English

Bounding Taylor approximation errors for the exponential function in the presence of a power weight function

Classical Analysis and ODEs 2024-03-05 v1

Abstract

Motivated by the needs in the theory of large deviations and in the theory of Lundberg's equation with heavy-tailed distribution functions, we study for n=0,1,...n=0,1,... the maximization of S: (1es(1+s11!+...+snn!))/sδ=En,δ(s)S:~\Bigl(1-e^{-s}\Bigl(1+\frac{s^1}{1!}+...+\frac{s^n}{n!}\Bigr)\Bigr)/s^{\delta} = E_{n,\delta}(s) over s0s\geq0, with δ(0,n+1)\delta\in(0,n+1), U: (1)n+1(eu(1u11!+...+(1)nunn!))/uδ=Gn,δ(u)U:~({-}1)^{n+1}\Bigl(e^{-u}-\Bigl(1-\frac{u^1}{1!}+...+({-}1)^n\,\frac{u^n}{n!} \Bigr)\Bigr)/u^{\delta}=G_{n,\delta}(u) over u0u\geq0 with δ(n,n+1)\delta\in(n,n+1). We show that En,δ(s)E_{n,\delta}(s) and Gn,δ(u)G_{n,\delta}(u) have a unique maximizer s=sn(δ)>0s=s_n(\delta)>0 and u=un(δ)>0u=u_n(\delta)>0 that decrease strictly from ++\infty at δ=0\delta=0 and δ=n\delta=n, respectively, to 0 at δ=n+1\delta=n+1. We use Taylor's formula for truncated series with remainder in integral form to develop a criterion to decide whether a particular smooth function S(δ)S(\delta), δ(0,n+1)\delta\in(0,n+1), or U(δ)U(\delta), δ(n,n+1)\delta\in(n,n+1), respectively, is a lower/upper bound for sn(δ)s_n(\delta) and un(δ)u_n(\delta), respectively. This criterion allows us to find lower and upper bounds for sns_n and unu_n that are reasonably tight and simple at the same time. Furthermore, as a consequence of the identities ddδ[lnMEn,δ]=lnsn(δ)\frac{d}{d\delta}\,[{\rm ln}\,ME_{n,\delta}] ={-}{\rm ln}\,s_n(\delta) and ddδ[lnMGn,δ]=lnun(δ)\frac{d}{d\delta}\,[{\rm ln}\,MG_{n,\delta}]={-}{\rm ln}\,u_n(\delta), we show that MEn,δME_{n,\delta} and MGn,δMG_{n,\delta} are log-convex functions of δ(0,n+1)\delta\in(0,n+1) and δ(n+1,n)\delta\in(n+1,n), respectively, with limiting values 1 (δ0\delta\downarrow0) and 1/(n+1)!1/(n+1)! (δn+1\delta\uparrow n+1) for EE, and 1/n!(δn)1/n!\,(\delta\downarrow n) and 1/(n+1)!(δn+1)1/(n+1)!\,(\delta\uparrow n+1) for GG. The minimal values E^n\hat{E}_n and G^n\hat{G}_n of MEn,δME_{n,\delta} and MGn,δMG_{n,\delta}, respectively, as a function of δ\delta, as well as the minimum locations δn,E\delta_{n,E} and δn,G\delta_{n,G} are determined in closed form.

Keywords

Cite

@article{arxiv.2403.01940,
  title  = {Bounding Taylor approximation errors for the exponential function in the presence of a power weight function},
  author = {A. J. E. M. Janssen},
  journal= {arXiv preprint arXiv:2403.01940},
  year   = {2024}
}
R2 v1 2026-06-28T15:08:14.175Z