Details

Autor(en) / Beteiligte

• Dolcetti, G.
• Alkmim, M.
• Cuenca, J.
• De Ryck, L.
• Krynkin, A.

Titel

Robust reconstruction of scattering surfaces using a linear microphone array

Ist Teil von

• Journal of sound and vibration, 2021-03, Vol.494, p.115902, Article 115902

Ort / Verlag

Amsterdam: Elsevier Ltd

Erscheinungsjahr

2021

Quelle

Access via ScienceDirect (Elsevier)

Beschreibungen/Notizen

• •The shape of a 2D rigid surface is reconstructed from the scattered sound field.•Uncertainties are assessed numerically and experimentally for the first time.•Previous approaches are biased at low frequency and unreliable at high frequency.•A new approach based on broadband data combines accuracy and robustness. The analysis of sound scattered by a rough surface and measured by multiple microphones positioned in the far field yields an estimate of the unknown scattering surface profile. Expanding from previous work, the approach used in this paper is based on an expansion and linearization of the Kirchhoff integral equation, and applies to a low density of receivers. Here, the original algorithm is modified in order to reduce the measurement bias, and extended to broadband signals to over-constrain the problem and improve its robustness. The improved method is rigorously assessed alongside the original algorithm and its small perturbation version, for a two-dimensional geometry and for scattering surfaces with a spatial power-function spectrum. The impact of the measurement setup and surface characteristics on the reconstruction uncertainty are evaluated by means of numerical simulations. Additional experimental data obtained for three known surface profiles reveal the impact of noise and measurement uncertainties. The optimal measurement configuration requires a trade-off between resolution (higher at high frequencies), and robustness (higher at low frequencies). This limit is overcome at least partially by the proposed multiple-frequency extension. The resulting measured uncertainties were close to the theoretical expectation of approximately 2% of the acoustic wavelength.