1.4 Inverse functions  (Page 2/11)

Is the function $f$ graphed in the following image one-to-one?

No.

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Finding a function’s inverse

We can now consider one-to-one functions and show how to find their inverses. Recall that a function maps elements in the domain of $f$ to elements in the range of $f.$ The inverse function maps each element from the range of $f$ back to its corresponding element from the domain of $f.$ Therefore, to find the inverse function of a one-to-one function $f,$ given any $y$ in the range of $f,$ we need to determine which $x$ in the domain of $f$ satisfies $f(x)=y.$ Since $f$ is one-to-one, there is exactly one such value $x.$ We can find that value $x$ by solving the equation $f(x)=y$ for $x.$ Doing so, we are able to write $x$ as a function of $y$ where the domain of this function is the range of $f$ and the range of this new function is the domain of $f.$ Consequently, this function is the inverse of $f,$ and we write $x=f^{\mathrm{-1}}(y).$ Since we typically use the variable $x$ to denote the independent variable and $y$ to denote the dependent variable, we often interchange the roles of $x$ and $y,$ and write $y=f^{\mathrm{-1}}(x).$ Representing the inverse function in this way is also helpful later when we graph a function $f$ and its inverse $f^{\mathrm{-1}}$ on the same axes.

Graphing inverse functions

Let’s consider the relationship between the graph of a function $f$ and the graph of its inverse. Consider the graph of $f$ shown in [link] and a point $\left(a,b\right)$ on the graph. Since $b=f(a),$ then $f^{\mathrm{-1}}\left(b\right)=a.$ Therefore, when we graph $f^{\mathrm{-1}},$ the point $(b,a)$ is on the graph. As a result, the graph of $f^{\mathrm{-1}}$ is a reflection of the graph of $f$ about the line $y=x.$