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Standing Waves in a Cavity01:28

Standing Waves in a Cavity

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A household microwave and lasers are examples of standing electromagnetic waves in a cavity. When two conducting metal plates are placed parallel at the nodal planes, it creates a cavity where standing waves are formed. The cavity between the two planes is analogous to a stretched string held at the points x = 0 and x = L. Here, the distance 'L' between the two planes must be an integer multiple of half of the wavelength. The wavelengths that satisfy this condition are given by:
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Modes of Standing Waves: II01:04

Modes of Standing Waves: II

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The starting point for expressing the modes of standing waves is understanding the boundary conditions that the waves must follow. The boundary conditions are derived from the physical understanding of how the standing waves are sustained, that is, how the vibrating particles of the medium behave at the boundaries imposed on them.
For a tube open at one end and closed at the other filled with air, the modes are such that there is always an antinode at the open end and a node at the closed end....
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Propagation of Waves01:07

Propagation of Waves

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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...
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Standing Waves01:17

Standing Waves

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Sometimes waves do not seem to move; rather, they just vibrate in place. Unmoving waves can be seen on the surface of a glass of milk kept in a refrigerator, which is one example of standing waves. Vibrations from the refrigerator motor create waves on the milk that oscillate up and down but do not seem to move across the surface. These waves are formed or created by the superposition of two or more identical moving waves in opposite directions. The waves move through each other, with their...
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Equations of Wave Motion01:02

Equations of Wave Motion

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Mathematically, the motion of a wave can be studied using a wavefunction. Consider a string oscillating up and down in simple harmonic motion, having a period T. The wave on the string is sinusoidal and is translated in the positive x-direction as time progresses. Sine is a function of the angle θ, oscillating between +A and −A and repeating every 2π radians. To construct a wave model, the ratio of the angle θ and the position x is considered.
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Travelling Waves01:04

Travelling Waves

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A wave is a disturbance that propagates from its source, repeating itself periodically, and is typically associated with simple harmonic motion. Mechanical waves are governed by Newton's laws and require a medium to travel. A medium is a substance in which a mechanical wave propagates, and the medium produces an elastic restoring force when it is deformed.
Water waves, sound waves, and seismic waves are some examples of mechanical waves. For water waves, the wave propagation medium is...
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Related Experiment Video

Updated: Jul 5, 2025

Fabrication And Characterization Of Photonic Crystal Slow Light Waveguides And Cavities
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Fabrication And Characterization Of Photonic Crystal Slow Light Waveguides And Cavities

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Computing leaky Lamb waves for waveguides between elastic half-spaces using spectral collocation.

Evripides Georgiades1, Michael J S Lowe1, Richard V Craster1,2

  • 1Department of Mechanical Engineering, Imperial College London, London SW7 1AY, United Kingdom.

The Journal of the Acoustical Society of America
|January 23, 2024
PubMed
Summary
This summary is machine-generated.

A new spectral collocation method accurately computes complex leaky waves in elastic waveguides, overcoming numerical challenges for non-destructive evaluation. This advance enhances guided wave inspection capabilities.

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Area of Science:

  • Acoustics
  • Materials Science
  • Computational Mechanics

Background:

  • Guided wave inspections in non-destructive evaluation involve elastic structures embedded in other media.
  • Calculating leaky waves in such systems is complex due to non-trivial wave propagation and numerical challenges.
  • Existing methods struggle with the exponential amplitude growth of leaky waves in surrounding media.

Purpose of the Study:

  • To develop an accurate and efficient numerical method for identifying leaky wave modes in elastic waveguides.
  • To address the challenges posed by complex wavenumber solutions in leaky wave computation.
  • To enable reliable analysis of guided wave propagation in embedded elastic structures.

Main Methods:

  • A spectral collocation method was employed to discretize elastic domains.
  • Complex paths were mapped using domain discretization, tailored to exterior bulk wavespeeds, ensuring numerical decay and physical preservation.
  • The method iterated through all radiation cases to retrieve dispersion and attenuation curves.

Main Results:

  • The spectral collocation method accurately identified leaky wave modes propagating into elastic half-spaces.
  • Full sets of dispersion and attenuation curves were successfully retrieved.
  • Results were validated against the commercial software 'Disperse' and finite element simulations.

Conclusions:

  • The presented spectral collocation method offers an accurate and efficient solution for computing leaky waves in complex elastic systems.
  • This method overcomes limitations of existing numerical techniques, particularly regarding amplitude growth in surrounding media.
  • The findings are crucial for advancing non-destructive evaluation techniques using guided waves in embedded structures.