A. Nassib, M. Almutiry, Y. Guzel, M. Wicks, L. Monte
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引用次数: 2
摘要
在本文中,我们构建了三维ISAR图像,以更好地了解电大PEC圆柱体的电磁散射。在这种情况下,成像只是重建成像目标电导率的空间分布,σ(x, y, z)。根据衍射几何理论(GTD),如果工作频率处的波长相对于目标尺寸较小,则散射场由许多电隔离散射中心的贡献组成。ISAR成像算法依赖于一个假设,即观测区域由一组无限小的各向同性散射体组成(即点散射体模型)。这种近似是基于忽略方向依赖的标量对比函数的应用,因为点散射体在所有方向上都是各向同性辐射的。通过从模拟数据中检索标量反射率函数获得三维图像重建,从而提供被调查目标的信息。
FEKO based ISAR analysis for 3D object reconstruction
In this paper, we constructed a 3D ISAR image to better understand electromagnetic scattering by an electrically large PEC cylinder. Imaging in this context is simply the reconstruction of the spatial distribution of the conductivity of the imaged target, σ(x, y, z). According to the geometric theory of diffraction (GTD), if the wavelength at the operating frequency is small relative to the target size, then the scattered field consists of contributions from a number of electrically isolated scattering centers. ISAR imaging algorithms rely upon an assumption that the area under observation consists of a collection of infinitesimally small isotropic scatterers (i.e., the point scatterer model). This approximation is based upon the application of a scalar contrast function which ignores directional dependency, since point scatterers radiate isotropically in all directions. 3D image reconstruction is obtained through retrieval of the scalar reflectivity function from simulated data, which provides information regarding the target under investigation.
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