This blog is dedicated to the sublime instruments called nose flutes and which produce the most divine sound ever. We have chosen to discard all the native models from S. Pacific and Asia, for they need fingering to be played. We'll concentrate on "buccal cavity driven" nose flutes : the well patented and trademarked metal or plastic ones, plus, by a condemnable indulgence, some wooden craft or home-made productions.

Sep 21, 2014

Nose Flute Physics - I

In june 2003, the Wright Center for Innovative Science Education, department of Tufts University (Medford, Massachusetts) published a book by David R Lapp, ant entitled The Physics of Music and Musical Instruments.

Mr. David Lapp is a Physics teacher who is the author of many Physics and Education publications (see here).



The Physics of Music and Musical Instruments is a 119 pages PDF book (download it here) with 7 chapters, among them one is dedicated to Aerophones (wind instruments). Those 24 pages are obviouly mostly devoted to the study of vibrations, air flow, sound waves, differences between open and closed pipes, providing the right equations for each type of instrument. The chapters include exercises and are ended by one or more "Investigation" sections. One of those, in the Aerophone chapter, is devoted to the nose flute.

The Nose Flute Investigation part begins with a presentation of our beloved instrument (represented here by a Trophy Humanatone specimen), and exposes it as being incomplete — Actually it is only part of a musical instrument — immediately followed by a a reassuring completion — the remainder being the mouth cavity of the player. No offence then, and contrarywise, it is a very clever point of view. Indeed, Mr. Lapp seems to be a nose flute friend: The result is a clear, pleasing, flute-like tone

The nose flute is comparable to a closed pipe, with a variable pitch, exactly like a slide whistle, which stopper would be your tongue. At the very end of the book, there is a Physics of Music Resource Vendors section, and the very last paragraph is this text:



Well, I'm not going to paraphrase what Mr. Lapp explains in his article, but just sum it up:

- Vibrations in a nose flute act as in a closed pipe, like a slide whistle
- The frequency provided by closed pipes is the result of the equation F = v/4L

(where v is the speed of sound and L the vibrating length)


The two next pages are a form of 6 questions-exercises. The two last are interesting, notably the #5:

If you played the nose flute, what is the lowest theoretical note on the Equal Tempered Scale that you personally would be able to get? (You will need to make a measurement to answer this question.)

Well, using the F = v/4L equation, with (v = 343 m/s for the speed of sound) and measuring my mouth depth drove me to wrong results... Indeed, I previously checked with a frequency meter the lowest and sharpest notes I can produce with a Bocarina nose flute.

I got 347 Hz (near F4 stands at 349 Hz) and 2321 Hz (near D7 at 2349 Hz). So, with 347 Hz at the lowest, with v=343 m/s, I get L=343/(4*347) = 0,247 meaning the vibrating length of my mouth is 24,7 cm !!

If someone can explain me this result...
Is F=v/4L really the right model to apply to a nose flute ?
Should it not be a Helmholtz resonator (much more tricky, by the way)?


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>>To Nose Flute Physics - Part 2

7 comments:

  1. Ah yes, the same applies for jew's harps (guimbardes en Français). In his mastrs thesis "Helmholts & coupled resonators acoustics in jew's harp playing" Sylvain Trias explains in 109 pages how it works. It's very complicated and beyond my capability to sum this up in a few words here. Better read it yourself. Here: https://docs.google.com/file/d/0B6Kf2pm4kLhFYjI3Mjc1YjctZjdmMi00MTMzLTg1MjAtODRhMmI0YzAyOWZh/edit?hl=en&pli=1 Jew's'harps are overtone instruments and noseflutes are not but the principles will remain the same I guess.
    Yours, Harm

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  2. Thank you Harm! I'm gonna read that good stuff :)

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  3. Again, great find! I love the questions which are great teasers.

    It would be very interesting to measure the wind tones and whisper tones that the nose flute can produce.

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  4. It's a very good and high level textbook !

    Wikipedia "Helmholtz resonance" is interesting.
    http://en.wikipedia.org/wiki/Helmholtz_resonance
    one of the links.
    http://hyperphysics.phy-astr.gsu.edu/hbase/waves/cavity.html


    The table of the whisler's tone range on this page is also interesting.
    # I coudn't find the original english source.
    http://torinaki.com/whistling-info/tone-range
    My range was F4 to G7.

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    1. Thank you for the links too, dear Hiroshi! I will study that and publish a second part to this little study

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  5. Well guys, it's good that there are people involved in physics and stuff, me for my part am just a lazy music player, besides that a diva, so you have my great respect and appreciation but I will not follow into the depths of noseflute physics, sorry :( - but really a cool thing to think about if you like to think ;)

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    1. Dear Diva, you are very welcome NOT to be interested in those technical posts! :) Your art flies far above those little considerations.

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