Multiple mode analysis of waveguides using compact FDTD

Asi, A.; Shafai, L.

doi:10.1109/aps.1993.385331

Cited by 3 publications

(1 citation statement)

References 7 publications

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“…However, these techniques consume too much computational power and can only calculate single mode characteristics and patterns. Later efforts were able to improve these techniques into two-dimensional formulations called the Compact 2D FDTD method [41,42,43] that later led to methods that were able to solve multimode patterns [44,45]. Despite having computational efficiency, the compact 2D FDTD method requires propagation constant β as an input and depends on signal processing techniques to calculate multimode parameters.…”

Section: D Application: Propagation Characteristics Of General Guidementioning

confidence: 99%

Multiresolution Frequency Domain Technique for Electromagnetics

Gokten¹,

Elsherbeni²,

Arvas³

2012

Synthesis Lectures on Computational Electromagnetics

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Synthesis Lectures on Computational Electromagnetics will publish 50-to 100-page publications on topics that include advanced and state-of-the-art methods for modeling complex and practical electromagnetic boundary value problems. Each lecture develops, in a unified manner, the method based on Maxwell's equations along with the boundary conditions and other auxiliary relations, extends underlying concepts needed for sequential material, and progresses to more advanced techniques and modeling. Computer software, when appropriate and available, is included for computation, visualization and design. The authors selected to write the lectures are leading experts on the subject that have extensive background in the theory, numerical techniques, modeling, computations and software development. The series is designed to: • Develop computational methods to solve complex and practical electromagnetic boundary-value problems of the 21st century. • Meet the demands of a new era in information delivery for engineers, scientists, technologists and engineering managers in the fields of wireless communication, radiation, propagation, communication, navigation, radar, RF systems, remote sensing, and biotechnology who require a better understanding and application of the analytical, numerical and computational methods for electromagnetics.

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