{ "id": "1601.08241", "version": "v1", "published": "2016-01-29T20:27:24.000Z", "updated": "2016-01-29T20:27:24.000Z", "title": "Homotopical Complexity a 3D Billiard Flow", "authors": [ "Caleb C. Moxley", "Nandor J. Simanyi" ], "comment": "10 pages, 1 figure. arXiv admin note: text overlap with arXiv:1008.1623, arXiv:math/0610350", "categories": [ "math.DS" ], "abstract": "In this paper we study the homotopical rotation vectors and the homotopical rotation sets for the billiard flow on the unit flat torus with three, mutually intersecting and mutually orthogonal cylindrical scatterers removed from it. The natural habitat for these objects is the infinite cone erected upon the Cantor set $\\text{Ends}(\\textbf{F}_3)$ of all \"ends\" of the hyperbolic group $\\textbf{F}_3=\\pi_1(\\mathbf{Q})$. An element of $\\text{Ends}(\\textbf{F}_3)$ describes the direction in (the Cayley graph of) the group $\\textbf{F}_3$ in which the considered trajectory escapes to infinity, whereas the height function $s$ ($s\\ge 0$) of the cone gives us the average speed at which this escape takes place. The main results of this paper claim that the orbits can only escape to infinity at a speed not exceeding $\\sqrt{3}$, and in any direction $e\\in\\text{Ends}(\\mathbf{F}_3)$ the escape is feasible with any prescribed speed $s$, $0\\leq s\\leq 1/3$. This means that the radial upper and lower bounds for the rotation set $R$ are actually pretty close to each other. We also provide effective lower and upper bounds for the topological entropy of the studied billiard flow.", "revisions": [ { "version": "v1", "updated": "2016-01-29T20:27:24.000Z" } ], "analyses": { "subjects": [ "37D50", "34D05" ], "keywords": [ "3d billiard flow", "homotopical complexity", "rotation set", "homotopical rotation", "unit flat torus" ], "note": { "typesetting": "TeX", "pages": 10, "language": "en", "license": "arXiv", "status": "editable" } } }