Invariant integration
on a group
Integration of functions on a topological group that has a certain invariant property with respect to the group operations. Thus, let 
be a locally compact topological group, let 
be the vector space of all continuous complex-valued functions with compact support on 
and let 
be an integral on 
, that is, a positive linear functional on 
(
for 
). The integral 
is called left-invariant (or right-invariant) if 
(or 
) for all 
, 
; here
 |
The integral 
is called (two-sided) invariant if it is both left- and right-invariant. The mapping 
, where 
, 
, defines a one-to-one correspondence between the classes of left- and right-invariant integrals on 
. If 
, then 
is called inversion invariant.
There exists on every locally compact group 
a non-zero left-invariant integral; it is unique up to a numerical factor (the Haar–von Neumann–Weil theorem). This integral is called the left Haar integral. The following equation holds:
 |
where 
, 
and 
is a continuous homomorphism from the group 
into the multiplicative group of positive real numbers (a positive character). Furthermore, 
. The character 
is called the modulus of 
. If 
, then 
is called unimodular. In this case 
is a two-sided invariant integral.
In particular, every compact group (where 
, 
) and every discrete group (where 
, 
) is unimodular.
According to the Riesz theorem, every integral on 
is a Lebesgue integral with respect to some Borel measure 
which is uniquely defined in the class of Borel measures that are finite on each compact subset 
. The left- (or right-) invariant measure 
corresponding to the left (right) Haar integral on 
is called the left (right) Haar measure on 
.
Let 
be a closed subgroup of 
and let 
be the modulus of 
. If 
can be extended to a continuous positive character of 
(cf. Character of a group), then there exists on the left homogeneous space 
a relatively invariant integral 
, that is, a positive functional on the space 
of continuous functions with compact support on 
that satisfies the identity
 |
for all 
, 
; here
 |
and 
is the modulus of 
. This integral is defined by the rule 
, where 
is the left Haar integral on 
and 
is a function on 
such that
 |
(
is the left Haar integral on 
and 
is the restriction of 
to 
.) This is well-defined since 
is a mapping from 
onto 
and 
when 
. The notion of an invariant mean (cf. Invariant average) is closely related to that of invariant integration.
References
| [1] | N. Bourbaki, "Elements of mathematics. Integration" , Addison-Wesley (1975) pp. Chapt.6;7;8 (Translated from French) |
| [2] | A. Weil, "l'Intégration dans les groupes topologiques et ses applications" , Hermann (1940) |
| [3] | L.H. Loomis, "An introduction to abstract harmonic analysis" , v. Nostrand (1953) |
| [4] | E. Hewitt, K.A. Ross, "Abstract harmonic analysis" , 1 , Springer (1979) |
Comments
References
| [a1] | H. Reiter, "Classical harmonic analysis and locally compact groups" , Clarendon Press (1968) |
Invariant integration. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Invariant_integration&oldid=47413