Talk:Minkowski inequality

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proof is incomplete

Latest comment: 16 years ago7 comments2 people in discussion

The proof is incomplete as one of the conditions to use Hoelder's inequality is in this case that ${\displaystyle |f+g|^{p-1}\in L^{q}}$  or equivalently that ${\displaystyle |f+g|\in L^{p}}$ . To avoid reasoning circularly this would have to be proved without using the Minkowski inequality. Anybody knows how to do this in a nice way? --MarSch 13:58, 1 October 2007 (UTC)Reply

This condition is not necessary for the use of Holder's inequality (it is only used if one wants to prove that both sides of Holder's inequality are finite). R.e.b. 15:20, 1 October 2007 (UTC)Reply

The current proof of Hölder's inequality uses this finiteness condition to justify, in effect, division (normalization). So if what you say is correct then the problem has merely shifted from here to there. --MarSch 13:23, 2 October 2007 (UTC)Reply

Holder's inequality holds trivially if one of the functions has infinite norm. R.e.b. 14:59, 2 October 2007 (UTC)Reply

You are correct of course. --MarSch 16:58, 2 October 2007 (UTC)Reply

The division by ${\displaystyle (\|f+g\|_{p})^{p-1}}$  at the end of the proof also requires that finiteness of ${\displaystyle \|f+g\|_{p}}$  has been proven. --MarSch 10:54, 3 October 2007 (UTC)Reply

Okay, I think we're all good now. Thanks R.e.b.. --MarSch 12:19, 4 October 2007 (UTC)Reply

The proof is due to Hardy and Littlewood

Latest comment: 15 years ago1 comment1 person in discussion

I believe so, but I don't have a source confirming it at hand. So, I'm putting this here instead of the article. -- Taku (talk) 00:12, 2 January 2009 (UTC)Reply

Comments for Minkowski's integral inequality.

Latest comment: 11 years ago1 comment1 person in discussion

Since the integral form is for some obscure reason often not covered in elementary textbooks, I find that the section concerning the integral form ought to be put in a completely precise form. In that regard, the conditions stated are insufficient. Both measures are usually assumed sigma-finite. The proof of the integral form is more or less the same as the non-integral version (with an extra limit argument to assure finiteness), but relies on the Fubini-Tonelli Theorem (at the point where sum and integration are interchanged), which is where the sigma-finite condition enters. Note that the standard counter example to the Fubini-Tonelli Theorem for non-sigma-finite measures is also a counter example for Minkowski's Integral Inequality for non-sigma-finite measures: Take ${\displaystyle f:[0,1]\times [0,1]\rightarrow [0,1]}$  with f(x,y)=1 if x=y and zero otherwise, and put Lebesgue meaure in one coordinate and counting measure in the other. The sigma-finite condition on both measure spaces is thus not superfluous.

Also, I find the following form of Minkowski's Integral Inequality enlightening, as it shows in a pretty neat fashion the relation between the 'normal' Minkowski inequality and the integral version (generalising by considering integrals instead of sums):

Note that the standard Minkowski Inequality can be put in the form

${\displaystyle \|\!\sum _{j}\!f_{j}\|_{p}\leq \sum _{j}\!\|f_{j}\|_{p}}$ .

Now we see that the integral form can equivalently be cast in the form

${\displaystyle \|\!\int \!F(x,\cdot )\,dx\|_{p}\leq \int \!\|F(x,\cdot )\|_{p}\,dx}$ ,

where the dot means that the norm is calculated with respect to the dotted variable. Isdatmaths (talk) 09:21, 14 February 2013 (UTC)Reply

Cleaner proof from Tao

Latest comment: 6 years ago1 comment1 person in discussion

How does the community feel about the proof presented on this page? In Terence Tao's "An Epsilon of Room", he presents a short proof (Lemma 1.3.3) that doesn't rely on any other results like Hoelder's inequality. It's a simple convexity argument that seems like it'd be more approachable to a layman who has not seen either Holder or Minkowski before. — Preceding unsigned comment added by Snakeboy666 (talk • contribs) 14:51, 3 February 2018 (UTC)Reply

Topology by Muhammad amin

Latest comment: 1 year ago1 comment1 person in discussion

Lemma.minkowski inequality proof 119.73.115.23 (talk) 19:21, 16 January 2023 (UTC)Reply