https://whystartat.xyz/index.php?action=history&feed=atom&title=Inverse_functions_and_preimagesInverse functions and preimages - Revision history2026-05-24T20:33:01ZRevision history for this page on the wikiMediaWiki 1.39.0https://whystartat.xyz/index.php?title=Inverse_functions_and_preimages&diff=351&oldid=prevSpagety: Created page with "Category:Ambiguities Category:Inconsistencies Category:Unpleasantness Category:Conflicting definitions The notation \(f^{-1}\) usually denotes the composition..."2022-10-20T20:07:14Z<p>Created page with "<a href="/wiki/Category:Ambiguities" title="Category:Ambiguities">Category:Ambiguities</a> <a href="/wiki/Category:Inconsistencies" title="Category:Inconsistencies">Category:Inconsistencies</a> <a href="/wiki/Category:Unpleasantness" title="Category:Unpleasantness">Category:Unpleasantness</a> <a href="/wiki/Category:Conflicting_definitions" title="Category:Conflicting definitions">Category:Conflicting definitions</a> The notation \(f^{-1}\) usually denotes the composition..."</p>
<p><b>New page</b></p><div>[[Category:Ambiguities]]<br />
[[Category:Inconsistencies]]<br />
[[Category:Unpleasantness]]<br />
[[Category:Conflicting definitions]]<br />
<br />
The notation \(f^{-1}\) usually denotes the compositional inverse function of \(f\), that is, a function \(g\) such that, for all \(x\) in the domain of \(f\), \(g(f(x)) = x\), and, for all \(x\) in the domain of \(g\), \(f(g(x))=x\). This is a special case of the convention that \(f^n\) denotes the \(n\)-fold composition of \(f\) with itself, but, confusingly, it is also used in some contexts where \(f^n\) normally denotes \(n\)-fold ''pointwise multiplication'' of \(f\) with itself; see [[Powers of trigonometric functions]]. The inverse function does not exist unless \(f\) is injective.<br />
<br />
In some contexts, \(f^{-1}\) denotes the preimage function from the power set of the codomain of \(f\) to the power set of the domain of \(f\), defined by \(f^{-1}(Y) = \{x : f(x) \in Y\}\). This exists for all functions, whether or not they are injective.<br />
<br />
In other contexts, like when \(f\) is an element of a ring of functions on a space, \(f^{-1}\) can denote the ''multiplicative'' inverse of \(f\). This only exists if \(f(x)\) is invertible for all \(x\).<br />
<br />
<br />
==References==<br />
[https://math.stackexchange.com/questions/1024280/most-ambiguous-and-inconsistent-phrases-and-notations-in-maths Most ambiguous and inconsistent phrases and notations in maths] on math.stackexchange<br />
<references/></div>Spagety