calculus concept collection - chapter 3 need for
TRANSCRIPT
Calculus Concept Collection - Chapter 3
Need for Derivatives: Tangent Lines to a Curve
Answers
1. Secant line.
2. Tangent line
3. 0 0( ) ( )f x h f x is called “the rise” in the process of finding the slope of a tangent line?
4. 0 0( )x h hx is assumed to go to 0 as the two chosen points get closer and closer.
5. The slope of a line tangent to a curve is the limit of the slope of the secant line as the two
points getting closer to each other.
6. 2y x
7. 5 8y x
8. 3 7y x
9. 3 8y x
10. 5 22y x
11. 20 16y x
12. 2y x
13. 19 5y x
14. 8 3y x
15. 10y x
16. 19 7y x
17. y x
18. 2 3y x
19. 3y
20. 36 19y x
Need for Derivatives: Instantaneous Rates of Change
Answers
Find the Average Rate of Change
1. Average rate of changes is 70.
2. Average rate of changes is 267.
3. Average rate of changes is 248.
4. Average rate of changes is 109.
5. Average rate of changes is -423.
Find the Instantaneous Rate of Change:
6. Instantaneous rate of change of (C) with respect to (x) is -198.
7. Instantaneous rate of change of (N) with respect to (x) is 59.
8. Instantaneous rate of change of (H) with respect to (x) is 80.
9. Instantaneous rate of change of (N) with respect to (x) is -299.
10. Instantaneous rate of change of (C) with respect to (x) is -116.
Use the definition of the derivative to find f(x) and then find the equation of the
tangent line at x = x0.
11. '( ) 12 , ( 54) 36( 3)f x x y x
12. 1 10
'( ) , ( 10) ( 8)202 2
f x y xx
13. 2'( ) 9 , ( 5) 9( 1)f x x y x
14. 2
1'( ) , ( 1) ( 1)
( 2)f x y x
x
15. 2'( ) 2 , ( ( )) 2 ( )f x ax y ab b ab x b
16. 2/3
1 1'( ) , ( 1) ( 1)
33f x y x
x
17. **Suppose that f has the property that f(x + y) = f(x) + f(y) + 3xy and . Find f(0) and f'(x).
18. **Find dy/dx
Solve Rate of Change Problems
19. f'(100) = 9999 is the rate of change of the cost of producing 100 jars.
20. f'(100) = -0.6 means that 100 minutes after the pie is placed in the room, it’s temperature is decreasing (slope is negative) at a rate of 0.6 degree per minute.
21. The unit of f'(x) is rate of change of virus per hour , or number of virus per hour?
22. f'(x) is the rate of change per day of the number of people being affected at day x.
23. Average rate of change of J with respect to x is 79.
24. Given 2( ) 0.00826 24 196f x x x , then the instantaneous rate of change at x=15 is
'(15) 0.016528(15 1.) 2 75f °F /minute. The temperature of the cake is decreasing at 1.75
°F /minute.
The Derivative
Answers
1.
2.
3.
4.
5.
6.
7.
8. Hint: Take the limit from both sides.
9. Hint: Take the limit from both sides.
10.
11. The definition of a derivative states that
0
( ) ( )l) im'(h
f x h x
hf x
f
2 2 2 2 2
0 0 0
( ) ( ) ( ) (22( ) 2) 2 ) 2lim m
2(lim li
h h h
f x h f x x h xx h x hx h x h x x
h h h
group like terms: 2 2 2 2
0 0
4 2 2 4 2lim lim
2
h h
hx h x h x xx hx h h
h h
All terms in the numerator contain a factor of h, so now we may simplify. 2
0 0 0
4 2 4 2 1lim lim lim4 2 1
1h h h
hx h h x hx h
h
Now that h is not the denominator, we may safely evaluate the limit.
0lim4 2 1 4 2(0) 1 1'( ) 4h
x x xf hx
We wish to know the value of the derivative at x=2.
4(2'( )) 92 1f .
12. The definition of a derivative states that
0
( ) ( )l) im'(h
f x h x
hf x
f
2 2 2 2 2
0 0
3( 1) 7 3( 1) 7 3( 1 2 2 2 ) 7 3( 2 1) 7lim limh h
x h x x h hx x h x x
h h
Combine like terms. 2
0
3(2 2 )limh
hx h h
h
Now h can be reduced from each term: 2
0 0 0 0
3(2 2 ) 3(2 23(2 2)
)li 6m lim 3 6lim lim
1h h h hx h x h
hx h h x h
h
and the limit can be evaluated:
0'( ) 6 3 6 6 3(0l ) 6 6im 6
hf x x h x x
13. 1
'( )12
f xx
14. 1 1
6 2( 5)'( 5)
4f
15. 2
1'( )
( 1)f
xx
Differentiation Rules: Constants and Variable Powers
Answers
1. The Power Rule: If n is a real number, then for all real values of x 1[ ]n ndx nx
dx
.
2. 6' 35y x
3. ' 3y
4. 1
'( )3
f x
5. 3 2 5' 4 6
2y x x
x
6. 3' 100 60y x x
7. Given 122 4 2'(1) 4 (1) 4y
8. '( ) 0y x
9. 1 4533 5'(2) 5 ( ) 12 1.7 0u
10. '(4) 0y
11. 1.37'(1) 0.37(1 0) .37d
12. 4'( ) 3g x x
13. 0.004'( ) 0.096u x x
14. '( ) 1k x
15.3 1355y x
Differentiation Rules: Sums and Differences
Answers
1. 2 21 1 1' (3 ) (4 ) 0 2
2 2 2 2
3y x x x x
2. 2 2' 3 2 2
2y x x
3. ' 0 0 2 0 0 1 2 1y x x
4. 4
8
7' 3y x
x
5. 3/2
1 1 1 1' 1
22 2y
xxx x
6. 2(9 24 16) 18 24d
x x xdx
7.
17
9 5/4 12'( ) 9.35
12f x x x
8. 2 2(2 1) (4 4 1) 8 4d d
x x x xdx dx
9. 2(25 30 9) 50 30d
x x xdx
10. 2'(0) 9(0) 10(0) 2 2v
11. Just differentiate each term individually.
2 12 3 0 4 3'( ) 2 xf x x
12. Rewrite the x’s in the denominators as negative powers and roots as fractional powers, then
differentiate term-by-term.
1/2 11 1( ) x
xf
xx x
3/2 2 3/2 2
3/2 2
1 1 1 1( 1)
2'(
2)
2x x x
xf x x
x
3/2 2'(
1 1 1 11
2(1) 2 21)
1f .
13. First determine the product of the binomial, then differentiate term-by-term: 2 2
1
( 1)( 2 2 2 3 2
2 3 0 2
)
3
x x xy x x x x
dyx x
dx
at 1
2x ,
12( ) 3 1 3 2
2
dy
dx .
14. First find a general form for f’. 2 1 2'( ) 2 2 23 6f x a x x ax x
2'( 2) 6 ( 2) 2( 2) 24 4f a a
24 4 0
24 4
1
6
a
a
a
15. First, distribute a . Then differentiate term-by-term. 2 25) 5
'( ) 2 0
(
''( )
)
2
( ax a
f x ax
f
f x a x
x a
''(5) 20 2 10af a
Differentiation Rules: Products and Quotients
Answers
1. Write y as the product of functions: ( ) ( )x xy f g ,
3 2 2'( ) 3( ) 3 6 1x x f x xf x x x
3 4 2 37( ) ( 2'2 8) 6x gg x x xx x
By the product rule, ( ) '( ) ( ) '( )dy
f x g x g x f xdx
:
3 2 2 2 3 43( 3 28 ) 6 1)(2)(6 (3 7 )dy
x x xdx
x xxx x x
2. 2 2 3
1 1 1 2( ) '( )f x f x
x x x x
, and
4 3( ) (3 7) '( ) 12g x x g x x
By the product rule: 3 4
2 2 3
1 1 1 212 (3 7)x x
x x x
dy
dx x
3. 2( ) ( 3 4) '( ) ( 6 1)f x x x f x x , and
( ) ( 3 3) '( ) 3g x x g x
By the product rule: 2( 3 4)( 3) ( 6 1)( 3 3)xdy
dxx x x
4. By the product rule: ( ) '( 2) ( 2) '( 2) ( 2) '( 2) 54k r k r r k , then
54 ( 2) '( 2) 54
( 2) 3'( 2) 18
k rr
k
5. By the product rule: 2'( ) (4 4 5)(3) (8 4)(3 3)g x x x x x , then
'(2) (16 8 5)(3) (16 4)(6 3) 45g
6. 2 2( 3)( 4 4) (2 )( 2 4 1)dy
x x x x xdx
7. By the product rule: ( ) ' ' 'ta ta t a , then
( ) '(1) (1) '(1) '(1) (1) 272ta t a t a
272 (1) '(1) 272
(1) 16'(1) 17
t aa
t
8. By the product rule: 2'( ) (2 3 1)(2) (4 3)(2 1)d x x x x x , then
'( 1) (2 3 1)(2) ( 4 3)( 2 1) 3d .
9. Write y as the product of functions: ( ) ( )x xy f g ,
3 22 1 '( ) 2) 3( xf f xx xx
4 3( 7 8 '( )) 164 7x gg x xx x
By the product rule,
2 4 3 3'( ) ( ) '( ) ( ) (3 2)(4 7 8) (16 7)( 2 1)dy
f x g x g x f x x x x x x xdx
10. Write y as the product of functions, ( ) ( )x xy f g :
22 2 2 1/22 1 1 1
( 2) ( 2) ( 2)24 4 2
xx x x x
x xy
x
2 2 '( ) 2( ) x xf fx x
1/2 3/2(1 1
'( )2 4
) x g x xg x
2 21/2 3/2 2
3/2 3/2
1 1 2 2 2' '( ) ( ) '( ) ( ) 2 ( ) ( 2)
2 4 4 42)(
x x xy f x g x g x f x x x x x
x xxx
11. First find the derivative using the product rule. 45 53 2 4 3 2( ) (2( ) ) )(2g x x x x x x xy f x x x x x
5 4 3 2 4 3 2'( ) '( ) 10 4( ) 2) 2 1( 3x x x x f x gf x g x xx x x x x
4 3 2 4 35 2
'( ) ( ) '( ) ( ) '( ) ( ) '( )
4 3
( ) 2 '( ) ( )
2(10 )(22 1 )
tanm f x g x g x f x f x f x f x f x f
x x x x x x
x f x
x x x
Evaluate the slope at x=-1: 4 3 2 5 4 3 24( 1) 3( 1) 2( 1) 1) (2( 1) ( 1) ( 1) ( 1) ( 1))
2 (10 4 3 2 1) ( 2 1 1 1 1) 2 4 0
2 (10( )
0
1tanm
0tanm at x=-1. Next we need the y-coordinate:
4 3 2 2 25 ( 1) ( 1) ( 1) ( 1))(2( 1) ( 2 1 1 1 1) 0y
Since the slope is 0, the tangent line is the horizontal line 0y .
12. First write y as the product of functions, ( ) ( )xy f x g .
33 3 12 1 1
(2 1) (2 1)x
x xx
y xx
3 21 '( ) 6( ) 2 ff x x x x
1 2
2)
1' )( (g xg x xx
x
2 3 32 1 2 3
2 2
6 2 1 2 1(2 1)' '( ) ( ) '( 6) ( ) 6 ( )
x x xxy f x g x g x x x
x xf x
xx x
13. There are various approaches. For instance, one may FOIL the first two terms of the
product: 2 2 3 2 210)(3 3 5) (( 2 7 20 70) (3 3( 5)2 7)y x x x x x x x x x
3 2 27 20 70 '( ) 6 14) 2 20( x x f xf x xx x
2( ) 3 3 5 '( ) 6 3g x x x g x x
2 2 3 2'( ) ( ) '( ) ( ) (6 14 20)(3 3 5) (6 3)(2 7 20 70)dy
f x g x g x f x x x x x x x x xdx
14. Let ( )
( )( )
f xh x
g x
with ( ) 0g x . Then ( ) ( ) ( )f x h x g x .
By the product rule: '( ) ' ' ' 'f
f x h g h g g h gg
.
Solving for 'h : 2
' '' '
' ''
f gf fgf g
gf fgg g gh
g g g
15. By the quotient rule: 2
' ''
u qu uq
q q
.
Then 2 2
(0) '(0) (0) '(0) (0)98'(0) 7
(0) (0)
u q u u q q
q q q
, and
98
(0) 147
q .
16. Let ( )
( )( )
f xb x
g x ; then
2( ) 5 4 (2) 2f x x x f
'( ) 2 5 '(2) 1f x x f with
5 2 (2) 1( 0) xg x g
'( ) 5 '(2) 5g x g
2
10( 1)
( 10)
( 2)( 5)'(2) 0b
17. Start by finding dy
dx.
1 ( )
2 1 ( )
x f x
x g xy
'( )( ) 1 1xf x fx
( ) 2 1 '( ) 2g xg x x
2 2 2 2
( ) ( ) ( ) ( ) 1(2 1) 2( 1) 2 1 2 1 2
( ( )) (2 1) (2 1) (2 1)
dy f x g x g x f x x x x x
dx g x x x x
Use the quotient rule again on dy
dx:
'( )) 0( 2 xf fx
2 2 4 1 '( ) 8 4( ) (2 1) 4g x xx x g xx
2 2
2 2 4 4 4 3
( ) ( ) ( ) ( ) 0(2 1) (8 4)( 2) 2(8 4) 8(2 1) 8
( ( )) (2 1) (2 1) (2 1) (2 1)
d y f x g x g x f x x x x x
dx g x x x x x
2
2 3
8
(2 1)
d y
dx x
18. 3
2
( )
1
3
( )
x f x
x g xy
3 23) ( )( ' 3f f xx xx
2 1 '( ) 2( ) x xg gx x
2 2 3 4 2 4 4 2
2 2 2 2 2 2 2
( ) ( ) ( ) ( ) 3 ( 1) 2 ( 3) 3 2 6 3 6
( ( )) ( 1) ( 1)
3'
( 1)
f x g x g x f x x x x x x x x x x
g x x x x
x xy
4 2
2 2
3
( )'
6
1
xy
x x
x
19. The function can be simplified. 2 6 5 ( 1)( 5)
15 5
x x x xxy
x x
wherever it is defined.
1dy
dx .
20. 2 3 2
5 5
( 3) 3 ( )
5 5 ( )
x x x f x
xy
g
x
x x
3 2 23 ' 3( )) ( 6x ff x x x x x
45 ') ( )( 55 g x xg x x
2 5 4 3 2
2 5 2
( ) ( ) ( ) ( ) (3 6 )( 5) 5 ( 3
( ( )) )
)'
( 5
f x g x g x f x x x x x x xy
g x x
.
At 1x , 2 5 4 3 2
5 2 2
2
(3( 1) 6( 1))(( 1) ( 1)) 5( 1) (( 1) 3( 1) (3 6)(0) 5(1)( 1 3)
(( 1) 5) ( 1 5)
5 4 20 5
( 6) 36 8
)'y
21. Since the denominator is a constant, it is not necessary to use the quotient rule. 5 3
5 33 1 1( 3 1)
4 4( )
x xf xx x
4 21(( )' 5 9
4) xf x x
3 31 9(20'' )
2( ) 18 5
4x x xf xx
Derivatives of Trigonometric Functions
Answers
1.
2.
3.
4.
5.
6.
7.
8.
9. '( / 6) 2 3y
10. 5 4 5( cos( )) ' 5 cos( ) sin( )x x x x x x
11. By the product rule 2 2 2 2( csc( )) ' ( ) 'csc( ) csc( ) ' 2 csc( ) (csc( )cot( ))x x x x x x x x x x x
12. The derivative is equal tosec( ) tan( )x x .
To obtain this, note that the expression can be simplified as follows
1 sin( ) 1sec( )
sin( ) cos( )csc( ) tan( )
cos( )
xx
x x xx x
And the derivative of secant is just sec( ) tan( )x x .
13. 2 2
1 0 (cos( )) sin( ) sin( ) 1) ' tan( )sec( )
cos( ) cos( ) cos( )cos ( ) cos ((sec( )) '
)(x
x x xx x
x x xx x
14. The solution is 2sec ( )x .
We first simplify the expression:
cos( )1 1 cos( )2) tan( )
2 sin( )tan( ) tan( ) sin( )
2 2 2
cot(
xx
x xx
x x x
And then the derivative of tangent is just secant squared.
15. The derivative equals 0.
We can simplify the expression: 2 2 2
2 2
2 2 2 2
1 cos ( ) 1 cos ( ) sin ( )( ) cot 1
sin ( ) sin ( ) sin ( ) scsc (
in ()
)
x x xx
x x x xx
This makes it clear that the derivative is zero.
This problem is also solvable by taking the derivative of the expression as it is
written in the problem, but that method is longer and has more room for error.
Differentiation Rules: The Chain Rule
Answers
1. 2 38( ) 39(2 3 ) (4 3)f x x x x
2.
42 5
5 3
3 10( ) 3
5
x xf x
x x
3. 3
2
3( 1)( )
(3 6 1)
xf x
x x
4.
5.
6.
7.
8.
9.
10.
11. 2
3
3( 3)'( )
(2 5)
xf x
x
12. Let By the chain rule,
where Thus
13. 1
3 5 2 421
( 89) (2
)3 5xx x x
.
The outer function is the square root, whose derivative is 1
21
2x
. Substituting in
the inner function gives 1
3 5 21
( 89)2
x x
. Multiplying by the derivative of the
inner function gives our answer: 1
3 5 2 421
( 89) (2
)3 5xx x x
.
14. cos(sin(sin( ))cos(sin( )cos( )x x x .
To solve this problem we must apply the chain rule multiple times. The derivative
of the outer sine is cosine, and composing that with sine of sine of x yields
cos(sin(sin( ))x . We must multiply this by the derivative of the interior function,
sine of sine of x. Using the chain rule again, we get:
sin(sin( )) cos(sin( ))cos( )d
x x xdx
. Multiplying yields:
cos(sin(sin( ))cos(sin( )cos( )x x x .
15. The rule that is proven is the inverse function theorem.
Our equation is 1( ( ))f f x x .
We differentiate the left hand side using the chain rule.
1 1 1( ( )) '( ( )) ( )d d
f f x f f x f xdx dx
.
The right hand side is also easy to differentiate:
1d
xdx
Therefore, since 1( ( ))f f x x , we have that:
1 1'( ( )) ( ) 1d
f f x f xdx
.
Solving algebraically for the derivative of inverse, we have:
1
1
1
( ))(
()
f xf x
x f
d
d
This is the inverse function theorem.
Derivatives of Exponential Functions
Answers
1. ' 7 ln 7xy
2. 2' 2ln3 3 xy
3. ' 5 ln5 6xy x
4. 2 12 · ·ln 2.xy x
5. 2
[ ] 2 .u u xde u e y xe
dx
6. 2( )0 0
2 ( )'( )
k x xk x xf x e
7.
8.
9.
10.
11. ' 3 3 ln3 3 (1 ln3)x x x x x xy e e e
12. 2 2 1' 2ln3( 1)3 x xy x
13. ' 2 3 ln 2 2 3 ln3 2 3 (ln 2 ln3)x x x x x xy
14. sin cos (sin cos )x x xy e x e x e x x
15. 2'( ) 3 2 xf x x e , so the slope at (0,2) is 0 1e , and the line is 2y x .
Implicit Differentiation
Answers
1.
2.
3.
4.
5.
6.
7.
8.
9.
10. Implicit differentiation yields: '2
ky
y , so that 0
0
'( )2
ky x
y , which is the slope of the
tangent line at 0 0( , )x y . The equation of the tangent line is 0 0
0
( )2
ky y x x
y . Multiplying
both sides by 0y , using the fact that 2
0 0y kx , and simplifying algebraically gives the result
0 0( )2
ky y x x .
11. ( sin( ) sin( )) ( sin( )) ( sin( ))d d d
x y y x x y y xdx dx dx
.
Use the product rule on each term in the sum.
( sin( )) ( ) sin( ) (sin( )) 1 sin( ) cos( ) 'd d d
x y x y x y y x y ydx dx dx
( sin( )) sin( ) sin( ) 'sin cos( )d d d
y x y x y x y x y xdx dx dx
Sum the two terms’ derivatives.
( sin( ) sin( )) sin( ) 'cos( ) 'sin( ) cos( )d
x y y x y xy y y x y xdx
.
12. Differentiate term-by-term.
2 ' 1 2 ' 0x xy y yy .
Move terms that do not contain y’ to the RHS.
' 2 ' 2xy yy x y
Isolate y’.
( 2 ) ' 2
2'
2
x y y x y
x yy
x y
13. First, differentiate term-by-term 2 22 13 ' 2 (2 ) ' 0y y x y yy
We could solve for y’ now, but since we are only interested in evaluating y’ at one point,
it is probably easier to plug in (x,y)=(1,1) and then solve for y’. 223(1) ' 2(1)(2(2(1) 1 0
3 ' 2 4 ' 1 0
7 ' 1 0
7 ' 1
1'
7
1)) '
y
y
y
y
y
y
y
This gives the slope of the tangent line at (1,1). Now write the equation of the line in
point-slope form.
1( 1)
71y x
14. Perform the chain rule, using the product rule to find the derivative of the “inside function”:
1/2 1/2 1/21 1( ) ( ) ( ) ( ) ( ) (1 ')
2 2 2
d d d y xyxy xy xy xy xy y xy
dx dx dx xy
.
15. First find the first derivative by differentiating term-by-term.
1
cos( ) 1
(2 cos( )) 1
1(2 cos( ))
2 cos(
2
)
dyy
dx
dyy y
dx
dyy y
dx
dyy
dx
y y
Find 2
2
d y
dxby differentiating again; we can use quotient rule or chain rule. Here are the
steps for chain rule: 2
1 2
2
2 2
2
(2 cos( )) (2 cos( )) (2 cos( ))
1 1(2 sin( ) ) (2 sin( ))
(2 cos( )) (2 cos( ))
2 sin( )
(2 cos( ))
1d y d d
y y y y y ydx dx dx
dy dy dyy y
y y dx dx y y dx
y dy
y y dx
Substitute in1
2 cos( )
dy
dx y y
2
2 32
2 sin( ) 1 2 sin( )
(2 cos( )) 2 cos( ) (2 cos( ))
d y y y
dx y y y y y y
Higher Order Derivatives
Answers
1. Given: 3 2( ) 4 3 2 3v x x x x
2'( ) 12 6 2v x x x
''( ) 24 6v x x
2. Given: . What is ?
'( ) 2 5m x x
''( ) 2m x
3. Given: . What is ?
4 3'( ) 3 12 xxd x x e x e
34 3 212 12 3''( ) 3 6x x xx x ed x x e x e x e
2 2( 8 12) 3 )''( x x xd x x e
4. Given: 5( ) 2 ( )t x x sin x
5 4 4'( ) 2 ( ) 10 ( ) 2 (cos( ) 5sin( ))cost x x x x sin x x x x
4 3"( ) 2 ( sin( ) 5cos( )) 8 (cos( ) 5sin( ))t x x x x x x x
3"( ) 2 [( 20) in( ) (5 4)cos( )]t x x x s x x x
5. Given: 53 xy x e
45 1' 3 5x xy ex e x
5 4 4 315 15 6' 0' 3 x xx xx ey x e x e x e
3 2( 10 2'' 3 0)xy x e x x
6. Given 3
2y
x , then
4
6'y
x
;
5
24''y
x ; and
6
120'''y
x
.
6
120'''(1) 120
1y
7. By the quotient rule: 2
' ''
u qu uq
q q
.
Then 2 2
(0) '(0) (0) '(0) (0)98'(0) 7
(0) (0)
u q u u q q
q q q
, and
98
(0) 147
q .
8. Let ( )
( )( )
f xb x
g x ; then
2( ) 5 4 (2) 2f x x x f
'( ) 2 5 '(2) 1f x x f with
5 2 (2) 1( 0) xg x g
'( ) 5 '(2) 5g x g
2
10( 1)
( 10)
( 2)( 5)'(2) 0b
9. Given: ( )3 4
xem x
x
2 2
(3 4) (3 1)'( )
(3 4) (
3)
3 4
(
)
x x xx e e x em x
x x
10. Given: ( )
4
sin xy
x
2
( 4) ( ) sin'
( 4)
x cos x xy
x
11. Given ( )( )
xq x
sin x .
2
sin cos'( )
( )
x x xq x
sin x
2
4
( ) ( sin ) 2sin cos (sin cos )''( )
( )
sin x x x x x x x xq x
sin x
12. 3
2
( )
'( ) 3 1
''( ) 6
f t t t
f t t
f t t
This last expression is our acceleration.
13. 2( ) sin( ) 3
'( ) cos( ) 6
''( ) sin( ) 6
f t t t
f t t t
f t t
Since the sine function is bounded by one, the car is accelerating.
14. Negative jerk.
( ) cos( )
'( ) sin( )
''( ) cos( )
'''( ) sin( )
f t t
f t t
f t t
f t t
At the prescribed time, we have that 3 3
) sin(sin ) 12
(2
.
15. First we take derivatives.
4 3 2
3 2
2
1 3( )
12 6
1
5
'( ) 10
''( ) 3 1
2
0
3
3
f t t t
t t
t
f t t
f t t t
Now we know that 2 3 10 ( 5)( 2)t t t t . Assuming time begins at zero, the
only point at which there is no acceleration is 5t .
16. N+1. Any polynomial, differentiated enough times, will be zero. Each term will become zero
when the number of times its been differentiated exceeds its degree, i.e. 2x differentiated
three times is zero, 3x differentiated four times is zero, etc. Therefore an N-degree
polynomial’s derivative will become zero after it is differentiated N+1 times.