Infinite-dimensional q-Jacobi Markov processes
Abstract
The classical Jacobi polynomials on the interval [-1,1] are eigenfunctions of a second order differential operator. It is well known that this operator generates a diffusion process on [-1,1]. Further, this fact admits an extension to N dimensions (Demni (2010), Remling-R\"osler (2011)) leading to a 3-parameter family of diffusion processes XN on the space of N-particle configurations in [-1,1]. The generators of the processes XN are related to Heckman-Opdam's Jacobi polynomials attached to the root system BCN. The first result of the paper shows that the processes XN have a q-analog, the N-dimensional q-Jacobi processes. These are Feller Markov processes related to the N-variate symmetric big q-Jacobi polynomials. The later polynomials were introduced and studied by Stokman (1997) and Stokman-Koornwinder (1997); they depend on two Macdonald parameters (q,t) and 4 extra continuous parameters. The N-dimensional q-Jacobi processes are still defined on a space of N-particle configurations, only now the particles live not on [-1,1] but on certain one-dimensional q-grids. The second result (the main one) asserts that the N-dimensional q-Jacobi processes survive a limit transition as N goes to infinity and two of the extra parameters vary together with N in a certain way. In the limit, one obtains a family of Feller Markov processes which are infinite-dimensional in the sense that they live on configurations with infinitely many particles. The proof uses a lifting of the multivariate big q-Jacobi polynomials to the algebra of symmetric functions -- a construction that does not hold for the Heckman-Opdam's Jacobi polynomials. Note also that the large-N limit transition is carried out without any space scaling, which would be impossible in the continuous case.
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