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 be a metric space, and a real-valued function for each natural number . We say that the sequence epi-converges to a function if for each
Extended real-valued extension
The following extension allows epi-convergence to be applied to a sequence of functions with non-constant domain.
Denote by the extended real numbers. Let be a function for each . The sequence epi-converges to if for each
In fact, epi-convergence coincides with the -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. hypo-converges to if
and
Relationship to minimization problems
Assume we have a difficult minimization problem
where and . We can attempt to approximate this problem by a sequence of easier problems
for functions and sets .
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
So that the problems and are equivalent to the original and approximate problems, respectively.
If epi-converges to , then . Furthermore, if is a limit point of minimizers of , then is a minimizer of . In this sense,
Epi-convergence is the weakest notion of convergence for which this result holds.
Properties
- epi-converges to if and only if hypo-converges to .
- epi-converges to if and only if converges to as sets, in the Painlevé–Kuratowski sense of set convergence. Here, is the epigraph of the function .
- If epi-converges to , then is lower semi-continuous.
- If is convex for each and epi-converges to , then is convex.
- If and both and epi-converge to , then epi-converges to .
- If converges uniformly to on each compact set of and are continuous, then epi-converges and hypo-converges to .
- 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
- Rockafellar, R. Tyrrell; Wets, Roger (2009). "Epigraphical Limits". Variational Analysis. Grundlehren der mathematischen Wissenschaften. Vol. 317. Springer Science & Business Media. pp. 238–297. doi:10.1007/978-3-642-02431-3_7. ISBN 978-3-540-62772-2.
- Kall, Peter (1986). "Approximation to optimization problems: an elementary review". Mathematics of Operations Research. 11 (1): 9–18. doi:10.1287/moor.11.1.9.
- Attouch, Hedy; Wets, Roger (1989). "Epigraphical analysis". Annales de l'Institut Henri Poincaré C. 6: 73–100. Bibcode:1989AIHPC...6...73A. doi:10.1016/S0294-1449(17)30036-7.