Difference between revisions of "Calculus:Power Rule"

Power Rule

${\displaystyle (x^{n})'=n*x^{n-1}}$

Hint

n can be any number that is a kind of constant ${\displaystyle 1 \over 2}$ is constant.

also when you have square root

${\displaystyle {\sqrt {x}}}$

you can look it as

${\displaystyle x^{1 \over 2}}$

Examples

Example 1

EX1:${\displaystyle f'(x^{6})}$

Using the Power rule ${\displaystyle f'(x^{n})=n*x^{n-1}}$

${\displaystyle f'(x^{6})=6*x^{6-1}}$

${\displaystyle f'(x^{6})=6x^{5}}$

Example 2

EX2:${\displaystyle f'(x^{7})}$

Using the Power rule ${\displaystyle f'(x^{n})=n*x^{n-1}}$

${\displaystyle f'(x^{7})=7*x^{7-1}}$

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

Example 3

EX3:${\displaystyle f'(x^{7})}$

Using the Power rule ${\displaystyle f'(x^{n})=n*x^{n-1}}$

${\displaystyle f'(x^{7})=7*x^{7-1}}$

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

Example 4

EX4:${\displaystyle f'({x^{7} \over 7})}$

Using the Power rule ${\displaystyle f'(x^{n})=n*x^{n-1}}$

${\displaystyle f'({x^{7} \over 7})={1 \over 7}7*x^{7-1}}$

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

Example 5

EX5:${\displaystyle f'({\sqrt[{4}]{x}})}$

first turn it in to exponent ${\displaystyle f'({\sqrt[{4}]{x}})=f'({x^{1 \over 4}})}$

use the power rule

${\displaystyle f'({\sqrt[{4}]{x}})=({x^{{1 \over 4}-{1}}})}$

${\displaystyle f'({\sqrt[{4}]{x}})=({x^{-3 \over 4}})}$

Example 6

EX6:${\displaystyle f'({\sqrt[{4}]{x}})}$

first turn it in to exponent ${\displaystyle f'({{\sqrt[{4}]{x}}^{3}})=f'({x^{3 \over 4}})}$

use the power rule

${\displaystyle f'({{\sqrt[{4}]{x}}^{3}})=({x^{{3 \over 4}-{1}}})}$

${\displaystyle ff'({{\sqrt[{4}]{x}}^{3}})=({x^{-1 \over 4}})}$