8 research outputs found
On the Stretch Factor of Polygonal Chains
Let be a polygonal chain. The stretch factor of
is the ratio between the total length of and the distance of its
endpoints, . For a parameter , we call a -chain if , for
every triple , . The stretch factor is a global
property: it measures how close is to a straight line, and it involves all
the vertices of ; being a -chain, on the other hand, is a
fingerprint-property: it only depends on subsets of vertices of the
chain.
We investigate how the -chain property influences the stretch factor in
the plane: (i) we show that for every , there is a noncrossing
-chain that has stretch factor , for
sufficiently large constant ; (ii) on the other hand, the
stretch factor of a -chain is , for every
constant , regardless of whether is crossing or noncrossing; and
(iii) we give a randomized algorithm that can determine, for a polygonal chain
in with vertices, the minimum for which is
a -chain in expected time and
space.Comment: 16 pages, 11 figure
Self-approaching paths in simple polygons
info:eu-repo/semantics/inPres
Self-approaching paths in simple polygons
We study self-approaching paths that are contained in a simple polygon. A self-approaching path is a directed curve connecting two points such that the Euclidean distance between a point moving along the path and any future position does not increase, that is, for all points a, b, and c that appear in that order along the curve, cSCOPUS: cp.pinfo:eu-repo/semantics/publishe
Self-approaching paths in simple polygons
\u3cp\u3eWe study the problem of connecting two points in a simple polygon with a self-approaching path. A self-approaching path is a directed curve such that the Euclidean distance between a point moving along the path and any future position does not increase, that is, for all points a, b, and c that appear in that order along the curve, |ac|≥|bc|. We analyze properties of self-approaching paths inside simple polygons, and characterize shortest self-approaching paths. In particular, we show that a shortest self-approaching path connecting two points in a simple polygon can be forced to follow a general class of non-algebraic curves. While this makes it difficult to design an exact algorithm, we show how to find the shortest self-approaching path under a model of computation which assumes that we can compute involute curves of high order. Lastly, we provide an efficient algorithm to test if a given simple polygon is self-approaching, that is, if there exists a self-approaching path for any two points inside the polygon.\u3c/p\u3
Self-approaching paths in simple polygons
We study the problem of connecting two points in a simple polygon with a self-approaching path. A self-approaching path is a directed curve such that the Euclidean distance between a point moving along the path and any future position does not increase, that is, for all points a, b, and c that appear in that order along the curve, [Formula presented]. We analyze properties of self-approaching paths inside simple polygons, and characterize shortest self-approaching paths. In particular, we show that a shortest self-approaching path connecting two points in a simple polygon can be forced to follow a general class of non-algebraic curves. While this makes it difficult to design an exact algorithm, we show how to find the shortest self-approaching path under a model of computation which assumes that we can compute involute curves of high order. Lastly, we provide an efficient algorithm to test if a given simple polygon is self-approaching, that is, if there exists a self-approaching path for any two points inside the polygon
Self-approaching paths in simple polygons
We study self-approaching paths that are contained in a simple polygon. A self-approaching path is a directed curve connecting two points such that the Euclidean distance between a point moving along the path and any future position does not increase, that is, for all points a, b, and c that appear in that order along the curve, |ac| >= |bc|. We analyze the properties, and present a characterization of shortest self-approaching paths. In particular, we show that a shortest self-approaching path connecting two points inside a polygon can be forced to follow a general class of non-algebraic curves. While this makes it difficult to design an exact algorithm, we show how to find a self-approaching path inside a polygon connecting two points under a model of computation which assumes that we can calculate involute curves of high order. Lastly, we provide an algorithm to test if a given simple polygon is self-approaching, that is, if there exists a self-approaching path for any two points inside the polygon