Edge Tone

When air is directed at an edge, it does not divide smoothly, but tends to move to one side and form a swirl or vortex. Predisposed toward vortex formation by the flow through the slit, the resulting undulating flow may take the stream below the edge. As noted below, the behavior of an edge which is associated with a pipe is quite different from that of a free edge.

The pressure created by this interaction with the edge feeds back to the area of the slit, tending to push the stream upward. The reverse happens when the stream moves to the top side of the edge and then the process repeats itself. As a result, a periodic flipping of the airstream from side to side can produce a sound called an edge tone. More efficient edge tone instruments can be created by coupling a slit, an edge, and an air column. When such an instrument has been produced, the frequency is determined primarily by the air column resonant frequencies which will control the rate of oscillation of the air across the edge. The edgetone effect in such an instrument serves to help initiate and sustain the tone, and can help make the transition to a higher harmonic of the air column.

The difference between the "edgetone" as envisioned in the sounding of a flute, recorder, organ pipe, etc. and the tones produced by directing air over an edge which is not coupled to an air column has been a subject of considerable discussion and investigation. Benade comments "Until recently there has been a tendency ... to confuse the sounds produced by blowing a narrow air jet against a sharp edge when the edge forms part of a flute or an organ pipe (air reed behavior) with those produced when the system is run in isolation (edge-tone behavior). In the latter case a type of repetitive eddying called vortex shedding takes place on alternate sides of the air jet, and a sound is produced if a sharp edge is used to separate the two sets of vortices. Vortex phenomena have only a secondary influence on flute-type sound production; moreover, at ordinary musical blowing pressures the edge-tone frequencies are so high as to be nearly inaudible.

Some of the literature which addresses the differences between the free edgetones and the behavior of the edges in flutes and organ pipes:

  1. Coltman, John W., "Sounding Mechanism of the Flute and Organ Pipe", J. Acoust. Soc. Am. 44 (1968)
  2. Fletcher, N. H., "Nonlinear Interactions in Organ Flue Pipes," J. Acoust. Soc. Am. 56 (1974)
  3. Bouasse, H., Instruments a' Vent, 2 vols., Paris: Librairie Delagrave, 1929,1930.
  4. Cremer, L. and Ising, H., "Die selbsterregten Schwingungen von Orgelpfeifen," Acustica 19, 143-153,(1968)
  5. Elder, S. A., "Edgetones versus Pipetones," J. Acoust. Soc. Am. 64, 1721-1723, (1978)

Effect of increasing air velocityChanging slit-to-edge distanceFlute as edge tone instrument
"Flow-controlled valve model" for pipe excitation
Index

Woodwind instruments

Musical instruments

References
Benade
Sec 22.6, p492
 
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Slit, Edge and Air Column

The slit aids tone production because air forced through a slit or small opening tends toward an undulating path with side eddies spun off from it. This aids the vortex formation when it strikes the edge.

The unconstrained edge tone has a frequency proportional to the airstream velocity and inversely proportional to the diameter of the edge. It is a source of oscillation in the air and helps initiate and sustain the tone produced by airflow over an isolated edge. For musical instruments such as the flute and organ pipe, the role of the edge is viewed differently; the unconstrained edge frequency is actually much higher than the playing frequency. The oscillation in the pipe is sometimes modeled as a "flow-controlled valve". The air column has natural resonant frequencies determined by its length and tends to take control and determine the frequency of the tone initiated by the air oscillation at the edge. The air column becomes the dominant effect on the air vibrations in the instrument, and will force the air oscillation at the edge to match the natural frequency of the air column.
Edge tone
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Air Oscillations from Slits

When air is forced through a small opening or slit, the fast-moving airstream moves through slower air. It's edges meet resistance from that slower air and tend to peel back and form vortices. These vortices interact with the stream, exerting a sideways influence on it and causing it to move in an undulating path. This undulation can actually produce a substantial amount of sound, as when you whistle. An even greater amount of sound can be produced by coupling the slit to an edge.

The undulations in the stream move along the stream at something less than one half the speed of the air in the stream ( about 0.4 V according to Backus). Then the faster the airstream speed, the faster the oscillations of the stream when it hits an edge.

For other discussions see Rigden p114 and Backus p 220.
Flute discussion
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Woodwind instruments

Musical instruments

Reference
Hall
p. 235
 
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Slit and Edge

For a slit and an edge, not coupled to an air column, the frequency of the edgetone tends to be about

for the first main edgetone regime.

This regime, referred to as Region I of the edgetone behavior, is the main operating mode for organ pipes and presumably also for the flute. Note that the pitch can be made to go up by either increasing the airstream velocity, or by decreasing the distance from the slit to the edge (both applicable to playing the flute). Because of the feedback mechanism to the slit, the effective diameter of the edge does not figure directly in this pitch relationship as it does in the case of aeolian tones.

Flute discussion
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Woodwind instruments

Musical instruments

Reference
Hall
p. 235
 
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