(Discrete) Almansi Type Decompositions: An umbral calculus framework based on osp(1|2) symmetries

Abstract

We introduce the umbral calculus formalism for hypercomplex variables starting from the fact that the algebra of multivariate polynomials [x] shall be described in terms of the generators of the Weyl-Heisenberg algebra. The extension of [x] to the algebra of Clifford-valued polynomials P gives rise to an algebra of Clifford-valued operators whose canonical generators are isomorphic to the orthosymplectic Lie algebra osp(1|2). This extension provides an effective framework in continuity and discreteness that allow us to establish an alternative formulation of Almansi decomposition in Clifford analysis (c.f. Ryan90,MR02,MAGU) that corresponds to a meaningful generalization of Fischer decomposition for the subspaces (D')k. We will discuss afterwards how the symmetries of sl2() (even part of osp(1|2)) are ubiquitous on the recent approach of Render (c.f. Render08), showing that they can be interpreted in terms of the method of separation of variables for the Hamiltonian operator in quantum mechanics.