Epi-convergence

In mathematical analysis, epi-convergence is a type of convergence for real-valued and extended real-valued functions.

Epi-convergence is important because it is the appropriate notion of convergence with which to approximate minimization problems in the field of mathematical optimization. The symmetric notion of hypo-convergence is appropriate for maximization problems. Mosco convergence is a generalization of epi-convergence to infinite dimensional spaces.

Definition

Let $X$ be a metric space, and $f^{\nu }:X\to \mathbb {R}$ a real-valued function for each natural number $\nu$ . We say that the sequence $(f^{\nu })$ epi-converges to a function $f:X\to \mathbb {R}$ if for each $x\in X$

{\begin{aligned}&\liminf _{\nu \to \infty }f^{\nu }(x^{\nu })\geq f(x){\text{ for every }}x^{\nu }\to x{\text{ and }}\\&\limsup _{\nu \to \infty }f^{\nu }(x^{\nu })\leq f(x){\text{ for some }}x^{\nu }\to x.\end{aligned}}

Extended real-valued extension

The following extension allows epi-convergence to be applied to a sequence of functions with non-constant domain.

Denote by ${\overline {\mathbb {R} }}=\mathbb {R} \cup \{\pm \infty \}$ the extended real numbers. Let $f^{\nu }$ be a function $f^{\nu }:X\to {\overline {\mathbb {R} }}$ for each $\nu \in \mathbb {N}$ . The sequence $(f^{\nu })$ epi-converges to $f:X\to {\overline {\mathbb {R} }}$ if for each $x\in X$

{\begin{aligned}&\liminf _{\nu \to \infty }f^{\nu }(x^{\nu })\geq f(x){\text{ for every }}x^{\nu }\to x{\text{ and }}\\&\limsup _{\nu \to \infty }f^{\nu }(x^{\nu })\leq f(x){\text{ for some }}x^{\nu }\to x.\end{aligned}}

In fact, epi-convergence coincides with the $\Gamma$ -convergence in first countable spaces.

Hypo-convergence

Epi-convergence is the appropriate topology with which to approximate minimization problems. For maximization problems one uses the symmetric notion of hypo-convergence. $(f^{\nu })$ hypo-converges to $f$ if

\limsup _{\nu \to \infty }f^{\nu }(x^{\nu })\leq f(x){\text{ for every }}x^{\nu }\to x

and

\liminf _{\nu \to \infty }f^{\nu }(x^{\nu })\geq f(x){\text{ for some }}x^{\nu }\to x.

Relationship to minimization problems

Assume we have a difficult minimization problem

\inf _{x\in C}g(x)

where $g:X\to \mathbb {R}$ and $C\subseteq X$ . We can attempt to approximate this problem by a sequence of easier problems

\inf _{x\in C^{\nu }}g^{\nu }(x)

for functions $g^{\nu }$ and sets $C^{\nu }$ .

Epi-convergence provides an answer to the question: In what sense should the approximations converge to the original problem in order to guarantee that approximate solutions converge to a solution of the original?

We can embed these optimization problems into the epi-convergence framework by defining extended real-valued functions

{\begin{aligned}f(x)&={\begin{cases}g(x),&x\in C,\\\infty ,&x\not \in C,\end{cases}}\\[4pt]f^{\nu }(x)&={\begin{cases}g^{\nu }(x),&x\in C^{\nu },\\\infty ,&x\not \in C^{\nu }.\end{cases}}\end{aligned}}

So that the problems $\inf _{x\in X}f(x)$ and $\inf _{x\in X}f^{\nu }(x)$ are equivalent to the original and approximate problems, respectively.

If $(f^{\nu })$ epi-converges to $f$ , then $\limsup _{\nu \to \infty }[\inf f^{\nu }]\leq \inf f$ . Furthermore, if $x$ is a limit point of minimizers of $f^{\nu }$ , then $x$ is a minimizer of $f$ . In this sense,

\lim _{v\to \infty }\operatorname {argmin} f^{\nu }\subseteq \operatorname {argmin} f.

Epi-convergence is the weakest notion of convergence for which this result holds.

Properties

$(f^{\nu })$ epi-converges to $f$ if and only if $(-f^{\nu })$ hypo-converges to $-f$ .
$(f^{\nu })$ epi-converges to $f$ if and only if $(\operatorname {epi} f^{\nu })$ converges to $\operatorname {epi} f$ as sets, in the Painlevé–Kuratowski sense of set convergence. Here, $\operatorname {epi} f$ is the epigraph of the function $f$ .
If $f^{\nu }$ epi-converges to $f$ , then $f$ is lower semi-continuous.
If $f^{\nu }$ is convex for each $\nu \in \mathbb {N}$ and $(f^{\nu })$ epi-converges to $f$ , then $f$ is convex.
If $f_{1}^{\nu }\leq f^{\nu }\leq f_{2}^{\nu }$ and both $(f_{1}^{\nu })$ and $(f_{2}^{\nu })$ epi-converge to $f$ , then $(f^{\nu })$ epi-converges to $f$ .
If $(f^{\nu })$ converges uniformly to $f$ on each compact set of $\mathbb {R} ^{n}$ and $(f^{\nu })$ are continuous, then $(f^{\nu })$ epi-converges and hypo-converges to $f$ .
In general, epi-convergence neither implies nor is implied by pointwise convergence. Additional assumptions can be placed on an pointwise convergent family of functions to guarantee epi-convergence.

References

R. Tyrrell Rockafellar and Roger Wets, Variational Analysis. Chapter 7 ; Vol. 317. Springer Science & Business Media, 2009.
Peter Kall, Approximation to optimization problems: An elementary review; Mathematics of Operations Research 19, pp. 9–18 (1986)
Hedy Attouch and Roger Wets, Epigraphical analysis; Annales de l'IHP Analyse non linéaire Vol. 6. 1989.

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