Approximate convexity with respect to a subfield

Abstract

Let \({\mathbb{F}}\) be a subfield of \({\mathbb{R}}\) and X be a linear space over \({\mathbb{F}}\). Let \({ D\subseteq X }\) be a nonempty \({\mathbb{F}}\)-convex set, \({ D^*:=D-D:=\{x-y : x,y\in D\} }\), and \({\alpha \colon {D^* \rightarrow \mathbb{R}}}\) be a nonnegative even function. The function \({ f \colon {D\rightarrow \mathbb{R}}}\) is called \({(\alpha,\mathbb{F})}\)-convex, if it satisfies the inequality

$$\begin{aligned}{f(tx+(1-t)y)\leq tf(x)+(1-t)f(y) + t\alpha((1-t)(x-y))+(1-t)\alpha(t(y-x))}\end{aligned}$$

for all \({x,y\in D}\) and for all \({t\in \mathbb{F}\cap [0,1]}\). In this paper we characterize \({(\alpha,\mathbb{F})}\)-convex functions by comparison of modified difference ratios and support properties. If \({\alpha}\) satisfies some additional conditions, we obtain the differentiability of \({(\alpha,\mathbb{F})}\)-convex functions in the appropriate sense.