In mathematical analysis, in particular the subfields of convex analysis and optimization, a proper convex function is an extended real-valued convex function with a non-empty domain, that never takes on the value and also is not identically equal to
In convex analysis and variational analysis, a point (in the domain) at which some given function is minimized is typically sought, where is valued in the extended real number line [1] Such a point, if it exists, is called a global minimum point of the function and its value at this point is called the global minimum (value) of the function. If the function takes as a value then is necessarily the global minimum value and the minimization problem can be answered; this is ultimately the reason why the definition of "proper" requires that the function never take as a value. Assuming this, if the function's domain is empty or if the function is identically equal to then the minimization problem once again has an immediate answer. Extended real-valued function for which the minimization problem is not solved by any one of these three trivial cases are exactly those that are called proper. Many (although not all) results whose hypotheses require that the function be proper add this requirement specifically to exclude these trivial cases.
If the problem is instead a maximization problem (which would be clearly indicated, such as by the function being concave rather than convex) then the definition of "proper" is defined in an analogous (albeit technically different) manner but with the same goal: to exclude cases where the maximization problem can be answered immediately. Specifically, a concave function is called proper if its negation which is a convex function, is proper in the sense defined above.
Definitions
editSuppose that is a function taking values in the extended real number line If is a convex function or if a minimum point of is being sought, then is called proper if
- for every
and if there also exists some point such that
That is, a function is proper if it never attains the value and its effective domain is nonempty.[2] This means that there exists some at which and is also never equal to Convex functions that are not proper are called improper convex functions.[3]
A proper concave function is by definition, any function such that is a proper convex function. Explicitly, if is a concave function or if a maximum point of is being sought, then is called proper if its domain is not empty, it never takes on the value and it is not identically equal to
Properties
editFor every proper convex function there exist some and such that
for every
The sum of two proper convex functions is convex, but not necessarily proper.[4] For instance if the sets and are non-empty convex sets in the vector space then the characteristic functions and are proper convex functions, but if then is identically equal to
The infimal convolution of two proper convex functions is convex but not necessarily proper convex.[5]
See also
editCitations
edit- ^ Rockafellar & Wets 2009, pp. 1–28.
- ^ Aliprantis, C.D.; Border, K.C. (2007). Infinite Dimensional Analysis: A Hitchhiker's Guide (3 ed.). Springer. p. 254. doi:10.1007/3-540-29587-9. ISBN 978-3-540-32696-0.
- ^ Rockafellar, R. Tyrrell (1997) [1970]. Convex Analysis. Princeton, NJ: Princeton University Press. p. 24. ISBN 978-0-691-01586-6.
- ^ Boyd, Stephen (2004). Convex Optimization. Cambridge, UK: Cambridge University Press. p. 79. ISBN 978-0-521-83378-3.
- ^ Ioffe, Aleksandr Davidovich; Tikhomirov, Vladimir Mikhaĭlovich (2009), Theory of extremal problems, Studies in Mathematics and its Applications, vol. 6, North-Holland, p. 168, ISBN 9780080875279.
References
edit- Rockafellar, R. Tyrrell; Wets, Roger J.-B. (26 June 2009). Variational Analysis. Grundlehren der mathematischen Wissenschaften. Vol. 317. Berlin New York: Springer Science & Business Media. ISBN 9783642024313. OCLC 883392544.