Talk:Buckingham π theorem

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I don't understand. Could you give an example? --non-mathematician

Surely the reduction is by the number of dependent variables? As it stands I don't think this explanation makes sense. David Martland 16:01 Dec 6, 2002 (UTC)

It's really a theorem about free abelian groups, though.

Charles Matthews 07:34, 17 Sep 2003 (UTC)

I removed the example about the atomic bomb because it is not correct: Taylor did not use dimensional analysis to make his estimates. The example could be reinstated if it is rewritten to say that it is possible to arrive at a result similar to Taylor's using dimensional analysis. — Preceding unsigned comment added by 82.83.58.235 (talk) 19:11, 1 December 2011 (UTC)[reply]

The example about the period of a pendulum seems a little confused between G and g -- the universal gravitational constant of the known universe, or the acceleration due to gravity on the surface of the Earth. The period of a pendulum is independent of the mass of the pendulum, but not independent of the mass of the Earth or the radius from its center. The discussion is right except for giving the units of g: not "length cubed divided by time squared divided by mass", but "length divided by time squared".

I've gone ahead and made that change. Other minor readability things would still help here. Also sorry for forgetting a summary of the edit.

One would think such a simple yet powerful algorithm would have direct application to physics engines, despite the fact that it yields no solutions. Surprisingly, I can't seem to find any such uses. If anyone knows of such an implementation, please make the relevant changes.

I wish there was some public-domain software available to use this theorem, as I think its wonderful to be able to magically generate a formula(s) for anything you like, but I'm not much of a mathematician.

Using the constraints of Levels of Measurement and Extensive and Intensive measurements could further constrain the formulas generated.

I've read through this about fifty times and I'm not clear on how ${\displaystyle \pi _{0}}$ changes to ${\displaystyle g(\pi _{1})}$. Shouldn't it be an addition of that ${\displaystyle g}$ value, and not a multiplication? --aciel 00:47, 1 February 2007 (UTC)[reply]

Its because ${\displaystyle f(\pi _{0},\pi _{1})=0}$. Because of this, you can say ${\displaystyle \pi _{0}=g(\pi _{1})}$. For example, if ${\displaystyle f(\pi _{0},\pi _{1})=\pi _{1}^{2}-{\sqrt {\pi _{0}}}+3}$ then, because ${\displaystyle f(\pi _{0},\pi _{1})=0}$ it follows that ${\displaystyle \pi _{0}=(\pi _{1}^{2}+3)^{2}}$ PAR 01:28, 1 February 2007 (UTC)[reply]

The g isn't a value, anyway, it symbolizes a function.

If this helps, choose a constant value for ${\displaystyle \pi _{1}}$ so then you can think of ${\displaystyle f(\pi _{0},\pi _{1})=0}$ (for all values of ${\displaystyle \pi _{0}}$) as defining a new function (which we may name ${\displaystyle h_{\pi _{1}}}$) such that ${\displaystyle h_{\pi _{1}}(\pi _{0})=0}$. Then simply invert it to see ${\displaystyle \pi _{0}=h_{\pi _{1}}^{-1}(0)}$. If you consider this proceedure for various values of ${\displaystyle \pi _{1}}$ you are basically saying that ${\displaystyle \pi _{0}=g({\pi _{1}},0)}$ or more importantly ${\displaystyle \pi _{0}=g_{0}({\pi _{1}})}$. An alternative approach is to define the function ${\displaystyle g_{0}}$ in the following way: for any single particular value of ${\displaystyle \pi _{1}}$, consider every possible value of ${\displaystyle x}$ and try inserting each of those values into ${\displaystyle f(x,\pi _{1})}$ until you find the one that gives you zero, then define "${\displaystyle g_{0}(\pi _{1})}$" as that special value found for x. At least this ensures ${\displaystyle f(g_{0}(\pi _{1}),\pi _{1})=0}$. Provided that there is only exactly one possible value that works for ${\displaystyle g_{0}(\pi _{1})}$, this proves that in those circumstances ${\displaystyle \pi _{0}}$ would also share the same value. Cesiumfrog (talk) 23:54, 4 November 2010 (UTC)[reply]

I am inclined to agree with the original concerned poster...this aspect of the example is not as clear as it could be for the typical reader. It omits some intermediate steps that I think most won't immediately understand without some explanation. Without it, this example doesn't make sense to someone who simply wants to understand how to use the Buckingham ${\displaystyle \pi }$ methodology. This could be improved if a "qualified" person expands this part of the page. --Lacomj (talk) 23:22, 14 May 2011 (UTC)[reply]

Surely someone can right up a better example for the use of this theorem?

The best I can come up with off the top of my head would be matching parameters (Reynolds, Mach numbers, etc) for wind tunnel or other such scaled fluid flow modeling.

130.134.81.16 20:18, 10 July 2007 (UTC)[reply]

...as Π is usually for "product". Or does it matter? (to anyone?) Wikicat (temp-2k7) 14:10, 25 October 2007 (UTC)[reply]

I believe the name is taken from Buckinghams use of lower case π to represent the dimensionless parameters. So it would be lower case, not upper case. PAR 18:26, 25 October 2007 (UTC)[reply]

The so-called "proof" is nothing but an explanation of how to treat dimensions as a vector space. It doesn't actually prove the theorem, even informally. Halberdo (talk) 09:15, 11 March 2009 (UTC)[reply]

Agreed. The "proof" is only a statement about dimensions. there's not even a hint of why this matters at all, or why this could help with scaling. 2803:9800:9504:7B33:D973:7310:557A:AC54 (talk) 02:27, 17 May 2022 (UTC)[reply]

Agreed. That "proof" is not a proof at all, most of all not formal. There is nothing said, for example, about the rank of the dimensional matrix. Besides, the theorem, that's at least my opinion, is wrongly stated. It's the something like the maximum number of linear independent dimensionless terms that the PI-Theorem makes a statement about, if I'm not mistaken. Added confusing template ManDay (talk) 14:13, 21 January 2011 (UTC)[reply]

This article contained this:

(p=n-k)-dimensional

I changed it to this:

(p = n − k)-dimensional

Variables should be italicized; parentheses and digits should not. A minus sign differs from a hyphen. Proper spacing should be used.

See WP:MOSMATH. 138.192.56.24 (talk) 00:55, 6 May 2011 (UTC)[reply]

The cooling power of a cold surface is given by heat transfer = surface area * delta T * heat transfer coefficient, and thus directly proportional to surface area. The cooling rate of an equal volume of smaller ice cubes is thus proportional to 1/length of the cubes as correctly explained in the article. This is simple, straightforward Physics. If the Buckingham Pi Theorem is invoked to claim this is wrong, then please also explain what is wrong with the straightforward calculation with basic Physics. It seems far less likely to me that simple Physics formulas are wrong than the more complex argument with the dimensional analysis. As an experimental Physicist, I would think that this kind of assertion should anyway be accompanied by a measurement.

Thinking more about this, I think I see the problem with the Pi Theorem argument: the cooling power of a given ice cube is indeed proportional to its surface area, and that is what the Pi Theorem calculation picks up in the example. However, that is not what we are looking for. There is a boundary condition that the Pi Theorem does not know about, namely that a GIVEN CONSTANT volume V of ice cubes is put in the liquid. This causes the surface area of the cubes to scale with 1/l, which has nothing to do with the Physics of this process itself, but is a consequence of the boundary condition.

— Preceding unsigned comment added by 147.86.223.1 (talk) 06:54, 10 November 2021 (UTC)[reply]

The example was removed in February, so I won't reinstate it until people have had a chance to discuss how to improve the exposition as requested. One explanation here [1] is there are more layers of molecules for the heat to conduct through to the centre after passing through the surface, which introduces a length factor separate from the volume-to-surface-area ratio.

The heat equation ${\displaystyle {\dot {T}}=D\nabla ^{2}T}$ provides a shorter proof the time scales as ${\displaystyle L^{2}}$: since ${\displaystyle D}$ has dimension ${\displaystyle {\mathsf {L}}^{2}{\mathsf {T}}^{-1}}$, ${\displaystyle L^{2}/D}$ is a timescale. This argument is famously applied to cooking time too. (Slide 18 here [2] phrases it in terms of rescaling rather than dimensional analysis.) 2A02:C7E:2C9:9300:3DC3:47BB:5335:58BA (talk) 10:41, 10 April 2022 (UTC)[reply]