In mathematics, and specifically in operator theory, a positive-definite function on a group relates the notions of positivity, in the context of Hilbert spaces, and algebraic groups. It can be viewed as a particular type of positive-definite kernel where the underlying set has the additional group structure.
Let G be a group, H be a complex Hilbert space, and L(H) be the bounded operators on H. A positive-definite function on G is a function that satisfies
\sums,t\langleF(s-1t)h(t),h(s)\rangle\geq0,
for every function h: G → H with finite support (h takes non-zero values for only finitely many s).
In other words, a function F: G → L(H) is said to be a positive-definite function if the kernel K: G × G → L(H) defined by K(s, t) = F(s−1t) is a positive-definite kernel.
A unitary representation is a unital homomorphism Φ: G → L(H) where Φ(s) is a unitary operator for all s. For such Φ, Φ(s-1) = Φ(s)*.
Positive-definite functions on G are intimately related to unitary representations of G. Every unitary representation of G gives rise to a family of positive-definite functions. Conversely, given a positive-definite function, one can define a unitary representation of G in a natural way.
Let Φ: G → L(H) be a unitary representation of G. If P ∈ L(H) is the projection onto a closed subspace H` of H. Then F(s) = P Φ(s) is a positive-definite function on G with values in L(H`). This can be shown readily:
\begin{align} \sums,t\langleF(s-1t)h(t),h(s)\rangle&=\sums,t\langleP\Phi(s-1t)h(t),h(s)\rangle\ {}&=\sums,t\langle\Phi(t)h(t),\Phi(s)h(s)\rangle\ {}&=\left\langle\sumt\Phi(t)h(t),\sums\Phi(s)h(s)\right\rangle\ {}&\geq0 \end{align}
for every h: G → H` with finite support. If G has a topology and Φ is weakly(resp. strongly) continuous, then clearly so is F.
On the other hand, consider now a positive-definite function F on G. A unitary representation of G can be obtained as follows. Let C00(G, H) be the family of functions h: G → H with finite support. The corresponding positive kernel K(s, t) = F(s-1t) defines a (possibly degenerate) inner product on C00(G, H). Let the resulting Hilbert space be denoted by V.
We notice that the "matrix elements" K(s, t) = K(a-1s, a-1t) for all a, s, t in G. So Uah(s) = h(a-1s) preserves the inner product on V, i.e. it is unitary in L(V). It is clear that the map Φ(a) = Ua is a representation of G on V.
The unitary representation is unique, up to Hilbert space isomorphism, provided the following minimality condition holds:
V=vees\Phi(s)H
where
vee
Identify H as elements (possibly equivalence classes) in V, whose support consists of the identity element e ∈ G, and let P be the projection onto this subspace. Then we have PUaP = F(a) for all a ∈ G.
Let G be the additive group of integers Z. The kernel K(n, m) = F(m - n) is called a kernel of Toeplitz type, by analogy with Toeplitz matrices. If F is of the form F(n) = Tn where T is a bounded operator acting on some Hilbert space. One can show that the kernel K(n, m) is positive if and only if T is a contraction. By the discussion from the previous section, we have a unitary representation of Z, Φ(n) = Un for a unitary operator U. Moreover, the property PUaP = F(a) now translates to PUnP = Tn. This is precisely Sz.-Nagy's dilation theorem and hints at an important dilation-theoretic characterization of positivity that leads to a parametrization of arbitrary positive-definite kernels.