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Line 3: [[File:Multivalued_function.svg\|right\|frame\|This diagram represents a multi-valued, but not a proper (single-valued) [[Function (mathematics)\|function]], because the element 3 in ''X'' is associated with two elements, ''b'' and ''c'', in ''Y''.]] A '''set-valued function''', also called a '''correspondence''' or '''set-valued [[Relation (mathematics)\|relation]]''', is a mathematical [[Function (mathematics)\|function]] that maps elements from one set, the [[___domain of a function\|___domain of the function]], to subsets of another set.<ref name=":02">{{Cite book \|last=Aliprantis \|first=Charalambos D. \|url=https://www.google.com.br/books/edition/Infinite_Dimensional_Analysis/Ma31CAAAQBAJ \|title=Infinite Dimensional Analysis: A Hitchhiker’s Guide \|last2=Border \|first2=Kim C. \|date=2013-03-14 \|publisher=Springer Science & Business Media \|isbn=978-3-662-03961-8 \|pages=523 \|language=en}}</ref><ref name=":0">{{Cite book \|last=Wriggers \|first=Peter \|url=https://www.google.com.br/books/edition/New_Developments_in_Contact_Problems/R4lqCQAAQBAJ \|title=New Developments in Contact Problems \|last2=Panatiotopoulos \|first2=Panagiotis \|date=2014-05-04 \|publisher=Springer \|isbn=978-3-7091-2496-3 \|pages=29 \|language=en}}</ref> Set-valued functions are used in a variety of mathematical fields, including [[Mathematical optimization\|optimization]], [[control theory]] and [[game theory]]. Set-valued functions are also known as [[multivalued function]]s in some references,<ref>{{Cite book \|last=Repovš \|first=Dušan \|url=https://www.worldcat.org/oclc/39739641 \|title=Continuous selections of multivalued mappings \|date=1998 \|publisher=Kluwer Academic \|others=Pavel Vladimirovič. Semenov \|isbn=0-7923-5277-7 \|___location=Dordrecht \|oclc=39739641}}</ref> but this article and the article [[Multivalued function]] follow the authors who make a distinction. Line 9: == Distinction from multivalued functions == [[File:Multivalued_functions_illustration.svg\|thumb\|right\|600px\|Illustration distinguishing multivalued functions from set-valued relations according to the criterion in page 29 of ''New Developments in Contact Problems'' by Wriggers and Panatiotopoulos (2014).]] Although other authors may distinguish them differently (or not at all), Wriggers and Panatiotopoulos (2014) distinguish multivalued functions from set-valued functions (which they called ''set-valued relations'') by the fact that multivalued functions only take multiple values at finitely (or denumerably) many points, and otherwise behave like a [[Function (mathematics)\|function]].<ref name="~~WriggersPanatiotopoulos~~:0"~~>{{Cite~~ ~~book \|last=Wriggers \|first=Peter \|url=https:~~//www.google.com.br/books/edition/New_Developments_in_Contact_Problems/R4lqCQAAQBAJ \|title=New Developments in Contact Problems \|last2=Panatiotopoulos \|first2=Panagiotis \|date=2014-05-04 \|publisher=Springer \|isbn=978-3-7091-2496-3 \|pages=29 \|language=en}}</ref> Geometrically, this means that the graph of a multivalued function is necessarily a line of zero area that doesn't loop, while the graph of a set-valued relation may contain solid filled areas or loops.<ref name="~~WriggersPanatiotopoulos~~:0" /> Alternatively, [[multivalued function]] is a set-valued function {{mvar\|f}} that has a further [[continuous function\|continuity]] property, namely that the choice of an element in the set <math>f(x)</math> defines a corresponding element in each set <math>f(y)</math> for {{mvar\|y}} close to {{mvar\|x}}, and thus defines [[locally]] an ordinary function.

Set-valued function: Difference between revisions