Cm Eigenfunctions of Perron-Frobenius Operators and a New Approach to Numerical Computation of Hausdorff Dimension: Applications in R1

Abstract

We develop a new approach to the computation of the Hausdorff dimension of the invariant set of an iterated function system or IFS. In the one dimensional case that we consider here, our methods require only C3 regularity of the maps in the IFS. The key idea, which has been known in varying degrees of generality for many years, is to associate to the IFS a parametrized family of positive, linear, Perron-Frobenius operators Ls. The operators Ls can typically be studied in many different Banach spaces. Here, unlike most of the literature, we study Ls in a Banach space of real-valued, Ck functions, k 2. We note that Ls is not compact, but has essential spectral radius s strictly less than the spectral radius λs and possesses a strictly positive Ck eigenfunction vs with eigenvalue λs. Under appropriate assumptions on the IFS, the Hausdorff dimension of the invariant set of the IFS is the value s=s* for which λs =1. This eigenvalue problem is then approximated by a collocation method using continuous piecewise linear functions. Using the theory of positive linear operators and explicit a priori bounds on the derivatives of the strictly positive eigenfunction vs, we give rigorous upper and lower bounds for the Hausdorff dimension s*, and these bounds converge to s* as the mesh size approaches zero.