We study several problems concerning convex polygons whose vertices lie in a Cartesian product of two sets of n real numbers (for short, grid). First, we prove that every such grid contains a convex polygon with Omega(log n) vertices and that this bound is tight up to a constant factor. We generalize this result to d dimensions (for a fixed d in N), and obtain a tight lower bound of Omega(log^{d-1}n) for the maximum number of points in convex position in a d-dimensional grid. Second, we present polynomial-time algorithms for computing the longest convex polygonal chain in a grid that contains no two points with the same x- or y-coordinate. We show that the maximum size of such a convex polygon can be efficiently approximated up to a factor of 2. Finally, we present exponential bounds on the maximum number of convex polygons in these grids, and for some restricted variants. These bounds are tight up to polynomial factors

Barequet, Gill

De Carufel, Jean Lou

Dumitrescu, Adrian

Meulemans, Wouter

Ophelders, Tim

Pennarun, Claire

Tóth, Csaba D.

Verdonschot, Sander

Wang, Yusu

English

arXiv

We study several problems concerning convex polygons whose vertices lie on a grid defined by the Cartesian product of two sets of n real numbers, using each coordinate at most once. First, we prove that all such grids contain a convex polygon with Ω(log n) vertices and that this bound is asymptotically tight. Second, we present two polynomial-time algorithms that find the largest convex polygon of a restricted type. These algorithms give an approximation of the unrestricted case. It is unknown whether the unrestricted problem can be solved in polynomial time

De Carufel, Jean-Lou

Tóth, Cs.D.

NARCIS 

On convex polygons in cartesian products

We study several problems concerning convex polygons whose vertices lie on a grid defined by the Cartesian product of two sets of n real numbers, using each coordinate at most once. First, we prove that all such grids contain a convex polygon with Ω(log n) vertices and that this bound is asymptotically tight. Second, we present two polynomial-time algorithms that find the largest\u3cbr/\u3econvex polygon of a restricted type. These algorithms give an approximation of the unrestricted case. It is unknown whether the unrestricted problem can be solved in polynomial time

Carufel, Jean Lou  De

Meulemans, W Wouter

Ophelders, TAE Tim

Tóth, CsD

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Dagstuhl Research Online Publication Server

Convex Polygons in Cartesian Products

We study several problems concerning convex polygons whose vertices lie in a Cartesian product of two sets of n real numbers (for short, grid). First, we prove that every such grid contains a convex polygon with Ω(log n) vertices and that this bound is tight up to a constant factor. We generalize this result to d dimensions (for a fixed d ∈ ℕ), and obtain a tight lower bound of Ω(logd-1 n) for the maximum number of points in convex position in a d-dimensional grid. Second, we present polynomial-time algorithms for computing the longest convex polygonal chain in a grid that contains no two points with the same x- or y-coordinate. We show that the maximum size of such a convex polygon can be efficiently approximated up to a factor of 2. Finally, we present exponential bounds on the maximum number of convex polygons in these grids, and for some restricted variants. These bounds are tight up to polynomial factors.</p

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Convex polygons in Cartesian products

We study several problems concerning convex polygons whose vertices lie on a grid defined by the Cartesian product of two sets of n real numbers, using each coordinate at most once. First, we prove that all such grids contain a convex polygon with Ω(log n) vertices and that this bound is asymptotically tight. Second, we present two polynomial-time algorithms that find the largestconvex polygon of a restricted type. These algorithms give an approximation of the unrestricted case. It is unknown whether the unrestricted problem can be solved in polynomial time

We study several problems concerning convex polygons whose vertices lie in a Cartesian product of two sets of n real numbers (for short, grid). First, we prove that every such grid contains a convex polygon with Ω(log n) vertices and that this bound is tight up to a constant factor. We generalize this result to d dimensions (for a fixed d ∈ ℕ), and obtain a tight lower bound of Ω(logd-1 n) for the maximum number of points in convex position in a d-dimensional grid. Second, we present polynomial-time algorithms for computing the longest convex polygonal chain in a grid that contains no two points with the same x- or y-coordinate. We show that the maximum size of such a convex polygon can be efficiently approximated up to a factor of 2. Finally, we present exponential bounds on the maximum number of convex polygons in these grids, and for some restricted variants. These bounds are tight up to polynomial factors

\u3cp\u3eWe study several problems concerning convex polygons whose vertices lie in a Cartesian product of two sets of n real numbers (for short, grid). First, we prove that every such grid contains a convex polygon with Ω(log n) vertices and that this bound is tight up to a constant factor. We generalize this result to d dimensions (for a fixed d ∈ ℕ), and obtain a tight lower bound of Ω(log\u3csup\u3ed-1\u3c/sup\u3e n) for the maximum number of points in convex position in a d-dimensional grid. Second, we present polynomial-time algorithms for computing the longest convex polygonal chain in a grid that contains no two points with the same x- or y-coordinate. We show that the maximum size of such a convex polygon can be efficiently approximated up to a factor of 2. Finally, we present exponential bounds on the maximum number of convex polygons in these grids, and for some restricted variants. These bounds are tight up to polynomial factors.\u3c/p\u3

Tóth, Csaba D

https://drops.dagstuhl.de/opus/volltexte/2019/10426/pdf/LIPIcs-SoCG-2019-22.pdf

Convex Polygons in Cartesian Products

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