The finite-difference time-domain (FDTD) method is a numerical technique used for solving Maxwell's equations in the time domain. It is widely used for microwave simulation and has been applied to various areas such as antenna design and electromagnetic compatibility analysis.
This course provides an introduction to the finite-difference time-domain (FDTD) method for simulating microwave devices. Topics include the basics of the FDTD method, numerical dispersion, and stability analysis.
This paper presents a review of the FDTD method for microwave simulation. The method is based on discretizing Maxwell's equations in both space and time, and it has been widely used for simulating various microwave devices and structures.
This online course covers the fundamentals of the FDTD method for microwave engineering. It includes topics such as the basics of the FDTD method, boundary conditions, and simulation of microwave devices.
This video provides an introduction to the FDTD method for microwave simulation. It covers the basics of the method, including the discretization of Maxwell's equations and the implementation of boundary conditions.
ANSYS HFSS is a commercial software package that uses the FDTD method for simulating microwave devices and structures. It provides a user-friendly interface for creating and simulating 3D models of microwave devices.
This article presents an overview of open-source FDTD software for microwave simulation. It includes a comparison of different software packages, including Meep and OpenEMS.
This review article provides an overview of the FDTD method for microwave simulation. It covers the history of the method, its advantages and limitations, and its applications in various areas of microwave engineering.