Character group
In mathematics, a character group is the group of representations of a group by complex-valued functions. These functions can be thought of as one-dimensional matrix representations and so are special cases of the group characters that arise in the related context of character theory. Whenever a group is represented by matrices, the function defined by the trace of the matrices is called a character; however, these traces do not in general form a group. Some important properties of these one-dimensional characters apply to characters in general:
- Characters are invariant on conjugacy classes.
- The characters of irreducible representations are orthogonal.
The primary importance of the character group for finite abelian groups is in number theory, where it is used to construct Dirichlet characters. The character group of the cyclic group also appears in the theory of the discrete Fourier transform. For locally compact abelian groups, the character group (with an assumption of continuity) is central to Fourier analysis.
Preliminaries
Let be an abelian group. A function mapping the group to the non-zero complex numbers is called a character of if it is a group homomorphism from to —that is, if for all .
If is a character of a finite group , then each function value is a root of unity, since for each there exists such that , and hence .
Each character f is a constant on conjugacy classes of G, that is, f(hgh−1) = f(g). For this reason, a character is sometimes called a class function.
A finite abelian group of order n has exactly n distinct characters. These are denoted by f1, ..., fn. The function f1 is the trivial representation, which is given by for all . It is called the principal character of G; the others are called the non-principal characters.
Definition
If G is an abelian group, then the set of characters fk forms an abelian group under pointwise multiplication. That is, the product of characters and is defined by for all . This group is the character group of G and is sometimes denoted as . The identity element of is the principal character f1, and the inverse of a character fk is its reciprocal 1/fk. If is finite of order n, then is also of order n. In this case, since for all , the inverse of a character is equal to the complex conjugate.
Alternative definition
There is another definition of character group[1]pg 29 which uses as the target instead of just . This is useful while studying complex tori because the character group of the lattice in a complex torus is canonically isomorphic to the dual torus via the Appell-Humbert theorem. That is,
We can express explicit elements in the character group as follows: recall that elements in can be expressed as
for . If we consider the lattice as a subgroup of the underlying real vector space of , then a homomorphism
can be factored as a map
This follows from elementary properties of homomorphisms. Note that
giving us the desired factorization. As the group
we have the isomorphism of the character group, as a group, with the group of homomorphisms of to . Since for any abelian group , we have
after composing with the complex exponential, we find that
which is the expected result.
Examples
Finitely generated abelian groups
Since every finitely generated abelian group is isomorphic to
the character group can be easily computed in all finitely generated cases. From universal properties, and the isomorphism between finite products and coproducts, we have the character groups of is isomorphic to
for the first case, this is isomorphic to , the second is computed by looking at the maps which send the generator to the various powers of the -th roots of unity .
Orthogonality of characters
Consider the matrix A = A(G) whose matrix elements are where is the kth element of G.
The sum of the entries in the jth row of A is given by
- if , and
- .
The sum of the entries in the kth column of A is given by
- if , and
- .
Let denote the conjugate transpose of A. Then
- .
This implies the desired orthogonality relationship for the characters: i.e.,
- ,
where is the Kronecker delta and is the complex conjugate of .
See also
References
- See chapter 6 of Apostol, Tom M. (1976), Introduction to analytic number theory, Undergraduate Texts in Mathematics, New York-Heidelberg: Springer-Verlag, ISBN 978-0-387-90163-3, MR 0434929, Zbl 0335.10001