Canonical Commutation Relations: A quick proof of the Stone-von Neumann theorem and an extension to general rings

Abstract

Let R be a (not necessary commutative) ring with unit, d≥ 1 an integer, and λ a unitary character of the additive group (R,+). A pair (U,V) of unitary representations U and V of Rd on a Hilbert space H is said to satisfy the canonical commutation relations (relative to λ) if U(a) V(b)= λ(a· b)V(b) U(a) for all a=(a1, …, ad), b= (b1, …, bd)∈ Rd, where a· b= Σk=1d ak bk. We give a new and quick proof of the classical Stone von Neumann Theorem about the essential uniqueness of such a pair in the case where R is a local field (e.g. R= R). Our methods allow us to give the following extension of this result to a general locally compact ring R. For a unitary representation U of Rd on a Hilbert space H, define the inflation U(∞) of U as the (countably) infinite multiple of U on H(∞)=i∈ N H. Let (U1, V1), (U2, V2) be two pairs of unitary representations of Rd on corresponding Hilbert spaces H1, H2 satisfying the canonical commutation relations (relative to λ). Provided that λ satisfies a mild faithful condition, we show that the inflations (U1(∞), V1(∞)), (U2(∞), V2(∞)) are approximately equivalent, that is, there exists a sequence (n)n of unitary isomorphisms n: H1(∞) H2(∞) such that n U2(∞)(a) - n U1(∞)(a) n*=0 and n V2(∞)(b) - n V1(∞)(b) n*=0, uniformly on compact subsets of Rd.

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