Finding the Sequence of Largest Small n-Polygons by Numerical Optimization
Abstract
LSP(n), the largest small polygon with n vertices, is the polygon of unit diameter that has maximal area A(n). It is known that for all odd values , LSP(n) is the regular n-polygon; however, this statement is not valid for even values of n. Finding the polygon LSP(n) and A(n) for even values has been a long-standing challenge. In this work, we develop high-precision numerical solution estimates of A(n) for even values , using the Mathematica model development environment and the IPOPT local nonlinear optimization solver engine. First, we present a revised (tightened) LSP model that greatly assists the efficient solution of the model-class considered. This is followed by numerical results for an illustrative sequence of even values of n, up to . Our results are in close agreement with, or surpass, the best results reported in all earlier studies. Most of these earlier works addressed special cases up to , while others obtained numerical optimization results for a range of values from . For completeness, we also calculate numerically optimized results for a selection of odd values of n, up to : these results can be compared to the corresponding theoretical (exact) values. The results obtained are used to provide regression model-based estimates of the optimal area sequence {A(n)}, for all even and odd values n of interest, thereby essentially solving the entire LSP model-class numerically, with demonstrably high precision.
Cite
@article{arxiv.2101.01263,
title = {Finding the Sequence of Largest Small n-Polygons by Numerical Optimization},
author = {János D. Pintér and Frank J. Kampas and Ignacio Castillo},
journal= {arXiv preprint arXiv:2101.01263},
year = {2021}
}