Directional sound source modeling using the adjoint Euler equations in a finite-difference time-domain approach

Stein, Lewin; Straube, Florian; Weinzierl, Stefan; Lemke, Mathias

doi:10.1121/10.0002425

Cited by 7 publications

(2 citation statements)

References 21 publications

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“…Discrete adjoint equations were used in this study, which discretized the flow solver first and then discretized the adjoint equation on the same mesh. In this manner, better accuracy of CFD solutions can be obtained, especially for the turbulence problem [57]. Similar to the flow solver, the least square cell-based approach was selected for gradient, standard approach for pressure, and second order upwind differencing for momentum.…”

Section: Methodsmentioning

confidence: 99%

Adjoint Solver-Based Analysis of Mouth-Tongue Morphologies on Vapor Deposition in the Upper Airway

Talaat,

Si,

2024

Preprint

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Even though inhalation dosimetry is determined by three factors (i.e., breathing, aerosols, and the respiratory tract), the first two categories have been more widely studied than the last. Both breathing and aerosols are quantitative variables that can be easily changed, while respiratory airway morphologies are difficult to reconstruct, modify, and quantify. Despite several methods are available for model reconstruction and modification, developing an anatomically accurate airway model and morphing it to various physiological conditions remains labor-intensive and technically challenging. The objective of this study is to explore the feasibility of using an adjoint-CFD model to understand airway shape effects on vapor deposition and control vapor flux into the lung. A mouth-throat model was used, with the shape of the mouth and tongue being automatically varied via adjoint morphing, and the vapor transport being simulated using ANSYS Fluent coupled with a wall absorption model. Two chemicals with varying adsorption rates, Acetaldehyde and Benzene, were considered, which exhibited large differences in dosimetry sensitivity to airway shapes. For both chemicals, large shape deformations were explored to find the maximal possible morphing; both the maximal and intermediate deformations were simulated for morphology parametric studies. Results show that changing the mouth-tongue shape can alter the oral filtration by 3.2% for Acetaldehyde and 0.27% for Benzene under a given inhalation condition. This study demonstrates that the hybrid adjoint-CFD approach can be a practical and efficient method to investigate morphology-associated variability in inhalation dosimetry of vapors and nanomedicines.

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Section: Methodsmentioning

confidence: 99%

Adjoint Solver-Based Analysis of Mouth-Tongue Morphologies on Vapor Deposition in the Upper Airway

Talaat,

Si,

2024

Preprint

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“…Time-domain simulations can be based on the wave equation [14], the non-linear Euler equations [31,32] or the acoustic equations as its linearized form. A variety of numerical methods has been utilized, like the finitedifference (FD) [4], the finite element (FEM) [5], the finite volume (FVM) [2] or the discontinuous Galerkin method (DG) [25].…”

Section: Introductionmentioning

confidence: 99%

Approximate Acoustic Boundary Conditions in the Time-Domain using Volume Penalization

Lemke¹,

Reiß²

2022

Preprint

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Immersed boundary methods allow describing complex objects on simple Cartesian grids in time-domain simulations. The penalization technique employed here is a physically motivated Brinkman method that models objects as porous material by including a friction term and an effective volume. We investigate how the approach can mimic different acoustic boundary conditions. It is validated concerning different acoustic setups, including rigid walls and various absorber configurations.

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Raumakustische Simulation und Auralisation

Vorländer

Feistel²

2023

Handbuch Der Audiotechnik

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Directional sound source modeling using the adjoint Euler equations in a finite-difference time-domain approach

Cited by 7 publications

References 21 publications

Adjoint Solver-Based Analysis of Mouth-Tongue Morphologies on Vapor Deposition in the Upper Airway

Adjoint Solver-Based Analysis of Mouth-Tongue Morphologies on Vapor Deposition in the Upper Airway

Approximate Acoustic Boundary Conditions in the Time-Domain using Volume Penalization

Raumakustische Simulation und Auralisation

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