Continuous function: Difference between revisions

In mathematics, a continuous function is, intuitively speaking, a function whose "value" does not jump abruptly for any vanishingly "small" variation to its argument. Another way to think about a continuous function is that any "small" change in the argument of the function can only effect a correspondingly "small" change in the value of the function.

Formal definition

A function f from a topological space ${\displaystyle (X,O_{X})}$ to another topological space ${\displaystyle (Y,O_{Y})}$, usually written as ${\displaystyle f:(X,O_{X})\rightarrow (Y,O_{Y})}$, is a continuous function if for every point ${\displaystyle x\in X}$ and for every open set ${\displaystyle U_{y}\in O_{Y}}$ containing the point y=f(x), there exists an open set ${\displaystyle U_{x}\in O_{X}}$ containing x such that ${\displaystyle f(U_{x})\subset U_{y}}$. Here ${\displaystyle f(U_{x})=\{f(x')\in Y\mid x'\in U_{x}\}}$. In a variation of this definition, instead of being open sets, ${\displaystyle U_{x}}$ and ${\displaystyle U_{y}}$ can be taken to be, respectively, a neighbourhood of x and a neighbourhood of ${\displaystyle y=f(x)}$.

An important equivalent definition, but perhaps less convenient to work with directly, is that a function ${\displaystyle f:(X,O_{X})\rightarrow (Y,O_{Y})}$ is continuous if for any open (respectively, closed) set ${\displaystyle U\in O_{Y}}$ the set ${\displaystyle f^{-1}(U)=\{x\in X\mid f(x)\in U\}}$ is an open (respectively, closed) set in ${\displaystyle O_{x}}$. In this definition, a continuous function is simply a function which maps open sets to open sets or, equivalently, closed sets to closed sets.

The first definition corresponds to a generalization of the ${\displaystyle \delta -\epsilon }$ argument which are usually taught in first year calculus courses to, among other things, define continuity for functions which map the real numbers to itself.