3.3 Differentiation rules (Page 2/14)

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Find $\frac{d}{d x} (x^{4}) .$

$4 x^{3}$

As we shall see, the procedure for finding the derivative of the general form $f (x) = x^{n}$ is very similar. Although it is often unwise to draw general conclusions from specific examples, we note that when we differentiate $f (x) = x^{3},$ the power on $x$ becomes the coefficient of $x^{2}$ in the derivative and the power on $x$ in the derivative decreases by 1. The following theorem states that the power rule holds for all positive integer powers of $x .$ We will eventually extend this result to negative integer powers. Later, we will see that this rule may also be extended first to rational powers of $x$ and then to arbitrary powers of $x .$ Be aware, however, that this rule does not apply to functions in which a constant is raised to a variable power, such as $f (x) = 3^{x} .$

The power rule

Let $n$ be a positive integer. If $f (x) = x^{n},$ then

f^{'} (x) = n x^{n - 1} .

Alternatively, we may express this rule as

\frac{d}{d x} x^{n} = n x^{n - 1} .

Proof

For $f (x) = x^{n}$ where $n$ is a positive integer, we have

f^{'} (x) = lim_{h \to 0} \frac{{(x + h)}^{n} - x^{n}}{h} .

Since {(x + h)}^{n} = x^{n} + n x^{n - 1} h + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} h^{2} + (\begin{matrix} n \\ 3 \end{matrix}) x^{n - 3} h^{3} + … + n x h^{n - 1} + h^{n},

we see that

{(x + h)}^{n} - x^{n} = n x^{n - 1} h + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} h^{2} + (\begin{matrix} n \\ 3 \end{matrix}) x^{n - 3} h^{3} + … + n x h^{n - 1} + h^{n} .

Next, divide both sides by h :

\frac{{(x + h)}^{n} - x^{n}}{h} = \frac{n x^{n - 1} h + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} h^{2} + (\begin{matrix} n \\ 3 \end{matrix}) x^{n - 3} h^{3} + … + n x h^{n - 1} + h^{n}}{h} .

Thus,

\frac{{(x + h)}^{n} - x^{n}}{h} = n x^{n - 1} + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} h + (\begin{matrix} n \\ 3 \end{matrix}) x^{n - 3} h^{2} + … + n x h^{n - 2} + h^{n - 1} .

Finally,

\begin{matrix} f^{'} (x) & = lim_{h \to 0} (n x^{n - 1} + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} h + (\begin{matrix} n \\ 3 \end{matrix}) x^{n - 3} h^{2} + … + n x h^{n - 1} + h^{n}) \\ = n x^{n - 1} . \end{matrix}

□

Applying the power rule

Find the derivative of the function $f (x) = x^{10}$ by applying the power rule.

Using the power rule with $n = 10,$ we obtain

f' (x) = 10 x^{10 - 1} = 10 x^{9} .

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Find the derivative of $f (x) = x^{7} .$

$f^{'} (x) = 7 x^{6}$

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The sum, difference, and constant multiple rules

We find our next differentiation rules by looking at derivatives of sums, differences, and constant multiples of functions. Just as when we work with functions, there are rules that make it easier to find derivatives of functions that we add, subtract, or multiply by a constant. These rules are summarized in the following theorem.

Sum, difference, and constant multiple rules

Let $f (x)$ and $g (x)$ be differentiable functions and $k$ be a constant. Then each of the following equations holds.

Sum Rule . The derivative of the sum of a function $f$ and a function $g$ is the same as the sum of the derivative of $f$ and the derivative of $g .$

\frac{d}{d x} (f (x) + g (x)) = \frac{d}{d x} (f (x)) + \frac{d}{d x} (g (x));

that is,

for j (x) = f (x) + g (x), j^{'} (x) = f^{'} (x) + g^{'} (x) .

Difference Rule . The derivative of the difference of a function f and a function g is the same as the difference of the derivative of f and the derivative of $g :$

\frac{d}{d x} (f (x) - g (x)) = \frac{d}{d x} (f (x)) - \frac{d}{d x} (g (x));

that is,

for j (x) = f (x) - g (x), j^{'} (x) = f^{'} (x) - g^{'} (x) .

Constant Multiple Rule . The derivative of a constant c multiplied by a function f is the same as the constant multiplied by the derivative:

\frac{d}{d x} (k f (x)) = k \frac{d}{d x} (f (x));

that is,

for j (x) = k f (x), j^{'} (x) = k f^{'} (x) .

Proof

We provide only the proof of the sum rule here. The rest follow in a similar manner.

For differentiable functions $f (x)$ and $g (x),$ we set $j (x) = f (x) + g (x) .$ Using the limit definition of the derivative we have

j^{'} (x) = lim_{h \to 0} \frac{j (x + h) - j (x)}{h} .

By substituting $j (x + h) = f (x + h) + g (x + h)$ and $j (x) = f (x) + g (x),$ we obtain

j^{'} (x) = lim_{h \to 0} \frac{(f (x + h) + g (x + h)) - (f (x) + g (x))}{h} .

Rearranging and regrouping the terms, we have

j^{'} (x) = lim_{h \to 0} (\frac{f (x + h) - f (x)}{h} + \frac{g (x + h) - g (x)}{h}) .

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Source: OpenStax, Calculus volume 1. OpenStax CNX. Feb 05, 2016 Download for free at http://cnx.org/content/col11964/1.2

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