The authors investigate an inverse source problem in aeroacoustics, where an unknown acoustic source φ located in a sub-region Ω0 of an enclosed room Ω needs to be determined from acoustic oscillations measured outside of Ω0, in the measurement region Ω1. The acoustic wave propagation is modeled by the Helmholtz equation.
The authors propose using a bi-level regularization scheme, where the upper-level iteratively updates the source term, and the lower-level solves the Helmholtz equation approximately using a finite element method (FEM) with adaptive mesh refinement. The adaptive mesh refinement is guided by the data noise level and the regularization effect, as suggested in prior work on bi-level regularization.
The authors demonstrate the numerical advantages of the bi-level approach with adaptive mesh refinement over the classical Landweber algorithm in terms of reconstruction time and quality, for both 1% and 10% relative noise levels. The bi-level algorithm reached the discrepancy principle much earlier than the direct Landweber algorithm, and the final residual was smaller for the bi-level approach. For higher noise levels, the bi-level algorithm outperformed the direct Landweber method in all respects despite needing only one mesh refinement, justifying the intuition that higher noise levels can be efficiently handled with coarser grids.
The authors also discuss the potential application of the bi-level algorithm in the field of optimal experimental design for inverse problems governed by nonlinear PDEs.
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