Minkowski inequality

In mathematical analysis, the Minkowski inequality establishes that the $L^{p}$ spaces satisfy the triangle inequality in the definition of normed vector spaces. The inequality is named after the German mathematician Hermann Minkowski.

Let ${\textstyle S}$ be a measure space, let ${\textstyle 1\leq p\leq \infty }$ and let ${\textstyle f}$ and ${\textstyle g}$ be elements of ${\textstyle L^{p}(S).}$ Then ${\textstyle f+g}$ is in ${\textstyle L^{p}(S),}$ and we have the triangle inequality

$\|f+g\|_{p}\leq \|f\|_{p}+\|g\|_{p}$

with equality for ${\textstyle 1<p<\infty }$ if and only if ${\textstyle f}$ and ${\textstyle g}$ are positively linearly dependent; that is, ${\textstyle f=\lambda g}$ for some ${\textstyle \lambda \geq 0}$ or ${\textstyle g=0.}$ Here, the norm is given by:

$\|f\|_{p}=\left(\int |f|^{p}d\mu \right)^{\frac {1}{p}}$

if ${\textstyle p<\infty ,}$ or in the case ${\textstyle p=\infty }$ by the essential supremum

$\|f\|_{\infty }=\operatorname {ess\ sup} _{x\in S}|f(x)|.$

The Minkowski inequality is the triangle inequality in ${\textstyle L^{p}(S).}$ In fact, it is a special case of the more general fact

$\|f\|_{p}=\sup _{\|g\|_{q}=1}\int |fg|d\mu ,\qquad {\tfrac {1}{p}}+{\tfrac {1}{q}}=1$

where it is easy to see that the right-hand side satisfies the triangular inequality.

Like Hölder's inequality, the Minkowski inequality can be specialized to sequences and vectors by using the counting measure:

${\biggl (}\sum _{k=1}^{n}|x_{k}+y_{k}|^{p}{\biggr )}^{1/p}\leq {\biggl (}\sum _{k=1}^{n}|x_{k}|^{p}{\biggr )}^{1/p}+{\biggl (}\sum _{k=1}^{n}|y_{k}|^{p}{\biggr )}^{1/p}$

for all real (or complex) numbers ${\textstyle x_{1},\dots ,x_{n},y_{1},\dots ,y_{n}}$ and where ${\textstyle n}$ is the cardinality of ${\textstyle S}$ (the number of elements in ${\textstyle S}$ ).

In probabilistic terms, given the probability space $(\Omega ,{\mathcal {F}},\mathbb {P} ),$ and $\mathbb {E}$ denote the expectation operator for every real- or complex-valued random variables $X$ and $Y$ on $\Omega ,$ Minkowski's inequality reads

\left(\mathbb {E} [|X+Y|^{p}]\right)^{\frac {1}{p}}\leqslant \left(\mathbb {E} [|X|^{p}]\right)^{\frac {1}{p}}+\left(\mathbb {E} [|Y|^{p}]\right)^{\frac {1}{p}}.

Proof

Proof by Hölder's inequality

First, we prove that ${\textstyle f+g}$ has finite ${\textstyle p}$ -norm if ${\textstyle f}$ and ${\textstyle g}$ both do, which follows by

$|f+g|^{p}\leq 2^{p-1}(|f|^{p}+|g|^{p}).$

Indeed, here we use the fact that ${\textstyle h(x)=|x|^{p}}$ is convex over ${\textstyle \mathbb {R} ^{+}}$ (for ${\textstyle p>1}$ ) and so, by the definition of convexity,

$\left|{\tfrac {1}{2}}f+{\tfrac {1}{2}}g\right|^{p}\leq \left|{\tfrac {1}{2}}|f|+{\tfrac {1}{2}}|g|\right|^{p}\leq {\tfrac {1}{2}}|f|^{p}+{\tfrac {1}{2}}|g|^{p}.$

This means that

$|f+g|^{p}\leq {\tfrac {1}{2}}|2f|^{p}+{\tfrac {1}{2}}|2g|^{p}=2^{p-1}|f|^{p}+2^{p-1}|g|^{p}.$

Now, we can legitimately talk about ${\textstyle \|f+g\|_{p}}$ . If it is zero, then Minkowski's inequality holds. We now assume that ${\textstyle \|f+g\|_{p}}$ is not zero. Using the triangle inequality and then Hölder's inequality, we find that

${\begin{aligned}\|f+g\|_{p}^{p}&=\int |f+g|^{p}\,\mathrm {d} \mu \\&=\int |f+g|\cdot |f+g|^{p-1}\,\mathrm {d} \mu \\&\leq \int (|f|+|g|)|f+g|^{p-1}\,\mathrm {d} \mu \\&=\int |f||f+g|^{p-1}\,\mathrm {d} \mu +\int |g||f+g|^{p-1}\,\mathrm {d} \mu \\&\leq \left(\left(\int |f|^{p}\,\mathrm {d} \mu \right)^{\frac {1}{p}}+\left(\int |g|^{p}\,\mathrm {d} \mu \right)^{\frac {1}{p}}\right)\left(\int |f+g|^{(p-1)\left({\frac {p}{p-1}}\right)}\,\mathrm {d} \mu \right)^{1-{\frac {1}{p}}}&&{\text{ Hölder's inequality}}\\&=\left(\|f\|_{p}+\|g\|_{p}\right){\frac {\|f+g\|_{p}^{p}}{\|f+g\|_{p}}}\end{aligned}}$

We obtain Minkowski's inequality by multiplying both sides by

${\frac {\|f+g\|_{p}}{\|f+g\|_{p}^{p}}}.$

Proof by a direct convexity argument

Given $t\in (0,1)$ , one has, by convexity (Jensen's inequality), for every $x\in S$

|f(x)+g(x)|^{p}={\Bigl |}(1-t){\frac {f(x)}{1-t}}+t{\frac {g(x)}{t}}{\Bigr |}^{p}\leq (1-t){\Bigl |}{\frac {f(x)}{1-t}}{\Bigr |}^{p}+t{\Bigl |}{\frac {g(x)}{t}}{\Bigr |}^{p}={\frac {|f(x)|^{p}}{(1-t)^{p-1}}}+{\frac {|g(x)|^{p}}{t^{p-1}}}.

By integration this leads to

\int _{S}|f+g|^{p}\,\mathrm {d} \mu \leq {\frac {1}{(1-t)^{p-1}}}\int _{S}|f|^{p}\,\mathrm {d} \mu +{\frac {1}{t^{p-1}}}\int _{S}|g|^{p}\,\mathrm {d} \mu .

One takes then

t={\frac {\Vert g\Vert _{p}}{\Vert f\Vert _{p}+\Vert g\Vert _{p}}}

to reach the conclusion.

Minkowski's integral inequality

Suppose that ${\textstyle (S_{1},\mu _{1})}$ and ${\textstyle (S_{2},\mu _{2})}$ are two 𝜎-finite measure spaces and ${\textstyle F:S_{1}\times S_{2}\to \mathbb {R} }$ is measurable. Then Minkowski's integral inequality is:^[1]^[2]

$\left[\int _{S_{2}}\left|\int _{S_{1}}F(x,y)\,\mu _{1}(\mathrm {d} x)\right|^{p}\mu _{2}(\mathrm {d} y)\right]^{\frac {1}{p}}~\leq ~\int _{S_{1}}\left(\int _{S_{2}}|F(x,y)|^{p}\,\mu _{2}(\mathrm {d} y)\right)^{\frac {1}{p}}\mu _{1}(\mathrm {d} x),\quad p\in [1,\infty )$

with obvious modifications in the case ${\textstyle p=\infty .}$ If ${\textstyle p>1,}$ and both sides are finite, then equality holds only if ${\textstyle |F(x,y)|=\varphi (x)\,\psi (y)}$ a.e. for some non-negative measurable functions ${\textstyle \varphi }$ and ${\textstyle \psi }$ .

If ${\textstyle \mu _{1}}$ is the counting measure on a two-point set ${\textstyle S_{1}=\{1,2\},}$ then Minkowski's integral inequality gives the usual Minkowski inequality as a special case: for putting ${\textstyle f_{i}(y)=F(i,y)}$ for ${\textstyle i=1,2,}$ the integral inequality gives

$\|f_{1}+f_{2}\|_{p}=\left(\int _{S_{2}}\left|\int _{S_{1}}F(x,y)\,\mu _{1}(\mathrm {d} x)\right|^{p}\mu _{2}(\mathrm {d} y)\right)^{\frac {1}{p}}\leq \int _{S_{1}}\left(\int _{S_{2}}|F(x,y)|^{p}\,\mu _{2}(\mathrm {d} y)\right)^{\frac {1}{p}}\mu _{1}(\mathrm {d} x)=\|f_{1}\|_{p}+\|f_{2}\|_{p}.$

If the measurable function ${\textstyle F:S_{1}\times S_{2}\to \mathbb {R} }$ is non-negative then for all ${\textstyle 1\leq p\leq q\leq \infty ,}$ ^[3]

$\left\|\left\|F(\,\cdot ,s_{2})\right\|_{L^{p}(S_{1},\mu _{1})}\right\|_{L^{q}(S_{2},\mu _{2})}~\leq ~\left\|\left\|F(s_{1},\cdot )\right\|_{L^{q}(S_{2},\mu _{2})}\right\|_{L^{p}(S_{1},\mu _{1})}\ .$

This notation has been generalized to

$\|f\|_{p,q}=\left(\int _{\mathbb {R} ^{m}}\left[\int _{\mathbb {R} ^{n}}|f(x,y)|^{q}\mathrm {d} y\right]^{\frac {p}{q}}\mathrm {d} x\right)^{\frac {1}{p}}$

for ${\textstyle f:\mathbb {R} ^{m+n}\to E,}$ with ${\textstyle {\mathcal {L}}_{p,q}(\mathbb {R} ^{m+n},E)=\{f\in E^{\mathbb {R} ^{m+n}}:\|f\|_{p,q}<\infty \}.}$ Using this notation, manipulation of the exponents reveals that, if ${\textstyle p<q,}$ then ${\textstyle \|f\|_{q,p}\leq \|f\|_{p,q}}$ .

Reverse inequality

When ${\textstyle p<1}$ the reverse inequality holds:

$\|f+g\|_{p}\geq \|f\|_{p}+\|g\|_{p}.$

We further need the restriction that both ${\textstyle f}$ and ${\textstyle g}$ are non-negative, as we can see from the example ${\textstyle f=-1,g=1}$ and ${\textstyle p=1}$

{\textstyle \|f+g\|_{1}=0<2=\|f\|_{1}+\|g\|_{1}.}

The reverse inequality follows from the same argument as the standard Minkowski, but uses that Holder's inequality is also reversed in this range.

Using the Reverse Minkowski, we may prove that power means with ${\textstyle p\leq 1,}$ such as the harmonic mean and the geometric mean are concave.

Generalizations to other functions

The Minkowski inequality can be generalized to other functions ${\textstyle \phi (x)}$ beyond the power function ${\textstyle x^{p}}$ . The generalized inequality has the form

$\phi ^{-1}\left(\textstyle \sum \limits _{i=1}^{n}\phi (x_{i}+y_{i})\right)\leq \phi ^{-1}\left(\textstyle \sum \limits _{i=1}^{n}\phi (x_{i})\right)+\phi ^{-1}\left(\textstyle \sum \limits _{i=1}^{n}\phi (y_{i})\right).$

Various sufficient conditions on ${\textstyle \phi }$ have been found by Mulholland^[4] and others. For example, for ${\textstyle x\geq 0}$ one set of sufficient conditions from Mulholland is

${\textstyle \phi (x)}$ is continuous and strictly increasing with ${\textstyle \phi (0)=0.}$
${\textstyle \phi (x)}$ is a convex function of ${\textstyle x.}$
${\textstyle \log \phi (x)}$ is a convex function of ${\textstyle \log(x).}$

References

^ Stein 1970, §A.1.
^ Hardy, Littlewood & Pólya 1988, Theorem 202.
^ Bahouri, Chemin & Danchin 2011, p. 4.
^ Mulholland, H. P. (1949). "On Generalizations of Minkowski's Inequality in the Form of a Triangle Inequality". Proceedings of the London Mathematical Society. s2-51 (1): 294–307. doi:10.1112/plms/s2-51.4.294.

Bahouri, Hajer; Chemin, Jean-Yves; Danchin, Raphaël (2011). Fourier Analysis and Nonlinear Partial Differential Equations. Grundlehren der mathematischen Wissenschaften. Vol. 343. Berlin, Heidelberg: Springer. ISBN 978-3-642-16830-7. OCLC 704397128.
Hardy, G. H.; Littlewood, J. E.; Pólya, G. (1988). Inequalities. Cambridge Mathematical Library (second ed.). Cambridge: Cambridge University Press. ISBN 0-521-35880-9.
Minkowski, H. (1953). Geometrie der Zahlen. Chelsea..
Stein, Elias (1970). Singular integrals and differentiability properties of functions. Princeton University Press..
M.I. Voitsekhovskii (2001) [1994], "Minkowski inequality", Encyclopedia of Mathematics, EMS Press
Lohwater, Arthur J. (1982). "Introduction to Inequalities".