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Hey. I did the rewrite, but I wasn't logged in. This is my first major rewrite, any comments or critiques would be appreciated (Andy Huston 03-21-2007)
I believe there is an error in the "Tension" section.
I direct your attention first to the sentence: "Increasing tension causes the sound waves to travel faster through the string." I find this sentence misleading because it suggests that the speed of the sound wave being transmitted increases as tension in the string increases and that the increased speed of the sound wave results in an increased frequency. Of course the speed of sound does not increase, it is the rate of vibration of the string that increases.
Secondly, and more significantly, I direct your attention to the first sentence in the second paragraph: "Because the length of the violin, which determines the wavelength of the sound waves, is constant, an increase in tension will cause a proportional change in the frequency." The equation cited, f*λ = v, is not really relevant to the discussion as string tension is not involved in the equation. The meaning which is conveyed is that wavelength remains contant and the frequency increrases proportionally to the velocity, which in turn increases proportionally to string tension. In fact it is velocity which remains constant in the above equation. Wavelength and frequency are always inversely proportional, and the wavelength is not absolutely determined (ie. fixed) by the length of the string (or violin). That would also mean that the frequency is fixed by the length of the violin! Which is absurd. Absurd! :)
Biirnats ( talk) 06:38, 22 April 2008 (UTC)
I appreciate that someone has put quite a bit of work into this article, presumably, since there is a lack of citations, from their own understanding, and I commend it. However, it is very confusing to read. At some point the article needs to explain that The bow hair sliding across the string sets up a vibration/standing wave in the string, which in turn causes the bridge to vibrate, which causes the table and the soundpost to vibrate, and the sound post causes the back to vibrate, and it is the combination of the table and back plates vibrating that creates the sound. As it is written at the moment, one might think the vibrating string is what is causing the sound. Chickpeana ( talk) 21:44, 13 November 2009 (UTC)
The whole article needs dusting off and refurbishing, but here are just a few particular observations:
The "Bow" section is an oversimplification. The equations give it a science-y appearance, but they are based on some unwarranted simplifications. Primarily, the stick-slip behavior of rosined hair is unlikely to be characterized by a single time-invariant scalar coefficient of friction. Higher-order effects of bow stick dynamics and hair elasticity make a significant difference to the sound, I believe. No doubt there is more to it than that...
I doubt that any serious violin-maker uses Chladni patterns as a routine tool for graduating top and back plates.
The whole business of transferring string vibrations to the surrounding air is described in fuzzy language
This article appears to be based on some general knowledge of violins and basic physics. It does not look like it was written by someone who has studied violin physics in depth, nor does it look like there has been much input from anyone who has actually built a violin. Not bad, but still very stubby, in my opinion.
The UNSW site does seem to be a valuable source here. __ Just plain Bill ( talk) 05:19, 17 January 2011 (UTC)
Thanks to all those who have contributed to this valuable article. I have corrected or removed a few of the more egregious physics fallacies, but there are still others. No personal criticism intended, but whoever wrote this article has only a tenuous understanding of the physics involved. For example, it is clearly wrong to state that the length of the violin "determines" the wavelength; consider that 4/4, 3/4, 2/4, and 1/4 violins all produce exactly the same notes ("wavelengths"), despite being of greatly different sizes.
Again, the effort is appreciated, and this is a good stub, but someone needs to clarify and clean up the physics explanations. __ Spoxjox ( talk) 22:50, 2 February 2011 (UTC)
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The result of the move request was: Moved to Violin acoustics per resounding consensus ( non-admin closure) Red Slash 19:21, 14 May 2020 (UTC)
Basic physics of the violin →
Physics of the violin – The term 'basic' is relative—what is simple and easy to comprehend to one reader may not be to someone else—and appears to be little used in other Wikipedia articles in this context. None of the sources so far listed in the article distinguish between the 'basic' physics of the violin family of instruments and physics which is more advanced (e.g. more mathematical or more in depth.
Amitchell125 (
talk) 07:07, 7 May 2020 (UTC)
The lead sentence of the Strings section says: "The open strings of a violin are of the same length from the bridge to the nut of the violin, but vary in pitch because they have different masses per unit length."
I thought that the violin strings different frequency was due to being screwed to different tensions. Geo Swan ( talk) 16:25, 10 May 2020 (UTC)
Under the section "Comparison with other members of the violin family," the average size of a violin is listed as 23⅜ inches, a viola is 27¼ inches, the cello is 48 inches, and the double bass is 74 inches. But it isn't clear what is being measured, or why the overall length is relevant. Unless I'm mistaken, only the length of the resonating body (minus the neck) matters for each instrument's overall sound, and that's typically 14 inches for a violin, 15-16½ inches for a viola (since it has no single standard size), roughly 30 inches for a cello, and about 41 inches for double bass. Bo Bogus ( talk) 09:16, 10 February 2024 (UTC)