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A close look at earthquakes provides evidence for the conditions appropriate for resonance, standing waves, and constructive and destructive interference. A building may vibrate for several seconds with a driving frequency matching the building's natural frequency of vibration; this produces a resonance that results in one building collapsing while the neighboring buildings do not. Often, buildings of a certain height are devastated, while other taller buildings remain intact. This...
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In the case of stringed instruments like the guitar, the elastic property that determines the speed of the sound produced is its linear mass density or the mass per unit length. This is simply called the linear density. If the string's linear density is constant along the string, then the linear density is simply the total mass divided by the total length.
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A torsional pendulum involves the oscillation of a rigid body in which the restoring force is provided by the torsion in the string from which the rigid body is suspended. Ideally, the string should be massless; practically, its mass is much smaller than the rigid body's mass and is neglected.
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Resonance is produced depending on the boundary conditions imposed on a wave. Resonance can be produced in a string under tension with symmetrical boundary conditions (i.e., has a node at each end). A node is defined as a fixed point where the string does not move. The symmetrical boundary conditions result in some frequencies resonating and producing standing waves, while other frequencies interfere destructively. Sound waves can resonate in a hollow tube, and the frequencies of the sound...
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Modes of Standing Waves: II01:04

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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.
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Related Experiment Video

Updated: Sep 26, 2025

Hemi-laryngeal Setup for Studying Vocal Fold Vibration in Three Dimensions
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Helmholtz vibrations in bowed strings.

R B Schwarz1

  • 1Materials Science Division, Los Alamos National Laboratory, Mail Stop G755, Los Alamos, New Mexico 87544, USA.

The Journal of the Acoustical Society of America
|April 24, 2022
PubMed
Summary
This summary is machine-generated.

Helmholtz oscillations in bowed instruments involve "slip" and "stick" regimes. This study models the "stick" phase, revealing energy gain during sticking and loss during slipping for vibrating strings.

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Area of Science:

  • Musical Acoustics
  • Vibrational Mechanics
  • Friction and Tribology

Background:

  • Helmholtz oscillations are fundamental to bowed string instruments (violin, cello).
  • Two regimes, 'slip' and 'stick,' characterize bow-string interaction.
  • The 'slip' regime is understood via velocity-dependent friction; the 'stick' regime remains less understood.

Purpose of the Study:

  • To propose and validate a physical model for the 'stick' regime of Helmholtz oscillations.
  • To understand the hair-string interaction force during the 'stick' phase.
  • To analyze the energy transfer dynamics in bowed string vibrations.

Main Methods:

  • Proposed a model where 'stick' interaction force is proportional to bow hair's acoustic impedance and relative velocity.
  • Solved the string's differential equation of motion with an enhanced formulation.
  • Avoided parasitic high-frequency oscillations in the model.

Main Results:

  • Validated the proposed physical model for the 'stick' regime.
  • Analyzed real-time characteristics: string shape, harmonic excitation, Schelleng ripples, and string energy.
  • Demonstrated energy gain by the bowed string during the 'stick' regime and energy loss during the 'slip' regime.

Conclusions:

  • The 'stick' regime's interaction force is linked to acoustic impedance and relative velocity.
  • The developed physical model accurately captures Helmholtz oscillation dynamics.
  • Bowed strings gain energy during 'stick' and lose it during 'slip,' explaining oscillation sustainment.