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Revision as of 08:01, 26 October 2010
Table of Derivatives
| Laplace Transform Pairs and Properties | ||
|---|---|---|
| General Rules | ||
| Derivative of a constant | $ \frac{d}{dx}\left( c \right) = 0, \ \text{ for any constant }c $ | |
| $ \frac{d}{dx}\left( c x \right) = c, \ \text{ for any constant }c $ | ||
| Linearity | $ \frac{d}{dx}\left( c_1 u_1+c_2 u_2 \right) = c_1 \frac{d}{dx}\left( u_1 \right)+c_2 \frac{d}{dx}\left( u_2 \right), \ \text{ for any constants }c_1, c_2 $ | |
| please continue | put new rule here | |
| Derivatives of trigonometric functions | ||
| sine | $ \sin u $ | $ \cos u \frac{du}{dx} $ |
| please continue | write a function here | write its derivative here |
| Name | Function | Derivative |
|---|---|---|
| sine | $ \sin u $ | $ \cos u \frac{du}{dx} $ |
| please continue | write a function here | write its derivative here |
| Name | Function | Derivative |
|---|---|---|
| exponential | $ e^u $ | $ e^u \frac{du}{dx} $ |
| please continue | write a function here | write its derivative here |
