In mathematics, the Riesz mean is a certain mean of the terms in a series. They were introduced by Marcel Riesz in 1911 as an improvement over the Cesàro mean. The Riesz mean should not be confused with the Bochner–Riesz mean or the Strong–Riesz mean.
Given a series
\{sn\}
s\delta(λ)=\sumn\le\left(1-
| n | |
| λ |
\right)\deltasn
Sometimes, a generalized Riesz mean is defined as
Rn=
| 1 | |
| λn |
| n | |
| \sum | |
| k=0 |
(λk-λk-1)\deltask
Here, the
λn
λn\toinfty
λn+1/λn\to1
n\toinfty
λn
Riesz means are often used to explore the summability of sequences; typical summability theorems discuss the case of
sn=
| n | |
| \sum | |
| k=0 |
ak
\{ak\}
\limn\toinftyRn
\lim\delta\tos\delta(λ)
Let
an=1
n
\sumn\le\left(1-
| n | |
| λ |
\right)\delta =
| 1 | |
| 2\pii |
| c+iinfty | |
| \int | |
| c-iinfty |
| \Gamma(1+\delta)\Gamma(s) | |
| \Gamma(1+\delta+s) |
\zeta(s)λsds =
| λ | |
| 1+\delta |
+\sumnbnλ-n.
Here, one must take
c>1
\Gamma(s)
\zeta(s)
\sumnbnλ-n
can be shown to be convergent for
λ>1
Another interesting case connected with number theory arises by taking
an=Λ(n)
Λ(n)
\sumn\le\left(1-
| n | |
| λ |
\right)\deltaΛ(n) =-
| 1 | |
| 2\pii |
| c+iinfty | |
| \int | |
| c-iinfty |
| \Gamma(1+\delta)\Gamma(s) | |
| \Gamma(1+\delta+s) |
| \zeta\prime(s) | |
| \zeta(s) |
λsds =
| λ | |
| 1+\delta |
+\sum\rho
| \Gamma(1+\delta)\Gamma(\rho) | |
| \Gamma(1+\delta+\rho) |
+\sumncnλ-n.
Again, one must take c > 1. The sum over ρ is the sum over the zeroes of the Riemann zeta function, and
\sumncnλ-n
is convergent for λ > 1.
The integrals that occur here are similar to the Nörlund–Rice integral; very roughly, they can be connected to that integral via Perron's formula.