Inverse function rule

In mathematics, the inverse of a function $y=f(x)$ is a function that, in some fashion, "undoes" the effect of $f$ (see inverse function for a formal and detailed definition). The inverse of $f$ is denoted as $f^{-1}$ , where $f^{-1}(y)=x$ if and only if $f(x)=y$ .

Their two derivatives, assuming they exist, are reciprocal, as the Leibniz notation suggests; that is:

{\frac {dx}{dy}}\,\cdot \,{\frac {dy}{dx}}=1.

This relation is obtained by differentiating the equation $f^{-1}(y)=x$ in terms of $x$ and applying the chain rule, yielding that:

{\frac {dx}{dy}}\,\cdot \,{\frac {dy}{dx}}={\frac {dx}{dx}}

considering that the derivative of $x$ with respect to $x$ is 1.

Writing explicitly the dependence of $y$ on $x$ , and the point at which the differentiation takes place, the formula for the derivative of the inverse becomes (in Lagrange's notation):

\left[f^{-1}\right]'(a)={\frac {1}{f'\left(f^{-1}(a)\right)}}

.

This formula holds in general whenever $f$ is continuous and injective on an interval $I$ , with $f$ being differentiable at $f^{-1}(a)$ ( $\in I$ ) and where $f'(f^{-1}(a))\neq 0$ . The same formula is also equivalent to the expression

{\mathcal {D}}\left[f^{-1}\right]={\frac {1}{({\mathcal {D}}f)\circ \left(f^{-1}\right)}},

where ${\mathcal {D}}$ denotes the unary derivative operator (on the space of functions) and $\circ$ denotes function composition.

Geometrically, a function and inverse function have graphs that are reflections, in the line $y=x$ . This reflection operation turns the gradient of any line into its reciprocal.

Assuming that $f$ has an inverse in a neighbourhood of $x$ and that its derivative at that point is non-zero, its inverse is guaranteed to be differentiable at $x$ and have a derivative given by the above formula.

Examples

$y=x^{2}$ (for positive $x$ ) has inverse $x={\sqrt {y}}$ .

{\frac {dy}{dx}}=2x{\mbox{ }}{\mbox{ }}{\mbox{ }}{\mbox{ }};{\mbox{ }}{\mbox{ }}{\mbox{ }}{\mbox{ }}{\frac {dx}{dy}}={\frac {1}{2{\sqrt {y}}}}={\frac {1}{2x}}

{\frac {dy}{dx}}\,\cdot \,{\frac {dx}{dy}}=2x\cdot {\frac {1}{2x}}=1.

At $x=0$ , however, there is a problem: the graph of the square root function becomes vertical, corresponding to a horizontal tangent for the square function.

$y=e^{x}$ (for real $x$ ) has inverse $x=\ln {y}$ (for positive $y$ )

{\frac {dy}{dx}}=e^{x}{\mbox{ }}{\mbox{ }}{\mbox{ }}{\mbox{ }};{\mbox{ }}{\mbox{ }}{\mbox{ }}{\mbox{ }}{\frac {dx}{dy}}={\frac {1}{y}}

{\frac {dy}{dx}}\,\cdot \,{\frac {dx}{dy}}=e^{x}\cdot {\frac {1}{y}}={\frac {e^{x}}{e^{x}}}=1

Additional properties

Integrating this relationship gives

{f^{-1}}(x)=\int {\frac {1}{f'({f^{-1}}(x))}}\,{dx}+C.

This is only useful if the integral exists. In particular we need

f'(x)

to be non-zero across the range of integration.

It follows that a function that has a continuous derivative has an inverse in a neighbourhood of every point where the derivative is non-zero. This need not be true if the derivative is not continuous.

Another very interesting and useful property is the following:

\int f^{-1}(x)\,{dx}=xf^{-1}(x)-F(f^{-1}(x))+C

Where

F

denotes the antiderivative of

f

.

The inverse of the derivative of f(x) is also of interest, as it is used in showing the convexity of the Legendre transform.

Let $z=f'(x)$ then we have, assuming $f''(x)\neq 0$ : ${\frac {d(f')^{-1}(z)}{dz}}={\frac {1}{f''(x)}}$ This can be shown using the previous notation $y=f(x)$ . Then we have:

$f'(x)={\frac {dy}{dx}}={\frac {dy}{dz}}{\frac {dz}{dx}}={\frac {dy}{dz}}f''(x)\Rightarrow {\frac {dy}{dz}}={\frac {f'(x)}{f''(x)}}$ Therefore:

${\frac {d(f')^{-1}(z)}{dz}}={\frac {dx}{dz}}={\frac {dy}{dz}}{\frac {dx}{dy}}={\frac {f'(x)}{f''(x)}}{\frac {1}{f'(x)}}={\frac {1}{f''(x)}}$

By induction, we can generalize this result for any integer $n\geq 1$ , with $z=f^{(n)}(x)$ , the nth derivative of f(x), and $y=f^{(n-1)}(x)$ , assuming $f^{(i)}(x)\neq 0{\text{ for }}0<i\leq n+1$ :

${\frac {d(f^{(n)})^{-1}(z)}{dz}}={\frac {1}{f^{(n+1)}(x)}}$

Higher derivatives

The chain rule given above is obtained by differentiating the identity $f^{-1}(f(x))=x$ with respect to $x$ . One can continue the same process for higher derivatives. Differentiating the identity twice with respect to $x$ , one obtains