English

Finiteness Principles for Smooth Convex Functions

Classical Analysis and ODEs 2024-02-27 v1

Abstract

Let ERnE \subset \mathbb{R}^n be a compact set, and f:ERf:E \to \mathbb{R}. How can we tell if there exists a convex extension FC1,1(Rn)F \in C^{1,1}(\mathbb{R}^n) of ff, i.e. satisfying FE=fEF|_E = f|_E? Assuming such an extension exists, how small can one take the Lipschitz constant Lip(F):=supx,yRn,xyF(x)F(y)xy\text{Lip}(\nabla F): = \sup_{x,y \in \mathbb{R}^n, x \neq y} \frac{|\nabla F(x) - \nabla F(y)|}{|x-y|}? We provide an answer to these questions for the class of strongly convex functions by proving that there exist constants k#Nk^\# \in \mathbb{N} and C>0C>0 depending only on the dimension nn, such that if for every subset SES \subset E, #Sk#\#S \leq k^\#, there exists an η\eta-strongly convex function FSC1,1(Rn)F^S \in C^{1,1}(\mathbb{R}^n) satisfying FSS=fSF^S|_S=f|_S and Lip(FS)M\text{Lip}(\nabla F^S) \leq M, then there exists an ηC{\frac{\eta}{C}}-strongly convex function FCc1,1(Rn)F \in C^{1,1}_c(\mathbb{R}^n) satisfying FE=fEF|_E = f|_E, and Lip(F)CM2/η\text{Lip}(\nabla F) \leq C M^2/\eta. Further, we prove a Finiteness Principle for the space of convex functions in C1,1(R)C^{1,1}(\mathbb{R}) and that the sharp finiteness constant for this space is k#=5k^\#=5.

Keywords

Cite

@article{arxiv.2402.16232,
  title  = {Finiteness Principles for Smooth Convex Functions},
  author = {Marjorie K. Drake},
  journal= {arXiv preprint arXiv:2402.16232},
  year   = {2024}
}
R2 v1 2026-06-28T14:59:42.688Z