Optimal-Degree Polynomial Approximations for Exponentials and Gaussian Kernel Density Estimation
Abstract
For any real numbers B 1 and δ ∈ (0, 1) and function f: [0, B] → R, let dB; δ (f) ∈ Z> 0 denote the minimum degree of a polynomial p(x) satisfying x ∈ [0, B] | p(x) - f(x) | < δ. In this paper, we provide precise asymptotics for dB; δ (e-x) and dB; δ (ex) in terms of both B and δ, improving both the previously known upper bounds and lower bounds. In particular, we show dB; δ (e-x) = ( \ B (δ-1), (δ-1) (B-1 (δ-1)) \), and dB; δ (ex) = ( \ B, (δ-1) (B-1 (δ-1)) \). Polynomial approximations for e-x and ex have applications to the design of algorithms for many problems, and our degree bounds show both the power and limitations of these algorithms. We focus in particular on the Batch Gaussian Kernel Density Estimation problem for n sample points in ( n) dimensions with error δ = n-(1). We show that the running time one can achieve depends on the square of the diameter of the point set, B, with a transition at B = ( n) mirroring the corresponding transition in dB; δ (e-x): - When B=o( n), we give the first algorithm running in time n1 + o(1). - When B = n for a small constant >0, we give an algorithm running in time n1 + O( -1 / -1). The -1 / -1 term in the exponent comes from analyzing the behavior of the leading constant in our computation of dB; δ (e-x). - When B = ω( n), we show that time n2 - o(1) is necessary assuming SETH.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.