TU-A6.1A.5
Broadband Structured Beams in Scattered Field FDTD for RCS Calculation
Joseph Diener, Atef Elsherbeni, Colorado School of Mines, United States
Session:
FDTD Methods and Applications I Oral
Track:
AP-S: Track 6: Computational Electromagnetics
Location:
Room 251C
Session Time:
Tue, 14 Jul, 08:00 - 11:40
Presentation Time:
Tue, 14 Jul, 09:20 - 09:40
Presentation
Discussion
Session TU-A6.1A
TU-A6.1A.1: 2.5D FDTD Modeling of 3D Dielectric Waveguides via a Two-Step Effective Index Method
Bikesh Shrestha, Ata Zadehgol, University of Idaho, United States
TU-A6.1A.2: A Polynomial Regression Model for FDTD Modeling of Nonlinear Dispersive Media
Tianhui Xu, Costas Sarris, University of Toronto, Canada
TU-A6.1A.3: Solving Nonlinear LLG Equation with FDTD Method for Modeling of RF Magnetic Devices
Li Li, ECE Purdue University, United States; Yuanxun Ethan Wang, ECE, University of California at Los Angeles, United States
TU-A6.1A.4: An FDTD Method for Calculating the Wave Reflection from an Arbitrarily Translating Plane
Hongyun Deng, George Eleftheriades, University of Toronto, Canada
TU-A6.1A.5: Broadband Structured Beams in Scattered Field FDTD for RCS Calculation
Joseph Diener, Atef Elsherbeni, Colorado School of Mines, United States
TU-A6.1A.6: Efficiency and Error Optimizations in ADI-FDTD Particle-In-Cell Model for Wave-Particle Interactions and Slow-wave Effects in THz Gap
Md Faiyaz Bin Hassan, Shubhendu Bhardwaj, University of Nebraska-Lincoln, United States
TU-A6.1A.7: Double Decaying PML Technique in FDTD Method of Maxwell’s and LLG Equations
Li Li, (1) Electrical and Computer Engineering Department, Purdue University, United States; Yuanxun Ethan Wang, (2) Electrical and Computer Engineering Department, University of California at Los Angeles, United States
TU-A6.1A.8: Parallel Programming for FDTD Method of Maxwell’s and LLG Equations
Li Li, (1) Electrical and Computer Engineering Department, Purdue University, United States; Yuanxun Ethan Wang, (2) Electrical and Computer Engineering Department, University of California at Los Angeles, United States
TU-A6.1A.9: Computing approximate solutions to Stochastic Maxwell’s equations using FDTD
Justin Crum, Naval Research Laboratory, United States
TU-A6.1A.10: An Improved Correction Scheme for Thin-Wire FDTD Modeling
Gaoxiang Yin, Tao Huang, Luo Huang, Xiaolin Jin, University of Electronic Science and Technology of China, China
Resources
No resources available.