Calculus: An Integrated Approach to Functions and their Rates of Change, Preliminary Edition Part 81 ppt

P A R TIX Applications and Computation of the Integral 25 Finding Antiderivatives— An Introduction to Indefinite Integration 25.1 A LIST OF BASIC ANTIDERIVATIVES In order to apply the Fu

24.2 The Average Value of a Function: An Application of the Definite Integral 781

6 The amount of a certain chemical in a mixture varies with time If g(t) = 5e−tis the number of grams of the chemical at time t, what is the average number of grams of the chemical in the mixture on the time interval [0, 1]?

7 The velocity of an object is given by 3 sin(π t)

(a) What is the object’s speed as a function of time?

(b) What is the object’s net displacement from t = 0 to t = 2?

(c) How far has the object traveled from t = 0 to t = 2?

(d) What is the object’s average velocity on [0, 2]?

(e) What is the object’s average speed on [0, 2]?

8 The graphs of functions f , g, h, and k are given below

Let I denote the average value of f on [0, 4]

Let II denote the average value of g on [0, 4]

Let III denote the average value of h on [0, 4]

Let IV denote the average value of k on [0, 4]

Put I, II, III, and IV, in ascending order, with “<” or “≤” signs between them as appropriate

(2, 5)

f

(2, 5)

g

(2, 5)

h

2.5

k

9 A bicycle speedometer will give the average velocity of a bicyclist over the time period the bicycle is moving By pressing a button the bicylist can reset the average velocity counter Suppose a long-distance cyclist has averaged 14 miles per hour for the first two hours of her trip She resets the average velocity counter For the next four hours her average velocity is 18 miles per hour

(a) What is the cyclist’s average velocity for the six-hour trip?

(b) How far has she traveled?

10 It takes a bicyclist 8 minutes to ride 1 mile uphill and then 2 minutes to ride 1 mile downhill Explain how we know that the cyclist’s average velocity for the hill is 12 miles per hour

11 The temperature of a hotplate of radius 5 inches varies with the distance from the center

of the plate For the area within 2 inches of the center the average temperature is 100 degrees For the area between 2 and 5 inches from the center the average temperature

is 80 degrees What is the average temperature of the plate?

12 Find the average value of | sin(3t)| on [0, 2π] Explain your reasoning

782 CHAPTER 24 The Fundamental Theorem of Calculus

13 The graph below shows the birthrate, B(t), and the death rate, D(t), for a population

of fish in a lake t is measured in years, and t = 0 represents 1960 The population of fish in 1960 was 4500 (Assume that births and deaths are the only factors that affect the population—no fishing, no immigration, etc.)

fish/year

t

D (t)

B (t)

(a) Write an expression for the total number of births between 1960 and 1996 (b) Write an expression for the average death rate between 1980 and 1990

(c) Write an expression for the fish population in 1996

(d) Approximate the year the population was greatest

(e) Was the 1996 population greater or less than 4500? Explain

P A R T

IX Applications and Computation of the Integral

25

Finding Antiderivatives—

An Introduction to Indefinite Integration

25.1 A LIST OF BASIC ANTIDERIVATIVES

In order to apply the Fundamental Theorem of Calculus we need to be able to find antideriva-tives This process can be challenging Therefore, it is useful to have at our disposal a list

of functions we can readily antidifferentiate We obtain this list by thinking about functions

we can readily differentiate and working backward

D e f i n i t i o n

The symbol f (x) dxstands for the entire family of functions that are antiderivatives

of f (x). f (x) dxis called the indefinite integral of f (x) f (x) is the integrand.

Recall that if F (x) is an antiderivative of f (x), then F (x) + C is also an antiderivative

of f (x) for any constant C

d

dx[F (x) + C] =dxd F (x) + 0 = f (x)

783

784 CHAPTER 25 Finding Antiderivatives—An Introduction to Indefinite Integration

Any two antiderivatives of f differ by an additive constant, so every antiderivative of f can

be written in the form F (x) + C

We know that

d

dx sin x = cos x; therefore

 cos x dx = sin x + C

Equivalently, we can write

d

dw sin w = cos w; therefore

 cos w dw = sin w + C

Or

d

dusin u = cos u; therefore

 cos u du = sin u + C

The variables x, w, and u are sometimes referred to as “dummy variables,” meaning that the statements we’ve made are equivalent, regardless of the variable we use. cos x dx = sin x + C, cos w dw = sin w + C, and cos u du = sin u + C all say the same thing

d

dxxn

= nxn−1  xndx =xn+1n+1+ C for n = −1 d

dx ln x =1x

 1

xdx = ln |x| + C (An explanation of the need for |x| will follow.) d

dxex= ex  exdx = ex+ C d

dxbx= (ln b) · bx  bxdx =ln b1 bx+ C d

dx sin x = cos x  cos x dx = sin x + C d

dx cos x = − sin x  sin x dx = − cos x + C

 d

dx cos x = − sin x, sodxd [− cos x] = sin x



d

dx tan x = sec2x  sec2x dx = tan x + C d

dx arcsin x =√1

1−x 2

√ 1−x 2dx = arcsin x + C d

dx arccos x =√−1

1−x 2

 √−1 1−x 2dx = arccos x + C d

dx arctan x =1+x12dx  1

1+x 2dx = arctan x + C

Comments:

The “+ C,” in each of these indefinite integrals is necessary; without the “+ C” we have given only one antiderivative as opposed to the entire family of antiderivatives From a graphical perspective, the “+ C” indicates that all antiderivatives of the function are vertical translates of one another

Why do we need the absolute value bars in 1xdx = ln |x| + C?

We are looking for an antiderivative of 1x

If x > 0 and F (x) = ln x, then F (x) =x1 Therefore, ln x is an antiderivative ofx1for

x >0

If x < 0, then ln x is undefined However, if we let F (x) = ln(−x), then F (x) =

1

−x · (−1) =x1 Therefore, ln(−x) is an antiderivative of 1x for x < 0

25.1 A List of Basic Antiderivatives 785

ln |x| =

ln x for x > 0 ln(−x) for x < 0. Therefore, we can use F (x) = ln |x| as an antiderivative of1x for all x = 0

1−x 2 dx = arccos x + C; on the other hand,  √−1

1−x 2 dx =

− √1

1−x 2 dx = − arcsin x + C Therefore, arccos x and − arcsin x must differ by a constant

− arcsin x = arccos x + C Find C

In addition to the list of specific antiderivatives given in the table on page 784, we can deduce principles for integration of the sum of functions and integration of a constant multiple of a function from the corresponding principles for differentiation

General Differentiation Rules Corresponding General Integration Rules

d

dx[f (x) + g(x)] =dxdf (x) +dxd g(x)  f (x) + g(x) dx =f (x) dx + g(x) dx d

dx



k f (x)= kdxdf (x)  k f (x) dx = k f (x) dx

The antiderivatives listed in the table on page 784 together with the two general integration rules above, enable us to evaluate a wide variety of definite integrals Learning how to undo the Chain Rule will allow us to evaluate an even broader range of definite and indefinite integrals We will do this, using a technique called substitution, in this chapter We can further expand the type of functions we can integrate by using the Product Rule in reverse and arriving at a technique called integration by parts This will be taken up in Section 29.1

In the problems below we apply general integration rules in combination with the basic antiderivatives displayed in the table on page 784 Our strategy is to manipulate the integrand algebraically so that it can be expressed as a sum Then the integral can be pulled apart into the sum of simpler integrals

EXAMPLE 25.1 Integrate the following (Try these on your own first; then read the solutions.)

(a)  1 + x2

2

dx (b)

 (x + 7)√x dx (c)

 2x + 3

x2 dx

SOLUTIONS

(a)

 

1 + x2

2

dx =

 

x4+ 2x2+ 1

 dx

=x

5

5 +2x

3

3 + x + C  Note that there’s no need to

use three separate constants



786 CHAPTER 25 Finding Antiderivatives—An Introduction to Indefinite Integration

(b)

 (x + 7)√x dx =



x√

x dx +



7√

x dx

=



x3/2dx + 7



x1/2+ C

=2

5x

5/2

+ 7 ·2

3x

3/2

+ C

=2

5x

5/2

+14

3 x

3/2

+ C (c)

 2x + 3

x2 dx =

 2x

x2 +x32dx

=

 2

x dx +

 3

x2dx

= 2

 1

x dx + 3



x−2dx

= 2 ln |x| + 3 x

−2+1

−2 + 1+ C

= 2 ln |x| −x3 + C

P R O B L E M S F O R S E C T I O N 2 5 1

In Problems 1 through 11, compute the integral.

1. 3x3+ 2x + π dx

2. Atndt, where A and n are constants and n = −1

3. 3x−1dx

4. dx2x

5. 3 sin t − 1+t32 dt

6. 5 dx7x

7. 2 cos w3 dw

8. x21+1 dx

9. e2p dp

10. sec52t dt

11. cos t + sec t tan t dt

25.2 Substitution: The Chain Rule in Reverse 787

In Problems 12 through 14, find antiderivatives for the given functions In other words, for each function f , find a function F such that F = f Check your answers.

12 (a) f (x) = e3x (b) f (x) =e3x

13 (a) f (x) =−12x (b) f (x) =1+x42

14 (a) f (x) = sin 2x (b) f (x) = cos(x/3)

15 (a) Differentiate f (x) = 5 tan(x2) + arctan 3x

(b) Find 10x sec2(x2) +1+9x3 2 dx

16 (a) Differentiate y =−π cos 3x3

(b) Find Asin Bx dx, where A and B are constants

17 (a) Suppose the velocity of an object is given by v(t) =1+t12 miles per hour Find its net change in position from t = 0 to t = 1, t measured in hours What is the total distance traveled on [0, 1]?

(b) Suppose that the velocity of an object is given by v(t) = 5t (t − 1) meters per second What is the net change in position between t = 0 and t = 2, t measured in seconds? What is the total distance traveled on [0, 2]?

18 Find the following indefinite integrals

(a) 2+xx dx (b) x32 dx (c) 3

1+x 2 dx (d) t43 +√4

t

 dt

19 Evaluate the following integrals

(a)(x + π)x2dx (b) √kx

(d) 2 −1x

 √

x dx (e)(x + 1)√5x dx

25.2 SUBSTITUTION: THE CHAIN RULE IN REVERSE

In Section 25.1, we used our knowledge of the derivatives of basic building block functions (like sin x, xn, and ln x) to create a list of “basic” or “familiar” integrals to keep at our fingertips We used two general rules of differentiation, the rules for differentiating the sum of functions and the constant multiple of a function, to obtain two general rules of integration In this section we will use the Chain Rule in reverse to arrive at an integration technique referred to as substitution This will enable us to greatly expand the type of functions we can antidifferentiate

From functions h(x) and u(x) we can build the composite function h(u(x)) in which the output of u is the input of h The Chain Rule tells us how to differentiate the composite

of differentiable functions:

d

dxh(u(x)) = h (u(x)) · u (x)

The derivative of h(u(x)) is the product of the derivative of h evaluated at u(x) and the derivative of u

788 CHAPTER 25 Finding Antiderivatives—An Introduction to Indefinite Integration

In the examples below we use the Chain Rule to differentiate composite functions and then give the corresponding antiderivative problem After presenting these problems (all variations on a theme) we will generalize

EXAMPLE 25.2 Theme and Variations In parts (a)–(c) we differentiate and then give the corresponding

antiderivative problem We apply the results of part (c) to parts (d)–(f)

(a) dxd sin(5x) = cos(5x) · 5  cos(5x) · 5 dx = sin(5x) + C (b) dxd sin(x2) = cos(x2) · 2x  cos(x2) · 2x dx = sin(x2) + C (c) dxd sin(u(x)) = cos(u(x)) · u (x)  cos(u(x)) · u (x) dx = sin(u(x)) + C

or, equivalently,

d

dx sin(u(x)) = cos(u(x)) · dudx

 cos(u(x)) ·dudx dx = sin(u(x)) + C (d)  cos(ex) · exdxhas the underlying structure cos(u(x)) · u (x) dx

 cos(ex) · ex dx = sin(ex)+C

 cos(u(x)) · u (x) dx = sin(u(x)) + C, where u(x) = exand u (x) = ex (e) cos(x + 5) dx has the underlying structure cos(u(x)) · u (x) dx

 cos(x + 5) · 1 dx = sin(x + 5) + C

 cos(u(x)) · u (x) dx = sin(u(x)) + C, where u(x) = x + 5 and u (x) = 1

(f ) cos(√x)

2 √

x dxhas the underlying structure cos(u(x)) · u (x) dx

 cos√

2√

x dx = sin(√x)

 cos(u(x)) · u (x) dx = sin(u(x)) + C, where u(x) =√xand u (x) = 2√1

There is a whole world of integrals accessible to us using the ideas of Example 25.2 Before we generalize, we distinguish between what we are able to do and what we are unable to do in the next example

EXAMPLE 25.3 Which of the following antiderivatives can be computed by using the Chain Rule in reverse?

Compute those we can do in this way

(a) cos 2x dx (b) xcos(x2) dx (c) 2 cos(x2) dx

Can we put this integral into the form cos(u(x)) · u (x) dx?

If so, u(x) = 2x Therefore, u (x) = 2 We’d like to see u (x)in the integrand; we’re missing a 2

25.2 Substitution: The Chain Rule in Reverse 789



cos(2x) dx =

 cos(2x) · 2 ·1

2 dx Multiply the integrand by

2

2 = 1

=1 2

 cos(2x) · 2 dx



k f (x) · dx = k



f (x) dx

=1 2

 cos(u(x)) · u (x) dx, where u(x) = 2x

=1

2sin(u(x)) + C

=1

2sin(2x) + C (b) xcos(x2) dx

Can we put this integral into the form cos(u(x)) · u (x) dx?

If so, u(x) = x2 Therefore, u (x) = 2x We’d like to see u (x)in the integrand; we’ve got the x but are missing a 2



xcos(x2) dx =

 cos(x2) · x dx

=1 2

 cos(x2) · 2x dx

=1 2

 cos(u(x)) · u (x) dx, where u(x) = x2

=1

2 sin(u(x)) + C

=1

2 sin(x

2

) + C (c) 2 cos(x2) dx

Can we put this integral into the form cos(u(x)) · u (x) dx?

If so, u(x) = x2 Therefore, u (x) = 2x We’d like to see u (x)in the integrand; we’re missing an x



2 cos(x2) dx =

 cos(x2) · 2 dx

Now we’re stuck We can multiply byxx (for x = 0), but we can’t pull the1x out of the integral



k f (x) dx = k



f (x) dx, only if k is constant

A missing constant in u (x)need not worry us, but a missing variable makes all the difference in the world; we can’t find an antiderivative using the Chain Rule in reverse.1

Just as the Chain Rule allows us to generalize each shortcut to differentiation we know, e.g.,dxd ln x =1xgeneralizing todxd ln(u(x)) =u(x)1 ·dudx, so too does it allow us to generalize each antiderivative in our table of antiderivatives

1 In fact, we can’t find an antiderivative at all unless we’re willing to express it as an infinite polynomial.

790 CHAPTER 25 Finding Antiderivatives—An Introduction to Indefinite Integration



xndx =xn+1n+1+ C generalizes to  u(x) u (x) dx =[u(x)n+1]n+1+ C, n = −1

 1

x dx = ln |x| + C generalizes to  u(x)1 · u (x) dx = ln |u(x)| + C



exdx = ex+ C generalizes to  eu(x)· u (x) dx = eu(x)+ C

 sin x dx = − cos x + C generalizes to  sin(u(x)) · u (x) dx = − cos(u(x)) + C

 cos x dx = sin x + C generalizes to  cos(u(x)) · u (x) dx = sin(u(x)) + C

 1 1+x 2dx = arctan x + C generalizes to  1

1+[u(x)]2· u (x) dx = arctan(u(x)) + C

and so on

This generalized table of integrals incorporates the antidifferentiation analogue of the Chain Rule This table is unnecessary, however, if we streamline our notation using the method of substitution Essentially we will replace u(x) by u and u (x) dxby du

The Mechanics of Substitution

When faced with an unfamiliar integral, we can use the technique of substitution to attempt

to transform it (altering its form but not its substance) into a familiar integral In other words, some integrals that look intimidating are really sheep in wolves’ clothing; structurally they are familiar integrals, but they are in disguise Substitution is a long-standing method we use to uncover the underlying structure of a problem.2

For instance, in Example 25.3(b) we looked at xcos(x2) dx In this form it is certainly not one of the integrals with which we are familiar Substitution allows us to see that essentially this integral is cos u du in disguise We make the substitution u = x2 and transform the integral xcos(x2) dxto an integral in u cos(x2)becomes cos u We must write x dx in terms of u

Since

u = x2 du

dx = 2x

We’ve differentiated both sides with respect to x We can write

du = 2x dx

In other words,dudx dx = 2x dx and we equatedudx dxwith du

Going from dudx = 2x to du = 2x dx should strike you as a little underhanded (and conceivably illegal) We’re treatingdudx as if it were a fraction, but it is not We have actually not defined du and dx independently However, this abuse of notation turns out to be all right; we will justify it momentarily First, let’s finish the example so you appreciate the handiness of it

Writing du = 2x dx allows us to express our original integral entirely in terms of u

2 Similarly, when working with equations like x 4 − 5x 2 + 4 = 0 the substitution u = x 2 helped expose the underlying quadratic structure of the equation: u 2 − 5u + 4 = 0, so (u − 4)(u − 1) = 0 We solve for u and then return to the original variable.

1 In fact, we can’t find an antiderivative at all unless we’re willing to express it as an infinite polynomial.