Riesz rearrangement inequality

In mathematics, the Riesz rearrangement inequality, sometimes called Riesz–Sobolev inequality, states that any three non-negative functions ${\displaystyle f:{ℝ}^n\to {ℝ}^{+}}$, ${\displaystyle g:{ℝ}^n\to {ℝ}^{+}}$ and ${\displaystyle h:{ℝ}^n\to {ℝ}^{+}}$ satisfy the inequality

${\displaystyle \underset{{ℝ}^n\times {ℝ}^n}{\iint }f(x)g(x-y)h(y)dxdy\le \underset{{ℝ}^n\times {ℝ}^n}{\iint }{f}^{*}(x)g^{*}(x-y)h^{*}(y)dxdy,}$

where ${\displaystyle f^{*}:{ℝ}^n\to {ℝ}^{+}}$, ${\displaystyle g^{*}:{ℝ}^n\to {ℝ}^{+}}$ and ${\displaystyle h^{*}:{ℝ}^n\to {ℝ}^{+}}$ are the symmetric decreasing rearrangements of the functions ${\displaystyle f}$, ${\displaystyle g}$ and ${\displaystyle h}$ respectively.

The inequality was first proved by Frigyes Riesz in 1930,^[1] and independently reproved by S.L.Sobolev in 1938. Brascamp, Lieb and Luttinger have shown that it can be generalized to arbitrarily (but finitely) many functions acting on arbitrarily many variables.^[2]

The Riesz rearrangement inequality can be used to prove the Pólya–Szegő inequality.

In the one-dimensional case, the inequality is first proved when the functions ${\displaystyle f}$, ${\displaystyle g}$ and ${\displaystyle h}$ are characteristic functions of a finite unions of intervals. Then the inequality can be extended to characteristic functions of measurable sets, to measurable functions taking a finite number of values and finally to nonnegative measurable functions.^[3]

In order to pass from the one-dimensional case to the higher-dimensional case, the spherical rearrangement is approximated by Steiner symmetrization for which the one-dimensional argument applies directly by Fubini's theorem.^[4]

In the case where any one of the three functions is a strictly symmetric-decreasing function, equality holds only when the other two functions are equal, up to translation, to their symmetric-decreasing rearrangements.^[5]

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