English

Finding the Sequence of Largest Small n-Polygons by Numerical Optimization

Optimization and Control 2021-01-06 v1

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 n3n \geq 3, 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 n6n \geq 6 has been a long-standing challenge. In this work, we develop high-precision numerical solution estimates of A(n) for even values n4n \geq 4, 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 n1000n \leq 1000. 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 n20n \leq 20, while others obtained numerical optimization results for a range of values from 6n1006 \leq n \leq 100. For completeness, we also calculate numerically optimized results for a selection of odd values of n, up to n999n \leq 999: 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.

Keywords

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}
}
R2 v1 2026-06-23T21:46:36.374Z