Lesson 23: Antiderivatives (slides)
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..
Sec on 4.7An deriva ves
V63.0121.001: Calculus IProfessor Ma hew Leingang
New York University
April 19, 2011
Announcements
I Quiz 5 on Sec ons4.1–4.4 April 28/29
I Final Exam Thursday May12, 2:00–3:50pm
I I am teaching Calc II MW2:00pm and Calc III TR2:00pm both Fall ’11 andSpring ’12
ObjectivesI Given a ”simple“ elementaryfunc on, find a func on whosederiva ve is that func on.
I Remember that a func onwhose deriva ve is zero alongan intervalmust be zero alongthat interval.
I Solve problems involvingrec linear mo on.
OutlineWhat is an an deriva ve?
Tabula ng An deriva vesPower func onsCombina onsExponen al func onsTrigonometric func onsAn deriva ves of piecewise func ons
Finding An deriva ves Graphically
Rec linear mo on
What is an antiderivative?
Defini onLet f be a func on. An an deriva ve for f is a func on F such thatF′ = f.
Who cares?Ques on
Why would we want the an deriva ve of a func on?
Answers
I For the challenge of itI For applica ons when the deriva ve of a func on is known butthe original func on is not
I Biggest applica on will be a er the Fundamental Theorem ofCalculus (Chapter 5)
Hard problem, easy check
Example
Find an an deriva ve for f(x) = ln x.
Solu on???
Hard problem, easy check
Example
Find an an deriva ve for f(x) = ln x.
Solu on???
Hard problem, easy check
Example
is F(x) = x ln x− x an an deriva ve for f(x) = ln x?
Solu on
ddx
(x ln x− x) = 1 · ln x+ x · 1x− 1 = ln x
"
Hard problem, easy check
Example
is F(x) = x ln x− x an an deriva ve for f(x) = ln x?
Solu on
ddx
(x ln x− x) = 1 · ln x+ x · 1x− 1 = ln x"
Why the MVT is the MITCMost Important Theorem In Calculus!
TheoremLet f′ = 0 on an interval (a, b). Then f is constant on (a, b).
Proof.Pick any points x and y in (a, b) with x < y. By MVT there exists apoint z in (x, y) such that
f(y) = f(x) + f′(z)(y− x)
But f′(z) = 0, so f(y) = f(x). Since this is true for all x and y in (a, b),then f is constant.
Functions with the same derivativeTheoremSuppose f and g are two differen able func ons on (a, b) withf′ = g′. Then f and g differ by a constant. That is, there exists aconstant C such that f(x) = g(x) + C.
Proof.
I Let h(x) = f(x)− g(x)I Then h′(x) = f′(x)− g′(x) = 0 on (a, b)I So h(x) = C, a constantI This means f(x)− g(x) = C on (a, b)
OutlineWhat is an an deriva ve?
Tabula ng An deriva vesPower func onsCombina onsExponen al func onsTrigonometric func onsAn deriva ves of piecewise func ons
Finding An deriva ves Graphically
Rec linear mo on
Antiderivatives of power functionsRecall that the deriva ve of apower func on is a powerfunc on.Fact (The Power Rule)
If f(x) = xr, then f′(x) = rxr−1.
So in looking foran deriva ves of powerfunc ons, try powerfunc ons!
..x
.
y
.
f(x) = x2
.
f′(x) = 2x
.
F(x) = ?
Antiderivatives of power functionsRecall that the deriva ve of apower func on is a powerfunc on.Fact (The Power Rule)
If f(x) = xr, then f′(x) = rxr−1.
So in looking foran deriva ves of powerfunc ons, try powerfunc ons!
..x
.
y
.
f(x) = x2
.
f′(x) = 2x
.
F(x) = ?
Antiderivatives of power functionsRecall that the deriva ve of apower func on is a powerfunc on.Fact (The Power Rule)
If f(x) = xr, then f′(x) = rxr−1.
So in looking foran deriva ves of powerfunc ons, try powerfunc ons!
..x
.
y
.
f(x) = x2
.
f′(x) = 2x
.
F(x) = ?
Antiderivatives of power functionsRecall that the deriva ve of apower func on is a powerfunc on.Fact (The Power Rule)
If f(x) = xr, then f′(x) = rxr−1.
So in looking foran deriva ves of powerfunc ons, try powerfunc ons!
..x
.
y
.
f(x) = x2
.
f′(x) = 2x
.
F(x) = ?
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I Try a power func on F(x) = axr
I Then F′(x) = arxr−1, so we want arxr−1 = x3.
I r− 1 = 3 =⇒ r = 4
, and ar = 1 =⇒ a =14.
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I Try a power func on F(x) = axr
I Then F′(x) = arxr−1, so we want arxr−1 = x3.
I r− 1 = 3 =⇒ r = 4
, and ar = 1 =⇒ a =14.
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I Try a power func on F(x) = axr
I Then F′(x) = arxr−1, so we want arxr−1 = x3.
I r− 1 = 3 =⇒ r = 4, and ar = 1 =⇒ a =14.
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I Try a power func on F(x) = axr
I Then F′(x) = arxr−1, so we want arxr−1 = x3.
I r− 1 = 3 =⇒ r = 4, and ar = 1 =⇒ a =14.
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I Try a power func on F(x) = axr
I Then F′(x) = arxr−1, so we want arxr−1 = x3.
I r− 1 = 3 =⇒ r = 4, and ar = 1 =⇒ a =14.
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others?
Yes, F(x) =14x4 + C is the most general form.
Antiderivatives of power functionsExample
Find an an deriva ve for the func on f(x) = x3.
Solu on
I So F(x) =14x4 is an an deriva ve.
I Check:ddx
(14x4)
= 4 · 14x4−1 = x3"
I Any others? Yes, F(x) =14x4 + C is the most general form.
General power functionsFact (The Power Rule for an deriva ves)
If f(x) = xr, then
F(x) =1
r+ 1xr+1
is an an deriva ve for f…
as long as r ̸= −1.
Fact
If f(x) = x−1 =1x, then F(x) = ln |x|+ C is an an deriva ve for f.
General power functionsFact (The Power Rule for an deriva ves)
If f(x) = xr, then
F(x) =1
r+ 1xr+1
is an an deriva ve for f as long as r ̸= −1.
Fact
If f(x) = x−1 =1x, then F(x) = ln |x|+ C is an an deriva ve for f.
General power functionsFact (The Power Rule for an deriva ves)
If f(x) = xr, then
F(x) =1
r+ 1xr+1
is an an deriva ve for f as long as r ̸= −1.
Fact
If f(x) = x−1 =1x, then F(x) = ln |x|+ C is an an deriva ve for f.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x|
=ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x)
=1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x
"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x|
=ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x)
=1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1)
=1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x
"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
What’s with the absolute value?
F(x) = ln |x| =
{ln(x) if x > 0;ln(−x) if x < 0.
I The domain of F is all nonzero numbers, while ln x is onlydefined on posi ve numbers.
I If x > 0,ddx
ln |x| = ddx
ln(x) =1x"
I If x < 0,ddx
ln |x| = ddx
ln(−x) =1−x
· (−1) =1x"
I We prefer the an deriva ve with the larger domain.
Graph of ln |x|
.. x.
y
. f(x) = 1/x
Graph of ln |x|
.. x.
y
. f(x) = 1/x.
F(x) = ln(x)
Graph of ln |x|
.. x.
y
. f(x) = 1/x.
F(x) = ln |x|
Combinations of antiderivatives
Fact (Sum and Constant Mul ple Rule for An deriva ves)
I If F is an an deriva ve of f and G is an an deriva ve of g, thenF+ G is an an deriva ve of f+ g.
I If F is an an deriva ve of f and c is a constant, then cF is anan deriva ve of cf.
Combinations of antiderivativesProof.These follow from the sum and constant mul ple rule forderiva ves:
I If F′ = f and G′ = g, then
(F+ G)′ = F′ + G′ = f+ g
I Or, if F′ = f,(cF)′ = cF′ = cf
Antiderivatives of PolynomialsExample
Find an an deriva ve for f(x) = 16x+ 5.
Solu on
The expression12x2 is an an deriva ve for x, and x is an
an deriva ve for 1. So
F(x) = 16 ·(12x2)+ 5 · x+ C = 8x2 + 5x+ C
is the an deriva ve of f.
Antiderivatives of PolynomialsExample
Find an an deriva ve for f(x) = 16x+ 5.
Solu on
The expression12x2 is an an deriva ve for x, and x is an
an deriva ve for 1. So
F(x) = 16 ·(12x2)+ 5 · x+ C = 8x2 + 5x+ C
is the an deriva ve of f.
Antiderivatives of Polynomials
Ques on
Do we need two C’s or just one?
AnswerJust one. A combina on of two arbitrary constants is s ll anarbitrary constant.
Antiderivatives of Polynomials
Ques on
Do we need two C’s or just one?
AnswerJust one. A combina on of two arbitrary constants is s ll anarbitrary constant.
Exponential FunctionsFactIf f(x) = ax, f′(x) = (ln a)ax.
Accordingly,Fact
If f(x) = ax, then F(x) =1ln a
ax + C is the an deriva ve of f.
Proof.Check it yourself.
In par cular,FactIf f(x) = ex, then F(x) = ex + C is the an deriva ve of f.
Exponential FunctionsFactIf f(x) = ax, f′(x) = (ln a)ax.
Accordingly,Fact
If f(x) = ax, then F(x) =1ln a
ax + C is the an deriva ve of f.
Proof.Check it yourself.
In par cular,FactIf f(x) = ex, then F(x) = ex + C is the an deriva ve of f.
Exponential FunctionsFactIf f(x) = ax, f′(x) = (ln a)ax.
Accordingly,Fact
If f(x) = ax, then F(x) =1ln a
ax + C is the an deriva ve of f.
Proof.Check it yourself.
In par cular,FactIf f(x) = ex, then F(x) = ex + C is the an deriva ve of f.
Exponential Functions
In par cular,
FactIf f(x) = ex, then F(x) = ex + C is the an deriva ve of f.
Exponential Functions
In par cular,
FactIf f(x) = ex, then F(x) = ex + C is the an deriva ve of f.
Logarithmic functions?I Remember we found F(x) = x ln x− x is an an deriva ve off(x) = ln x.
I This is not obvious. See Calc II for the full story.I However, using the fact that loga x =
ln xln a
, we get:
FactIf f(x) = loga(x)
F(x) =1ln a
(x ln x− x) + C = x loga x−1ln a
x+ C
is the an deriva ve of f(x).
Logarithmic functions?I Remember we found F(x) = x ln x− x is an an deriva ve off(x) = ln x.
I This is not obvious. See Calc II for the full story.
I However, using the fact that loga x =ln xln a
, we get:
FactIf f(x) = loga(x)
F(x) =1ln a
(x ln x− x) + C = x loga x−1ln a
x+ C
is the an deriva ve of f(x).
Logarithmic functions?I Remember we found F(x) = x ln x− x is an an deriva ve off(x) = ln x.
I This is not obvious. See Calc II for the full story.I However, using the fact that loga x =
ln xln a
, we get:
FactIf f(x) = loga(x)
F(x) =1ln a
(x ln x− x) + C = x loga x−1ln a
x+ C
is the an deriva ve of f(x).
Trigonometric functionsFact
ddx
sin x = cos xddx
cos x = − sin x
So to turn these around,Fact
I The func on F(x) = − cos x+ C is the an deriva ve off(x) = sin x.
I The func on F(x) = sin x+ C is the an deriva ve off(x) = cos x.
Trigonometric functionsFact
ddx
sin x = cos xddx
cos x = − sin x
So to turn these around,Fact
I The func on F(x) = − cos x+ C is the an deriva ve off(x) = sin x.
I The func on F(x) = sin x+ C is the an deriva ve off(x) = cos x.
Trigonometric functionsFact
ddx
sin x = cos xddx
cos x = − sin x
So to turn these around,Fact
I The func on F(x) = − cos x+ C is the an deriva ve off(x) = sin x.
I The func on F(x) = sin x+ C is the an deriva ve off(x) = cos x.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x
=1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
Solu on???
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x
=1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x
=1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x
=1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x
=1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x =1
sec x· sec x tan x
= tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x =1
sec x· sec x tan x = tan x
"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x =1
sec x· sec x tan x = tan x"
More about this later.
More TrigExample
Find an an deriva ve of f(x) = tan x.
AnswerF(x) = ln | sec x|.
Check
ddx
=1
sec x· ddx
sec x =1
sec x· sec x tan x = tan x"
More about this later.
Antiderivatives of piecewise functions
Example
Let
f(x) =
{x if 0 ≤ x ≤ 1;1− x2 if 1 < x.
Find the an deriva ve of f with F(0) = 1.
Antiderivatives of piecewise functions
Solu onWe can an differen ate each piece:
F(x) =
12x2 + C1 if 0 ≤ x ≤ 1;
x− 13x3 + C2 if 1 < x.
The constants need to be chosen so that F(0) = 1 and F iscon nuous (at 1).
F(x) =
12x2 + C1 if 0 ≤ x ≤ 1;
x− 13x3 + C2 if 1 < x.
I Note F(0) =1202 + C1 = C1, so if F(0) is to be 1, C1 = 1.
I This means limx→1−
F(x) =1212 + 1 =
32.
I On the other hand,
limx→1+
F(x) = 1− 13+ C2 =
23+ C2
So for F to be con nuous we need32=
23+ C2. Solving, C2 =
56.
F(x) =
12x2 + C1 if 0 ≤ x ≤ 1;
x− 13x3 + C2 if 1 < x.
I Note F(0) =1202 + C1 = C1, so if F(0) is to be 1, C1 = 1.
I This means limx→1−
F(x) =1212 + 1 =
32.
I On the other hand,
limx→1+
F(x) = 1− 13+ C2 =
23+ C2
So for F to be con nuous we need32=
23+ C2. Solving, C2 =
56.
F(x) =
12x2 + C1 if 0 ≤ x ≤ 1;
x− 13x3 + C2 if 1 < x.
I Note F(0) =1202 + C1 = C1, so if F(0) is to be 1, C1 = 1.
I This means limx→1−
F(x) =1212 + 1 =
32.
I On the other hand,
limx→1+
F(x) = 1− 13+ C2 =
23+ C2
So for F to be con nuous we need32=
23+ C2. Solving, C2 =
56.
OutlineWhat is an an deriva ve?
Tabula ng An deriva vesPower func onsCombina onsExponen al func onsTrigonometric func onsAn deriva ves of piecewise func ons
Finding An deriva ves Graphically
Rec linear mo on
Finding Antiderivatives Graphically
ProblemPictured is the graph of afunc on f. Draw the graph ofan an deriva ve for f.
..x
.
y
..1
..2
..3
..4
..5
..6
.......y = f(x)
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
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..
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..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
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. +. −. −. +.↗
.↗
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.↘
.↗
.
max
.
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.
f′ = F′′
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F
..
1
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2
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4
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
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. −. −. +.↗
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.↘
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.
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.
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f′ = F′′
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F
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −
. −. +.↗
.↗
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.↘
.↗
.
max
.
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.
f′ = F′′
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F
..
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2
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3
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4
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5
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −
. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
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3
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4
..
5
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6
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.
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +
.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
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2
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3
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4
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5
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6
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
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6
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.
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
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6
.
++
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−−
.
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.
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⌣
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.
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.
⌣
.
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shape
..
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
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.
−−
.
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.
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.
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
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.
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.
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.
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.
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.
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shape
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
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++
.
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.
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.
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.
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.
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F
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shape
..
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
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.
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.
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.
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.
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.
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.
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F
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
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.
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.
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⌣
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.
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.
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.
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.
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F
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shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
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.
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.
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.
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.
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.
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.
F
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shape
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
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.
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.
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.
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.
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F
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shape
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1
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
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.
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.
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.
⌣
.
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.
⌢
.
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.
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.
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.
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.
F
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shape
..
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
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++
.
⌣
.
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.
⌢
.
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.
⌣
.
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.
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.
F
.
shape
..
1
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3
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
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.
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.
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.
⌣
.
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.
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.
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.
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.
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.
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F
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shape
..
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
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.
−−
.
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.
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.
⌣
.
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.
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.
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.
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.
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.
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.
F
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shape
..
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3
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4
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5
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6
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
.
++
.
⌣
.
⌢
.
⌢
.
⌣
.
⌣
.
IP
.
IP
.
F
.
shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
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.
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.
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.
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.
IP
.
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.
F
.
shape
..
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..
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6
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
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.
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.
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.
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.
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.
shape
..
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..
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6
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
.
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.
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.
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.
shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
.
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.
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.
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.
shape
..
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
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.
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.
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.
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.
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.
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.
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shape
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
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.
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
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.
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shape
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.
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
.
++
.
⌣
.
⌢
.
⌢
.
⌣
.
⌣
.
IP
.
IP
.
F
.
shape
..
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..
2
..
3
..
4
..
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6
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.
.
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.
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.
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.
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.
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.
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.
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The only ques on le is: What are the func on values?
Using f to make a sign chart for FAssuming F′ = f, we can make a sign chart for f and f′ to find theintervals of monotonicity and concavity for F:
..x
.
y
..1
..2
..3
..4
..5
..6
......
.. f = F′.F
..1
..2
..3
..4
..5
..6
. +. +. −. −. +.↗
.↗
.↘
.↘
.↗
.
max
.
min
.
f′ = F′′
.
F
..
1
..
2
..
3
..
4
..
5
..
6
.
++
.
−−
.
−−
.
++
.
++
.
⌣
.
⌢
.
⌢
.
⌣
.
⌣
.
IP
.
IP
.
F
.
shape
..
1
..
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..
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..
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..
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..
6
.
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"
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.
.
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The only ques on le is: What are the func on values?
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
......
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.
I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
.
.....
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
.
.....
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
..
....
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
..
....
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
...
...
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
...
...
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
....
..
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
....
..
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
.....
.
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
......
Could you repeat the question?ProblemBelow is the graph of a func on f. Draw the graph of thean deriva ve for f with F(1) = 0.
Solu on
I We start with F(1) = 0.I Using the sign chart, we draw arcswith the specified monotonicity andconcavity
I It’s harder to tell if/when F crossesthe axis; more about that later.
..x
.
y
..1
..2
..3
..4
..5
..6
.......f
.
F
.
shape
..
1
..
2
..
3
..
4
..
5
..
6
.
"
.
".
.
.
"
.
IP
.
max
.
IP
.
min
......
OutlineWhat is an an deriva ve?
Tabula ng An deriva vesPower func onsCombina onsExponen al func onsTrigonometric func onsAn deriva ves of piecewise func ons
Finding An deriva ves Graphically
Rec linear mo on
Say what?
I “Rec linear mo on” just means mo on along a line.I O en we are given informa on about the velocity oraccelera on of a moving par cle and we want to know theequa ons of mo on.
Application: Dead Reckoning
Application: Dead Reckoning
ProblemSuppose a par cle of mass m is acted upon by a constant force F.Find the posi on func on s(t), the velocity func on v(t), and theaccelera on func on a(t).
Solu on
I By Newton’s Second Law (F = ma) a constant force induces aconstant accelera on. So a(t) = a =
Fm.
I Since v′(t) = a(t), v(t)must be an an deriva ve of theconstant func on a. So
v(t) = at+ C = at+ v0
where v0 is the ini al velocity.I Since s′(t) = v(t), s(t)must be an an deriva ve of v(t),meaning
s(t) =12at2 + v0t+ C =
12at2 + v0t+ s0
ProblemSuppose a par cle of mass m is acted upon by a constant force F.Find the posi on func on s(t), the velocity func on v(t), and theaccelera on func on a(t).
Solu on
I By Newton’s Second Law (F = ma) a constant force induces aconstant accelera on. So a(t) = a =
Fm.
I Since v′(t) = a(t), v(t)must be an an deriva ve of theconstant func on a. So
v(t) = at+ C = at+ v0
where v0 is the ini al velocity.I Since s′(t) = v(t), s(t)must be an an deriva ve of v(t),meaning
s(t) =12at2 + v0t+ C =
12at2 + v0t+ s0
ProblemSuppose a par cle of mass m is acted upon by a constant force F.Find the posi on func on s(t), the velocity func on v(t), and theaccelera on func on a(t).
Solu on
I By Newton’s Second Law (F = ma) a constant force induces aconstant accelera on. So a(t) = a =
Fm.
I Since v′(t) = a(t), v(t)must be an an deriva ve of theconstant func on a. So
v(t) = at+ C = at+ v0
where v0 is the ini al velocity.
I Since s′(t) = v(t), s(t)must be an an deriva ve of v(t),meaning
s(t) =12at2 + v0t+ C =
12at2 + v0t+ s0
ProblemSuppose a par cle of mass m is acted upon by a constant force F.Find the posi on func on s(t), the velocity func on v(t), and theaccelera on func on a(t).
Solu on
I By Newton’s Second Law (F = ma) a constant force induces aconstant accelera on. So a(t) = a =
Fm.
I Since v′(t) = a(t), v(t)must be an an deriva ve of theconstant func on a. So
v(t) = at+ C = at+ v0
where v0 is the ini al velocity.I Since s′(t) = v(t), s(t)must be an an deriva ve of v(t),meaning
s(t) =12at2 + v0t+ C =
12at2 + v0t+ s0
An earlier HatsumonExample
Drop a ball off the roof of the Silver Center. What is its velocity whenit hits the ground?
Solu onAssume s0 = 100m, and v0 = 0. Approximate a = g ≈ −10. Then
s(t) = 100− 5t2
So s(t) = 0 when t =√20 = 2
√5. Then
v(t) = −10t,
so the velocity at impact is v(2√5) = −20
√5m/s.
An earlier HatsumonExample
Drop a ball off the roof of the Silver Center. What is its velocity whenit hits the ground?
Solu onAssume s0 = 100m, and v0 = 0. Approximate a = g ≈ −10. Then
s(t) = 100− 5t2
So s(t) = 0 when t =√20 = 2
√5. Then
v(t) = −10t,
so the velocity at impact is v(2√5) = −20
√5m/s.
Finding initial velocity fromstopping distance
Example
The skid marks made by an automobile indicate that its brakes werefully applied for a distance of 160 before it came to a stop.Suppose that the car in ques on has a constant decelera on of20 ft/s2 under the condi ons of the skid. How fast was the cartraveling when its brakes were first applied?
Solu on (Setup)
I While braking, the car has accelera on a(t) = −20I Measure me 0 and posi on 0 when the car starts braking. Sos(0) = 0.
I The car stops at me some t1, when v(t1) = 0.I We know that when s(t1) = 160.I We want to know v(0), or v0.
Finding initial velocity fromstopping distance
Example
The skid marks made by an automobile indicate that its brakes werefully applied for a distance of 160 before it came to a stop.Suppose that the car in ques on has a constant decelera on of20 ft/s2 under the condi ons of the skid. How fast was the cartraveling when its brakes were first applied?
Solu on (Setup)
I While braking, the car has accelera on a(t) = −20
I Measure me 0 and posi on 0 when the car starts braking. Sos(0) = 0.
I The car stops at me some t1, when v(t1) = 0.I We know that when s(t1) = 160.I We want to know v(0), or v0.
Finding initial velocity fromstopping distance
Example
The skid marks made by an automobile indicate that its brakes werefully applied for a distance of 160 before it came to a stop.Suppose that the car in ques on has a constant decelera on of20 ft/s2 under the condi ons of the skid. How fast was the cartraveling when its brakes were first applied?
Solu on (Setup)
I While braking, the car has accelera on a(t) = −20I Measure me 0 and posi on 0 when the car starts braking. Sos(0) = 0.
I The car stops at me some t1, when v(t1) = 0.
I We know that when s(t1) = 160.I We want to know v(0), or v0.
Finding initial velocity fromstopping distance
Example
The skid marks made by an automobile indicate that its brakes werefully applied for a distance of 160 before it came to a stop.Suppose that the car in ques on has a constant decelera on of20 ft/s2 under the condi ons of the skid. How fast was the cartraveling when its brakes were first applied?
Solu on (Setup)
I While braking, the car has accelera on a(t) = −20I Measure me 0 and posi on 0 when the car starts braking. Sos(0) = 0.
I The car stops at me some t1, when v(t1) = 0.I We know that when s(t1) = 160.I We want to know v(0), or v0.
Implementing the SolutionIn general,
s(t) = s0 + v0t+12at2
Since s0 = 0 and a = −20, we have
s(t) = v0t− 10t2
v(t) = v0 − 20t
for all t.
Plugging in t = t1,
160 = v0t1 − 10t210 = v0 − 20t1
We need to solve these two equa ons.
Implementing the SolutionIn general,
s(t) = s0 + v0t+12at2
Since s0 = 0 and a = −20, we have
s(t) = v0t− 10t2
v(t) = v0 − 20t
for all t. Plugging in t = t1,
160 = v0t1 − 10t210 = v0 − 20t1
We need to solve these two equa ons.
SolvingWe have
v0t1 − 10t21 = 160 v0 − 20t1 = 0
I The second gives t1 = v0/20, so subs tute into the first:
v0 ·v020
− 10( v020
)2= 160
I Solve:
v2020
− 10v20400
= 160
2v20 − v20 = 160 · 40 = 6400
So v0 = 80 ft/s ≈ 55mi/hr
SolvingWe have
v0t1 − 10t21 = 160 v0 − 20t1 = 0
I The second gives t1 = v0/20, so subs tute into the first:
v0 ·v020
− 10( v020
)2= 160
I Solve:
v2020
− 10v20400
= 160
2v20 − v20 = 160 · 40 = 6400
So v0 = 80 ft/s ≈ 55mi/hr
SolvingWe have
v0t1 − 10t21 = 160 v0 − 20t1 = 0
I The second gives t1 = v0/20, so subs tute into the first:
v0 ·v020
− 10( v020
)2= 160
I Solve:
v2020
− 10v20400
= 160
2v20 − v20 = 160 · 40 = 6400
So v0 = 80 ft/s ≈ 55mi/hr
Summary of Antiderivatives so farf(x) F(x)
xr, r ̸= 11
r+ 1xr+1 + C
1x= x−1 ln |x|+ Cex ex + C
ax1ln a
ax + Cln x x ln x− x+ C
loga xx ln x− x
ln a+ C
sin x − cos x+ Ccos x sin x+ Ctan x ln | tan x|+ C
Final Thoughts
I An deriva ves are auseful concept, especiallyin mo on
I We can graph anan deriva ve from thegraph of a func on
I We can computean deriva ves, but notalways
..x
.
y
..1
..2
..3
..4
..5
..6
....... f.......F
f(x) = e−x2
f′(x) = ???