Exact and approximate solutions to the minimum of 1+x+·s+x2n

Abstract

The polynomial f2n(x)=1+x+·s+x2n and its minimizer on the real line x2n=arg\,inf f2n(x) for n∈ N are studied. Results show that x2n exists, is unique, corresponds to ∂x f2n(x)=0, and resides on the interval [-1,-1/2] for all n. It is further shown that ∈f f2n(x)=(1+2n)/(1+2n(1-x2n)) and ∈f f2n(x)∈[1/2,3/4] for all n with an exact solution for x2n given in the form of a finite sum of hypergeometric functions of unity argument. Perturbation theory is applied to generate rapidly converging and asymptotically exact approximations to x2n. Numerical studies are carried out to show how many terms of the perturbation expansion for x2n are needed to obtain suitably accurate approximations to the exact value.