Title :
3D FDTD simulation of nonlinear ferroelectric materials in rectangular waveguide
Author :
Caudle, Byron T. ; Baginski, Michael E. ; Kirkici, Hulya
Author_Institution :
Dept. of Electr. & Comput. Eng., Auburn Univ., Auburn, AL, USA
Abstract :
Nonlinear transmission lines (NLTLs) have numerous applications in the communications and defense industries due to their ability to form and propagate short duration, ultra wide band pulses. This paper simulates a short duration Gaussian transient exciting low order TEm, 0 modes in a nonlinear ferroelectric filled conducting waveguide. A three dimensional FDTD simulation is employed in the analysis and the ferroelectric filled waveguide model based on a nonlinear polarization relationship extrapolated from measurements. A small portion of the frequency band operates in the saturation polarization region. These terms will propagate at higher velocity than lower amplitude components and this effect counteracts dispersion and results in compression of the pulses into solitons as they propagate.
Keywords :
Gaussian processes; dielectric-loaded waveguides; dispersion (wave); electromagnetic wave polarisation; electronic engineering computing; ferroelectric materials; finite difference time-domain analysis; rectangular waveguides; solid modelling; 3D FDTD simulation; NLTL; amplitude component; communication industry; defense industry; dispersion; ferroelectric filled waveguide model; frequency band; nonlinear ferroelectric filled conducting waveguide; nonlinear ferroelectric material; nonlinear polarization; nonlinear transmission line; pulse compression; rectangular waveguide; saturation polarization region; short duration Gaussian transient; solitons; ultra wide band pulse; velocity;
Conference_Titel :
Power Modulator and High Voltage Conference (IPMHVC), 2012 IEEE International
Conference_Location :
San Diego, CA
Print_ISBN :
978-1-4673-1222-6
DOI :
10.1109/IPMHVC.2012.6518723
