISO 10534-1, Acoustics — determination of sound absorption coefficient and impedance in impedance tubes. Part 1: Method using standing wave ratio (1996). Google Scholar
10. ISO 10534-2, Acoustics — determination of sound absorption coefficient and impedance in impedance tubes. Part 2: Transfer function method (1998). Google Scholar
11. T. Thydal, F. Pind, C.-H. Jeong and A. P. Engsig-Karup , Experimental validation and uncertainty quantification in wave-based computational room acoustics, Appl. Acoust. 178 (2021) 107939. Crossref, Google Scholar
12. S. Marburg and H.-J. Hardtke , A study on the acoustic boundary admittance: Determination, results and consequences, Eng. Anal. Boundary Elem. 23 (1999) 737–744. Crossref, Google Scholar
13. B. Mondet, J. Brunskog, C.-H. Jeong and J. H. Rindel , From absorption to impedance: Enhancing boundary conditions in room acoustic simulations, Appl. Acoust. 157 (2020) 106884. Crossref, Google Scholar
14. E. Brandão, P. Mareze, A. Lenzi and A. R. da Silva , Impedance measurement of non-locally reactive samples and the influence of the assumption of local reaction, J. Acoust. Soc. Am. 133 (2013) 2722–2731. Crossref, Google Scholar
15. E. Brandão, A. Lenzi and S. Paul , A review of the in situ impedance and sound absorption measurement techniques, Acta Acust. united Acust. 101 (2015) 443–463. Crossref, Google Scholar
16. A. Tarantola , Inverse Problem Theory and Methods for Model Parameter Estimation (SIAM, Philadelphia, 2005). Crossref, Google Scholar
17. L. Chen and S. F. Wu , A modified Helmholtz equation least squares method for reconstructing vibroacoustic quantities on an arbitrarily shaped vibrating structure, J. Theor. Comput. Acoust. 29 (2021) 2150006. Link, Google Scholar
18. J. Kaipio and E. Somersalo , Statistical and Computational Inverse Problems, Applied Mathematical Sciences, Vol. 160 (Springer Science+Business Media, New York, 2005). Crossref, Google Scholar
19. M. Tamura , Spatial fourier transform method of measuring reflection coefficients at oblique incidence. I: Theory and numerical examples, J. Acoust. Soc. Am. 88 (1990) 2259–2264. Crossref, Google Scholar
20. M. Tamura, J. F. Allard and D. Lafarge , Spatial fourier–transform method for measuring reflection coefficients at oblique incidence. II. Experimental results, J. Acoust. Soc. Am. 97 (1995) 2255–2262. Crossref, Google Scholar
21. M. Nolan , Estimation of angle-dependent absorption coefficients from spatially distributed in situ measurements, J. Acoust. Soc. Am. 147 (2020) 119–124. Crossref, Google Scholar
22. A. Richard, E. Fernandez-Grande, J. Brunskog and C.-H. Jeong , Estimation of surface impedance at oblique incidence based on sparse array processing, J. Acoust. Soc. Am. 141 (2017) 4115–4125. Crossref, Google Scholar
23. E. Brandão and E. Fernandez-Grande , Analysis of the sound field above finite absorbers in the wave-number domain, J. Acoust. Soc. Am. 151 (2022) 3019–3030. Crossref, Google Scholar
24. M. Ottink, J. Brunskog, C.-H. Jeong, E. Fernandez-Grande, P. Trojgaard and E. Tiana-Roig , In situ measurements of the oblique incidence sound absorption coefficient for finite sized absorbers, J. Acoust. Soc. Am. 139 (2016) 41–52. Crossref, Google Scholar
25. J. Hald, W. Song, K. Haddad, C.-H. Jeong and A. Richard , In-situ impedance and absorption coefficient measurements using a double-layer microphone array, Appl. Acoust. 143 (2019) 74–83. Crossref, Google Scholar
26. A. Richard and E. Fernandez-Grande , Comparison of two microphone array geometries for surface impedance estimation, J. Acoust. Soc. Am. 146 (2019) 501. Crossref, Google Scholar
27. G. Carrillo, D. Fernández, D. Cabo and A. Prieto , Numerical study of in-situ acoustic impedance and reflection coefficient estimation of locally reacting surfaces with pressure-velocity probes, in Progress in Industrial Mathematics: Success Stories, Vol. 5, eds. M. Cruz, C. Parés and P. Quintela (Springer International Publishing, Cham, 2021), pp. 55–65. Crossref, Google Scholar
28. Z.-W. Luo, C.-J. Zheng, Y.-B. Zhang and C.-X. Bi , Estimating the acoustical properties of locally reactive finite materials using the boundary element method, J. Acoust. Soc. Am. 147 (2020) 3917–3931. Crossref, Google Scholar
29. G. Dutilleux, F. C. Sgard and U. R. Kristiansen , Low-frequency assessment of thein situ acoustic absorption of materials in rooms: An inverse problem approach using evolutionary optimization, Int. J. Numer. Methods Eng. 53 (2002) 2143–2161. Crossref, Google Scholar
30. R. Anderssohn and S. Marburg , Nonlinear approach to approximate acoustic boundary admittance in cavities, J. Comput. Acoust. 15 (2007) 63–79. Link, Google Scholar
31. G. P. Nava, Y. Yasuda, Y. Sato and S. Sakamoto , On the in situ estimation of surface acoustic impedance in interiors of arbitrary shape by acoustical inverse methods, Acoust. Sci. Technol. 30 (2009) 100–109. Crossref, Google Scholar
32. A. G. Prinn, A. Walther and E. A. P. Habets , Estimation of locally reacting surface impedance at modal frequencies using an eigenvalue approximation technique, J. Acoust. Soc. Am. 150 (2021) 2921–2935. Crossref, Google Scholar
33. A. Gelman, J. B. Carlin, H. S. Stern, D. B. Dunson, A. Vehtari and D. B. Rubin , Bayesian Data Analysis, Texts in Statistical Science Series, 3rd edn. (CRC Press/Taylor and Francis Group, Boca Raton, 2014). Google Scholar
34. C. J. Fackler, N. Xiang and K. V. Horoshenkov , Bayesian acoustic analysis of multilayer porous media, J. Acoust. Soc. Am. 144 (2018) 3582–3592. Crossref, Google Scholar
35. J.-D. Chazot, E. Zhang and J. Antoni , Acoustical and mechanical characterization of poroelastic materials using a bayesian approach, J. Acoust. Soc. Am. 131 (2012) 4584–4595. Crossref, Google Scholar
36. D. Beaton and N. Xiang , Room acoustic modal analysis using bayesian inference, J. Acoust. Soc. Am. 141 (2017) 4480–4493. Crossref, Google Scholar
37. J. Antoni , A bayesian approach to sound source reconstruction: Optimal basis, regularization, and focusing, J. Acoust. Soc. Am. 131 (2012) 2873–2890. Crossref, Google Scholar
38. J. M. Schmid, E. Fernandez-Grande, M. Hahmann, C. Gurbuz, M. Eser and S. Marburg , Spatial reconstruction of the sound field in a room in the modal frequency range using bayesian inference, J. Acoust. Soc. Am. 150 (2021) 4385–4394. Crossref, Google Scholar
39. N. Xiang, C. J. Fackler, Y. Hou and A. A. J. Schmitt , Bayesian design of broadband multilayered microperforated panel absorbers, J. Acoust. Soc. Am. 151 (2022) 3094–3103. Crossref, Google Scholar
40. D. Bush and N. Xiang , A model-based bayesian framework for sound source enumeration and direction of arrival estimation using a coprime microphone array, J. Acoust. Soc. Am. 143 (2018) 3934–3945. Crossref, Google Scholar
41. C. R. Landschoot and N. Xiang , Model-based bayesian direction of arrival analysis for sound sources using a spherical microphone array, J. Acoust. Soc. Am. 146 (2019) 4936–4946. Crossref, Google Scholar
42. D. Caviedes-Nozal, F. M. Heuchel, J. Brunskog, N. A. B. Riis and E. Fernandez-Grande , A bayesian spherical harmonics source radiation model for sound field control, J. Acoust. Soc. Am. 146 (2019) 3425–3435. Crossref, Google Scholar
43. J. Balint, F. Muralter, M. Nolan and C.-H. Jeong , Bayesian decay time estimation in a reverberation chamber for absorption measurements, J. Acoust. Soc. Am. 146 (2019) 1641–1649. Crossref, Google Scholar
44. N. Xiang, P. Goggans, T. Jasa and P. Robinson , Bayesian characterization of multiple-slope sound energy decays in coupled-volume systems, J. Acoust. Soc. Am. 129 (2011) 741–752. Crossref, Google Scholar
45. Y. Buot de l’Épine, J.-D. Chazot and J.-M. Ville , Bayesian identification of acoustic impedance in treated ducts, J. Acoust. Soc. Am. 138 (2015) EL114–EL119. Crossref, Google Scholar
46. A. Bockman, C. Fackler and N. Xiang , Bayesian-based estimation of acoustic surface impedance: Finite difference frequency domain approach, J. Acoust. Soc. Am. 137 (2015) 1658–1666. Crossref, Google Scholar
47. Z. Chen, N. Xiang and K. V. Horoshenkov , Boundary admittance estimation for wave-based acoustic simulations using bayesian inference, JASA Express Lett. 2 (2022) 081601. Crossref, Google Scholar
48. S. Marburg and R. Anderssohn , Fluid structure interaction and admittance boundary conditions: Setup of an analytical example, J. Comput. Acoust. 19 (2011) 63–74. Link, Google Scholar
49. M. Alnæs, J. Blechta, J. Hake, A. Johansson, B. Kehlet, A. Logg, C. Richardson, J. Ring, M. E. Rognes and G. N. Wells , The fenics project version 1.5 Arch. Numer. Softw. 3(100) (2015) 9–23. Google Scholar
50. N. Xiang , Model-based bayesian analysis in acoustics-a tutorial, J. Acoust. Soc. Am. 148 (2020) 1101–1120. Crossref, Google Scholar
51. D. Dowson and A. Wragg , Maximum-entropy distributions having prescribed first and second moments (corresp.), IEEE Trans. Inf. Theory 19 (1973) 689–693. Crossref, Google Scholar
52. P. Langer, M. Maeder, C. Guist, M. Krause and S. Marburg , More than six elements per wavelength: The practical use of structural finite element models and their accuracy in comparison with experimental results, J. Comput. Acoust. 25 (2017) 1750025. Link, Google Scholar
53. N. Metropolis, A. W. Rosenbluth, M. N. Rosenbluth, A. H. Teller and E. Teller , Equation of state calculations by fast computing machines, J. Chem. Phys. 21 (1953) 1087–1092. Crossref, Google Scholar
54. A. Gelman, D. Simpson and M. Betancourt , The prior can often only be understood in the context of the likelihood, Entropy 19 (2017) 555. Crossref, Google Scholar
55. S. Brooks , Handbook of Markov Chain Monte Carlo, Chapman & Hall/CRC - Handbooks of Modern Statistical Methods (CRC Press/Taylor & Francis, Boca Raton, 2011). Crossref, Google Scholar
56. M. D. Hoffman and A. Gelman , The no-u-turn sampler: Adaptively setting path lengths in hamiltonian monte carlo, J. Mach. Learn. Res. 15 (2014) 1593–1623. Google Scholar
57. S. Duane, A. D. Kennedy, B. J. Pendleton and D. Roweth , Hybrid monte carlo, Phys. Lett. B 195 (1987) 216–222. Crossref, Google Scholar
58. J. Salvatier, T. V. Wiecki and C. Fonnesbeck , Probabilistic programming in python using pymc3, PeerJ. Comput. Sci. 2 (2016) e55. Crossref, Google Scholar

Vol. 31, No. 04

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History

Received 21 July 2023

Revised 24 August 2023

Accepted 24 August 2023

Published: 4 November 2023

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This is an Open Access article published by World Scientific Publishing Company. It is distributed under the terms of the Creative Commons Attribution 4.0 (CC BY) License which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Bayesian Approach for the In Situ Estimation of the Acoustic Boundary Admittance

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