Example 1: Evaluate
Using formula (4) from the preceding list, you find that
.
Example 2: Evaluate
.
Because
using formula (4) from the preceding list yields
Example 3: Evaluate
Applying formulas (1), (2), (3), and (4), you find that
Example 4: Evaluate
Using formula (13), you find that
Example 5: Evaluate
Using formula (19) with a = 5, you find that
One
of the integration techniques that is useful in evaluating indefinite
integrals that do not seem to fit the basic formulas is
substitution and change of variables. This
technique is often compared to the chain rule for differentiation
because they both apply to composite functions. In this method, the
inside function of the composition is usually replaced by a single
variable (often
u). Note that the derivative or a constant multiple of the derivative of the inside function must be a factor of the integrand.
The purpose in using the substitution technique is to
rewrite the integration problem in terms of the new variable so that one
or more of the basic integration formulas can then be applied. Although
this approach may seem like more work initially, it will eventually
make the indefinite integral much easier to evaluate.
Note that for the final answer to make sense, it must be written in terms of the original variable of integration.
Example 6: Evaluate
Because the inside function of the composition is
x3 + 1, substitute with
Example 7:
Because the inside function of the composition is 5
x, substitute with
Example 8: Evaluate
Because the inside function of the composition is 9 –
x2, substitute with
Integration by parts
Another integration technique to consider in evaluating indefinite integrals that do not fit the basic formulas is
integration by parts. You may consider this
method when the integrand is a single transcendental function or a
product of an algebraic function and a transcendental function. The
basic formula for integration by parts is
where
u and
v are differential functions of the variable of integration.
A general rule of thumb to follow is to first choose
dv as the most complicated part of the integrand that can be easily integrated to find
v. The
u function will be the remaining part of the integrand that will be differentiated to find
du. The goal of this technique is to find an integral, ∫
v du, which is easier to evaluate than the original integral.
Example 9: Evaluate ∫
x sec
2
x dx.
Example 10: Evaluate ∫
x4 In
x dx.
Example 11: Evaluate ∫ arctan
x dx.
Trigonometric integrals
Integrals
involving powers of the trigonometric functions must often be
manipulated to get them into a form in which the basic integration
formulas can be applied. It is extremely important for you to be
familiar with the basic trigonometric identities, because you often used
these to rewrite the integrand in a more workable form. As in
integration by parts, the goal is to find an integral that is easier to
evaluate than the original integral.
Example 12: Evaluate ∫ cos3
x sin4
x dx
Example 13: Evaluate ∫ sec
6
x dx
Example 14: Evaluate ∫ sin
4
x dx
Trigonometric substitutions
If an integrand contains a radical expression of the form
a specific
trigonometric substitution may be helpful in evaluating the indefinite integral. Some general rules to follow are
- If the integrand contains
- If the integrand contains
- If the integrand contains
Right triangles may be used in each of the three
preceding cases to determine the expression for any of the six
trigonometric functions that appear in the evaluation of the indefinite
integral.
Example 15: Evaluate
Because the radical has the form
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| Figure 1 | Diagram for Example 15. |
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Example 16: Evaluate
Because the radical has the form
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| Figure 2 | Diagram for Example 16. |
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