Porous absorber: Difference between revisions

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Description

The Porous absorber benchmark models the sound pressure in a cavity excited by a single harmonic load. One side of the cavity is covered by a layer of poroelastic material, which adds dissipation to the system. The geometry of this model follows ^[1]. Various projection-based model order reduction methods have been applied and compared using this example as a benchmark in ^[2].

The cavity has the dimensions ${\displaystyle 0.75\times 0.6\times 0.4\mathrm{m}}$ and one wall is covered by a ${\displaystyle 0.05\mathrm{m}}$ thick poroelastic layer acting as a sound absorber. The poroelastic material is described by the Biot theory^[3] and the system is excited by a point source located in a corner opposite of the porous layer. The material parameters for the acoustic fluid and the poroelastic material have been chosen according to^[1]. The transfer function measures the mean acoustic pressure inside the cavity.

Dimensions

System structure:

${\displaystyle \begin{array}{rl}(K+\tilde{\gamma }(s)K_{p,1}+{\tilde{\rho }}_f(s)K_{p,2}+s^{2}M+s^2\tilde{\gamma }(s)M_{p,1}+s^2\tilde{\rho }(s)M_{p,2}+\frac{s^2{\varphi }^2}{\tilde{R}(s)}{M}_{p,3})x(s)& =B,\\ y(s)& =Cx(s),\end{array}}$

with the frequency dependent functions for the effective densities ${\displaystyle \tilde{\rho }(s),{\tilde{\rho }}_f(s)}$, the parameter ${\displaystyle \tilde{\gamma }(s)}$ relating the effective densities and the frequency dependent elasticity coefficients to the porosity, and the scaled effective bulk modulus ${\displaystyle \tilde{R}(s)}$. For more details on the functions, see ^[1].

System dimensions:

${\displaystyle K,K_{p,1},K_{p,2},M,M_{p,1},M_{p,2},M_{p,3}\in {\mathbb{ℝ}}^{n\times n}}$, ${\displaystyle B\in {\mathbb{ℝ}}^{n\times 1}}$, ${\displaystyle C\in {\mathbb{ℝ}}^{1\times n}}$, with ${\displaystyle n=386076}$.

Data

The data is available at Zenodo.

Remarks

• The numerical model resembles the results from^[1] in a frequency range from ${\displaystyle 100\mathrm{H}\mathrm{z}}$ to ${\displaystyle 1000\mathrm{H}\mathrm{z}}$. The frequency response in this range is also included in the dataset.
• The finite element discretization has been performed with Kratos Multiphysics.
• A comparison of different interpolation-based MOR methods using this benchmark example is available in^[2].

Citation

To cite this benchmark, use the following references:

• For the benchmark itself and its data:

 @Misc{dataAum23,
   author =       {Aumann, Q.},
   title =        {Matrices for an acoustic cavity with poroelastic layer},
   howpublished = {hosted at {MORwiki} -- Model Order Reduction Wiki},
   year =         2023,
   doi =          {10.5281/zenodo.8087341}
 }

• For the background on the benchmark:

 @Article{AumW23,
   author =       {Aumann, Q. and Werner, S.~W.~R.},
   title =        {Structured model order reduction for vibro-acoustic problems using interpolation and balancing methods},
   journal =      {Journal of Sound and Vibration},
   volume =       543,
   year =         2023,
   pages =        {117363},
   doi =          {10.1016/j.jsv.2022.117363},
   publisher =    {Elsevier {BV}}
 }

References