Salta al menu principale di navigazione Salta al contenuto principale Salta al piè di pagina del sito
FrancoAngeli Journals

Articoli Scientifici

2026-online first

Preliminary analysis of an in-situ measurement system for normal-incidence absorption coefficient using a microphone array

DOI
https://doi.org/10.3280/riaof-2026oa21889
Inviata
19 gennaio 2026
Pubblicato
20-04-2026

Abstract

Analisi preliminare di un sistema di misura in situ per il coefficiente di assorbimento a incidenza normale mediante array di microfoni

La caratterizzazione acustica dei materiali è cruciale per valutarne le proprietà fonoassorbenti in condizioni reali. I metodi standard, come il tubo d’impedenza (ISO 10534-2) e la camera riverberante (ISO 354), mostrano limiti nelle misure in situ. Questo studio propone un approccio innovativo per stimare il coefficiente di assorbimento a incidenza normale mediante un array di microfoni a basso costo (4×4). La tecnica si basa sul calcolo di impedenza acustica normalizzata e coefficiente di riflessione da coppie di microfoni, con calibrazione in campo libero. Il sistema copre 100 Hz–5000 Hz grazie a distanziatori variabili e riduce la complessità rispetto alle procedure tradizionali. La validazione numerica, tramite elementi finiti, e le prove in camera anecoica evidenziano buona concordanza con modelli analitici e standard, con scarti medi in linea con la riproducibilità delle tecniche normate. I risultati confermano la robustezza del metodo rispetto a variazioni geometriche ed effetti di bordo, aprendo la strada a misure rapide e affidabili in ambienti reali.

Riferimenti bibliografici (comprensivi di DOI)

  1. International Organization for Standardization, ISO 10534-2:2023 – Acoustics — Determination of sound absorp-tion coefficient and impedance in impedance tubes, (2023).
  2. E33 Committee, Test Method for Impedance and Absorption of Acoustical Materials Using a Tube, Two Microphones and a Digital Frequency Analysis System, (n.d.). https://doi.org/10.1520/E1050-19.
  3. International Organization for Standardization, ISO 354:2003 — Acoustics — Measurement of sound absorption in a rever-beration room, (2003).
  4. E33 Committee, Test Method for Sound Absorption and Sound Absorption Coefficients by the Reverberation Room Method, (n.d.). https://doi.org/10.1520/C0423-22.
  5. M. Tamura, Spatial Fourier transform method of measuring reflection coefficients at oblique incidence. I: Theory and nu-merical examples, The Journal of the Acoustical Society of America 88 (1990) 2259–2264. https://doi.org/10.1121/1.400068.
  6. M. Tamura, J.F. Allard, D. Lafarge, Spatial Fourier-transform method for measuring reflection coefficients at oblique inci-dence. II. Experimental results, The Journal of the Acoustical Society of America 97 (1995) 2255–2262. https://doi.org/10.1121/1.412940.
  7. L. Boeckx, G. Jansens, W. Lauriks, G. Vermeir, The Tamura method, a free field technique for scanning surfaces, in: Pro-ceedings of the Institute of Acoustics, 2003. https://www.ioa.org.uk/system/files/proceedings/l_boeckx_g_jansens_w_lauriks_g_vermeir_the_tamura_method_a_free_field_technique_for_scanning_surfaces.pdf.
  8. H. Aygun, Spatial Fourier transform method to determine re-flection and absorption coefficient of porous rigid materials applying Johnson-Champoux-Allard model, in: 2023.
  9. J. Hald, W. Song, K. Haddad, C.-H. Jeong, A. Richard, In-situ impedance and absorption coefficient measurements using a double-layer microphone array, Applied Acoustics 143 (2019) 74–83. https://doi.org/10.1016/j.apacoust.2018.08.027.
  10. A. Paszkiewicz, G. Herold, E. Sarradj, Microphone array measurement for the determination of the absorption coeffi-cient, in: Berlin Beamforming Conference (BeBeC), 2020. https://www.bebec.eu/fileadmin/bebec/downloads/bebec-2020/papers/BeBeC-2020-D31.pdf.
  11. S. Spors, T. Rettberg, On the Estimation of Acoustic Reflection Coefficients from In-Situ Measurements using a Spherical Mi-crophone Array, in: DAGA 2018, 2018. https://pub.dega-akustik.de/DAGA_2018/data/articles/000471.pdf.
  12. S.F. Wu, Techniques for Implementing Near-Field Acoustical Holography, Sound & Vibration Magazine (2010). http://www.sandv.com/downloads/1002wuxx.pdf.
  13. E. Fernandez-Grande, Four decades of near-field acoustic ho-lography, The Journal of the Acoustical Society of America 152 (2022) R1–R2. https://doi.org/10.1121/10.0011806.
  14. Microflown Technologies, In-situ Sound Absorption testing, (2024). https://www.microflown.com/products/acoustic-material-testing/in-situ-absorption.
  15. M. Li, W. Van Keulen, E. Tijs, M. Van De Ven, A. Molenaar, Sound absorption measurement of road surface with in situ technology, Applied Acoustics 88 (2015) 12–21. https://doi.org/10.1016/j.apacoust.2014.07.009.
  16. M. Nosko, E. Tijs, H.-E. de Bree, A study of influences of the in situ surface impedance measurement technique, in: DAGA Proceedings, 2008. https://pub.dega-akustik.de/DAGA_1999-2008/data/articles/003398.pdf.
  17. Y. Takahashi, T. Otsuru, R. Tomiku, In situ measurements of absorption characteristics using two microphones and envi-ronmental “anonymous” noise, Acoust. Sci. & Tech. 24 (2003) 382–385. https://doi.org/10.1250/ast.24.382.
  18. N. Okamoto, T. Otsuru, R. Tomiku, K. Ito, In-situ Sound Ab-sorption Measurement Method of Materials Using Ensemble Averaging, in: ICA 2019, 2019. https://pub.dega-akustik.de/ICA2019/data/articles/001305.pdf.
  19. L. Emmerich, P. Aste, E. Brandão, M. Nolan, J. Cuenca, U.P. Svensson, M. Maeder, S. Marburg, E. Zea, A data-driven two-microphone method for in situ sound absorption measure-ments of porous materials, The Journal of the Acoustical Socie-ty of America 158 (2025) 1711–1722. https://doi.org/10.1121/10.0039101.
  20. International Organization for Standardization, ISO 13472-1:2022 — Acoustics — Measurement of sound absorption properties of road surfaces in situ — Part 1: Extended surface method, (2022).
  21. International Organization for Standardization, ISO 13472-2:2025 — Acoustics — Measurement of sound absorption properties of road surfaces in situ — Part 2: Spot method for reflective surfaces, (n.d.).
  22. M. Garai, In situ sound absorption coefficient measurement of various surfaces, in: Conference Paper, 2002. https://www.academia.edu/72709462/In_Situ_Sound_Absorption_Coefficient_Measurement_of_Various_Surfaces.
  23. M. Bérengier, M. Garai, A state-of-the-art of in situ measure-ment of the sound absorption coefficient of road pavements, in: A. Farina (Ed.), Measurement Methods of Acoustical Prop-erties of Materials, 2003. https://www.angelofarina.it/Public/Standing-Wave/4_05.pdf.
  24. M.U.-16 v2 USB, ArrayMiniDSP, (2025). https://www.minidsp.com/products/usb-audio-interface/uma-16-microphone-array.
  25. A. Farina, Simultaneous Measurement of Impulse Response and Distortion with a Swept-Sine Technique, Journal of The Audio Engineering Society (2000). https://api.semanticscholar.org/CorpusID:9614437.
  26. J.F. Allard, N. Atalla, Propagation of Sound in Porous Media: Modelling Sound Absorbing Materials, 1st ed., Wiley, 2009. https://doi.org/10.1002/9780470747339.
  27. M. Garai, F. Pompoli, A simple empirical model of polyester fibre materials for acoustical applications, Applied Acoustics 66 (2005) 1383–1398. https://doi.org/10.1016/j.apacoust.2005.04.008.
  28. P. Bonfiglio, F. Pompoli, R. Lionti, A reduced-order integral formulation to account for the finite size effect of isotropic square panels using the transfer matrix method, The Journal of the Acoustical Society of America 139 (2016) 1773–1783. https://doi.org/10.1121/1.4945717.
  29. J.C. Lagarias, J.A. Reeds, M.H. Wright, P.E. Wright, Conver-gence Properties of the Nelder--Mead Simplex Method in Low Dimensions, SIAM J. Optim. 9 (1998) 112–147. https://doi.org/10.1137/S1052623496303470.