**Dimensional characteristics of the non-wandering sets of open billiards.** / Wright, Paul.

Research output: Thesis › Doctoral Thesis

Wright, P 2014, 'Dimensional characteristics of the non-wandering sets of open billiards', Doctor of Philosophy.

Wright, P. (2014). *Dimensional characteristics of the non-wandering sets of open billiards*

Wright P. Dimensional characteristics of the non-wandering sets of open billiards. 2014.

@phdthesis{4ed0c7d5161c4b14a01d2586ffd6d215,

title = "Dimensional characteristics of the non-wandering sets of open billiards",

abstract = "[Truncated] An open billiard is a dynamical system in which a pointlike particle moves at constant speed in an unbounded domain, reflecting off a boundary according to the classical laws of optics. This thesis is an investigation of dimensional characteristics of the non-wandering set of an open billiard in the exterior of three or more strictly convex bodies satisfying Ikawa’s no-eclipse condition. The billiard map for these systems is an axiom A diffeomorphism with a finite Markov partition. The non-wandering set is a hyperbolic set with stable and unstable manifolds satisfying a certain reflection property. The characteristics we investigate include the topological and measure-theoretic entropy, topological pressure, Lyapunov exponents, lower and upper box dimension and the Hausdorff dimension of the non-wandering set. In particular, we investigate the dependence of Hausdorff dimension on deformations to the boundary of the billiard obstacles. While the dependence of dimensional characteristics on perturbations of a system has been studied before, this is the first time this question has been answered for dynamical billiards. We find upper and lower bounds for the Hausdorff dimension using two different methods: one involving bounding the size of curves on convex fronts and the other using Bowen’s equation and the variational principle for topological pressure. Both methods lead to the same upper and lower bounds. In the first method, we use a well known recurrence relation for the successive curvatures of convex fronts to find bounds on the size of the fronts. This allows us to construct Lipschitz (but not bi-Lipszhitz) homeomorphisms between the non-wandering set and the one-sided symbol space. From there we obtain estimates of the dimension. This method has been previously used for open billiards in the plane. We extend it to higher dimensions and make improvements to the results in the plane. The second method is a more general approach from the dimension theory of dynamical systems. In the plane, the billiard map is conformal, meaning that its derivative is a multiple of an isometry. For conformal maps, the Hausdorff dimension of non-wandering sets is well-understood and satisfies Bowen’s equation. In higher dimensions, the billiard map is not conformal and the dimension only satisfies some estimates.",

keywords = "Open billiard, No-eclipse condition, Non-wandering set, Dimension theory, Symbolic dynamics, Bowen\{textquoteleft}s equation, Average conformal, Hausdorff dimension",

author = "Paul Wright",

year = "2014",

language = "English",

}

TY - THES

T1 - Dimensional characteristics of the non-wandering sets of open billiards

AU - Wright,Paul

PY - 2014

Y1 - 2014

N2 - [Truncated] An open billiard is a dynamical system in which a pointlike particle moves at constant speed in an unbounded domain, reflecting off a boundary according to the classical laws of optics. This thesis is an investigation of dimensional characteristics of the non-wandering set of an open billiard in the exterior of three or more strictly convex bodies satisfying Ikawa’s no-eclipse condition. The billiard map for these systems is an axiom A diffeomorphism with a finite Markov partition. The non-wandering set is a hyperbolic set with stable and unstable manifolds satisfying a certain reflection property. The characteristics we investigate include the topological and measure-theoretic entropy, topological pressure, Lyapunov exponents, lower and upper box dimension and the Hausdorff dimension of the non-wandering set. In particular, we investigate the dependence of Hausdorff dimension on deformations to the boundary of the billiard obstacles. While the dependence of dimensional characteristics on perturbations of a system has been studied before, this is the first time this question has been answered for dynamical billiards. We find upper and lower bounds for the Hausdorff dimension using two different methods: one involving bounding the size of curves on convex fronts and the other using Bowen’s equation and the variational principle for topological pressure. Both methods lead to the same upper and lower bounds. In the first method, we use a well known recurrence relation for the successive curvatures of convex fronts to find bounds on the size of the fronts. This allows us to construct Lipschitz (but not bi-Lipszhitz) homeomorphisms between the non-wandering set and the one-sided symbol space. From there we obtain estimates of the dimension. This method has been previously used for open billiards in the plane. We extend it to higher dimensions and make improvements to the results in the plane. The second method is a more general approach from the dimension theory of dynamical systems. In the plane, the billiard map is conformal, meaning that its derivative is a multiple of an isometry. For conformal maps, the Hausdorff dimension of non-wandering sets is well-understood and satisfies Bowen’s equation. In higher dimensions, the billiard map is not conformal and the dimension only satisfies some estimates.

AB - [Truncated] An open billiard is a dynamical system in which a pointlike particle moves at constant speed in an unbounded domain, reflecting off a boundary according to the classical laws of optics. This thesis is an investigation of dimensional characteristics of the non-wandering set of an open billiard in the exterior of three or more strictly convex bodies satisfying Ikawa’s no-eclipse condition. The billiard map for these systems is an axiom A diffeomorphism with a finite Markov partition. The non-wandering set is a hyperbolic set with stable and unstable manifolds satisfying a certain reflection property. The characteristics we investigate include the topological and measure-theoretic entropy, topological pressure, Lyapunov exponents, lower and upper box dimension and the Hausdorff dimension of the non-wandering set. In particular, we investigate the dependence of Hausdorff dimension on deformations to the boundary of the billiard obstacles. While the dependence of dimensional characteristics on perturbations of a system has been studied before, this is the first time this question has been answered for dynamical billiards. We find upper and lower bounds for the Hausdorff dimension using two different methods: one involving bounding the size of curves on convex fronts and the other using Bowen’s equation and the variational principle for topological pressure. Both methods lead to the same upper and lower bounds. In the first method, we use a well known recurrence relation for the successive curvatures of convex fronts to find bounds on the size of the fronts. This allows us to construct Lipschitz (but not bi-Lipszhitz) homeomorphisms between the non-wandering set and the one-sided symbol space. From there we obtain estimates of the dimension. This method has been previously used for open billiards in the plane. We extend it to higher dimensions and make improvements to the results in the plane. The second method is a more general approach from the dimension theory of dynamical systems. In the plane, the billiard map is conformal, meaning that its derivative is a multiple of an isometry. For conformal maps, the Hausdorff dimension of non-wandering sets is well-understood and satisfies Bowen’s equation. In higher dimensions, the billiard map is not conformal and the dimension only satisfies some estimates.

KW - Open billiard

KW - No-eclipse condition

KW - Non-wandering set

KW - Dimension theory

KW - Symbolic dynamics

KW - Bowen's equation

KW - Average conformal

KW - Hausdorff dimension

M3 - Doctoral Thesis

ER -

ID: 4598913