Quotient Rule for Derivatives

Theorem
Let $\map j x, \map k x$ be real functions defined on the open interval $I$.

Let $\xi \in I$ be a point in $I$ at which both $j$ and $k$ are differentiable.

Define the real function $f$ on $I$ by:


 * $\ds \map f x = \begin{cases}

\dfrac {\map j x} {\map k x} & : \map k x \ne 0 \\ 0 & : \text{otherwise} \end{cases}$

Then, if $\map k \xi \ne 0$, $f$ is differentiable at $\xi$, and furthermore:


 * $\map {f'} \xi = \dfrac {\map {j'} \xi \map k \xi - \map j \xi \map {k'} \xi} {\paren {\map k \xi}^2}$

It follows from the definition of derivative that if $j$ and $k$ are both differentiable on the interval $I$, then:


 * $\ds \forall x \in I: \map k x \ne 0 \implies \map {f'} x = \frac {\map {j'} x \map k x - \map j x \map {k'} x} {\paren {\map k x}^2}$

Proof
Let $\xi$ be such that $\map k \xi \ne 0$.

From Differentiable Function is Continuous‎, $k$ is continuous at $\xi$.

It follows that there exists an $\epsilon > 0$, such that $\size h < \epsilon \implies \map k {\xi + h} \ne 0$.

So let $\size h < \epsilon$.

Then we have:

Hence:

Thus by:
 * continuity of $k$ at $\xi$
 * differentiability of $j$ and $k$ at $\xi$
 * Combined Sum Rule for Limits of Real Functions:

it is concluded that:
 * $\ds \lim_{h \mathop \to 0} \frac {\map f {\xi + h} - \map f \xi} h = \frac 1 {\map k \xi^2} \paren {\map {j'} \xi \map k \xi - \map j \xi \map {k'} \xi}$

From the definition of differentiability, $f$ is differentiable at $\xi$, with stated value.