Bochner-Riesz means
Bochner–Riesz averages
Bochner–Riesz means can be defined and developed in different settings: multiple Fourier integrals; multiple Fourier series; other orthogonal series expansions. Below these three separate cases will be pursued, with regard to 
-convergence, almost-everywhere convergence, localization, and convergence or oscillation at a pre-assigned point.
A primary motivation for studying these operations lies in the fact that a general Fourier series or Fourier integral expansion can only be expected to converge in the sense of the mean square (i.e., 
) norm; by inserting various smoothing and convergence factors, the convergence can often be improved to 
, 
, or to the almost-everywhere sense.
If 
is an integrable function on a Euclidean space 
, with Fourier transform 
, the Bochner–Riesz means of order 
are defined by:
 |
This also can be formally written as a convolution with a kernel function. If 
(the critical index), then this kernel is integrable; in particular, 
is a bounded operator on 
, 
, and 
for almost every 
and 
. Below the critical index, one has the following results:
If 
and 
, then 
is a bounded operator on 
if and only if 
lies in the trapezoidal region defined by the inequalities 
.
If 
and 
, then 
is a bounded operator on 
if and only if 
lies in the trapezoidal region defined by the inequalities 
.
If 
and 
, then 
is a bounded operator on 
if 
lies in the triangular region defined by the inequalities 
and is an unbounded operator if either 
or 
.
For any 
, in the limiting case 
, 
is a bounded operator on 
if and only if 
. If 
and 
has 
continuous derivatives, then 
provided that 
. If 
in an open ball centred at 
, then 
when 
. There is also a Gibbs phenomenon for 
functions which have a simple jump across a hypersurface 
with respect to 
. If 
, then the set of accumulation points of 
when 
, 
equals the segment with centre 
and length 
, where 
.
If 
is an integrable function on the torus 
, the Bochner–Riesz means of order 
are defined by
 |
where the Fourier coefficient is defined by 
. If 
, then
 |
almost everywhere if 
; convergence in 
holds if 
and 
, 
. If 
, 
, then 
uniformly for 
. At the critical index, one has the following behaviour: for any open ball centred at 
, there exists an 
so that 
in the ball and 
. There exists an integrable function 
for which 
for almost every 
. If, in addition, 
is integrable and 
satisfies a Dini condition (cf. also Dini criterion) at 
, then 
.
Bochner–Riesz means can be defined with respect to any orthonormal basis 
of the Hilbert space corresponding to a self-adjoint differential operator 
with eigenvalues 
. In this setting, the Bochner–Riesz means of order 
are defined by
 |
In the case of multiple Hermite series corresponding to the differential operator 
on 
, one has 
and the convergence in 
holds if 
; almost-everywhere convergence holds if 
. In the case of an arbitrary elliptic differential operator on a compact manifold, it is known that if 
, then 
whenever 
. For second-order operators there is an 
convergence theorem, provided that 
and 
and 
.
References
| [a1] | S. Bochner, "Summation of multiple Fourier series by spherical means" Trans. Amer. Math. Soc. , 40 (1936) pp. 175–207 |
| [a2] | C. Fefferman, "A note on spherical summation multipliers" Israel J. Math. , 15 (1973) pp. 44–52 |
| [a3] | B.I. Golubov, "On Gibb's phenomenon for Riesz spherical means of multiple Fourier integrals and Fourier series" Anal. Math. , 4 (1978) pp. 269–287 |
| [a4] | B.M. Levitan, "Ueber die Summierung mehrfacher Fourierreihen und Fourierintegrale" Dokl. Akad. Nauk SSSR , 102 (1955) pp. 1073–1076 |
| [a5] | E.M. Stein, "Harmonic analysis" , Princeton Univ. Press (1993) |
| [a6] | S. Thangavelu, "Lectures on Hermite and Laguerre expansions" , Princeton Univ. Press (1993) |
| [a7] | C. Sogge, "On the convergence of Riesz means on compact manifolds" Ann. of Math. , 126 (1987) pp. 439–447 |
Bochner-Riesz means. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bochner-Riesz_means&oldid=22147