Real Numbers and Algebra

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Real Numbers and Algebra

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Title: Real Numbers and Algebra

1

Chapter 1
Real Numbers and Algebra

2
1.1 Describing Data with Set of numbers

Natural Numbers are counting numbers and
can be expressed as
N 1, 2, 3, 4, 5, 6, .
Set braces , are used to enclose the
elements of a set.
A whole numbers is a set of numbers, is given
by
W 0, 1, 2, 3, 4, 5,

3
Continued

The set of integers include both natural and
the whole numbers and is given by
I , -3, -2, -1, 0, 1, 2, 3, .
A rational number is any number can be
written as the ratio of two integers p/q,
where q 0. Rational numbers can be written
as fractions and include all integers.
Some examples of rational numbers are
8/1, 2/3, -3/5, -7/2, 22/7, 1.2, and 0.

4
continued

Rational numbers may be expressed in decimal form
that either repeats or terminates.
The fraction 1/3 may be expressed as 0.3, a
repeating decimal, and the fraction ¼ may be
expressed as 0.25, a terminating decimal. The
overbar indicates that 0.3 0.3333333.
Some real numbers cannot be expressed by
fractions. They are called irrational numbers.
2, 15, and ? are examples of irrational
numbers.

Identity Properties
For any real number a,
a 0 0 a a,
0 is called the additive identity and
a . 1 1 . a a,
The number 1 is called the multiplicative
identity.
Commutative Properties
For any real numbers a and b,
a b b a (Commutative Properties of
addition)
a.b b.a (Commutative Properties of
multiplication)

6
Continued

Associative Properties
For any real numbers a, b, c,
(a b) c a (b c) (Associative
Properties of addition)
(a.b) . c a . (b . c) (Associative Properties
for multiplication)
Distributive Properties
For any real numbers a, b, c,
a(b c) ab ac
and
a(b- c) ab - ac

7
1.2 Operation on Real Numbers

The Real Number Line

-3 -2 -1 0 1 2
3 Origin
-2 2
-2 2 Absolute value
cannot be negative 2 2
-3 -2 -1 0 1 2
3 Origin
8
Continued

If a real number a is located to the left of a
real number b on the number line, we say that a
is less than b and write altb.
Similarly, if a real number a is located to the
right of a real number b, we say that a is
greater than b and write agtb.
Absolute value of a real number a, written a ,
is equal to its distance from the origin on the
number line. Distance may be either positive
number or zero, but it cannot be a negative
number.

9
Arithmetic Operations

Addition of Real Numbers
To add two numbers that are either both positive
or both negative, add their absolute values.
Their sum has the same sign as the two numbers.
Subtraction of real numbers
For any real numbers a and b, a-b a (-b).
Multiplication of Real Numbers
The product of two numbers with like signs is
positive. The product of two numbers with unlike
signs is negative.
Division of Real Numbers
For real numbers a and b, with b 0, a/b a .
1/b
That is, to divide a by b, multiply a by the
reciprocal of b.

10
1.3 Bases and Positive Exponents

Squared 4
Cubed

4
4
4
4
4 4 . 4 42 4 .
4. 4 43

Exponent Base
11
Powers of Ten
12

1.3 Integer Exponents
Let a be a nonzero real number and n be a
positive integer. Then
an a. a. a. aa (n factors of a )
a0 1, and a n 1/an
a -n b m
b -m a n
a -n b n
b a

13
cont

The Product Rule
For any non zero number a and integers m and n,
am . an a mn
The Quotient Rule
For any nonzero number a and integers m and
n,
am
a m n
a n

Raising Products To Powers
For any real numbers a and b and integer n,
(ab) n a n b n
Raising Powers to Powers
For any real number a and integers m and n,
(am)n a mn
Raising Quotients to Powers
For nonzero numbers a and b and any integer
n.
a n an

b
bn
15
Continued

A positive number a is in scientific notation
when a is written as b x 10n, where 1 lt b lt 10
and n is an integer.
Scientific Notation
Example 52,600 5.26 x 104 and 0.0068 6.8 x
10 -3

16
1.4 Variables, Equations , and Formulas

A variable is a symbol, such as x, y, t, used to
represent any unknown number or quantity.
An algebraic expression consists of numbers,
variables, arithmetic symbols, paranthesis,
brackets, square roots.
Example 6, x 2, 4(t 1) 1,

X 1
17
cont

An equation is a statement that says two
mathematical expressions are equal.
Examples of equation
3 6 9, x 1 4, d 30t, and x y
20
A formula is an equation that can be used to
calculate one quantity by using a known value of
another quantity.
The formula y x/3 computes the no. of yards
in x feet. If x 15, then y15/3 5.

18
Square roots

The number b is a square root of a number a if b2
a.
Example - One square root of 9 is 3 because 32
9. The other
square root of 9 is 3 because (-3)2 9. We use
the symbol to
9 denote the positive or principal square root
of 9. That
is, 9 3. The following are examples of how
to evaluate
the square root symbol. A calculator is sometimes
needed to approximate square roots,
4 2
-
The symbol is read plus or minus. Note
that 2
-
represents the numbers 2 or 2.

19
Cube roots

The number b is a cube root of a number a if b3
a
The cube root of 8 is 2 because 23 8, which
may
be written as 3 8 2. Similarly 3 27 -3
because
(- 3)3 - 27. Each real number has exactly one
cube root.

20
1.5 Introduction to graphing

Relations is a set of Ordered pairs.
If we denote the ordered pairs in a relation
(x,y),
then the set of all x-values is called the
domain of the relation and the set of all y
values is called the range.

21
Example 1.

Find the domain and range for the relation given
by
S ( -1, 5), (0,1), (2, 4), (4,2), (5,1)
Solution
The domain D is determined by the first element
in each ordered pair, or
D -1, 0, 2, 4,5
The range R is determined by the second element
in each ordered pair, or R 1,2,4,5

22
The Cartesian Coordinate System
Quadrant II y Quadrant I
y
(1, 2)
2 1 0 -1 -2
Origin
2 1 -1 -2
x
x
-2 -1 1 2
-2 -1 1 2
Quadrant III Quadrant IV The xy
plane
Plotting a point
23
Scatterplots and Line Graphs

If distinct points are plotted in the xy- plane,
the resulting graph is called a scatterplot.

Y
7 6 5 4 3 2 1
(4, 6)
(3, 5)
(5, 4)
(2, 4)
(6, 3)
(1, 2)
X
1 2 3 4 5 6 7
0
24
Using Technology
25
Ex 9 page 44
Make a table for y x 2 / 9, starting at x 10
and incrementing by 10 and compare The table for
example 4 ( pg 41)
Go to Y and enter x 2 /9 Go to 2nd then
table set and enter Go to 2nd then table
26
Viewing Rectangle ( Page 57 )
Ymax
Ysc1
Xmax
Xmin
Xsc1
Ymin
-2, 3, 0.5 by -100, 200, 50
27
Making a scatterplot with a graphing
calculator Plot the points (-2, -2), (-1, 3), (1,
2) and (2, -3) in -4, 4, 1 by -4, 4, 1
(Example 10, page 58)
Go to 2nd then stat plot
Go to Stat Edit then enter points
Scatter plot
-4, 4, 1 by -4, 4, 1
28
Example 11Cordless Phone Sales
Enter line graph
Go to Stat edit and enter data
Hit graph
Enter datas in window
1985, 2002, 5 by 0, 40, 10
29

Chapter 2
Linear Functions and Models

30
Ch 2.1 Functions and Their Representations

A function is a set of ordered pairs (x, y),
where each x-value corresponds to exactly one
y-value.

Input x
Output y
Function f
(x, y) Input
Output
31
continued

y is a function of x because the output y is
determined by and depends on the input x. As a
result, y is called the dependent variable and x
is the independent variable
To emphasize that y is a function of x, we
use the notation y f(x) and is called a
function notation.
A function f forms a relation between inputs
x and outputs y that can be represented verbally
(Words) , numerically (Table of values) ,
symbolically (Formula), and graphically (Graph).

32
Representation of Function
y
Table of Values
Graph
20 16 12 8 4

y 3x
x
0 4 8 12 16 20 24

Numerically
Graphically
33
Diagrammatic Representation

Function
Not a function

x y
x
y

3 6 9
(1, 3), (2, 6), (3, 9)
1 2 3
4 5 6
1 2
1 2 3
4 5
(1, 4), (2, 5), (2, 6)
(1,4), (2, 4), (3, 5)
Example 1, pg - 77
34
Domain and Range Graphically

The domain of f is the set of all x- values, and
the range of f is the set of all y-values

y
3 2 1
Range R includes all y values
satisfying 0 lt y lt 3
x Domain D includes all x
values Satisfying 3 lt x lt 3
Range
-3 -2 -1 0 1 2 3
Domain
Pg 79 Ex-5
35
Vertical Line Test
If each vertical line intersects the graph at
most once, then it is a graph of a function

5
4
3
2
1
-1
-2
-3

Not a function
(-1, 1)
-4 -3 -2 -1 0
1 2 3 4
(-1, -1)
36
Continued

Not a function
4 3 2 1 -1 -2 -3
(-1, 1)
-3 -2 -1 0 1
2 3
(1, -1)
Example 9 page - 81
37
Using Technology
Graph of y 2x - 1
Hit Y and enter 2x - 1
Hit 2nd and hit table and enter data
- 10, 10, 1 by - 10, 10, 1
38
2.2 Linear Function

A function f represented by f(x) ax b,
where a and b are constants, is a linear
function.

100 90 80 70 60
100 90 80 70 60
f(x) 2x 80
0 1 2 3 4 5
6 0 1 2
3 4 5 6
Scatter Plot
A Linear Function
Ex- 1, 2, 3, 4, 5 Pg 91
39
Modeling data with Linear Functions

Example 7

1500 1250 1000 750 500 250 0
Cost (dollars)

8 12 16 20
x
Credits

Symbolic Representation f(x) 80x
50 Numerical representation 4 8
12 16
370 690 1010 1330
40
Using a graphing calculator

Example 5
Give a numerical and graphical representation
f(x) ½ x - 2
Numerical representation Y1 .5x 2 starting
x -3
Graphical representation

-10, 10, 1 by -10, 10, 1
41
2.3 The Slope of a line
Y

Cost (dollars)
Rise 3
Slope Rise 3 Run
2
Run 2
1 2 3 4 5 6

x Gasoline (gallons ) Cost
of Gasoline Every 2 gallons purchased the cost
increases by 3
42
2.3 Slope
rise y2 - y1 m run x2
- x1
y2
(x2, y2)

y2 y1 y1 (x1, y1)
x2 x1
Rise

The Slope m of the line passing through the
points (x1 y1 ) and (x2, y2) is
m y2 y1/x2 x1
Where x1 x2. That is, slope equals rise over
run.

Run
Ex- 1, 2 pg 104
43
4 3 2 1 0 -1 -2
4 3 2 1 -1 -2 -3
2
-1
m - ½ lt 0
m 2 gt 0
2
-4 -2 1 2 3 4
- 4 -2 1 2
Positive slope
Negative slope
m 0
m is undefined
Zero slope
Undefined slope
44
(0, 4)Example 2 - Sketch
a line passing through the point (0, 4) and
having slope - 2/3y - valuesdecrease 2
units each times x- values increase by 3(0 3,
4 2) (3, 2)

( 0, 4)
Rise -2
( 3, 2)
- 4 - 3 - 2 1 0 1 2
3 4
45
Slope-Intercept Form

The line with slope m and y intercept b is
given by
y mx b
The slope- Intercept form of a line

Example 3, and 4, 5, 6, 7 pg - 106
46
Example - 3
3 2 1 -1 -2 -3
Y ½ x
Y ½ x 2
-3 -2 -1 1 2
Y ½ x - 2
47
Analyzing Growth in Walmart

Example 9

Year 1997 1999 2002
2007 Employees 0.7 1.1 1.4 2.2
3.0 2.5 2.0 1.5 1.0 0.5
Employees (millions)
m3
m2
m1
Years
0 1999 2003 2007
m1 1.1 0.7 0.2
m2 1.4 - 1.1 0.1 and 1999
1997
2002 1999 m3
2.2 - 1.4 0.16
2007 - 2002
Average increase rate
48
2.4 Point- slope form

The line with slope m passing through the
point (x1 , y1 ) is given by
y m ( x - x1 ) y1
Or equivalently,
y y1 m (x x1)
The point- slope form of a line

(x, y)
y y1
(x1, y1)
x x1
m y y1 / x x1
Ex 1, 2,3 pg 117
49
Horizontal and Vertical Lines
Equation of vertical line

y
y
x h
x
x
b
h
y b
Equation of Horizontal Line
50
Continued

Parallel Lines
Two lines with the same slope are parallel.
m1 m2
Perpendicular Lines
Two lines with nonzero slopes m1 and m2 are
perpendicular
if m1 m2 -1

Examples 7, 8 Page - 123
51
m2 -1
m2 - 1/m1
m1 1
m2 - 1/2
m1 2
m1
52

Chapter 3
Linear Equations and Inequalities

53
3.1 Linear Equation in One Variable

A Linear Equation in one variable is an equation
that can be written in the form
ax b 0
Where a 0
A linear function can be written as f(x) ax b
Examples of Linear equation.
2x 1 0, -5x 10 x, and 3x 8 5

54
Properties of Equality

Addition Property of Equality
If a, b, c are real numbers, then
a b is equivalent to a c b c.
Multiplication Property of Equality
If a, b, c are real numbers with c 0, then
a b is equivalent to ac bc.

Example 1,2,3,4 pg 146
55
Example 7 Solving a Linear equation
graphicallyusing technology

-6, 6, 1 by -4, 4, 1

56
Example 8

1984, 1991, 1 by 0, 350, 50 in 1987 In 1987
CD and LP record sales were both 107 million
57
Standard form of a line

An equation for a line is in standard form when
it is written as
ax b c, where a, b, c are
constants
With a, b and c are constants with a and b not
both 0
To find x-intercept of a line, let y 0 in the
equation and solve for x
To find y-intercept of a line, let x 0 in the
equation and solve for x

58
3.2 Linear Inequality in One Variable

A linear inequality in one variable is an
inequality that can be written in the form
ax b gt 0, where a 0. ( The symbol gt may be
replaced with gt, lt, or gt )
There are similarities among linear functions,
equations, and inequalities. A linear function is
given by f(x) ax b, a linear equation by ax
b 0, and a linear inequality by ax b gt 0.

Examples of linear inequalities are
2x 1lt 0, 1-x gt 6, and 5x 1 lt 3 2x
A solution to an inequality is a value of the
variable that makes the statement true. The set
of all solutions is called the solution set. Two
inequalities are equivalent if they have the same
solution set.
Inequalities frequently have infinitely many
solutions. For example, the solution set to the
inequality x- 5gt 0 includes all real numbers
greater than 5, which can be written as x gt 5.
Using set builder notation, we can write the
solution set as x x gt 5 .
Meaning
This expression is read as the set of all real
numbers x such that x is greater than 5.

60
3.2 Solving a problem

Using a variable to an unknown quantity
Number problem
n is the smallest even integers
Three consecutive three even integers
n, n 2, n 4
n is the smallest odd integers
Three consecutive odd integers
n, n 2, n 4

61
Mixing acid ( Ex 8 pg 163)
20 2 liters
60 x liters
50 x 2 liters

Step 1 x liters of 60 sulphuric acid
x 2 Liters of 50 sulphuric
acid
Step 2 Concentration Solution Amount
Pure Acid
0.20 (20)
2 0.20(2)
0.60 (60)
x 0.60x
0.50(50)
x 2 0.50(x 2)
Equation 0.20(2) 0.60x
0.50(x 2)
(pure acid in 20 sol.) (pure acid
in 60 sol.) (pure acid in 50 sol.)
Step 3 Solve for x
0.20(2) 0.60x 0.50(x
2)
2 (2) 6x 5(x 2)
Multiply by 10
4 6x 5x 10
(Distributive Property) Subtract 5x and 4 from
each side x 6
Six liters of the 60 acid solution should be
added to the 2 liters of 20 acid solution.
Step 4 If 6 liters of 60 acid solution are
added to 2 liters of 20 solution, then there

62
Ex 46 (Pg 166) Anti freeze mixture

A radiator holds 4 gallons of fluid
x represents the amount of antifreeze that is
drained and replaced
The remaining amount is 4 x
20 of 70 of solution of 50
of solution
4 x gallons x gallons
4 gallons
0.20(4-x) 0.70x 0.50(4)
0.8 0.2x 0.7x 2
0.5x 1.2
x 2.4
The amount of antifreeze to be drained and
replaces is 2.4 gallons

63
Geometric Formulas
h

Perimeter of triangle P abc unit
Area of triangle
A ½ bh sq.unit
Area of Rectangle LW sq.unit
Perimeter P 2(L W) unit
Area of Parallelogram
A bh sq.unit
Area Volume of cylinder
A 2 rh sq.unit
V r2 h cu.unit
Area Volume of a cube
A 6a2 sq.unit
V a3 cu.unit

a

c
b
W
L
h b
h
r

a
a
a
64
3.3 Properties of Inequalities

Let a, b, c be real numbers.
a lt b and ac lt bc are equivalent
( The same number may be added to or subtracted
from both sides of an inequality.)
If c gt 0, then a lt b and ac lt bc are equivalent.
(Both sides of an inequality may be multiplied or
divided by the same positive number)
If clt 0, then a lt b and ac gt bc are equivalent.
Each side of an inequality may be multiplied or
divided by the same negative number provided the
inequality symbol is reversed.

65
Fig. 3.14 Graphical Solutions (Pg 172)
Distance (miles)

y1 y2
y2 y1
x 2 0 1 2 3
4 Time ( hours ) Distances of two
cars

Distance ( milesDistance
When x 2 , y1 y2, ie car 1 and car 2 both are
150 miles From Chicago
y1 lt y2 when xlt 2 car 1 is closer to Chicago
than car 2 y1 is below the graph of y2 y1 gt y2
when x gt 2 Car 1 is farther from Chicago than
Car 2 Y1 above the graph of y2
66
Continued

Ex 5 (Pg 173) Solving an inequality
graphically
Solve 5 3x lt x 3
y1 5 3x and y2 x 3 Intersect at the
point (2, -1)

5 4 3 2 1
X 2
y1
y2
-4 -3 -2 -1 0 1 2 3
4
y1 y2 when x 2
-1 -2 -3
(2, -1)
y1 lt y2 when x gt 2 , y1 is below the graph of
y2 Combining the above result y1 lt y2 when x
gt 2
Thus 5 3x lt x 3 is satisfied when x gt 2. The
solution set is x / xgt 2
67
Using Technology

Hit window
Hit Graph Hit Y Enter inequality
Enter
-5, 5, 1 by -5, 5, 1
68
Ex 80 ( Pg 178) Sales of CD and LP records
Hit Y , enter equations Enter table
set Enter window
Hit Table
Hit graph
1987 or after CD sales were greater than or equal
to LP records
69
3.4 Compound inequalities

A compound inequality consists of two
inequalities joined by the words and or or.
The following are two examples of compound
inequalities.
2x gt -3 and 2x lt 5
2(1) gt -3 and 2(1) lt 5 1
is a solution
True True
5 2 gt 3 or 5 1 lt -5 5 is
a solution
x 2 gt 3 or x 1 lt -5
True False

Example 1
Example 2
70
. Cont.

If a compound inequality contains the word and,
solution must satisfy both inequalities.
For example, x 1 is a solution of the first
compound inequality because
2 (1) gt -3 and 2 (1) lt 5
True
True
are both true statements.
If a compound inequality contains the word or,
solution must satisfy atleast one of the two
inequalities. Thus x 5 is a solution to the
second
compound inequality.
5 2 gt 3 or 5 1 lt -5
True False

71
Symbolic Solutions and Number Lines

x lt 6 xgt - 4 x lt 6 and x gt - 4
-8 -6 -4 -2 0 2 4
6 8
(
-8 -6 -4 -2 0 2
4 6 8

(
-8 -6 -4 -2 0 2 4
6 8 - 4lt x lt 6
72
Three-part inequality

Sometimes compound inequality containing the word
and can be combined into a three part inequality.
For example, rather than writing
x gt 5 and x lt 10
We could write the three-part inequality
5 lt x lt 10

(

-1 0 1 2 3 4 5 6 7 8
9 10 5 lt x lt 10
73
Example 5Page 184

Solve x 2 lt -1 or x 2 gt 1
x lt -3 or x gt -1 (
subtract 2 )
The solution set for the compound inequality
results from taking the union of the first two
number lines. We can write the solution, using
builder notation, as
x x lt - 3 U x x gt - 1 or
x x lt - 3 or x gt - 1
x lt - 3
x gt - 1
x lt - 3 or x gt -1

)
- 4 -3 -2 -1 0 1
2 3 4
(
- 4 -3 -2 -1 0 1
2 3 4
)
(
- 4 -3 -2 -1 0 1
2 3 4
74
Interval NotationTable 3.5 (Page 186)

Inequality Interval Notation
Number line Graph
- 1 lt x lt 3 ( - 1, 3)
- 3 lt x lt 2 ( - 3, 2
- 2 lt x lt 2 - 2, 2
x lt - 1 or x gt 2 ( - ? , - 1) U (2, ? )
x gt - 1 ( - 1, ? )
x lt 2 ( - ?, 2

(
)
-4 -3 -2 -1 0 1 2 3 4

(
-4 -3 -2 -1 0 1 2 3 4 -4 -3
-2 -1 0 1 2 3 4 -4 -3 -2
-1 0 1 2 3 4 -4 -3 -2 -1
0 1 2 3 4 -4 -3 -2 -1 0 1
2 3 4

(
)
(

75
Example 6 (Page 185)

Solving a compound inequality numerically and
graphically Using Technology
Tution at private colleges and universities from
1980 to 1997
Can be modelled by f(x) 575(x 1980) 3600
Estimate when average tution was between 8200
and 10,500.

Hit Y and enter equation Hit Window
and enter Hit 2nd and Table

1980, 1997, 1 by 3000, 12000, 3000
Hit 2nd and calc and go to Intersect and enter 4
times to get intersection
76
Ex 85 (Page 189)Solve graphically and
numerically. Write your answer in interval
notationx 1 lt -1 or x 1 gt 1 Y1 -1,
Y2 x 1, Y3 1
-5, 5, 1 by -5, 5, 1
x 1 lt - 1 or x 1 gt 1 Solution in
interval notation is ( - ? -2) U (0, ? )
77
School EnrollmentExample 92 (Pg 190)

Enrollment (millions)

1980 1990 2000
Year

Chapter 4
Systems of Linear Equations

79
4.1 Systems of Linear Equations in two variables

The system of linear equation with two variables.
Each equation contains two variables, x and y.
Example x y 4
x y 8
An ordered pair (x, y) is a solution to linear
equation
if the values for x and y satisfy both equations.
The standard form is
ax by c
dx ey k
Where a, b, c, d, e, k are constants.

80
Types of Linear Equations in two variables

A system of linear equations in two variables can
be represented graphically by two lines in the
xy-plane
The lines intersect at a single point, which
represents a unique solution. Consistent system
The equations are called independent equation
If the two lines are parallel it is an
inconsistent system and no solution
If two lines are identical and every point on
the line represents solution and give infinitely
many solutions. The equations are called
dependent equations

81
..cont.

Example
The equations x y 1 and 2x 2y 2 are
equivalent.
If we divide the second equation by 2 we obtain
the first equation. As a result, their graphs are
identical and every point on the line represents
a solution.Thus there are infinitely many
solutions, and the system of equations is a
dependent system.

y
y
y x
x

x
Unique
dependent
Inconsistent
82
The Substitution Method

Consider the following system of equations.
2x y 5
3x 2y 4
It is convenient to solve the first equation for
y to obtain y 5 2x. Now substitute ( 5 2x)
for y into the second equation.
3x 2(y) 4 Second equation
3x 2(5-2x)
4, Substitute
to obtain a linear equation in one variable.
3x
2(5 2x) 4
3x 10
4x 4 Distributive property
7x 10 4
Combine like terms
7x 14
Add 10 to both sides
x 2
Divide both sides by 7
To determine y we substitute x 2 into y 5
2x to obtain
y 5 2(2) 1
The solution is (2, 1).

83
Elimination Method

The elimination method is the second way to solve
linear systems symbolically. This method is based
on the property that equals added to equals are
equal. That is, if
a b and c d
Then a c b d
Note that adding the two equations eliminates the
variable y
Example
2x y 4
x y 1
3x 5
or x 5/3 and solve for x
Substituting x 5/3 into the second equation
gives
5/3 y
1 or y - 2/3
The solution is (5/3, - 2/3)

84
Solve the system of equations using
Technology4.1 Pg 226

Ex 43 Ex 44
No
solution Infinitely
many solutions
85
Burning caloriesEx 74 pg 239

During strenuous exercise an athelete can burn on
Rowing machine Stair
climber
10 calories per minute 11.5 calories per
minute
In 60 minute an athelete burns 633 calories by
using both exercise machines
Let x minute in rowing machine, y minute in stair
climber
The equations are
x y 60
10x 11.5 y 633
Find x and y
-10x - 10 y -600 (Multiply by -10)
10x 11.5 y 633
Add 1.5y 33, y 33/1.5 22 minute in
stair climber
and x 38 minute in rowing machine

86
Mixing acids Ex 76 ( Pg 239 )

x represents the amount of 10 solution of
Sulphuric acid
y represents the amount of 25 solution of
Sulphuric acid
According to statement x y 20
10 of x 25 of
y 0.18(20)
0.10x .25 y
3.6
.1x .25y
3.6 Multiply by 10
x 2.5y
36
x y 20
Subtract 1.5 y 16
y
16/1.5 10.6
x
20 y 20 10.6 9.4
Mix 9.4 ml of 10 acid with 10.6 ml of 25 acid

87
River current ( Ex 84, pg 240 )

x
Speed of tugboat
y
Speed of current
Distance Speed x Time
165 (x y) 33 Upstream x y
5
165 (x y) 15 Downstream x y
11
By elimination method 2x
16, x 8
y 3
The tugboat travels at a rate of 8 mph and river
flows at a rate of 3 mph

88
Solving Linear inequalities in Two variables

x lt 1 x gt 1
-2 -1 0 1 2 3 4
- 2 -1 1 2 3
- 2 -1 1 2

-1
x 2y lt 4
y lt 2x - 1
x intercept 4 (4, 0) y intercept -2
(0, -2)
Choose a test point Let x 0, y 0
x - 2y lt 4 0 - 2(0) lt 4 0 lt 4 which is true
statement Shade containing (0, 0)
89
Solving System of Linear Inequalities ( Pg 244)x
y lt 4y gt x
Testing point x y lt 4 x 1, y 2
1 2 lt 4 ( True )

Shaded region Testing point 2 gt 1 (
True)
(1, 2)
(1, 2)
y gt x
-4 -3 -2 -1 0 1 2 3 4
Shaded region
Shaded region
To solve inequalities
( 1, 2)
90
Modeling target heart rates (Ex 5 Pg 246 )For
Aerobic Fitness
A persons Maximum heart rate ( MHR) 220 - A
200 175 150 125 100 75 50 25
Heart Rate Beats Per minute
T - 0.8A 196 ( Upper Line ) T - 0.7 A
154 (Lower Line )

0 20 30 40 50 60 70 80
Age in years
(30, 150) is a
solution

0.8 (40) 196 lt 165 When A 40 yrs
- 0.7 (40) 196gt 125

150 lt - 0.8 (30) 196 172 True 150 gt - 0.7
(30) 196 133 True
91
Solving a system of linear inequalities with
technologyEx 6 ( Pg 247 )

Shade a solution set for the system of
inequalities, using graphing calculator
- 2x y gt 1 or ygt 2x 1

2x y lt 5 or y lt 5 2x
- 15, 15, 5 by - 10, 10, 5

- 15, 15, 5 by - 10, 10, 5
Hit 2nd and Draw then go to Shade
92

Linear Functions and Polynomial Functions
Every linear function can be written as
f(x) ax b and is an example of a polynomial
function. However, polynomial functions of degree
2 or higher are nonlinear functions. To model
nonlinear data we use polynomial functions of
degree 2 or higher.

Chapter 5
Polynomial Expressions and Functions

94
5.1 Polynomial Functions

The following are examples of polynomial
functions.
f(x) 3 Degree 0
Constant
f(x) 5x 3 Degree 1
Linear
f(x) x2 2x 1 Degree 2
Quadratic
f(x) 3x3 2x2 6 Degree 3
Cubic

95
Polynomial Expressions

A term is a number, a variable, or a product of
numbers
and variables raised to powers.
Examples of terms include
15, y, x4, 3x3 y, x-1/2 y-2 , and 6 x-1 y3
If the variables in a term have only nonnegative
integer
exponents, the term is called a monomial.
Examples of
monomials include
4, 5y, x2, 5x 2 z4, - x y4 and 6xy4

96
Monomials
x
x
x
x

x
y
y
y
Volume x3
Total Area xy xy xy 3xy
97
Modeling AIDS cases in the United StatesEx 11 (
Pg 308 )
600 500 400 300 200 100
Aids Cases (Thousands)
0 4 6 8 10 12 14

Year ( 1984
1994 )
f(x) 4.1x2 - 25x 46 f(7) 4.1(7) 2-
25.7 46 71.9 f(17) 4.1 (17) 2 25.7 46
805.9
98
Modeling heart rate of an athelete ( ex 12 )
250 200 150 100 50
Heart Rate (bpm)
0 1 2 3 4 5 6 7 8
Time (minutes )
P(t) 1.875 t2 30t 200
Where 0 lt t lt 8
P(0) 1.875(0) 2 30(0) 200 200 (Initial
Heart Rate) P(8) 1.875(8) 2 30(80 ) 200 80
beaqts per minute (After 8 minutes)
The heart rate does not drop at a constant rate
rather, it drops rapidly at first and then
gradually begins to level off
99
A PC for all(Ex 102 Pg 312)
200 150 100 50

Worldwide computer

0 1998 2000 2002 2004
Year
f(x) 0.7868 x2 12x 79.5 x 0
corresponds to 1997 x 1 corresponds to 1998 and
so on x 6 corresponds to 2003 f(6) 0.7868 x
6 2 12 x 6 79.5 179.8248 180
million(approx)
100
5.2 Review of Basic Properties

Using distributive properties
Multiply
4 (5 x) 4.5 4. x 20 4x

20
4x
4

x
Area 20 4x

101
Using Technology
-6, 6, 1 by -4, 4, 1 -6, 6,
1 by -4, 4, 1
102
.Cont

Multiplying Binomials
Multiply (x 1)(x 3)
Geometrically
Symbolically

a) Geometrically x 1
1 x
3
x2 3x

x 3
x 3 Area (x 1)(x
3) Area x2
4x 3 b) Symbolically apply distributive
property (x 1)(x 3) (x 1)(x) (x 1)(3)
x.x 1.x x.3 1.3 x 2 x 3x 3 x2
4x 3
x
103
Some Special products

(a b) (a - b) a 2 - b 2
Sum
(a b) 2 a 2 2ab b 2
Difference
(a b) 2 a 2 - 2ab b 2

104
Squaring a binomial

(a b) 2 a2 ab ab b2 a2 2ab b2

a a2
ab b ba
b2
a b
(a b)2 a2 2ab b2
105
5.3 Factoring Polynomials

Common Factors
Factoring by Grouping
Factoring and Equations ( Zero Product Property)

106
Zero- Product Property

For all real numbers a and b, if ab 0, then a
0 or b 0 ( or both)

107
Ex 5 Solving the equation 4x x2 0
graphically and symbolically
Graphically

Numerically
x y
-1 -5
0 0
3
4
3
0
5 -5

Symbolically
4x x 2 0
x(4 x) 0 (Factor out x )
x 0 or 4 x 0 ( Zero Product property)
x 0 or x 4

4 3 2 1
-3 -2 -1 1 2 3
4 5 6
108
5.4 Factoring TrinomialsFactoring x2 bx
cx2 bx c , find integers m and n that
satisfy m.n c and m n bx2 bx c (x
m)(x n)
109
5.4 Factoring Trinomials ax 2 bx c by
grouping

Factoring Trinomials with Foil
3x 2 7x 2 ( 3x 1 ) ( x
2 )

x 6x 7x
If interchange 1 and 2 (3x 2)(x 1) 3x2
5x 2 which is incorrect
2x 3x 5x
110
5.5 Special types of Factoring

Difference of Two Squares
(a b) (a b) a2 - b2
(a b) 2 a2 2ab b2
(a b) 2 a2 - 2ab b2
Sum and Difference of Two Cubes
(a b)(a2 ab b2) a3 b3
(a b)(a2 ab b2 ) a3 b3
Verify
( a b) (a2 ab b2) a. a2 a . ab a. b2
b. a2 -b . ab b. b2
a3 - a2 b a b2 a2 b - a b2 b3
a3 b3

Perfect Square
111
5.6 Polynomial Equations

Solving
Quadratic Equations
Higher Degree Equations

112
Using Technology
-4.7, 4.7, 1 by -100, 100, 25

Y 16x4 64x3 64x2
x 0 , y 0, x 2 y 0
113

Chapter 6
Rational Expressions and Functions

114

6.1 Rational Expressions and Functions
Rational Function
Let p(x) and q(x) be polynomials. Then a
rational function is given by
f(x) p(x)/ q(x)
The domain of f includes all x-values such
that q(x) 0
Examples - 4 , x
, 3x2 6x 1
x x
5 3x - 7

115
Identify the domain of rational function(Ex 2
pg 376)

g(x) 2x
x2 - 3x 2
Denominator x2 - 3x 2 0
(x 1)(x 2) 0 Factor
x 1 or x 2
Zero product property
Thus D x / x is any real number except 1 and
2

116
Using technology( ex 57, pg 384 )
-4.7 , 4.7 , 1 by -3.1, 3.1, 1
(ex 64, pg 384)
117

Highway curve ( ex 72, page 384 )
R(m) 1600/(15m 2)

500 400 300 200 100
Radius
0 0.2 0.4 0.6 0.8
slope
a) R(0.1) 1600 / (15(0.1) 2) 457 About
457 a safe curve with a slope of 0.1 will have
a minimum radius of 457 ft b) As the slope of
banking increases , the radius of the curve
decreases c) 320 1600/(15m 2) , 320( 15m
2) 1600 , 4800m 640 1600 4800m 960, m
960/4800 0.2
118
Evaluating a rational function Ex 4, Pg
-377Evaluate f(-1), f(1), f(2)

Numerical value x -3 -2 -1
0 1 2 3
y 3/2
4/3 1 0 __ 4 3
f(x) 2x
x - 1

4 3 2 1
-4 -3 -2 -1 1 2 3
Vertical asymptote
f(-1) 1 f(1) undefined and f(2)
4
119

6.2 Products and Quotients of Rational
Expression
To multiply two rational expressions, multiply
numerators and multiply denominators.
A/B. C/D AC /BD B and D are nonzero.
Example 2/3 . 5/7 10/21
To divide two rational expressions, multiply by
the reciprocal of the divisor.
A/B C/D AC/BD B, C, and D are
nonzero
Example 3/4 - 2/4
3.4/4.5 3/5

120

6.3 Sums and Differences of Rational Expressions
To add (or subtract) two rational expressions
with like denominators, add (or subtract) their
numerators. The denominator does not change.
A/C B/C (A B)/C
Example - 1/5 2/5 (1 2) / 5 3/5
A/C B/C (A B) /C
3/5 - 2/ 5 (3 2)/5 1/5

121
6.4 Solving rational equations graphically and
numerically ( Ex- 3 (a) pg 409 )

1/2 x/3 x/5
Solution- The LCD for 2,3, and 5 is their
product, 30.
30( 1/2 x/3) x/5 . 30 Multiply by the LCD.
30/2 30x/3 30x/5 Distributive
property
15 10x 6x Reduce
4x -15 Subtract 6x
and 15
x -15/4 Solve
Graphically Y1 1/2 x/3 Y2 X/5

-9, 9, 1 by -6, 6, 1
122
Determining the time required to empty a pool (
pg 415, no.68)

A pump can empty a pool in in 40 hours. It can
empty 1/40 of the pool in 1 hour.
In 2 hour, can empty a pool in 2/40 th of the
pool
Generally in t hours it can empty a pool in t/40
of the pool.
Second pump can empty the pool in 70 hours. So it
can empty a pool in t/70 of the pool in t hours.
Together the pumps can empty
t/40 t/70 of the pool in t hours.
The job will complete when the fraction of the
pool is empty equals 1.
The equation is
t/40 t/ 70 1
Multiply (40)(70)
(40)(70) t/40 t/ 70 1 (40)(70)
70t 40t 2800
110t 2800
t 2800/110 25.45 hr Two pumps can empty a
pool in 25.45 hr

123
Example 6( pg 412)

x speed of slower runner
x 2 the speed of the winner
d rt , t d/r
The time for slower runner 3/x, ran 3 miles
at x miles per hour
The winning time is 3/(x 2 ) , the winner
ran 3 miles at x 2 miles per hr
Add 3 minutes 3/60 1/20 hr to the winners
time, as finishes race 3 minutes ahead of another
runner which equals the slower runners time
3/(x2) 1/20 3/x
Multiply each side by the LCD, which is 20x(x
2)
20x(x 2)( 3/x 2) 1/20 20x(x 2)3/x
60x x(x 2) 60(x 2) Distributive
property
60x x 2 2x 60x 120 ,,
x 2 2x 120 0
(x 12)(x 10) 0 Factor
x - 12 or x 10 Zero
product property
Running speed cannot be negative. The slower
runner is running at 10 miles per hour, and the
faster runner is running at 12 miles per hour.

124
Ex 73 Pg 416

A tugboat can travel 15 miles per hour in still
water
36 miles upstream ( 15 x) Total
time 5 hours
downstream (15 x)
t d/r
So the equation is 36/(15 x) 36/ (15 x)
5
The LCD is (15-x)(15 x)
Multiply both sides we get
(15 x)(15 x)36/(15 x) 36/ (15 x) 5
(15 x)(15 x)
540 36x 540 - 36x 1125 5x 2
5x2 45 0
5x2 45
x 9, x 3 mph

125
Modeling electrical resistance (Ex- 8, pg 413)
R1 120 ohms R2 160 ohms
R
1/R 1/R1 1/R2 1/120 1/ 160
1/120 . 4/4 1/160 . 3/3 LCD 480
4/480 3/480 7/480 R 480/7 69
ohms
126
6.6 Proportion

a c is equivalent to ad bc
b d
Example 6 8
5 x
6x 40
or x 40/6 20/3

h/44 6/4 h 6.44/4 66 feet

6 feet h
feet

4 feet 44
feet
127
Modeling AIDS cases
Y 1000 (x 1981)2
1980, 1997, 2 by -10000, 800000, 100000
128

Chapter 7
Radical Expressions and Functions

129
Chapter 7

Square Root
The number b is a square root of a if b2 a
Example 100 102 10
radical sign
Under radical sign the expression is called
radicand
Expression containing a radical sign is called a
radical expression.
Radical expressions are 6, 5 x 1 ,
and 3x
2x - 1

130
Cube Root

The number b is a cube root of a if b3 a
Example Find the cube root of 27
3 27 3 33 3

131
Estimating a cellular phone transmission distance
R
The circular area A is covered by one
transmission tower is A R2

2 The total area covered by
10 towers are 10 R , which must equal
to 50 square miles Now solve R R 1.26, Each
tower must broadcast with a minimum radius of
approximately 1.26 miles
132
Expression

For every real number
If n is an integer greater than 1, then a1 n
n a
Note If a lt 0 and n is an even positive
integer, then
a1 n is not a real number.
If m and n are positive integer with m/n in
lowest terms, then
a m n n a m ( n a ) m
Note If a lt 0 and n is an even integer, then a
m n
is not a real number.
If m and n are positive integer with m/n in
lowest terms, then
a - m n 1/ a m n a 0

133
Properties of ExponentLet p and q be rational
numbers. For all real numbers a and b for which
the expressions are real numbers the
followingproperties hold. Page -467

a p . a q a p q Product rule
a - p 1/ a p
Negative exponents
a/b -p b a p Negative
exponents for quotients
a p a p-q
Quotient rule for exponents
a q
a p q a pq Power
rule for exponents
ab p a p b p Power rule
for products
a p a p Power
rule for products
b b p
Power rule for quotients

1 2 3 4 5 6 7
134

Product Rule for Radical Expressions
Let a and b be real numbers, where n a and n b
are both defined. Then
n a . n b n a. b
To multiply radical expressions with the same
index, multiply the radicands.

135
Quotient Rule for Radical Expressions

Let a and b be real numbers, where a and b are
both defined and b 0.
a/b a/b
The Expression a
If agt0, then a a

136
Square Root Property

Let k be a nonnegative number. Then the solutions
to
the equation.
x2 k
are x k. If k lt 0. Then this equation has
no real
solutions.

Ex 2, 3, 4, 5, 6
137
Technology
5, 13, 1 by 0, 100, 10
138
To find cube root technologically
139
Technologically

Y1 x2

-6, 6, 1 by -4, 4, 1
140
7.2 Let a and b be real numbers whereare both
defined
,

Product rule for radical expression (Pg 472)

Quotient rule for radical expression where b 0
(Pg 475)

141
Pg -476

Rationalizing Denominators having square roots

142
7.3 Operations on Radical Expressions

Addition
10 4 (10 4) 14
Subtraction

10 - 4 (10 - 4) 6
Rationalize the denominator (Pg 484)
143
7.6 Complex NumbersPg 513
x 2 1 0 x 2 -1 x
Square root property
- 1
Now we define a number called the imaginary unit,
denoted by i
Properties of the imaginary unit i
- 1
i
A complex number can be written in standard form,
as a bi, where a and b are real numbers. The
real part is a and imaginary part is b
144
Pg 513
a ib

Complex Number -3 2i 5 -3i -1
7i - 5 2i 4 6i

Real part a - 3 5 0
-1 -5 4
Imaginary Part b 2 0 -3
7 -2 6
145
Complex numbers contains the set of real numbers

Complex numbers
a bi a and b real

Real numbers a bi b0
Imaginary Numbers a bi b 0
Rational Numbers -3, 2/3, 0 and 1/2
Irrational numbers 3 And -
11
146
Sum or Difference of Complex Numbers