Heat equation and Schr\"odinger equation with translation invariance on the infinite-dimensional vector space R∞

Abstract

The standard Laplacian - Rn in L2( Rn) is self-adjoint and translation invariant on the finite-dimensional linear space Rn. In this paper, we define a translation invariant operator - R∞ on R∞ as a non-negative self-adjoint operator in some non-separable Hilbert space L2( R∞). The set L2( R∞) is a translation invariant subset of the set CM( R∞) of all complex measures on the product measurable space R∞. Furthermore, we show that for any f∈ L2( Rn) and any u∈ L2( R∞), the separations of variables e R∞t(f u) =(e Rntf) (e R∞tu) \ (t∈ [0,+∞)) and e-1 R∞t(f u) =(e-1 Rntf) (e-1 R∞tu) \ (t∈ (-∞,+∞)) hold. This clearly shows that - R∞ is an analog of - Rn. The starting point for the discussion in this paper is to naturally introduce a translation invariant structure of Hilbert space into CM( R∞). L2( R∞) is a closed linear subspace of CM( R∞). The inner product of L2( R∞) is defined as that of CM( R∞). For a manifold, H\"ormander defined an inner product that does not depend on a particular measure. In fact, the way we introduce the inner product into CM( R∞) is a generalization of his. Not only is a statistical manifold on R∞ a submanifold of CM( R∞), but the real inner product Re( ·, · CM( R∞)) induces Fisher information metric.