Surface Impedance Determination via Numerical Resolution of the Inverse Helmholtz Problem

D. Patel, Prateek Gupta, C. Scalo
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引用次数: 6

Abstract

Assigning boundary conditions, such as acoustic impedance, to the frequency domain thermoviscous wave equations (TWE), derived from the linearized Navier-Stokes equations (LNSE) poses a Helmholtz problem, solution to which yields a discrete set of complex eigenfunctions and eigenvalue pairs. The proposed method -- the inverse Helmholtz solver (iHS) -- reverses such procedure by returning the value of acoustic impedance at one or more unknown impedance boundaries (IBs) of a given domain, via spatial integration of the TWE for a given real-valued frequency with assigned conditions on other boundaries. The iHS procedure is applied to a second-order spatial discretization of the TWEs on an unstructured staggered grid arrangement. Only the momentum equation is extended to the center of each IB face where pressure and velocity components are co-located and treated as unknowns. The iHS is finally closed via assignment of the surface gradient of pressure phase over the IBs, corresponding to assigning the shape of the acoustic waveform at the IB. The iHS procedure can be carried out independently for different frequencies, making it embarrassingly parallel, and able to return the complete broadband complex impedance distribution at the IBs in any desired frequency range to arbitrary numerical precision. The iHS approach is first validated against Rott's theory for viscous rectangular and circular ducts. The impedance of a toy porous cavity with a complex geometry is then reconstructed and validated with companion fully compressible unstructured Navier-Stokes simulations resolving the cavity geometry. Verification against one-dimensional impedance test tube calculations based on time-domain impedance boundary conditions (TDIBC) is also carried out. Finally, results from a preliminary analysis of a thermoacoustically unstable cavity are presented.
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利用反亥姆霍兹问题的数值解析确定表面阻抗
将边界条件(如声阻抗)赋给由线性化Navier-Stokes方程(LNSE)导出的频域热粘性波方程(TWE),会产生一个亥姆霍兹问题,其解会产生一组离散的复特征函数和特征值对。所提出的方法——逆亥姆霍兹求解器(iHS)——通过对给定实值频率的TWE与其他边界上的指定条件进行空间积分,在给定域的一个或多个未知阻抗边界(IBs)返回声阻抗值,从而逆转了这一过程。将his方法应用于非结构化交错网格布置上的TWEs的二阶空间离散化。只有动量方程被扩展到每个IB面中心,其中压力和速度分量共存,并被视为未知数。iHS最终通过分配IB上压力相位的表面梯度来关闭,对应于分配IB上声波波形的形状。iHS过程可以在不同频率下独立进行,使其非常平行,并且能够在任何期望的频率范围内将IB上的完整宽带复杂阻抗分布返回到任意数值精度。iHS方法首先针对Rott的粘性矩形和圆形管道理论进行了验证。然后重建具有复杂几何形状的玩具多孔腔的阻抗,并通过求解腔几何形状的完全可压缩非结构化Navier-Stokes模拟进行验证。基于时域阻抗边界条件(TDIBC)的一维阻抗试管计算也进行了验证。最后,给出了热声不稳定腔体的初步分析结果。
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