Abstract
After a short review of the quantum mechanics canonically associated with a classical real valued random variable with all moments, we begin to study the quantum mechanics canonically associated to the standard semi-circle random variable X, characterized by the fact that its probability distribution is the semi-circle law mu on [ 2; 2]. We prove that, in the identification of L-2 ([ 2; 2]; mu) with the 1-mode interacting Fock space, defined by the orthogonal polynomial gradation of mu, X is mapped into position operator and its canonically associated momentum operator P into i times the mu-Hilbert transform H-mu on L2 ([ 2; 2]; mu). In the first part of the present paper, after briefly describing the simpler case of the mu-harmonic oscillator, we find an explicit expression for the action, on the mu-orthogonal polynomials, of the semi-circle analogue of the translation group e(itP) and of the semi-circle analogue of the free evolution e(itP2/2), respectively, in terms of Bessel functions of the first kind and of confluent hyper-geometric series. These results require the solution of the inverse normal order problem on the quantum algebra canonically associated to the classical semi-circle random variable and are derived in the second part of the present paper. Since the problem to determine, with purely analytic techniques, the explicit form of the action of e(-tH mu) and e(-tH mu 2/2) on the mu-orthogonal polynomials is difficult, the above mentioned results show the power of the combination of these techniques with those developed within the algebraic approach to the theory of orthogonal polynomials.