Characterization algorithms for shift radix systems with finiteness property
For a natural number d and a d-dimensional real vector r let Tau(r) denote the (d-dimensional) shift radix system associated with r. Tau(r) is said to have the finiteness property iff all orbits of Tau(r) end up in the zero vector; the set of all corresponding parameters r is denoted by DN(d), where...
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| description | For a natural number d and a d-dimensional real vector r let Tau(r) denote the (d-dimensional) shift radix system associated with r. Tau(r) is said to have the finiteness property iff all orbits of Tau(r) end up in the zero vector; the set of all corresponding parameters r is denoted by DN(d), whereas D(d) consists of those parameters r for which all orbits are eventually periodic. DN(d) has a very complicated structure even for d=2. In the present paper two algorithms are presented which allow the characterization of the intersection of DN(d) and any closed convex hull of finitely many interior points of D(d) which is completely contained in the interior of D(d). One of the algorithms is used to determine the structure of DN(2) in a region considerably larger than previously possible, and to settle two questions on its topology: It is shown that DN(2) is disconnected and that the largest connected component has nontrivial fundamental group. The other algorithm is the first characterizing DN(d) in a given convex polyhedron which terminates for all inputs. Furthermore several infinite families of "cutout polygons" are deduced settling the finiteness property for a chain of regions touching the boundary of D(2). |
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Tau(r) is said to have the finiteness property iff all orbits of Tau(r) end up in the zero vector; the set of all corresponding parameters r is denoted by DN(d), whereas D(d) consists of those parameters r for which all orbits are eventually periodic. DN(d) has a very complicated structure even for d=2. In the present paper two algorithms are presented which allow the characterization of the intersection of DN(d) and any closed convex hull of finitely many interior points of D(d) which is completely contained in the interior of D(d). One of the algorithms is used to determine the structure of DN(2) in a region considerably larger than previously possible, and to settle two questions on its topology: It is shown that DN(2) is disconnected and that the largest connected component has nontrivial fundamental group. The other algorithm is the first characterizing DN(d) in a given convex polyhedron which terminates for all inputs. Furthermore several infinite families of "cutout polygons" are deduced settling the finiteness property for a chain of regions touching the boundary of D(2).</description><identifier>EISSN: 2331-8422</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Algorithms ; Computational geometry ; Convexity ; Hulls ; Orbits ; Parameters ; Topology</subject><ispartof>arXiv.org, 2014-01</ispartof><rights>2014. This work is published under http://arxiv.org/licenses/nonexclusive-distrib/1.0/ (the “License”). 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DN(d) has a very complicated structure even for d=2. In the present paper two algorithms are presented which allow the characterization of the intersection of DN(d) and any closed convex hull of finitely many interior points of D(d) which is completely contained in the interior of D(d). One of the algorithms is used to determine the structure of DN(2) in a region considerably larger than previously possible, and to settle two questions on its topology: It is shown that DN(2) is disconnected and that the largest connected component has nontrivial fundamental group. The other algorithm is the first characterizing DN(d) in a given convex polyhedron which terminates for all inputs. 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| subjects | Algorithms Computational geometry Convexity Hulls Orbits Parameters Topology |
| title | Characterization algorithms for shift radix systems with finiteness property |
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