Modeling a millimeter wave imaging system with a 2.5D BiCGS-FFT volume integral equation technique

Modeling a millimeter wave imaging system with a 2.5D BiCGS-FFT volume integral equation technique

The imaging performance of an active mm-wave imaging system can be studied using accurate numerical electromagnetic simulations. We present an exact forward solver to calculate the three-dimensional (3D) scattered fields of a two-dimensional (2D) inhomogeneous dielectric object which is illuminated...

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Hauptverfasser: Van den Bulcke, S., Franchois, A., Zhang, L., Stiens, J.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Computational efficiency
Dielectrics
Electromagnetic scattering
Fast Fourier transforms
Forward solver
Integral equations
Linear systems
Millimeter wave technology
millimeter waves
Moment methods
Numerical simulation
System performance
volume integral equation technique
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Zusammenfassung:The imaging performance of an active mm-wave imaging system can be studied using accurate numerical electromagnetic simulations. We present an exact forward solver to calculate the three-dimensional (3D) scattered fields of a two-dimensional (2D) inhomogeneous dielectric object which is illuminated with a given 3D time-harmonic incident field. Since the size of the scattering objects can be very large with respect to the wavelength, a 2.5D configuration is adopted. This reduces the computational cost while it maintains the capability of accurately studying the system performance. The 3D scattered fields are calculated by discretizing a contrast source integral equation with the Method of Moments. The resulting linear system is solved iteratively with a stabilized biconjugate gradient Fast Fourier Transform method.
ISSN:2164-3342
DOI:10.1109/EUCAP.2006.4584904