Skills Review for Integration by Parts

Learning Outcomes

  • Apply the power rule
  • Find the derivatives of the sine and cosine function.
  • Find the derivatives of the standard trigonometric functions.
  • Find the derivative of exponential functions
  • Find the derivative of logarithmic functions
  • Apply substitution integration shortcut formulas

In the Integration by Parts section, we will learn how to evaluate integrals where one part of the integral is easily differentiable while the other part is easily integrable. Here we will review some derivative-taking techniques along with substitution integration shortcuts.

Apply the Power Rule

We know that

[latex]\dfrac{d}{dx}\left(x^2\right)=2x[/latex]   and   [latex]\dfrac{d}{dx}\left(x^{\frac{1}{2}}\right)=\dfrac{1}{2}x^{−\frac{1}{2}}[/latex]

As we shall see, there is a procedure for finding the derivative of the general form [latex]f(x)=x^n[/latex]. The following theorem states that this power rule holds for all non-variable powers of [latex]x[/latex].

The Power Rule


Let [latex]n[/latex] be a number. If [latex]f(x)=x^n[/latex], then

[latex]f^{\prime}(x)=nx^{n-1}[/latex]

 

Alternatively, we may express this rule as

[latex]\dfrac{d}{dx}(x^n)=nx^{n-1}[/latex]

Example: Applying Basic Derivative Rules

Find the derivative of the function [latex]f(x)=x^{10}[/latex] by applying the power rule.

Example: Applying Basic Derivative Rules

Find the derivative of [latex]f(x)=2x^5+7[/latex].

Example: Applying Basic Derivative Rules

Find the derivative of [latex]f(x)=\sqrt{x}[/latex].

Try It

Find the derivative of [latex]f(x)=2x^{-3}-6x^2+3[/latex].

Try It

Find the derivative of [latex]f(x)=\sqrt{x^7}[/latex].

Find the Derivatives of the Standard Trigonometric Functions.

The Derivatives of [latex]\sin x[/latex] and [latex]\cos x[/latex]


The derivative of the sine function is the cosine and the derivative of the cosine function is the negative sine.

[latex]\frac{d}{dx}(\sin x)= \cos x[/latex]

 

[latex]\frac{d}{dx}(\cos x)=−\sin x[/latex]

Example: Differentiating a Function Containing [latex]sinx[/latex]

Find the derivative of [latex]f(x)=5x^3 \sin x[/latex].

The Derivatives of  [latex]\tan x, \, \cot x, \, \sec x[/latex],  and  [latex]\csc x[/latex]


The derivatives of the remaining trigonometric functions are as follows:

[latex]\frac{d}{dx}(\tan x)=\sec^2 x[/latex]

 

[latex]\frac{d}{dx}(\cot x)=−\csc^2 x[/latex]

 

[latex]\frac{d}{dx}(\sec x)= \sec x \tan x[/latex]

 

[latex]\frac{d}{dx}(\csc x)=−\csc x \cot x[/latex]

Try It

Find the derivative of [latex]f(x)= \cot x[/latex].

Find the Derivatives of Exponential and Logarithmic Functions with Base e

Derivative of the Natural Exponential Function


Let [latex]E(x)=e^x[/latex] be the natural exponential function. Then

[latex]E^{\prime}(x)=e^x[/latex]

 

In general,

[latex]\frac{d}{dx}(e^{g(x)})=e^{g(x)} g^{\prime}(x)[/latex]

If it helps, think of the formula as the chain rule being applied to natural exponential functions. The derivative of [latex]e[/latex] raised to the power of a function will simply be [latex]e[/latex] raised to the power of the function multiplied by the derivative of that function.

Example: Differentiating An Exponential Function

Find the derivative of [latex]f(x)=e^{\tan (2x)}[/latex].

Try It

Find the derivative of [latex]f(x)=e^{5x^2}[/latex].

Now that we have the derivative of the natural exponential function, we can use implicit differentiation to find the derivative of its inverse, the natural logarithmic function.

The Derivative of the Natural Logarithmic Function


If [latex]x>0[/latex] and [latex]y=\ln x[/latex], then

[latex]\frac{dy}{dx}=\dfrac{1}{x}[/latex]

 

More generally, let [latex]g(x)[/latex] be a differentiable function. For all values of [latex]x[/latex] for which [latex]g^{\prime}(x)>0[/latex], the derivative of [latex]h(x)=\ln(g(x))[/latex] is given by

[latex]h^{\prime}(x)=\dfrac{1}{g(x)} g^{\prime}(x)[/latex]

Example: Differentiating A Natural Logarithmic Function

Find the derivative of [latex]f(x)=\ln(x^3+3x-4)[/latex]

Try It

Find the derivative of [latex]g(x)=\ln(3x+7)[/latex].

 

 Apply Substitution Integration Shortcut Formulas

When integrating certain functions using substitution, certain patterns can be noticed in the answers. Here, we will review some shortcut integration formulas that are a result of substitution.

SUbstitution Integration Shortcut Formulas


Let [latex]a[/latex] be a constant, then

  • [latex]\displaystyle\int e^{ax} dx=\dfrac{e^{ax}}{a}+C[/latex]
  • [latex]\displaystyle\int \sin ax dx=-\dfrac{\cos ax }{a}+C[/latex]
  • [latex]\displaystyle\int \cos ax dx=\dfrac{\sin ax }{a}+C[/latex]

     

Example: Using a Substitution Integration Shortcut Formula

Find [latex]\displaystyle\int e^{10x} dx[/latex].

Try It

Find [latex]\displaystyle\int \cos 2x dx[/latex].