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Propagation of Waves01:07

Propagation of Waves

When a wave propagates from one medium to another, part of it may get reflected in the first medium, and part of it may get transmitted to the second medium. In such a case, the interface of the two mediums can be considered as a boundary that is neither fixed nor free.
Consider a scenario where a wave propagates from a string of low linear mass density to a string of high linear mass density. In such a case, the reflected wave is out of phase with respect to the incident wave, however the...
Propagation Speed of Electromagnetic Waves01:30

Propagation Speed of Electromagnetic Waves

Electromagnetic waves are consistent with Ampere's law. Assuming there is no conduction current Ampere's law is given as:
Reflection of Waves01:07

Reflection of Waves

When a wave travels from one medium to another, it gets reflected at the boundary of the second medium. A common example of this is when a person yells at a distance from a cliff and hears the echo of their voice. The sound waves (longitudinal waves) traveling in the air are reflected from the bounding cliff. Similarly, flipping one end of a string whose other end is tied to a wall causes a pulse (transverse wave) to travel through the string, which gets reflected upon reaching the wall. In...
Plane Electromagnetic Waves I01:30

Plane Electromagnetic Waves I

The existence of combined electric and magnetic fields that propagate through space as electromagnetic (EM) waves is the most significant prediction of Maxwell's equations. As Maxwell's equations hold in free space, the predicted electromagnetic waves do not require a medium for their propagation. An EM wave comprises an electric field, defined as the force per charge on a stationary charge, and a magnetic field, which is the force per charge on a moving charge.
The EM field is assumed to be a...
Electromagnetic Waves in Matter01:30

Electromagnetic Waves in Matter

Electromagnetic waves can travel in the vacuum as well as in matter. For example light, which is an electromagnetic wave, can travel through air, water, or glass.
Consider the electromagnetic wave passing through a dielectric medium. In such a case, Maxwell's equations get modified. In Ampere's law, ε0 , the dielectric permittivity of free space is replaced with ε, the permittivity of dielectric. Also, the vacuum permeability μ0 is replaced by the permeability of the medium, μ.
Furthermore, the...
Bending of Members Made of Several Materials01:11

Bending of Members Made of Several Materials

In analyzing a structural member composed of two different materials with identical cross-sectional areas, it is crucial to understand how their distinct elastic properties affect the member's response under load. The analysis involves assessing stress and strain distributions using the transformed section concept, which accounts for variations in material properties.
Hooke's Law determines stress in each material, stating that stress is proportional to strain but varies due to each material's...

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Related Experiment Video

Updated: Jun 13, 2026

Characterization of Anisotropic Leaky Mode Modulators for Holovideo
09:36

Characterization of Anisotropic Leaky Mode Modulators for Holovideo

Published on: March 19, 2016

Beam propagation method in anisotropic media.

L Thylen, D Yevick

    Applied Optics
    |April 17, 2010
    PubMed
    Summary

    This study extends the beam propagation method for anisotropic media. The new formalism analyzes integrated optics devices, improving optical simulations.

    Area of Science:

    • Optics and Photonics
    • Computational Electromagnetics

    Background:

    • The beam propagation method (BPM) is a standard numerical technique for simulating light propagation in optical waveguides.
    • Traditional BPM formulations are primarily suited for isotropic or weakly anisotropic media.
    • Accurate modeling of complex optical devices often requires accounting for material anisotropy.

    Purpose of the Study:

    • To extend the beam propagation method (BPM) to accurately model light propagation in anisotropic optical media.
    • To apply the developed formalism to analyze the performance of various integrated optics devices.
    • To provide a robust computational tool for the design and optimization of photonic integrated circuits.

    Main Methods:

    • Developed an extended beam propagation method (BPM) formalism incorporating anisotropic material properties.

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    Last Updated: Jun 13, 2026

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  • Implemented the extended BPM for numerical simulations of electromagnetic wave propagation.
  • Applied the method to analyze specific integrated optics devices, such as directional couplers and Y-junctions.
  • Main Results:

    • The extended BPM successfully simulated light propagation in anisotropic media, showing good agreement with theoretical predictions.
    • Analysis of integrated optics devices revealed the significant impact of anisotropy on device performance, including mode confinement and coupling efficiency.
    • The method demonstrated computational efficiency for analyzing complex photonic structures.

    Conclusions:

    • The extended beam propagation method provides a powerful and accurate tool for simulating optical phenomena in anisotropic integrated optics.
    • This advancement facilitates the design and optimization of next-generation photonic devices by enabling precise modeling of anisotropic effects.
    • The developed formalism is broadly applicable to various integrated optical components and systems.