Calculus: An Integrated Approach to Functions and their Rates of Change, Preliminary Edition Part 55 potx

16.3 USING THE CHAIN RULEIn this section, we take a second look at applying the Chain Rule.. EXAMPLE 16.6 Once we know the Chain Rule, there is no problem if we forget the Quotient Rule,

22 f (x) = x(x + 3)2

23 f (x) = (x − 2)(x + 1)2

24 f (x) = (3 − x)2(x − 1)

25 f (x) = ex(x − 3)3

26 Prove that if f (x) = (x − a)3

inflection at x = a

27 (a) Which of the following are equal to e−x2? Identify all correct answers.

i e−(x)(x) ii (e−x)x iii e1x

x

iv.e1x

2

v (e−x)2 vi (e−2)x vii e−2x viii e(−x)2

(b) Differentiate e−x2

28 Graph f (x) = e−x2and answer the following questions

(a) What is the domain of f ? The range?

(b) Is f an even function, an odd function, or neither?

(c) For what values of x is f increasing? Decreasing?

(d) Find all relative maximum and minimum points

(e) Does f have an absolute maximum value? An absolute minimum value? A greatest lower bound? If any of these exist, identify them

(f ) Find the x-coordinates of the points of inflection

(Note: This function is a good one to keep in mind It is extremely useful in both

probability and statistics because, with some minor adjustments, it gives us a normal distribution curve.)

16.2 THE DERIVATIVE OF xn WHERE n IS ANY

REAL NUMBER

At this point we have proven thatdxdxn= nxn−1for any integer n In fact, this formula holds

if n is any real number We can use the Chain Rule to prove this fact.

Suppose that r is any real number and we want to finddxd xr The key is to rewrite xr

so we can use derivative formulas that we already know

xr= eln xr exand ln x are inverses, so eln z= z

= erln x Use log rule (iii)

Now we take the derivative

dxx

r

=dxd erln x

= erln x·dxd (rln x) Use the Chain Rule: d

dxe

mess

= emess · (mess)

= erln x·r

x Keep in mind that r is a constant

= xr·xr Rewrite erln xas xr

= rxr−1

We now can take the derivative of xnwhere n is any real number

d

dxx

n

= nxn−1

EXERCISE 16.1 Find y if y =xππx+(2x)π2 2.1

Answer

y = π−2[π xπ −1πx+ xπ(ln π ) πx

+ (2.1)22.1x1.1]

P R O B L E M S F O R S E C T I O N 1 6 2

For Problems 1 through 3, find y .

1 y = x2π + 2πx

2 y = (2x2+ 1)

√ 3

3 y = (3x)√2+1+√1

π x

4 Differentiate the following, simplifying the expression first if useful

(a) y = πe3t2+π (b) y = ln(et

+ 1) (c) y =√π2

x 2 +4 (d) y =(ln x)12.6 (e) y =(ln x12 ) 1.5 (f) y =√3

ln(et+ 1)

5 Find y , simplifying the expression first where useful

(a) y = exxe (b) y = e1/x (c) y =√e−xx (d) y =
ln√

1 − x−3.5 (e) y = lnx+1x−1 (f) y = (1 − ln x)5/4 (g) y = ln√x(x + 1) (h) y = 5

1 e6x +x

6 Identify and classify all critical points of the function f (x) = (x2− 4)xπ +1for x > 0

16.3 USING THE CHAIN RULE

In this section, we take a second look at applying the Chain Rule

EXAMPLE 16.6 Once we know the Chain Rule, there is no problem if we forget the Quotient Rule, because

f (x) g(x) can be written as f (x) · [g(x)]−1 Derive the Quotient Rule from the Product Rule

SOLUTION

d

dx

f (x)

g(x)



= f (x) ·dxd [g(x)−1] + [g(x)−1] · dxdf (x) Use the Product Rule

= f (x) · (−1)[g(x)]−2g (x) + [g(x)]−1· f (x) Use the Chain Rule to find

d

dx[g(x)−1] = −1[g(x)]−2· g (x)

= −f (x)·g[g(x)] 2(x)+fg(x) (x) Rewrite negative exponents as

fractions

= −f (x)·g[g(x)] 2(x)+g(x)·f[g(x)] (x)2 Get a common denominator of [g(x)]2

= g(x)·f (x)−f (x)·g[g(x)]2 (x) Combine into one fraction

We can apply the Chain Rule to relate rates of change; as illustrated in the following example

EXAMPLE 16.7 In Nepal the daily kerosene consumption in restaurants and guesthouses throughout the

country can be modeled by the function K(x), where x is the number of tourists in the country Tourism is seasonal; let x(t) be the number of tourists at time t In our model, K(x)and x(t) are continuous and differentiable At a certain time, there are 5,000 tourists

in Nepal and the number is decreasing at a rate of 40 per day Write an expression for the rate at which kerosene consumption is changing with time at this moment

SOLUTION We’re looking fordKdt We know that dKdt =dKdx ·dxdt, anddxdt = −40

Therefore,dKdt = K (5000) · (−40) = −40K (5000), where

K (5000) =dKdx



 x=5000

Before applying the Chain Rule to more complicated expressions and situations, we’ll summarize our knowledge of differentiation, using the Chain Rule to express familiar differentiation formulas in a more general way

Derivatives: A Summary

Graphical Interpretation:If y = f (x), then the derivative of f is the slope function, giving the slope of the tangent line to f at the point (x, f (x)) For instance, f (2) gives the slope

of f at x = 2

Instantaneous Rate of Change:The derivative evaluated at x = 2 gives the instantaneous rate of change of y with respect to x at x = 2

Notation: y , f , f (x), y (x),dxdy,dfdx all mean the same thing.dxd is an operator that means

“take the derivative of what follows.”

Limit Definition:The following expressions are equivalent and are equal to f (x).

f (x) = lim

h→0

f (x + h) − f (x)

"x→0

"y

"x = lim

"x→0

f (x + "x) − f (x)

"x

D i f f e r e n t i a t i o n F o r m u l a s

1 y = f (x) + g(x) y = f (x) + g (x) Sum Rule

2 y = kf (x) kconstant y = kf (x) Constant Multiple Rule

3 y = f (x)g (x) y = f (x)g(x) + g (x)f (x) Product Rule

For the product of two functions

− fg

5 y = [g(x)]n nconstant y = n[g(x)]n−1· g (x) Generalized Power Rule

(Variable in base)

6 y = bg(x) bconstant y = bg(x)(ln b)g (x) Exponential Function

(Variable in exponent)

ln b·g(x)1 g (x) Logarithmic Function

y = ln[g(x)] y =g(x)1 g (x)

The world of functions we can differentiate has broadened immensely! If faced with a function we cannot differentiate using these shortcuts,2we can return to the limit definition

of derivative If we cannot make headway obtaining an exact value for a derivative and the function we’re working with is reasonably well behaved, we can still use numerical methods

to approximate the derivative at a point, and we can obtain qualitative information using a graphical approach

CAUTIONBe sure you know the difference between an exponential function like f (x) = (π + 1)2x and a generalized power function like f (x) = (x2+ π)π2 If the variable is in the base, then we differentiate using the generalized power rule; if the variable is in the exponent, we use the generalized rule for exponential functions

Feel free to think of some of these differentiation formulas more informally For instance,

the derivative of (mess)n is n(mess)n−1· (mess) , the derivative of ln(mess) is mess1 · (mess) , and the derivative of emess is emess · (mess)

2

These rules are all obtained by applying the Chain Rule to the differentiation rules we have been using Then when you look at a complicated expression, you can categorize it For instance, the expression

1

 ln(x2+ 1)

is basically (mess)−1/2, meaning were we to construct the expression assembly-line style,

the last worker on the line would take the mess coming along the line and raise it to the

−1/2 The derivative of (mess)−1/2is −12(mess)−3/2· (mess) What’s the mess? Basically,

it is ln(stuff), so

(mess) = 1

stuff · (stuff ) Putting this together,

d dx

 1

 ln(x2+ 1)

=dxd
ln(x2+ 1)−

1

= −12

ln(x2+ 1)

−3

·(x21 + 1) · 2x.

What we’ve done—albeit informally—is to decompose √ 1

ln(x 2 +1) into f (g(h(x))), where

f (x) = x−1/2, g(x) = ln x, and h(x) = x2+ 1

x−→h x2+ 1−→ ln(xg 2+ 1)−→f  1

ln(x2+ 1) So

= f (g(h(x))) · g (h(x)) · h (x)

A WORD OF ADVICE Many students, having learned shortcuts to differentiation, approach problems by charging them, sleeves rolled up, brutally hacking away There is no virtue

in doing a problem in the most difficult way possible; it does not put you on higher moral

ground Rather, you increase the likelihood of making an error Instead, when presented

with a function to differentiate, take a moment to consider how to prepare the function for differentiation.Sometimes, a bit of thoughtful reformulation will save you time and energy (Of course, there are times when it is necessary to dig in and get your hands all dirty If it

is necessary, do it with relish!) The meaning of this advice is clarified in the next example

EXAMPLE 16.8 Differentiate y = ln(1−x)1+x3

SOLUTION If you’re enthusiastically charging the problem, you might informally say that basically

this is ln(mess), where mess is (stuff )1/2and to differentiate stuff , the Quotient Rule and

generalized power rule come into play If you’re formally charging headlong into this, you might valiantly decompose the function as follows:

h(x) = 1 + x (1 − x)3 g(x) =√x

f (x) = ln x, where

ln



1 + x (1 − x)3= f (g(h(x)))

Notice that h alone is a bulky expression

Alternatively, you can save yourself a lot of work by rewriting ln 1+x

( 1−x) 3: ln



1 + x (1 − x)3= ln



1 + x (1 − x)3

1

=1

2 ln



1 + x (1 − x)3



=1

2 ln(1 + x) −1

2ln(1 − x)3

=1

2 ln(1 + x) −3

2ln(1 − x)

Now the expression is ready for differentiation

dy

dx = 1 2

 1

1 + x −

 3 2

 1

1 − x · −1

2(1 + x)+

3 2(1 − x)

2 + 2x +

3

2 − 2x

EXAMPLE 16.9 Suppose f and g are differentiable functions Find h (x)if

h(x) =

 [f (x)]3· ln(g(x))

SOLUTION This is basically of the form (mess)1/2where mess is the product [f (x)]3· ln(g(x))

h (x) = 1

2(mess)

−1/2, (mess)

=12
[f (x)]3· ln(g(x))−1/2· ddx[f (x)]3· ln(g(x)) + [f (x)]3dxd



=1 2

[f (x)]3· ln(g(x))−1/2·

 3[f (x)]2· f (x) · ln(g(x)) + [f (x)]3·g

(x) g(x)



Notice that the operator notation,dxd , is useful for record-keeping It can be read as “I plan

to take the derivative of this, but I haven’t done it yet.”

EXAMPLE 16.10 Two ships leave from a port The first one sails due east, while the second one sails due

north At 10:00 a.m the first boat is 4 miles from the port and is traveling at 35 miles per hour At this instant the second boat is 3 miles north of the port and is traveling at 15 miles per hour At what rate is the distance between the ships increasing at 10:00 a.m.?

SOLUTION Let x(t) = the distance between the port and the first boat at time t y(t) = the distance

between the port and the second boat at time t Then the distance between the two boats at time t, t in hours, is given by

D(t ) =

 [x(t)]2+ [y(t)]2

We want to finddDdt at 10:00 a.m D(t) is basically of the form (mess)1/2

D (t ) =1

2

[x(t)]2+ [y(t)]2−1/2· (t ) + 2y(t) · y (t )

At 10:00a.m x(t) = 4, y(t) = 3, x (t ) = 35, and y (t ) = 15, so

dD

dt =1

2(4

2 + 32)−1/2· [2 · 4 · 35 + 2 · 3 · 15]

=1 2

1

√

25·

=1

5 · 185

= 37

At 10:00 a.m the distance between the ships is increasing at 37 miles per hour

In Section 17.4 we will look at other ways of approaching this problem and problems similar These other approaches depend, ultimately, on the Chain Rule

Exploratory Problems for Chapter 16

Finding the Best Path

1.A pumping station that will service two towns is to be built on the shore of a straight river The towns are 10 miles apart; one

of them is 3 miles from the river and the other is 9 miles from the river Pipes will run from the pumping station to the center of each town Where should the pumping station be located in order

to minimize the amount of piping used?

town

town

town

town 9

3 10

River L

Pumping station

Hint:Begin by determining the distance L in the figure above Then the amount of piping can be expressed in terms of x where

x is the distance between the pumping station and the point on the river closest to one of the towns What is the domain of the function you are minimizing?

2.A family lives on the western shore of a long, straight river in a rural area The only store in the vicinity is located on the eastern shore of the river, directly across from a point 6 miles down the river The river is 1 mile wide They can get to the store by a combination of boat and foot Where should they build their dock

so the commute to the store takes the minimum amount of time?

home

6 miles

R I V E R

1 mile Store (with store's dock)

(a) Answer this question assuming that one can walk at a rate of

4 miles per hour and row at a rate of 3 miles per hour (b) Now assume that one can walk at a rate of 4 miles per hour, but with a new boat upgrade, the boating rate can be increased

to 5 miles per hour Where should the dock be built if they purchase a new boat?

P R O B L E M S F O R S E C T I O N 1 6 3

1 Just outside Newburgh, the New York State Thruway (I-87), running north-south, intersects Interstate 84, which runs east-west At noon a car is at this intersection and traveling north at a constant speed of 55 miles per hour At this moment a Greyhound bus is 150 miles west of the intersection and traveling east at a steady pace of 65 miles per hour

(a) When will the bus and the car be closest to one another?

(b) What is the minimum distance between the two vehicles?

(c) How far away from the intersection is the bus at this time?

(Hint: Minimize the square of the distance rather than the distance itself Explain why

this strategy is valid.)

2 Draw a semicircle of radius 2 Inscribe a rectangle as shown What are the dimensions

of the rectangle of the largest area? What is the largest area?

(Hint: Strategize What is your goal? What are you trying to maximize? Write an

expression for the thing you’re trying to maximize Make sure you get it in one variable Find and classify the critical points.)

3 What is the largest value of ln(x+1)x+1 ?

4 Differentiate

(a) y =xln 2+11 (b) y = ln(5x3+ 8x) (c) y = (2x)(x2+ x)7 (d) y =ln(5x) + e6x (e) y =√7

ln x (f) y =4x/3 ln 3x

5 Differentiate

(a) y =22x

(b) y = 22 x

(c) y =eπ x

x (d) y =xx32+1

x



(f) y =2 ln(8x32

+1)

6 What is the global maximum value of the function f (x) =√3

x 2

+1 and where is it attained?

Instructions: First just look at this function Without any calculus, try to figure out

the answer (It may be useful to check symmetry considerations.) Now use the first derivative to support your answer

7 The graph of h(x) is given below.

1 1

–1 –1 –2 –3

–2 –3 – 4

2

2

3

3

(–3, –4)

(3, –3)

(5, 2)

y

h (x)

x

(a) For which values of x is h (x)negative?

(b) This part of the question concerns the function f given by

f (x) = [h(x)]2, where the graph of h(x) is given above

i Find all the points (x-values) at which the graph of f (x) has a horizontal tangent line

ii On a number line, indicate the sign of f (x)

iii Identify the x-coordinates of all the local maxima and minima of f

iv On the interval [−3, 5], what is the largest value taken on by f (i.e., what is the global or absolute maximum value of f for x in [−3, 5])?

v On the interval [−3, 5], what is the smallest value taken on by f ? (c) Let g(x) = |h(x)|

i Sketch the graph of g(x)

ii Is g (x)defined everywhere? If not, where is g (x)undefined?

8 Suppose that f and g are differentiable functions We are given the following informa-tion:

Evaluate the following If there is not enough information to do so, indicate this (a) y = f (g(x)) What is dydx



 x=0? (b) y = g(f (x)) What is y(0)?