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In this section, we introduce the idea of the indefinite integral. We also look at the process of variable substitution to find antiderivatives of more.

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Presentation on theme: "In this section, we introduce the idea of the indefinite integral. We also look at the process of variable substitution to find antiderivatives of more."— Presentation transcript:

1 In this section, we introduce the idea of the indefinite integral. We also look at the process of variable substitution to find antiderivatives of more complex functions.

2 For any function f, is called the indefinite integral of f and represents the most general antiderivative of f.

3 For any function f, is called the indefinite integral of f and represents the most general antiderivative of f. For example:

4 Find each of the following: (a) (b) (c)

5 Find each of the following: (d) (e) (f)

6 What if the integrand is not something that we recognize as a “basic” antiderivative rule? For example, We would like to do a variable substitution so that the “new” integral is one that we recognize as a “basic” antiderivative rule.

7 Let f, u, and g be continuous functions such that: for all x. Then:

8 Substitute: Choose a function u = u(x) such that the substitution of u for x and du for dx changes into Antidifferentiate: Solve - that is, find G(u) such that Resubstitute: Substitute x back in for u to get the answer to have an antiderivative of the original function

9 Looking again at

10 Find each of the following: (a) (b)

11 Find each of the following: (a) (b)

12 Find each of the following: (a) (b)

13 Let f, u, and g be continuous functions such that: for all x. Then:

14 Find each of the following: (a) (b)

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