Lines, Circles, Planes and Spheres
Let \(S\) be a set of \(n\) points in \(\mathbb{R}^3\), no three collinear and not all coplanar. If at most \(n-k\) are coplanar and \(n\) is sufficiently large, the total number of planes determined is at least \(1 + k \binom{n-k}{2}-\binom{k}{2}(\frac{n-k}{2})\). For similar conditions and suffici...
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| description | Let \(S\) be a set of \(n\) points in \(\mathbb{R}^3\), no three collinear and not all coplanar. If at most \(n-k\) are coplanar and \(n\) is sufficiently large, the total number of planes determined is at least \(1 + k \binom{n-k}{2}-\binom{k}{2}(\frac{n-k}{2})\). For similar conditions and sufficiently large \(n\), (inspired by the work of P. D. T. A. Elliott in \cite{Ell67}) we also show that the number of spheres determined by \(n\) points is at least \(1+\binom{n-1}{3}-t_3^{orchard}(n-1)\), and this bound is best possible under its hypothesis. (By \(t_3^{orchard}(n)\), we are denoting the maximum number of three-point lines attainable by a configuration of \(n\) points, no four collinear, in the plane, i.e., the classic Orchard Problem.) New lower bounds are also given for both lines and circles. |
| doi_str_mv | 10.48550/arxiv.0907.0724 |
| format | Article |
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If at most \(n-k\) are coplanar and \(n\) is sufficiently large, the total number of planes determined is at least \(1 + k \binom{n-k}{2}-\binom{k}{2}(\frac{n-k}{2})\). For similar conditions and sufficiently large \(n\), (inspired by the work of P. D. T. A. Elliott in \cite{Ell67}) we also show that the number of spheres determined by \(n\) points is at least \(1+\binom{n-1}{3}-t_3^{orchard}(n-1)\), and this bound is best possible under its hypothesis. (By \(t_3^{orchard}(n)\), we are denoting the maximum number of three-point lines attainable by a configuration of \(n\) points, no four collinear, in the plane, i.e., the classic Orchard Problem.) 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If at most \(n-k\) are coplanar and \(n\) is sufficiently large, the total number of planes determined is at least \(1 + k \binom{n-k}{2}-\binom{k}{2}(\frac{n-k}{2})\). For similar conditions and sufficiently large \(n\), (inspired by the work of P. D. T. A. Elliott in \cite{Ell67}) we also show that the number of spheres determined by \(n\) points is at least \(1+\binom{n-1}{3}-t_3^{orchard}(n-1)\), and this bound is best possible under its hypothesis. (By \(t_3^{orchard}(n)\), we are denoting the maximum number of three-point lines attainable by a configuration of \(n\) points, no four collinear, in the plane, i.e., the classic Orchard Problem.) 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If at most \(n-k\) are coplanar and \(n\) is sufficiently large, the total number of planes determined is at least \(1 + k \binom{n-k}{2}-\binom{k}{2}(\frac{n-k}{2})\). For similar conditions and sufficiently large \(n\), (inspired by the work of P. D. T. A. Elliott in \cite{Ell67}) we also show that the number of spheres determined by \(n\) points is at least \(1+\binom{n-1}{3}-t_3^{orchard}(n-1)\), and this bound is best possible under its hypothesis. (By \(t_3^{orchard}(n)\), we are denoting the maximum number of three-point lines attainable by a configuration of \(n\) points, no four collinear, in the plane, i.e., the classic Orchard Problem.) New lower bounds are also given for both lines and circles.</abstract><cop>Ithaca</cop><pub>Cornell University Library, arXiv.org</pub><doi>10.48550/arxiv.0907.0724</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Lower bounds Mathematics - Combinatorics Planes |
| title | Lines, Circles, Planes and Spheres |
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