Riesz rearrangement inequality


In mathematics, the Riesz rearrangement inequality states that for any three non-negative functions, and satisfies the inequality
where, and are the symmetric decreasing rearrangements of the functions, and respectively.

History

The inequality was first proved by Frigyes Riesz in 1930,
and independently reproved by S.L.Sobolev in 1938. It can be generalized to arbitrarily many functions acting on arbitrarily many variables.

Applications

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

Proofs

One-dimensional case

In the one-dimensional case, the inequality is first proved when the functions, and 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.

Higher-dimensional case

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.

Equality cases

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.