Shooting and bouncing rays: Calculating RCS of an arbitrary cavity

Ling, Hao; Chou, Ri-Chee; Lee, S.

doi:10.1109/aps.1986.1149823

Cited by 50 publications

(44 citation statements)

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“…Up to now, in the open literature many cavity scattering problems have been analysed by using a variety of analytical and numerical techniques. The most used two typical methods are the waveguide modal approach [1,2] and the high frequency ray techniques [3,4]. However, the solutions obtained by these methods remain valid depending on the length of the cavity size.…”

Section: Introductionmentioning

confidence: 99%

Diffraction of Electromagnetic Waves by an Open Ended Parallel Plate Waveguide Cavity with Impedance Walls

Ãetiner¹,

GÃ1⁄4neÅ²

2000

PIER

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Section: Introductionmentioning

confidence: 99%

Diffraction of Electromagnetic Waves by an Open Ended Parallel Plate Waveguide Cavity with Impedance Walls

Ãetiner¹,

GÃ1⁄4neÅ²

2000

PIER

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“…(3), the electric and magnetic field at the point of r S of the antenna is replaced by the field at the point r P of the projection plane multiplied by divergence and phase factors [18][19][20][21]. If a radome encloses the antenna 'A' as shown in Fig.…”

Section: Formulationmentioning

confidence: 99%

Prediction of Radome Bore-Sight Errors Using a Projected Image of Source Distributions

Lee¹,

Park²

2009

PIER

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Abstract-In this paper, a calculation method for bore sight error voltage is presented for aperture antennas enclosed in radomes of arbitrary shapes.The method adopts a ray tracing technique frequently used in computer graphics field in constructing two dimensional computer graphics images to obtain a projected image of source distribution, thereby bore sight error voltages and far field radiation patterns are calculated fast and accurately. Besides, the method enables us to use various acceleration schemes used in computer graphics readily. Numerical calculations show that projected source images with a resolution higher than 0.1λ and multiple reflections taken into account produce reliable results. The validity of the method is verified by comparison with results of an analytic solution.

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“…This problem serves as a simple model of duct structures such as jet engine intakes of aircrafts and cracks occurring on surfaces of general complicated bodies. Some of the diffraction problems involving twoand three-dimensional (2-D and 3-D) cavities have been analyzed thus far based on high-frequency techniques and numerical methods [7][8][9][10][11][12][13]. It appears, however, that the solutions due to these approaches are not uniformly valid for arbitrary dimensions of the cavity.…”

Section: Introductionmentioning

confidence: 99%

Plane Wave Diffraction by a Finite Parallel-Plate Waveguide With Four-Layer Material Loading: Part I - The Case of E Polarization

Zheng¹,

Kobayashi²

2008

PIER B

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Abstract-The plane wave diffraction by a finite parallel-plate waveguide with four-layer material loading is rigorously analyzed for the case of E polarization using the Wiener-Hopf technique. Introducing the Fourier transform for the scattered field and applying boundary conditions in the transform domain, the problem is formulated in terms of the simultaneous Wiener-Hopf equations, which are solved via the factorization and decomposition procedure together with a rigorous asymptotics. The scattered field is evaluated explicitly by taking the inverse Fourier transform and applying the saddle point method. Representative numerical examples of the radar cross section (RCS) are shown for various physical parameters and the far field scattering characteristics are discussed in detail.

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Shooting and bouncing rays: Calculating RCS of an arbitrary cavity

Cited by 50 publications

References 1 publication

Diffraction of Electromagnetic Waves by an Open Ended Parallel Plate Waveguide Cavity with Impedance Walls

Diffraction of Electromagnetic Waves by an Open Ended Parallel Plate Waveguide Cavity with Impedance Walls

Prediction of Radome Bore-Sight Errors Using a Projected Image of Source Distributions

Plane Wave Diffraction by a Finite Parallel-Plate Waveguide With Four-Layer Material Loading: Part I - The Case of E Polarization

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