图 1  半空间声场示意图　(a)声源、传声器阵列和阻抗边界的布置; (b)声源几何中心及其关于边界的镜像点与场点、阻抗边界之间的几何关系

Fig. 1.  Schematic of the half-space sound field: (a) Setup of the source, the microphone array and the impedance boundary; (b) geometric relationship between the geometric center of the source, the mirror point, the field point and the impedance boundary.

图 2  单位圆内部区域的网格划分

Fig. 2.  Mesh of the region inside the unit circle.

图 3  仿真声场示意图　(a)脉动球声源、传声器阵列、参考传声器和阻抗边界的布置; (b)阵列上传声器的编号

Fig. 3.  Schematic of the simulated sound field: (a) Setup of the dilating sphere source, the microphone array, the reference microphone and the impedance boundary; (b) the indices of the microphones mounted on the array.

图 4  相对误差的曲面图　(a)误差E随反射系数${R_{\rm p}}$变化的分布; (b)误差${\varepsilon ^{{\text{pres}}}}$随反射系数均值${\bar R_{\rm p}}$变化的分布

Fig. 4.  Surface plot of the relative error: (a) The error E versus reflection coefficient ${R_{\rm p}}$; (b) the error ${\varepsilon ^{{\text{pres}}}}$ versus mean value of the reflection coefficient ${\bar R_{\rm p}}$.

图 5  半空间总声压、声源直接辐射声压的重构值和声源直接辐射声压的理论值在阵列测点的分布

Fig. 5.  Sound pressure distributions at the measurement points on the array, including the total values in the half-space, the reconstructed values and the benchmark values radiated directly from the source.

图 6  声阻抗率重构的相对误差${\varepsilon ^{{\text{imp}}}}$和声源直接辐射声压重构的相对误差${\varepsilon ^{{\text{pres}}}}$随频率f的变化曲线

Fig. 6.  Relative error of the reconstructed specific acoustic impedance ${\varepsilon ^{{\text{imp}}}}$ and the relative error of the reconstructed sound pressure ${\varepsilon ^{{\text{pres}}}}$ radiated directly from the source versus frequency f.

图 7  声阻抗率重构的相对误差${\varepsilon ^{{\text{imp}}}}$和声源直接辐射声压重构的相对误差${\varepsilon ^{{\text{pres}}}}$随参考传声器坐标${z_{{\text{ref}}}}$的变化曲线　(a)$f = $$ 100{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (b)$f = 900{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (c)$f = 1700{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (d)$f = 2500{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (e)$f = 3300{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$

Fig. 7.  Relative error of the reconstructed specific acoustic impedance ${\varepsilon ^{{\text{imp}}}}$ and the relative error of the reconstructed sound pressure ${\varepsilon ^{{\text{pres}}}}$ radiated directly from the source versus coordinate of the reference microphone ${z_{{\text{ref}}}}$: (a)$f = 100{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (b)$f = 900{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (c)$f = 1700{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (d)$f = 2500{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$; (e) $f = 3300{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{Hz}}$.

图 8  声阻抗率重构的相对误差${\varepsilon ^{{\text{imp}}}}$和声源直接辐射声压重构的相对误差${\varepsilon ^{{\text{pres}}}}$随边界参数${\sigma _{\text{e}}}$的变化曲线　(a) ${z_{{\text{ref}}}} = 0{\kern 1 pt} $; (b) ${z_{{\text{ref}}}} = $$ 0.05{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (c) ${z_{{\text{ref}}}} = 0.10{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (d) ${z_{{\text{ref}}}} = 0.15{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$

Fig. 8.  Relative error of the reconstructed specific acoustic impedance ${\varepsilon ^{{\text{imp}}}}$ and the relative error of the reconstructed sound pressure ${\varepsilon ^{{\text{pres}}}}$ radiated directly from the source versus boundary parameter ${\sigma _{\text{e}}}$: (a) ${z_{{\text{ref}}}} = 0{\kern 1 pt} $; (b) ${z_{{\text{ref}}}} = 0.05{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (c) ${z_{{\text{ref}}}} = 0.10{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (d) ${z_{{\text{ref}}}} = 0.15{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$.

图 9  声阻抗率重构的相对误差${\varepsilon ^{{\text{imp}}}}$和声源直接辐射声压重构的相对误差${\varepsilon ^{{\text{pres}}}}$随边界参数${\alpha _{\text{e}}}$的变化曲线　(a) ${z_{{\text{ref}}}} = 0{\kern 1 pt} $; (b) ${z_{{\text{ref}}}} = 0.05{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (c) ${z_{{\text{ref}}}} = 0.10{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (d) ${z_{{\text{ref}}}} = 0.15{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$

Fig. 9.  Relative error of the reconstructed specific acoustic impedance ${\varepsilon ^{{\text{imp}}}}$ and the relative error of the reconstructed sound pressure ${\varepsilon ^{{\text{pres}}}}$ radiated directly from the source versus boundary parameter ${\alpha _{\text{e}}}$: (a) ${z_{{\text{ref}}}} = 0{\kern 1 pt} $; (b) ${z_{{\text{ref}}}} = 0.05{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (c) ${z_{{\text{ref}}}} = 0.10{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$; (d) ${z_{{\text{ref}}}} = 0.15{\kern 1 pt} {\kern 1 pt} {\kern 1 pt} {\text{m}}$.