Math Final

Question 1

You have 10 meters of fence and want to build an enclosure that is as small as possible, but it can’t be narrower than one goat (1/2 meter). How long and wide should you make the enclosure?

Answer 1

1) Draw & Label a Picture

2) Write down what you wish to optimize:

3) Write an equation that expresses what you wish to optimize & in terms of variables

4) Reduce equation down to 1 variable using constraint in problem

5) Differentiate & solve for Global Extrema wanted: find f(x) at critical, singular & endpoints

6) Check if realistic within domain:

w=1/2m
l=9/2

Question 2

6 steps to performing Optimization

Answer 2

1) Draw & Label a Picture

2) Write down what you wish to optimize:

3) Write an equation that expresses what you wish to optimize & in terms of variables

4) Reduce equation down to 1 variable using constraint in problem

5) Differentiate & solve for Global Extrema wanted: find f(x) at critical, singular & endpoints

6) Check if realistic within domain

Question 3

Optimization on open vs closed interval

Answer 3

If f (x) is continuous on a closed interval, then f(x) has a global maximum and a global minimum on that interval

A continuous function on an open interval does not necessarily have a global maximum and a global minimum on that interval. However, you can still have a local and global extrema by determining where the function is increasing and where it is decreasing.

Question 4

100m of fencing to enclose a rectangular area against a straight wall. What is the largest area you can enclose?

Answer 4

1) Draw & Label a Picture

2) Write down what you wish to optimize:

3) Write an equation that expresses what you wish to optimize & in terms of variables

4) Reduce equation down to 1 variable using constraint in problem

5) Differentiate & solve for Global Extrema wanted: find f(x) at critical, singular & endpoints

6) Check if realistic within domain

A=1250
w=25

Question 5

Extremas & How to Evaluate for Them

Answer 5

Found evaluating the function at critical f’(x)=0, singular f’(x)=DNE & endpoints f(a)=#, f(z)=#, interval of [a,b]

Local Max x=c if f(c)f(x) for all x near c

Local Min x=c if f(c)f(x) for all x near c

2nd Derivative Test:
- If f’‘(c)<0 then c is a local max
- If f’‘(c)>0 then c is a local min

Global Max x=c if f(c)f(x) for all x
Global Min at x=c if f(c)f(x) for all x

Question 6

Find Global extrema of -x^4+x^2+1 on (-5,0)

Answer 6

Global Max at x=-sqrt(1/2)
Global Min at x=0

Question 7

1m long string cut into 2. One piece forms a square the other into a circle. Where to cut the string to maximize the total enclosed area of both shapes?

Answer 7

1) Draw & Label a Picture

2) Write down what you wish to optimize:

3) Write an equation that expresses what you wish to optimize & in terms of variables

4) Reduce equation down to 1 variable using constraint in problem

5) Differentiate & solve for Global Extrema wanted: find f(x) at critical, singular & endpoints

6) Check if realistic within domain

x=1/12

Question 8

Sketch x^2, x^3, logx, e^x, sinx, cosx, tanx, 1/x, sqrt(x), absolute x

Answer 8

See desmos

Question 9

Which term in a polynomial function will dominate for small x & large x

Answer 9

For small x, smaller degrees of power will dominate.

For large x, larger degrees of power will dominate

Question 10

Sketch & asymptotically show e^x dominates any power function

Answer 10

(e^x, x>k)>x^k

Question 11

Polynomial Power Function

Answer 11

f(x)=Kx^n, K ^ n are constants, can be negative or fraction

Question 12

Polynomial Functions

Answer 12

f(x)=anx^n+an-1x^n-1+…+a2x^2+anx+a0, a & k are constants

Question 13

Sketch f(x)=x^2-x^4, f(x)=3x+x^2, e^x-x^4 using asymptotic reasoning

Answer 13

See desmos + notes for reasoning

Question 14

Hill Function, for small & large x what does it look like

Answer 14

f(x)=(Ax^n)/(B+x^n)

Reason out denominator first, then simplify
For small x, f(x)=Ax^n/B
For large x, f(x)=A

Question 15

Asymptotic Reasoning Process

Answer 15

1. What is negligable at small x, simplify equation
2. What is negligable at large x, simply equation
3. Sketch out, find points where they intersect if required

Question 16

Explain with words & graphs what lim(x>a^+/-) f(x)=L

Answer 16

Limit of f(x) as x approaches a is equal to L means f(x) is arbitrarily close to L provided x is sufficiently close to a (but not equal to a)

Limit of f(x) as x approaches a from below is equal to L is arbitrarily close to L provided x is sufficiently close to a and x<a (left hand limit)

Limit of f(x) as x approaches a from above is equal to L is arbitrarily close to L provided x is sufficiently close to a and x>a (right hand limit)

If function does not approach a single number as x approaches a, the limit does not exist (DNE)

Question 17

Explain with words & graphs what lim(x>a^+/-) f(x)=+/- infinity

Answer 17

Vertical asymptotes

Question 18

Explain with words & graphs what lim(x>+/- infinity) f(x)=L

Answer 18

Horizontal asymptotes.

Limit of f(x) is arbitrarily large & +/- provided x is sufficiently close to a (but not equal to a)

Question 19

How to calculate limit

Answer 19

Easy, continuous function’s limits computed by substituting =limx->a f(x)=f(a)

Not nice (0/0, infinity) function’s limits computed by simplifying into nice function, finding holes, VA & HA asymptotes & finally substituting

Question 20

How to find features of quotient functions

Answer 20

(x+3)/(x+3)(x-2) Hole: x=-3, Vertical A: x=2 sub in x=1.9, 2.1 to find +/- limits, Horizontal A: n<d y=0, n=d y=coe/coe, n>d y=oblique, sub in x=+/- infinity

Question 21

Identify & explain what a function with a continuous domain is

Answer 21

f(x) is continuous at x=a if xaf(x)=f(x), unbroken, consistent graph, no abrupt changes in value (ex. Polynomials, trig, e^x, log(x))

Discontinuous (ex. piecewise, traffic light)

Question 22

Points of Discontinuity

Answer 22

Jump Discontinuity: piecewise

Removable Discontinuity: hole

Infinity Discontinuity: vertical asymptotes

Question 23

When given a function with paraments, how to select parameter values to make a function continuous

Answer 23

Set equations equal at x=a, if x<k=f(x), xk=g(x), f(k)=g(k), solve for variable

Question 24

Average Rate of Change

Answer 24

Slope of a Secant Line =[f(x1)-f(x0)]/x1-x0

Question 25

Solve for f’(1), if f(x)=x^2

Answer 25

2

Question 26

Linear Approximation + Use

Answer 26

Linear Approximation/Tangent Line to f(x) at x=a is L(x)=f(a)+f’(a)(x-a), used to approximate hard values of functions

Question 27

Linear approximation to f(x)=e^x at x=a=0, f’(0)=1

Find e^1/10

Answer 27

L(x)=f’(0)+f’(0)(x-0)=e0+1(x-0) = 1+x

L(1/10)=1+1/10=1.1

Question 28

Euleur’s Number e

Answer 28

lim(h>0) eh-1/h=1

Question 29

Solve for derivative of e^x

Answer 29

e^x

Question 30

Differential Equation + 2 Examples

Answer 30

Differential Equation y’(t)=y(t): a unknown function & its derivatives with a solution that satisfies it

1. y=e^x, y’=e^x, velocity vs acceleration, compound interest, bacteria growth, population growth
2. y=Ce^x, y’=Ce^x, h>0(Ce(x+h)-Ce^x)/h=h>0(Ce^xeh-Ce^x)/h=limh>0 Ce^x(eh-1)/h=Cex

Question 31

Instantaneous Rate of Change

Answer 31

Derivative of f(x) at x0 is f’(x0)=d/dxf(x)=lim(h>0)[f(x+h)-f(x)]/h

Doesn’t exist at corners, sudden changes in slope, jumps or where the limit is infinite number

Question 32

Linearity of Differentiation + Proof

Answer 32

Proof using the limit definition of derivative & use to break down derivatives of sums + constant multiples

Question 33

Power Rule + Proof

Answer 33

Proof using the limit definition of derivative & use for integer exponents

Question 34

Derivative of a function

Answer 34

f’(x) = df/dx =limh>0(f(x+h)-f(x))/h

Used to solve derivatives, show how derivatives can be equivalent, etc.

Question 35

Find derivative of f(x)=3x+x^2

Answer 35

f’(x)=3+2x

Question 36

Derivative of an exponent (a^x) & tan(x)

Answer 36

d/dx 4^x=4^xlog(4)
d/dx a^x=a^xlog(a)
d/dx a^f(x)=a^f(x)log(f(x))f’(x)
d/dx tan(x)=sec^2(x)

Question 37

Reciprocal Rule + Proof

Answer 37

See notes

Question 38

Product Rule + Proof

Answer 38

See notes

Question 39

Find derivative of f(x)=x^2+1/x^2

Answer 39

f’(x)=2x-2/x^3

Question 40

Find derivative of f(x)=x*e^x

Answer 40

f’(x)=e^x+x*e^x

Question 41

Quotient Rule + Proof

Answer 41

See notes

Question 42

Find derivative of f(x)=(x^3+1)(x^2+2)

Answer 42

f’(x)=3x(x^2+2)+(x^3+1)2x

Question 43

Graphically show trig f(x)s & their derivatives

Answer 43

See notes

Question 44

Addition Formulas

Answer 44

sin(a+b)=sin(a)cos(b)+sin(b)cos(a)
cos(a+b)=cos(a)cos(b)-sin(a)sin(b)
limh>0 sin(h)/h=1
limh>0 cos(h)-1/h=0

Question 45

Derivative sinx, cosx & tanx proof

Answer 45

See notes

Question 46

Chain Rule

Answer 46

d/dxf(g(x)) = f’(g(x))g’(x) = df/dgdg/dx

Question 47

Differentiate f(x)=sin(3x)

Answer 47

cos(3x)(3)

Question 48

Differentiate f(x)=(x^3-2x+1)^6

Answer 48

6(x^3-2x+1)^5(3x*2)

Question 49

Implicit Differentiation

Answer 49

1. Taking derivative of both sides using Chain rule
2. Solve for dy/dx

Question 50

Differentiate x^2+y^2=1, then find x where y’=1 using Algebra & Diagram

Answer 50

dy/dx=-2x/2y
x=+/- 1/sqrt(2)

Question 51

Logarithmic Differentiation

Answer 51

Applying the natural logarithm to both sides of equation to make it easier to differentiate, especially in f(x)^g(x), combining Chain Rule+Implicit Differentiation+Logarithmic Rules

1. Take log of both sides, simplifying using log rules
2. Take d/dx of both sides (implicit differentiation+chain rule)
3. Isolate for y’(x)

Question 52

Differentiate x^a using logarithmic differentiation

Answer 52

f(x)= x^a
logf(x) = logx^a
1/f(x) * f’(x) = alogx
1/(x^a) * f’(x)=a/x
f’(x) = a/x(x^a)
f’(x)= ax^(a-1)

Question 53

How to solve a related rate question?

Answer 53

1. Draw & label a picture + Write down what is known
2. Write down what you wish to find
3. Write down an equation that relates the thing whose rate y (reduce to 1 variable)
4. Differentiate & Solve
5. Check if answer makes sense

Rate of Change of Area = L’W + LW’
Rate of Change of Focal Length of Lense
Rate of Change of radius of expanding circle
Rate of change of water level entering inverted cone
Rate of Change of angle of a moving person across a room

Question 54

Wall = 5.9m
Rate of Change of Walking = 1/4m/s
x = opposite/walking distance
tangent = angle

At tangent=pi/4, what is the rate of change of tangent?

Answer 54

Draw label diagram
Find dtangent/dt or rate of change of tangent or f’(pi/4) f(x)=tangent
t * tan(tangent)=tx/L –> differentiate ^ solve
(1215.6)1.4

Question 55

An inverted cylindrical cone, 28 m deep and 14 m in diameter across the top, is being filled with water at a constant rate of 13 m3/min. At what rate is the water rising in the tank when the depth of the water is 1m, 10m, 27m

Answer 55

208/pi(h)^2

Question 56

Draw sin(x)=arcsin(y) & sin(y)=arcsin(x) at range[-pi/2,pi/2]<->domain[-1,1]

Answer 56

See Diagram

Question 57

Draw cos(x)=arccos(y) & sin(y)=arccos(x) at range[-0,pi]<->domain[-1,1]

Answer 57

See diagram

Question 58

Differentiate arcsin(x) in terms of x

Answer 58

d/dxsin(y)=dx/dx
cos(y)dy/dx=1

Triangle + SOH CAH TOA

dydx=11-x2

Question 59

Differentiate arccos(x) in terms of x

Answer 59

d/dxcos(y)dy/dx=dx/dx
dy/dx=-1/sin(y)

Triangle + SOH CAH TOA

dy/dx=-1/sqrt(1-x2)

Question 60

Differentiate arccos(e^2x) in terms of x

Answer 60

2e^(2x)/sqrt(1-e^4x)

Question 61

Draw tan(x)=arctan(y) & tan(y)=arctan(x) at range[-pi/2,pi/2]<->domain[-infinity,infinity]

Answer 61

See diagram

Question 62

Differentiate arctan(x) in terms of x

Answer 62

d/dxtan(y)=dx/dx
sec^2(y)dy/dx=1
dy/dx=1/sec2(y)
dy/dx=cos^2(y)

Triangle + SOH CAH TOA

dy/dx=1/1+x2

Question 63

How to determine concavity?

Answer 63

If f(x)’‘>0 = slope is increasingly increasing = concave up = f(x) lies above its tangent lines on that interval
Diagram

If f(x)’‘<0 = slope is increasingly decreasing = concave down = f(x) lies below its tangent lines on that interval
Diagram

Question 64

Degree 0 & 1(linear) approximation around x=0? Diagram?

Answer 64

T0(x) be the degree 0 approximation of f(x) around x=0: T0(x)=f(0)=1
Let T1(x)be the linear approximation to f(x) about x=0: T1(x)=f(0)+f’(0)(x-a)=1+1(x-0) = 1+x

The higher the degree of approximation, the better the approximation

Question 65

Degree n Approximation to f(x) at x=a is ?

Answer 65

Tn(x)=f(a)+f’(a)(x-a)+f’‘(a)/2(x-a)^2+f’’‘(a)/3!(x-a)^3+…+f(n)(a)/n!*(x-a)^n

Question 66

Taylor vs Maclaurin Polynomial

Answer 66

Taylor x=a
Maclaurin x=a=0

Question 67

Proof of Degree nth Approximation

Answer 67

Find c0,c1,c2,c3,…,cn, such that the kth derivatives match: T^(k)n(x)=f(^k)(a) for k=0,1,2,3,…,n

Question 68

Proof of Degree 3 e^x Approximation

Answer 68

Let T2(x)=c0+c1(x-0)+c2(x-0)2=c0+c1x+c2x2 be the degree 2 approximation to f(x)=ex about x=0
Find c0, c1 and c2 such that
T2(0)=f(0)=1 → c0+c1(0)+c2(0)2=c0=1
T’2(0)=f’(0)=1 → c1+2c2(0)=c1=1
T’‘2(0)=f’‘(0)=1 → 2c2=1, c2=1/2
Therefore: T2(x)=c0+c1x+c2x2 = 1+1x+1/2x

Question 69

cos(x) nth Degree Maclaurin Polynomial + Show Work

Answer 69

Tn(x)=1-x2/2!+x4/4!+…

Question 70

sin(x) nth Degree Maclaurin Polynomial:

Answer 70

Tn(x)=x-x3/3!+x5/5!+…

Question 71

Find degree 3 MP of f(x)=4xe^2x:

Answer 71

expand: T3(x)=4x[1+(2x)+(2x)2/2!+(2x)3/3!]

Question 72

Derive f(x)=a/1-x general formula of nth degree Maclaurin Polynomial

Answer 72

Tn(x)=a+ax+ax^2+ax^3+…+ax^n

Question 73

Find limit of the partial sums Sn as n–>infinity

Answer 73

Sn(x)=a+ax+ax2+…+axn-1
xSn(x)=ax+ax2+ax3+…+axn-1+axn
Sn(x)-xSn(x)=a-axn
Sn=a(1-x^n)/(1-x)
lim n–>infinity a +ax+ax2+…+axn-1 = a/1-x if absolute x < 1 so x^n is negligeble

Question 74

Make statement about 5-10/3+20/9-40/27+….

Answer 74

lim n–>infinity (5+5(-2/3)+5(-2/3)^2+5(-2/3)^3… )
=5/(1+2/3)=3

Question 75

Find the sixth degree Taylor Polynomial T6(x) about x=0 of (e^3x^2)/(1+5^x^3)

Answer 75

T6(x)= 1 + 3x^2-5x^3+ 0x^3 + 9/2x^4 - 15x^5 +59/2x^6

Question 76

water tank is in the shape of an inverted right circular cone with top diameter 6 metres and depth 8 metres. Suppose that the tank is leaking water. Note the volume of a right circular cone is V = 1/3πr2h, where r is the radius and h is the height of the cone.

a) Suppose that when the water is 4 metres deep, the water leaks out of the tank at a rate of 3 m^3//hr. What is the rate of change of the depth of the water at this point in time?

b) Suppose now that the water from the conical tank is leaking directly into another tank, which is in the shape of a cube, and has base area A m2. How fast is the depth of the water in the cubic tank increasing atthe same moment in time described in part (a)?

Answer 76

a) h’ = 4/3pi m/hr
b) h’c = 3A m/hr

Question 77

Consider a container filled with some fixed amount of ideal
gas. Suppose that the container is perfectly isolating, the thickness of its wall is negligible and it is capable of expanding or shrinking while staying perfectly spherical (you may think of an ideal balloon). The pressure p, the volume V and the temperature T of the gas satisfy the ideal gas law pV = nRT, where n is the amount of the gas enclosed in moles and R is a universal constant.

You may use that the volume of a solid ball of radius r is V = 4/3πr3 and the surface area of a sphere of radius r is A = 4πr2

(a) Suppose that we heat up the gas at a constant rate of 3 K/s while keeping the pressure at a constant level 3/4 Pa. What is the rate of change of the radius of the container, when the surface area of the container is 0.4 m2? Your answer should be in terms of n and R.

b) Now suppose that we keep the temperature constant while we are expanding the container in such a way that its radius is increasing at a constant rate of 0.1 m/s . What is d/dt log(p) when the radius of the container is 0.6 m?

Answer 77

dr/dt = 10nR.

d/dt log(p) = − 0.3
0.6 = −1/2

Question 78

Consider an isosceles triangle of base 10cm and
sides x centimetres. Suppose x is increasing at a rate of 4cm per second.
a) What is the rate of change of the height of the triangle when x = 13cm?
b) What is the rate of change of the area of the triangle when x = 13cm?

Answer 78

a) h’ = 13/3

b) A’= 65/3

Question 79

Curve Sketching Process

Answer 79

1) f(x)
- Domain Restrictions: Vertical asymptotes, Horizontal asymptotes, Holes
- Intercepts
- Positive+Negative Intervals

2) f’(x)
- Critical Points, Singular Points
- Increase & Decrease Intervals
- Local Extremas (Min/Max)

3) f’‘(x)
- Concavity

4) Global Extrema
- End, critical & singular points

Question 80

What info can be pulled from just f(x)

Answer 80

Domain, +ve,-ve, intercepts, DNE, even, odd, periodic, asymptotes

Domain Restrictions: roots x>0 unless x^even, log(x), 1/x

Vertical Asymptotes: restrictions in denominator/when is denominator equal to 0 or limx>? f(x)=+/-infinity

Horizontal asymptotes: limx>infinity f(x)=? and limx>-infinity f(x)=?
1. x-f(x)=, no horizontal asymptote
2. N=D, y=Coefficients of N/D
3. N>D, y=N/D
4. N<D, y=0

Holes: factor, simplify, mark down what terms cancel out, set them to 0, isolate for x, sub into f(x)

Intercepts:
- x-intercept: set y=0, isolate for x
- y-intercept, set x=0, isolate for y

Postive +Negative Intervals:
- Test signs of intervals b/w roots & domain restrictions using f(x), -ve=-ve interval,+ve=+ve interval
- If f(x) is continuous, then f(x) will only switch sign around where f(x)=0 or DNE

Question 81

What info can be pulled from just f’(x)

Answer 81

positive (f increasing), negative (f decreasing), f ′ = 0 or f ′ DNE

Critical Points, Singular Points:
- Critical Point (c): f’(c)=0, round
- Singular Point (s): f’(s)=DNE, sharp pointy

Increase & Decrease Intervals:
- Test signs of intervals b/w critical & singular points using f(x),
- -ve=interval of decrease,
- +ve=interval of increase

Local Extremas (Min/Max): First Derivative Test: if a function is continuous and switches from decreasing to increasing at x=c, there is a local minimum at x=c. If f(x) switches from increasing to decreasing at x=c, there is a local maximum at x=c

Question 82

What info can be pulled from just f’‘(x)

Answer 82

positive (f concave up), negative (f concave down), f ′′ = 0 or f ′′ DNE

Concavity:
- Find points where f’‘(x)=0 or DNE , then test signs of intervals b/w them
- +ve=Concave Up
- -ve=Concave Down
- Inflection Point: an existing point where concavity switches

Question 83

How to find global extrema in open vs closed interval?

Answer 83

• Evaluate f(x) at end, critical & singular points
• Smallest = global minimum
• Largest = global maximum
• Check concavity to double check
• If f(x) is continuous on a closed interval, then f(x) has a global max and min on that interval
• If f(x) is continuous on an open interval, there doesn’t have to be a global max and min on that interval, can still be determined

Question 84

Sketch graph x^2/(x^2+1)

Answer 84

See desmos
1) f(x)
- Domain Restrictions: Vertical asymptotes, Horizontal asymptotes, Holes
- Intercepts
- Positive+Negative Intervals

2) f’(x)
- Critical Points, Singular Points
- Increase & Decrease Intervals
- Local Extremas (Min/Max)

3) f’‘(x)
- Concavity

4) Global Extrema
- End, critical & singular points

Question 85

Sketch graph
x^2+8/x

Answer 85

See desmos
1) f(x)
- Domain Restrictions: Vertical asymptotes, Horizontal asymptotes, Holes
- Intercepts
- Positive+Negative Intervals

2) f’(x)
- Critical Points, Singular Points
- Increase & Decrease Intervals
- Local Extremas (Min/Max)

3) f’‘(x)
- Concavity

4) Global Extrema
- End, critical & singular points

Question 86

f(x)=1/(1+e^(-kx)), k>0

What would happen to the graph if we changed the 1 to a 2?

Answer 86

If numerator changes 1-> 2 horizontal asymptote goes from y=1>y=2, more and more far apart

If denominator changes 1->2 vertical asymptote goes from 1=e^-kx > 2=e^-kx

See Desmos

Question 87

Extrema

Answer 87

Extrema: found evaluating the function at critical f’(x)=0, singular f’(x)=DNE & endpoints f(a)=#, f(z)=#, interval of [a,b]

• Local Max x=c if f(c)f(x) for all x near c
• Local Min x=c if f(c)f(x) for all x near c

2nd Derivative Test:
If f’‘(c)<0 then c is a local max
If f’‘(c)>0 then c is a local min

• Global Max x=c if f(c)f(x) for all x
• Global Min at x=c if f(c)f(x) for all x

Question 88

Find extrema of f(x)=-x^4+x^2+1 on (-5,0)

Answer 88

x=-1/(sqrt(2))

Question 89

Geometric Optimization: 1m long string cut into 2. One piece forms a square the other into a circle. Where to cut the string to maximize the total enclosed area of both shapes?

Answer 89

String should be cut at x=112 for largest enclosed area.

Question 90

Optimization Process

Answer 90

1) Draw & Label Picture
2) Write down what you wish to optimize: Area of enclosed space
3) Write an equation that expresses what you wish to optimize & in terms of variables
4) Reduce equation down to 1 variable using constraint in problem
5) Differentiate & solve for Global Extrema wanted: find f(x) at critical, singular & endpoints
6) Check if realistic within domain:

Question 91

Algebraic Equation vs Differential Equation (Examples)

Answer 91

Algebraic Equation: contains an unknown number that is solved for
- Ex. 4=y2, y=4=2, Solution:2, Check:4=(2)2,4=4, LS=RS

Differential Equation: contains an unknown function & its derivatives that is solved for
- Solution=Function that satisfies the differential equation dydx=y
ddxe^x=e^x, Check:d/dx e^x=ex,ex=ex, LS=RS
d/dxCe^x=Ce^x, Check: d/dxCe^x=Ce^x, Ce^x=Ce^x, LS=RS

Question 92

How to check if a function satisfies a differential equation

Answer 92

There could be many solutions & that don’t necessarily look similar.
1) Take is derivative dydx
2) Sub in to see if LS=RS

Question 93

Check which function satisfies differential equation: dy/dx+x2-1=y

A)y=x2+1 B)y=x2+2x+1

Answer 93

A)y=x2+1, y’=2x,
LS:dydx+x2-1-y , sub in y’=2x, 0=2x+x2-1
RS: y=x2+1
LSRS, A) is not a solution to the differential equation

B)y=x2+2x+1, y’=2x+2
LS: dydx+x2-1, sub in y’, =2x+2+x2-1=x2+2x+1
RS: y, sub in y=x2+2x+1
LS=RS, B) Is a solution to the differential equation

Question 94

Check which function satisfies differential equation: dydx=xy,
A)-x,
B)x+5
C)sqrt(x^2+5)

Answer 94

A)-x, y’=-1
B)x+5,y’=1
C)x2+5,y’=1/2(x^2+5)^–1/2*(2x)

Question 95

Ansatz + Process

Answer 95

Ansatz: guess of form of the solution involving parameters/can find parameter values that give solution

1) Take necessary derivatives
2) Set LS=RS
3) Isolate & Solve for unknown parameter

Question 96

Ansatz: Given differential equation y’‘-9y=0, y=e^ax find values of a such that y is a solution

Answer 96

^Therefore, y=e^-3x & y=e3x are both solutions to the differential equation, all in the form of y=Ce^x

Question 97

Ansatz: Given differential equation y’‘+4y=0 & ansatz y=sin(ax) find values of a such that y is a solution

Answer 97

Therefore, y=sin(2x),y=sin(0x) or sin(-2x) are solutions to the differential equation

Question 98

Initial Value Problem + 3 Solutions

Answer 98

Differential equation with an initial condition
1) Soln to dy/dt=ay with initial condition y(0) is y(t)=y(0)e^at
2) Soln to dy/dt=a(y-b) with initial condition y(0) is y(t)=(y(0)-b)e^at+b
3) Soln to differential equation dydt=y(1-y) is the logistic model y=1/(1+e^-t)

Question 99

Proof to Soln to dy/dt=ay with initial condition y(0) is y(t)=y(0)e^at

Sketch the solutions to the differential equation dydx=2y, with initial condition y(0)=100

Answer 99

For any t value, slope is 2y. y(0)=Ce^2(0)=C=100, so y=100e^2t satisfies the initial value problem.

See notes

Question 100

Proof to Soln to dy/dt=a(y-b) with initial condition y(0) is y(t)=(y(0)-b)e^at+b

Transform the differential equation dydt=a(y-b) by setting u=y-b & solving the differential equation with initial condition y(0)

Answer 100

Let u(t)=y(t)-b -> du/dt=dy/dt=a(y-b)=au,
Since du/dt=au is familiar to dy/dt=ay with soln y=C=y(0)e^at, so u(t)=u(0)e^at
In terms of y(t): y(t)-b=(y(0)-b)e^at y(t)=(y(0)-b)e^at+b

Question 101

Newton’s Law of Cooling: suppose y(t) is the temperature of your coffee, and b is the temperature of the room, y temp is hotter than >b room temperature

1) Sketch 3 solutions to differential equation dydt=a(y-b) given a<0, b>0, y(0)>b, for y(0)=b and for y(0)<b in terms of y(t)

2) Sketch phase line, assuming a=-3, b=2 so dydt=-3(y-2) in terms ofy as function of t & dydt=-3(y-2) as a function of y

Answer 101

Everything approaches b, see notes

If dydt>0 coffee temp is increasing as y<b +ve=a(y-b)=a(-ve), a=-ve, a<0
If dydt=0, coffee temp is staying same y=b 0=a(y-b)=a(0), a=anything
If dydt<0, coffee temp is decreasing y>b, -ve=a(y-b)=a(+ve), a=-ve, a<0

Stable steady state y=2

Question 102

Temperature at the time of death was 37. Temperature 32.5 at 1:30. Temperature 30.3 at 2:30. Room temperature is 20. Time of death if bodies follow Newton’s Law of Cooling=dy/dt=a(y-b), y(t)=(y(0)-b)e^at?

Answer 102

Let y(t)=temp of body, t=time after death at 1:20
1) y(0)=37, y(t)=32.5, y(t+1)=30.3, b=20, unknown=a & t
2) y(t)=(y(0)-b)eat+b 32.5=(37-20)eat+20eat=12.517

3) y(t+1)=(y(0)-b)eat+b 30.3=(30.3-20)eat+20eat=10.317

4) ea(t+1)eat=10.3/1712.5/17a=In(10.312.5)

5) With a, Isolate for t*

So at 1:30 it’s been 95mins since time of death, so murder occurred at 11:55pm

Question 103

Phase Line

Answer 103

Phase line records dy/dt values on a horizontal y-axis

Slope Fields: y vs t axis
Phase line: dy/dx vs y axis

Identify critical points & record movement in b/w
f(y)>0, the solution y(t) is increasing=right pointing arrows

f(y)<0, the solution y(t) is increasing=left pointing arrows

f(y)=equilibrium

Question 104

Slope Field

Answer 104

Slope Field: values of dy/dt on y vs t axes

Question 105

Steady State

Answer 105

Steady State: state in which a system is not changing, such as if y remains constant for all t (dydx=0) for a solution y(t) to a differential equation
- Stable Steady State: if all nearby solutions tend to it
- Unstable Steady State: if all nearby solutions tend away from it
- Semistable: otherwise

Question 106

Soln to differential equation dy/dt=y(1-y) is the logistic model y=1/(1+e-t)

Answer 106

dydt=0 when y=0,1

Question 107

Sketch slope field & phase line of

1) Soln to dy/dt=ay with initial condition y(0) is
2) Soln to dy/dt=a(y-b) with initial condition y(0) is
3) Soln to differential equation dydt=y(1-y) is

Answer 107

y(t)=y(0)e^at
y(t)=(y(0)-b)e^at+b
the logistic model y=1/(1+e^-t)

Question 108

Find the distance fallen x(t) as a function of time analytically, experimentally, numerically?

Answer 108

Analytically - Newton’s Second Law of Motion: x(t), x’‘(t)=g=acceleration due to gravity
- if object starts from rest initial velocity is 0 =x(0)=x’(x)=0
- x(t)=12gt2 satisfies both differential equations
x’(t)=1/2g2t=gt,x’(0)=0, x’‘(t)=g

Experimentally: used to evaluate accuracy of model, estimate parameter values in a specific model or compare b/w different models
- Drop object at different heights, record time it takes, plot a graph, compare with analytical model graph

Numerically: allows us calculate numerical solutions to differential equations when we cannot solve them analytically, to solve for x(t) only knowing x’‘(t)=g
v(t)=x’(t), v’(t)=x’‘(t)=g
v(ti+1)=v(ti)+v’(ti)t=v(ti)+gt

Question 109

Euler’s Method deriving equation + visual + computer

Answer 109

Euler’s Method y(ti+1)=y(ti)+y’(ti)t, t=ti+t-ti, linear approximation to the function y at the point t=ti+1
- To satisfy differential equation dydt=f(y), y(t0)=y0, let y’(t)=f(y) so - y(t1)=y(t0)+f(y(t0))t
Initial Condition y0=__
- Linear approximation to point t0 evaluated at t1: y1=y(t0)+f(y(t0))t
- Linear approximation to point t1 evaluated at t2: y2=y(t1)+f(y(t1))t
- Linear approximation to point t2 evaluated at t3: y3=y(t2)+f(y(t2))t

See notes

Question 110

Sketch solution to dy/dt=y, y(0)=1 using Euler’s Method on paper + on computer

Answer 110

See notes

Question 111

Sketch solution to dy/dx=y(1-y), y(0)=18 using Euler’s Method on computer

Answer 111

See notes

Question 112

Issues with Euler’s Method

Answer 112

Underestimation or Overestimation: Numerical solution will keep underestimating as it uses tangent line for a concave up function or overestimating for a concave down function. Meaning tangent lines/linear approximations will always be below/below the function.

Second Order Taylor Approximation of x(ti+1) about ti: x(ti+1)=x(ti)+x’‘(ti)/2*(delta t)2
- Error depends on t and is added to each approximation,
D- ecreasing the time step t reduces the error in the numerical approximation

Question 113

Newton’s Method: deriving equation + visual + computer

Answer 113

Newton’s Method: xn+1=xni-f(xn)/f’(xn) to estimate root (x-intercept) with only the expressions for f(x) & f’(x)
Derivation: L(x)=f(x0)+f’(x0)(x1-x0)=0x1=x0-f(x0)f’(x0)

See notes

Question 114

Issues with Newton’s Method

Answer 114

Things could go wrong when using Newton’s Method as at times numbers don’t always converge
Beware of starting points near min or max where division could be by 0
Approximation is too far away from the roots to give an accurate estimate

Question 115

Differences b/w Euler & Newton’s Method

Answer 115

Euler calculates linear approximation at all y values of f(x) using differential equations (& its solutions)

Newton calculates roots using linear approximations closer & closer.

Question 116

Apply Newton’s method to f(x)=x^5-2x^4+3x^2+1

Answer 116

See desmos + computer

Question 117

Plot points (x,y,x)=(2,1,3),(1,3,2)

Plot planes x, y, z

Evaluate z values for given pairs of f(1,2)=e^(x^2+y^2)

Answer 117

See notes

Question 118

Determine domain & Range of f(x,y) process.

Answer 118

Determine domain of f, what combinations of x and y will f accept by thinking in terms of one variable function

Determine range of f, what values of f can be output by thinking in terms of one variable function and checking endpoints/boundaries of x & y

Question 119

Determine domain & Range of
f(x,y)=e^(x^2+y^2)
f(x,y)=sqrt(9-x^2-y^2)
f(x,y)=log(arctan(x+y))

Answer 119

Domain:
ex2+y2ex2, no restrictions so domain is all x and all y

9-x2-y29-x2, 9-x20, 9x2, 3x . Domain x2+y29 or x+y3

No restrictions on arctan(x+y), log(x) only accepts x>0 so arctan(x+y)>0 when x+y>0 or y>-x

Range:
Range is [1,infinity) as all x2+y20 and e0 will only output range of 1 or higher

Range is [0,3] as domain is 0<x^2+y^2<9, so plug in x^2=0,f(x)=sqrt(9-0^2)=3 and x^2=9, f(x)=sqrt(9-3^2)=0

Range is (log(0),log(pi/2))=(-infinity,log(pi/2)) as x+y>0 so plug in x+y=0,f(x,y)=log(arctan(0))=log(0) and x+y=, f(x,y)=log(arctan(infinity))=log(pi/2), so0<arctan(x+y)<pi/2

Question 120

Partial Derivatives + f(x,y)=3y^2sin(x+3)

Answer 120

A partial Derivative in x, at a point (x,y), written dfdxfx or fx(x,y) , describes the slope of the line tangent to f(x,y) along the x direction while keeping y fixed (x,z graph).
f(x,y)=3y2sin(x+3)fx=3y2cos(x+3)

A partial Derivative in y, at a point (x,y), written dfdyfy or fy(x,y) , describes the slope of the line tangent to f(x,y) along the y direction while keeping x fixed (y,z graph).
f(x,y)=3y2sin(x+3)fy=6ysin(x+3)

Question 121

Second Order Partial Derivative with respect to x & y +
f(x,y)=3y^2sin(x+3)

Answer 121

See notes
fxx=-3y^2sin(x+3)
fxy or yx=6ycos(x+3)
fyy=6sin(x+3)

Question 122

Level Curves + Given z=x2+y2, sketch level curves corresponding to z=4,1,0,-1

Answer 122

Level Curves (z constant): horizontal slices of a 3 dimensional surface on z-plane in terms of x & y

4=x2+y2
1=x2+y2
0=x2+y2
-1=x2+y2

Question 123

Traces + Given z=x^2+y^2, sketch traces corresponding to y=0,x=0,x=1,y=2

Answer 123

Trace (x or y constant): vertical slices of a 3 dimensional surface on x or y-plane in terms of z and leftover dimension

z=x^2
z=y^2
z=1+y^2
z=4+x^2

Question 124

Sketch surface of z=x^2+y^2

Answer 124

1) Domain + Range Restrictions
2) Level Curves
3) Traces
4) Combine

See notes

Question 125

Critical, Singular & Saddle Points on f(x,y)

Answer 125

A function f(x,y) has a critical point at (a,b) if fx(a,b)=0 and fy=0. fx=0 and fy=0, slope in any x or y direction is 0.

A function f(x,y) has a singular point at (a,b) if fx(a,b)=DNE or fy=DNE
- f’(x)=#0,-ve, log(-ve),arcsincos(-1>#>1), etc.

A Saddle Point is a critical point at neither a max or min, is there anywhere that you can sit on.
- Inflection points (x3)
- Max in one direction, min in the other (x2-y2), think of a saddle (horse hump max, sitting area min)

Question 126

Critical Points of functions

f(x,y)=x^2+y^2
f(x,y)=x^2-x^4+y^2
f(x,y)=x^2

Answer 126

f(x,y)=x^2+y^2: one critical point at (0,0)

f(x,y)=x^2-x^4+y^2 have: 3 critical points at (0,0),(-1/sqrt2,0),(1/sqrt2,0)

f(x,y)=x^2 have: critical points at (0,yR)

Question 127

Singular Points of function
f(x,y)=/x/+(x-1)^2+y^2

f(x,y)=sqrt(x^2+y^2)

Answer 127

-x+(x-1)2, x>0
x+(x-1)2, x>0

1 critical point at (12,0), singular points at (0,yR)

1 singular point at (0,0)

Question 128

Process to find absolute extrema in f(x,y) with a boundary

Answer 128

1) Find critical points
2) Find singular points
3) Boundary to 1 Variable
4) Find Glboal extrema of boundary
5) Sub in global extrema of boundary into function
6) Sub critical, singular & boundary points into original
7) Compare all z-values to find global extrema in form (x,y)

Question 129

Find absolute extrema f(x,y)=(x-1)^2+y^2, to the region x^2+y^2<=4

Answer 129

Global Max: f(-2,0)
Global Min: f(1,0)

Question 130

Find absolute extrema f(x,y)=x^2y+xy^2-3xy without boundary

Answer 130

Min: f(1,1)=-1
Max: f(4,4)=80

Question 131

Process to find absolute extrema in f(x,y) without a boundary

Answer 131

1) Find max & min of boundary of shape, setting to 1 variable, first derivative to find extrema
2) Find max & min within shape by taking partial derivatives, combining into points where slope in all direction fy=fx=0
3) Subbing in endpoint, singular + critical points into original function

Question 132

Calculate all four second-order partial derivatives of
f(x,y)=(3x+2y)e^y

Answer 132

fxx=0
fyx=3e^y
fyy=3xe^y+2e^y+2e^y+2ye^y
fxy=3e^y

Question 133

Find critical points of f(x,y)=6x-x^2-3xy^2

Answer 133

(3,0) (0,-sqrt(2)) (0,+sqrt(2))

Question 134

What f(x,y) have no global max or min?

A) f=xy,
B) f=x^3+y^3,
C) f=x^2+y^2,
D) f=sin(xy),
E) f=x^2-e^y

Answer 134

Has no limited range. Goes on to infinities. Can make function infinitely negative or positive.

A, B, E