In this paper we prove central limit theorems of the following kind: let $S^d \subset \mathbb{R}^{d + 1}$ be the unit sphere of dimension $d \geq 2$ with uniform distribution $\omega_d$. For each $k \epsilon \mathbb{N}$, consider the isotropic random walk $(X_n^k)_{n \geq 0}$ on $S^d$ starting at the north pole with jumps of fixed sizes $\angle (X_n^k, X_{n - 1}^k) = \pi/\sqrt{k}$ for all $n \geq 1$. Then there is some $k_0(d)$ such that for all $k \geq k_0(d)$, the distributions $\varrho_k$ of $X_k^k$ have continuous, bounded $\omega_d$-densities $f_k$. Moreover, there is a (known) Gaussian measure $\nu$ on $S^d$ with $\omega_d$-density such that $||f_k - h||_{\infty} = O(1/k)$ and $||\varrho_k - \nu|| = O(1/k)$ for $k \to \infty$, where $O(1/k)$ is sharp. We shall derive this rate of convergence in the central limit theorem more generally for a quite general class of isotropic random walks on compact symmetric spaces of rank one as well as for random walks on $[0, \pi]$ whose transition probabilities are related to product linearization formulas of Jacobi polynomials.

Publié le : 1997-01-14
Classification:  Random walks on $n$-spheres,  central limit theorem,  Gaussian measures,  compact symmetric spaces of rank one,  total variation distance,  Jacobi polynomials,  60J15,  60F05,  60B10,  33C25,  42C10,  43A62

@article{1024404296,
     author = {Voit, Michael},
     title = {Rate of convergence to Gaussian measures on $n$-spheres and Jacobi
		 hypergroups},
     journal = {Ann. Probab.},
     volume = {25},
     number = {4},
     year = {1997},
     pages = { 457-477},
     language = {en},
     url = {http://dml.mathdoc.fr/item/1024404296}
}

Voit, Michael. Rate of convergence to Gaussian measures on $n$-spheres and Jacobi
		 hypergroups. Ann. Probab., Tome 25 (1997) no. 4, pp.  457-477. http://gdmltest.u-ga.fr/item/1024404296/