He earned his PhD in Optics in 2006 from the University of Central Florida. Raymond earned his BS and MS in Electrical Engineering from the Florida Institute of Technology in 19 respectively. Rumpf’s leadership, the EM Lab has produced numerous breakthroughs, discoveries, and first-ever achievements. Rumpf formed the EM Lab with a mission to develop revolutionary technologies in electromagnetics and photonics. He is the Schellenger Professor of Electrical Research in the Department of Electrical & Computer Engineering at the University of Texas at El Paso (UTEP) and the Director of the EM Lab. Raymond (Tipper) Rumpf is the EMProfessor, world renowned research and educator in the fields of computation and electromagnetics. Many background concepts are covered in the prerequisite that are needed to be successful in this course.ĭr. View select topics in this course completely free.īefore taking this course, please complete the prerequisite course "One-Dimensional Finite-Difference Time-Domain with MATLAB" at the link below. Rumpf's clear and step-by-step explanations, you will be able to simulate your own devices in no time! For each example, you will learn the theory of the device and the methodology used to simulate the devices. You will learn how to simulate a guided-mode resonance filter as well as simulate a hexagonal photonic crystal. You will simulate a grating and calculate the diffraction efficiencies of the diffraction orders. The course will step you line-by-line through guided code development and through multiple device examples. The course uses stunning visuals and animations to teach the concepts. And so much more!īuilding on the prerequisite course on 1D FDTD, this course will introduce you to 2D simulations and cover everything from deriving all of the equations to writing the programs in MATLAB. Learn the state-of-the-art convolutional perfectly matched layer absorbing boundary. Learn a unique implementation of the total-field/scattered-field technique to launch sources into your simulations and examine the scattered waves.
Learn the powerful "2x grid" method for modeling curved dielectric structures. Imagine developing a code that gives you simulation capabilities way beyond commercial software. This course will give you the ability to derive all the equations for 2D FDTD and implement them in MATLAB. Do you have ideas or designs that you would like to simulate but don't know how to start?Īre you ready to rise above your competition with stunning simulations and visualizations?
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