Calculus: An Integrated Approach to Functions and their Rates of Change, Preliminary Edition Part 75 ppsx

t Figure 22.13 SOLUTION Because v is increasing on the interval [0, 3], we can find lower bounds for the gazelle’s net change in position by using left-hand sums inscribed rectangles and

Let’s return for a moment to the problem of calculating the cheetah’s net change in position and approach it with a different mindset Let s(t) = the cheetah’s position at time

t Then v(t) = s(t ) In other words, dsdt = 2t + 5; s(t) is a function whose derivative is 2t + 5 Because s(t )is linear, we might suspect that s(t) is quadratic

If s(t) = t2+ 5t, then s(t ) = 2t + 5 In fact, if two functions have the same derivative, then the functions must differ by an additive constant; if f(x) = g(x), then f (x) = g(x) + C for some constant C Therefore,

s(t ) = t2+ 5t + C for some constant C Then the change in position from t = 1 to t = 4 is given by

s(4) − s(1) = 42+ 5(4) + C − [12+ 5(1) + C]

= 16 + 20 + C − 6 − C

In Chapter 24 we will explore the relationship between the two mindsets presented in Example 22.5b and arrive at a wonderful theorem that unifies them For the time being, there is a lot to be learned from the first mindset; we will stick with it for a while

EXAMPLE 22.6 A gazelle’s velocity is given by the graph below v(t) is increasing on [0, 3] and decreasing

on [3, 6] How can we find the net change in the gazelle’s position over the interval [0, 5]?

v (t) v (t) is increasing on [0, 3]

and decreasing on [3, 6].

t

Figure 22.13

SOLUTION Because v is increasing on the interval [0, 3], we can find lower bounds for the gazelle’s

net change in position by using left-hand sums (inscribed rectangles) and upper bounds by using right-hand sums (circumscribed rectangles)

v (t)

t

5 3

v (t)

t

5 3

Figure 22.14

722 CHAPTER 22 Net Change in Amount and Area: Introducing the Definite Integral

Because v is decreasing on the interval [3, 5], we can find lower bounds for the net change in position by using right-hand sums (inscribed rectangles) and upper bounds by using left-hand sums (circumscribed rectangles) See Figure 22.14

We can obtain lower and upper bounds for the gazelle’s net change in position on [0, 5]

by treating the intervals [0, 3] and [3, 5] independently For instance,

L = (Lnon [0, 3]) + (Rmon [3, 5]) gives a lower bound, while

U = (Rnon [0, 3]) + (Lmon [3, 5]) gives an upper bound

If we compute the limit as n and m increase without bound, L and U will both approach the area under the velocity curve from t = 0 to t = 5 This area corresponds to the gazelle’s net change in position on [0, 5]

If we did not treat the intervals [0, 3] and [3, 5] independently, we could still look at left- and right-hand sums to approximate the gazelle’s net change in position We could not, however, label them as under- or overestimates

v (t)

t

v (t)

t

Figure 22.15

Nevertheless, limn→∞(Rn− Ln) = 0; in fact, limn→∞Rnand limn→∞Lnboth correspond

to the area under the velocity curve

If we were to partition [5, 6] into n equal pieces and compute Lnand Rn, they would give us upper and lower bounds, respectively, for the displacement See Figure 22.16 Both

Lnand Rnwill be negative for all n > 1 limn→∞Ln= limn→∞Rn= the signed area under the curve

R n gives a lower bound (more negative than the actual displacement).

L n gives a upper bound (less negative than the actual displacement).

Figure 22.16
Examples 22.5 and 22.6 illustrate the interplay between the graphical and physical problems posed at the beginning of the section The net change of a quantity can be represented as the signed area under the graph of the rate of change function The question

of how to find the area under the graph of a function is an important one, and is of interest

on its own merits It will be the focus of the next section

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

Do Problem 1; it’s a key problem and worthy of discussion.

1 It’s flu season and a health clinic has set up a flu shot program for its patients The clinic

is open on Saturday from 8:00 a.m to 4:00 p.m (16:00) giving flu shots on a first-come, first-serve basis The clinic has the capacity to serve 30 patients per hour The function r(t ), whose graph is given below, gives the rate at which people are arriving at the clinic for shots

r (t) (people/hr)

t(time)

8 9 10 15 30 45

11 12 13 14 15 16 17

Explain your answers to the questions below by relating them to points, lengths, or areas on the graph.5

(a) At what time does a line start forming?

(b) At approximately what time is the length of the line increasing most rapidly? (c) At approximately what time is the line the longest? (The answers to (b) and (c) are different Explain why.)

(d) When the line is longest, approximately how many people are in line?

(e) Approximate the longest amount of time a person could wait for a shot (Assume that doors close to new arrivals at 4:00 p.m but everyone who has arrived by 4:00 p.m.is served.)

(f ) Approximately how long is the line at 3:00 p.m.?

(g) Approximate the number of people who came to the clinic for a flu shot this day

2 Maple syrup is being poured at a decreasing rate out of a tank By taking readings from the valve on the tank, we have the following information on the rate at which the syrup

is leaving the tank

(a) Find a good upper bound for the amount of maple syrup that has been poured out between time t = 0 and t = 8

(b) Find a good lower bound for this same amount

3 An industrial chemist is making a mixture in a large container A certain chemical, B,

is being introduced into the mixture at an ever-increasing rate Some of the rates have

5This problem, like Problem 8 in Section 22.2, was inspired by Peter Taylor’s wicket problem, from Calculus: The Analysis

724 CHAPTER 22 Net Change in Amount and Area: Introducing the Definite Integral

been registered below Time t = 0 marks the first introduction of this chemical into the mixture

Determine reasonable upper and lower bounds for the number of grams of chemical B

in the mixture at time t = 13

4 (a) By partitioning the interval [0, π/2] into four equal pieces and using the areas

of inscribed and circumscribed rectangles as appropriate, find upper and lower bounds for the area between the graph of sin x and the x-axis for x in the interval

[0, π/2] Draw a picture illustrating what you have done (Note: You will have

to use your calculator to get some of the values of sin x and to get a numerical answer.)

(b) Using the work you did in part (a), find upper and lower bounds for the area under the graph of sin x between x = 0 and x = π Explain what you have done using a picture

(c) Using the work you did in part (b), give upper and lower bounds for the area under the graph of cos x between x = −π/2 and π/2

5 Suppose velocity (in miles per hour) is given by v(t) = 3t, where t is measured in hours

We are interested in the distance traveled from t = 0 to t = k, where k is a constant (a) By solving the differential equation ds/dt = 3t and using the initial condition s(0) = s0, find the distance function s(t) Using s(t), find

i s(0)

ii s(k)

iii the distance traveled between t = 0 and t = k

(b) Find the area under the graph of v(t) from t = 0 to t = k Verify that your answers

to part (a) iii and (b) are the same

6 Suppose velocity (in miles per hour) is given by v(t) = mt + c, where m and c are positive constants

(a) Using your knowledge of the area of a trapezoid, find the area under the graph of v(t )on the interval [a, b], where a and b are positive constants

(b) By solving the differential equation ds/dt = mt + c and using the initial condition s(0) = s0, find the distance function s(t) Using s(t) find

i s(a)

ii s(b)

iii the distance traveled between t = a and t = b

Verify that your answers to parts (a) and (b) iii are the same

7 Below is the graph of the velocity of a bee traveling in a straight line from a clover to

a hive Find the following

(a) the distance traveled between t = 1 and t = 3

(b) the distance traveled between t = 0 and t = 8.

(c) the distance traveled between t = 3 and t = 5

v (t)

t

2

4

6

8

(1, 4)

(5, 8)

(8, 2)

8 (a) The velocity of an object at time t is given by v(t) = t2ft/sec Partition the time interval [0, 3] into 3 equal pieces each of length 1 second Find upper and lower bounds for the distance the object traveled between time t = 0 and t = 3 (b) Illustrate your work in part (a) by graphing v(t) and using areas of inscribed and circumscribed rectangles Draw two pictures, one illustrating the upper bound and the other the lower bound

(c) Repeat part (a), but this time partition the interval into 6 equal pieces, each of length 1/2 Make a sketch indicating the areas you have found

(d) What is the difference between Rnand Lnif the interval is partitioned into 50 equal pieces? 100 equal pieces?

(e) Into how many equal pieces must we partition [0, 3] to be sure that the difference between the right- and left-hand sums is less than or equal to 0.01?

9 Suppose v(t) gives the velocity of a trekker on the time interval [0, 3] and suppose that v(t) is positive and decreasing over this interval If we use a left-hand sum to approximate the distance she has covered over this time interval, will the approximation give a lower bound or an upper bound?

22.2 THE DEFINITE INTEGRAL

Suppose we want to find the signed area under the graph of a continuous function f on the interval [a, b] We’ll use the method of successive approximations and then apply a limit process We divide the interval [a, b] into n subintervals of equal width, each subinterval being of width x =b−an We label as shown where xk= a + kx for k = 0, 1, 2, , n The subintervals are [x0, x1], [x1, x2], , [xn−1, xn]6

6 Notice that x n = a + nx = a + n b−a

n = a + b − a = b.

726 CHAPTER 22 Net Change in Amount and Area: Introducing the Definite Integral

∆x ∆x

x0 x1 x2 x3 x n–1 x n

.

x1

.

Notice that x n = a + n(∆x)

Figure 22.17

On each subinterval, we approximate the function f (x) by a constant function and approx-imate the (signed) area under f by the (signed) area of a rectangle

For a left-hand sum, we approximate f (x) on each subinterval by a constant function whose height is the value of f at the left endpoint of that subinterval For example, on the second subinterval, [x1, x2], the height of the rectangle is f (x1)because x1is the x-coordinate of the left endpoint of that subinterval The width of every rectangle is x Accordingly, we write the left-hand sum using n subintervals as follows

Ln= f (x0)x + f (x1)x + · · · + f (xn−1)x

=

n−1



i=0

f (xi)x

We write the right-hand sum using n subintervals in a similar way, but this time beginning with x1and ending with xn

Rn= f (x1)x + f (x2)x + · · · + f (xn)x

=

n



i=1

f (xi)x

x1

x0 x2 . x n–1 x n

left-hand sum

x1

x0 x2 . x n–1 x n

right-hand sum

Figure 22.18

Notice that we are not making any statement about these approximating sums being upper or lower bounds for the exact area We are taking f to be a generic continuous bounded function, so we don’t know where f is increasing and where f is decreasing

The left- and right-hand sums are special cases of what is called a Riemann sum, after

the mathematician Bernhard Riemann We will focus our attention on left- and right-hand sums, partitioning [a, b] into equal pieces, but Riemann sums are approximating sums that allow for more freedom of construction than Rnand Ln To construct a Riemann sum for a bounded function f on [a, b], chop the interval [a, b], into n subintervals (not necessarily equal in width) Label the chops consecutively a = x0< x1< x2< · · · xn= b From each of the subintervals choose an x-value in that interval Call these x-values x1∗, x2∗, , xn∗where the subscript k indicates an x-value from the kth interval Let xkbe the width of the kth subinterval xk= xk− xk−1for k = 1, 2, , n Any sum of the formn

k=1f (xk∗)xkis referred to as a Riemann sum It is more compact to use summation notation than to write out the individual terms, and this way of expressing the sums is suggestive of the notation

we will soon introduce

Finding the Exact Area

To get better approximations to the area, we increase n, the number of subdivisions To get

an exact value for the area, we look at the limit as n increases without bound When we did

so in Example 22.5b, Lnand Rnboth approached the same value, this being the exact area under the curve In the general case the left- and right-hand sums will approach the same limiting value provided that f is continuous.7The size of their difference is given by

|Rn− Ln| = |(f (x1)x + f (x2)x + · · · + f (xn)x) − (f (x0)x + f (x1)x

+ · · · + f (xn−1)x)|

= |f (xn)x − f (x0)x|

= |f (b) − f (a)| ·b − a

f (b), f (a), b, and a are all fixed quantities; they do not change as n grows without bound Thus, the difference between the left- and right-hand sums approaches zero as n grows without bound

lim

n→∞Ln

We define the signed area under f from a to b to be limn→∞Rn(or limn→∞Ln) provided the limit exists The signed area under f on the interval [a, b] is called the definite integral of f from a to b Signed area means that we consider the area between f and the horizontal axis to be positive where f is positive (where f lies above the horizontal axis) and negative where f is negative (where f lies below the horizontal axis)

7 Being continuous is sufficient to guarantee that f is integrable, i.e., that the limit of the Riemann sums exists This is proven

728 CHAPTER 22 Net Change in Amount and Area: Introducing the Definite Integral

f

x

2 1

–1 –1 1 2 3 4 5 –2

–3

The shaded areas have a negative sign.

Figure 22.19

The definition given above agrees with our intuitive notion of signed areas in those instances in which we have such a notion For f a reasonably well-behaved function, the interval [a, b] can be partitioned into regions on which either f is increasing or f is decreasing.8By doing so, we can guarantee that within each region left- and right-hand sums will provide upper and lower bounds for the signed area within the region limn→∞Rn equals limn→∞Ln, so we can conclude that these quantities must also equal the exact value

of the signed area If f is not reasonably well-behaved, then the signed area under f on

[a, b] is defined to be limn→∞Rn

D e f i n i t i o n

The definite integral of f (x) from x = a to x = b is writtenb

a f (x) dx and read as “the integral from a to b of f (x)” We define it as follows Subdivide the interval [a, b] into n equal subintervals of width x =b−an and label these subintervals [x0, x1], [x1, x2], , [xn−1, xn], where xi= a + ix, for i = 0, 1, 2, n

 b

n→∞

n



i=1

f (xi)x = lim

n→∞

n−1



i=0

f (xi)x, provided the limits exist

If f is continuous on [a, b], then this limit is guaranteed to exist.9

a f (x) dx is laden with meaning 

is a script S, reminding us that the definite integral is the limit of a sum It recalls the Greek letter & for summation

in the Riemann sums approximating the area We approximate the area with areas of

rectangles; f (x) represents all the heights f (xi), and dx represents the widths, the x,

in the Riemann sums You can think of the limiting process as an agent of metamorphoses fromn

i=1f (xi)xtoabf (x)dx

8 More precisely, by “increasing” we really mean nondecreasing, and by “decreasing” we mean nonincreasing Intervals on which f is constant can be included in one or the other.

9 The definite integral  b

f (x)dx can be defined more generally as the limit of a general Riemann sum When the limit is computed |x k | must approach zero for all x k If the limit of the Riemann sum as the width of the largest xkgoes to zero exists,

it is equal to  b

f (x) dx Again, if f is continuous on [a, b], then the limit is guaranteed to exist.

Notice that the numbers a and b, called the endpoints of integration, do not appear

i=1f (xi)x and n−1

i=0 f (xi)x At first this may surprise you, but on more careful examination you can see that x0= a and xn= b As

nincreases without bound, x1gets arbitrarily close to a and xn−1gets arbitrarily close to b

Terminology

The function f (x) being integrated inb

a f (x)dxis called the integrand.

The values a and b are called the endpoints of integration or the lower and upper

limits of integration.

Interpretations of the Definite Integral

As we saw in the example of computing distance traveled, the definite integral,abf (x) dx, can be interpreted as

the signed area under the graph of f (x) between x = a and x = b, or the net change in the amount A(x) between x = a and x = b if f (x) is the rate of change

of A(x)

EXERCISE 22.1 Let f be the function graphed in Figure 22.19 Its graph is composed of three semicircles

Evaluate the following definite integrals by interpreting the definite integral as signed area (a)3

−1f (x) dx

Answers

EXERCISE 22.2 Suppose that f is continuous on the interval [−1, 3] We partition [−1, 3] into n equal

subintervals, each of length x, and form left- and right-hand Riemann sums, Lnand Rn, respectively Explain and illustrate the following

If f>0, then Ln<3

−1f (x) dx < Rn; and

if f<0, then Rn<3

−1f (x) dx < Ln These inequalities hold regardless of the sign of f

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

1 On the following page are the graphs of the velocities of three runners on the interval [0, 5] Express the distance each runner has traveled in this interval in terms of a definite integral Who has traveled the greatest distance in this time interval? Who has traveled the smallest distance in the time interval?

730 CHAPTER 22 Net Change in Amount and Area: Introducing the Definite Integral

v (t) in ft/min

t (in minutes) 5

A : velocity = f(t)

C : velocity = h(t)

B : velocity = g(t)

2 Summation notation review

(a) Write the following in summation notation

i 3 − 4 + 5 − 6 + 7 − · · · − 300

ii 2 + 4 + 6 + · · · + 1000 iii 1 + 3 + 5 + · · · + 999

iv 23−29+272 −812 + · · · +3215

v x + x2+ x3+ x4+ · · · + x40

vi 12

+ 22+ 32+ · · · + 1002 vii a0+ a1x + a2x2+ a3x3+ · · · + anxn (b) Write out the following sums

i 5 i=2i2 ii 4

k=02k iii 3

j =0ajxj

3 Find the following and express your answer as simply as possible

(a)10 k=1

k 5

2

k=0

k 5 2

(b)n k=1

k n

2

k=0

k n 2

4 Find upper and lower bounds for each of the following definite integrals by calculating left- and right-hand Riemann sums with the number of subdivisions indicated (a) 02x3dx (n = 4) (b) 131tdt (n = 6)

5 Below are the velocity graphs for a chicken and a goat Assume that at time t = 0 the goat and the chicken start out side by side and they both travel along the same straight dirt path Answer the questions below When the quantity corresponds to an area, describe this area on the graph and then give it using the appropriate definite integral or sums and differences of definite integrals The graphs intersect at t = 1.5 and t = 6.5 The graph of vg(t )is maximum at t = 4.5

velocity

t

1 2 3 4 5 6 7 8

v g (t): velocity of goat

v c (t): velocity of chicken