Helmholtz resonance

Helmholtz resonance

Helmholtz resonance is the phenomenon of air resonance in a cavity. The name comes from a device created in the 1850s by Hermann von Helmholtz to show the height of the various tones. An example of Helmholtz resonance is the sound created when one blows across the top of an empty bottle.

Qualitative explanation

When air is forced into a cavity, the pressure inside increases. Once the external force that forces the air into the cavity disappears, the higher-pressure air inside will flow out. However, this surge of air flowing out will tend to over-compensate, due to the inertia of the air in the neck, and the cavity will be left at a pressure slightly lower than the outside, causing air to be drawn back in. This process repeats with the magnitude of the pressure changes decreasing each time.

This effect is akin to that of a bungee-jumper bouncing on the end of a bungee rope, or a mass attached to a spring. Air trapped in the chamber acts as a spring. Changes in the dimensions of the chamber adjust the properties of the spring: a larger chamber would make for a weaker spring, and vice-versa.

The air in the port (the neck of the chamber) is the mass. Since it is in motion, it possesses some momentum. A longer port would make for a larger mass, and vice-versa. The diameter of the port is related to the mass of air and the volume of the chamber. A port that is too small in area for the chamber volume will "choke" the flow while one that is too large in area for the chamber volume tends to reduce the momentum of the air in the port.

Quantitative explanation

It can be shown [ [http://www.lightandmatter.com/html_books/0sn/ch05/ch05.html#Section5.5 Derivation of the equation for the resonant frequency of an Helmholtz resonator.] ] that the resonant frequency is given by::omega_{H} = sqrt{gammafrac{A^2}{m} frac{P_0}{V_0 (rad/s) ,

where:
*gamma (gamma) is the adiabatic index or ratio of specific heats. This value is usually 1.4 for air and diatomic gases.
* "A" is the cross-sectional area of the neck
*m is the mass in the neck
* "P0" is the static pressure in the cavity
* "V0" is the static volume of the cavity

For cylindrical or rectangular necks, we have: A = frac{V_n}{L} ,

where:
* "L" is the length of the neck
* "V_n" is the volume of air in the neckthus::omega_{H} = sqrt{gammafrac{A}{m} frac{V_n}{L} frac{P_0}{V_0

By the definition of density: frac{V_n}{m} = frac{1}{ ho} , thus:

:omega_{H} = sqrt{gammafrac{P_0}{ ho} frac{A}{V_0 L,and: f_H = frac{omega_H}{2pi} ,

where:
* "fH" is the resonant frequency (Hz)

The speed of sound in a gas is given by:

: v = sqrt{gammafrac{P_0}{ ho ,

thus, the frequency of the resonance is:

:f_{H} = frac{v}{2pi}sqrt{frac{A}{V_0L

The length of the neck appears in the denominator because the inertia of the air in the neck is proportional to the length. The volume of the cavity appears in the denominator because the spring constant of the air in the cavity is inversely proportional to its volume. The area of the neck matters for two reasons. Increasing the area of the neck increases the inertia of the air proportionately, but also decreases the velocity at which the air rushes in and out.

Applications

Helmholtz resonance finds application in internal combustion engines (see airbox), subwoofers and acoustics. In stringed instruments, such as the guitar and violin, the resonance curve of the instrument has the Helmholtz resonance as one of its peaks, along with other peaks coming from resonances of the vibration of the wood. An ocarina is essentially a Helmholtz resonator where the area of the neck can be easily varied to produce different tones. The West African djembe has a relatively small neck area, giving it a deep bass tone. The djembe may have been used in West African drumming as long as 3,000 years ago, making it much older than our knowledge of the physics involved.

Helmholtz resonators are used in architectural acoustics to reduce undesirable sounds (standing waves etc.) by building a resonator tuned to the problem frequency thereby eliminating it, most usually used for low frequency waves.

References


* Oxford Physics Teaching, History Archive, " [http://www.physics.ox.ac.uk/history.asp?page=Exhibit3 Exhibit 3 - Helmholtz resonators] " "(archival photograph)"
* [http://hyperphysics.phy-astr.gsu.edu/hbase/ph4060/p406ex2.html HyperPhysics Acoustic Laboratory]
* [http://hyperphysics.phy-astr.gsu.edu/hbase/waves/cavity.html HyperPhysics Cavity Resonance]
* [http://www.vibrationdata.com/Newsletters/January2004_NL.pdf Beverage Bottles as Helmholtz Resonators] "Science Project Idea for Students"
* [http://www.phys.unsw.edu.au/jw/Helmholtz.html Helmholtz Resonance] (web site on music acoustics)

Wikimedia Foundation. 2010.

Игры ⚽ Нужно сделать НИР?

Look at other dictionaries:

  • Helmholtz-Resonator — Ein Helmholtz Resonator (benannt nach Hermann von Helmholtz) ist ein akustischer Resonator. Dem Laien aus dem Alltag bekannt sein dürfte er als Flasche, die, am Hals angeblasen, einen Ton erzeugt. Helmholtz Resonator aus Messing von ca. 1900 …   Deutsch Wikipedia

  • HELMHOLTZ (H. L. F. von) — Il n’est guère de domaines des sciences de la nature auxquels Helmholtz n’ait consacré quelque recherche. On pourrait répéter à son endroit ce qu’il disait lui même de Friedrich von Humboldt dans sa célèbre conférence inaugurale du colloque… …   Encyclopédie Universelle

  • résonance — [ rezɔnɑ̃s ] n. f. • v. 1450 mus.; de résonner 1 ♦ Prolongement ou amplification des sons dans certains milieux sonores (⇒ résonner). « Dans ce tombeau, un grignotement de rat [...] prenait des résonances étranges » (Gautier). Caisse de résonance …   Encyclopédie Universelle

  • resonance theory — n 1) a theory of hearing: different sections of the basilar membrane of the organ of Corti are tuned to different vibration rates and set up sympathetic vibrations that stimulate sensory nerve endings when the cochlear endolymph is vibrating at a …   Medical dictionary

  • Résonance de Helmholtz — Résonateur de Helmholtz en laiton. La résonance de Helmholtz est un phénomène de résonance de l air dans une cavité. Le nom provient d un dispositif créé dans les années 1850 par Hermann von Helmholtz afin de déterminer la hauteur des différents… …   Wikipédia en Français

  • Helmholtz — Hermann Ludwig von Helmholtz Hermann von Helmholtz Hermann Ludwig Ferdinand von Helmholtz était un scientifique, physiologiste et acousticien, né le 31 août 1821 à Potsdam et décédé à Berlin en 1894. Il démarra sa carrière comme médecin …   Wikipédia en Français

  • Helmholtz theory — an early theory of sound perception, now disproved; it held that each basilar fiber responded sympathetically to a definite tone and stimulated the hair cells of Corti organ, causing nerve impulses that were then carried to the brain. Called also …   Medical dictionary

  • Hermann von Helmholtz — Infobox Scientist name = Hermann von Helmholtz |225px image width = 225px caption = Hermann Ludwig Ferdinand von Helmholtz birth date = birth date|1821|8|31|mf=y birth place = Potsdam, Kingdom of Prussia residence = Germany nationality = German… …   Wikipedia

  • Hermann Ludwig von Helmholtz — Naissance 31 août 1821 Potsdam (Prusse) Décès 8 septe …   Wikipédia en Français

  • Hermann Helmholtz — Hermann Ludwig von Helmholtz Hermann von Helmholtz Hermann Ludwig Ferdinand von Helmholtz était un scientifique, physiologiste et acousticien, né le 31 août 1821 à Potsdam et décédé à Berlin en 1894. Il démarra sa carrière comme médecin …   Wikipédia en Français

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”