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Part 1 - Pre-Algebra Summary
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1/19/12
Table of Contents
1.
Numbers .................................................. 2
1.1.
1.2.
1.3.
1.4.
1.5.
1.6.
1.7.
1.8.
2.
Real Numbers.......................................... 7
2.1.
3.
PERCENT TO DECIMAL TO FRACTIONS ................................................................................................................. 12
Algebra .................................................. 13
6.1.
6.2.
6.3.
6.4.
6.5.
7.
OPERATIONS ........................................................................................................................................................ 11
Conversions ........................................... 12
5.1.
6.
DEFINITIONS .......................................................................................................................................................... 8
LEAST COMMON DENOMINATORS.......................................................................................................................... 9
OPERATIONS ........................................................................................................................................................ 10
Decimals ................................................ 11
4.1.
5.
OPERATIONS .......................................................................................................................................................... 7
Fractions ................................................. 8
3.1.
3.2.
3.3.
4.
NAMES FOR NUMBERS ........................................................................................................................................... 2
PLACE VALUES ...................................................................................................................................................... 3
INEQUALITIES ........................................................................................................................................................ 4
ROUNDING ............................................................................................................................................................. 4
DIVISIBILITY TESTS ............................................................................................................................................... 5
PROPERTIES OF REAL NUMBERS ............................................................................................................................ 5
PROPERTIES OF EQUALITY ..................................................................................................................................... 5
ORDER OF OPERATIONS ......................................................................................................................................... 6
DEFINITIONS ........................................................................................................................................................ 13
OPERATIONS OF ALGEBRA ................................................................................................................................... 14
SOLVING EQUATIONS WITH 1 VARIABLE.............................................................................................................. 15
SOLVING FOR A SPECIFIED VARIABLE .................................................................................................................. 16
EXPRESSIONS VS. EQUATIONS .............................................................................................................................. 17
Word Problems...................................... 18
7.1.
7.2.
7.3.
7.4.
7.5.
VOCABULARY ...................................................................................................................................................... 18
FORMULAS ........................................................................................................................................................... 19
STEPS FOR SOLVING ............................................................................................................................................. 20
RATIOS & PROPORTIONS ...................................................................................................................................... 21
GEOMETRY .......................................................................................................................................................... 22
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
1. Numbers
1.1. Names for Numbers
Real Numbers
(points on a number line)
Irrationals (can’t be written
as a quotient of integers)
  3.1415927....
2  1.41421356...
Rationals (can be written as a
quotient of integers)
3
4
4  2
1
3%  3
100
7
.7 
10
Integers
…,–3, –2, –1, 0, 1, 2, 3,…
Whole Numbers
0, 1, 2, 3, …
Natural Numbers
1, 2, 3…
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary



“AND”
TENTHS
HUNDREDTHS
2
1
.
1
2
1,000,000
100,000
10,000
1000
3
THOUSANDTHS
ONES
3
TEN-
TENS
4
THOUSANDTHS
HUNDREDS
5
Decimal
Point
THOUSANDS
6
THOUSANDS
HUNDRED-
7
TEN-
MILLIONS
8
THOUSANDS
TEN-MILLIONS
Place Values
10.000.000
4
1
10
1
1
1
1
100 1000 10,000
10
Place values – go up by powers of 10. 234 can be expressed as (2  100)  (3  10)  (4  1)
Commas – In numbers with more than 4 digits, commas separate off each group of 3 digits,
starting from the right. These groups are read off together.
Reading numbers – 123,406,009.023 = “One hundred twenty-three million, four hundred six
thousand, nine and twenty-three thousandths”
100
100,000,000
9
MILLIONS
HUNDRED-
1.2.
Page 3 of 22
1/19/12
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
1.3.
< Less than
> Greater than
 Less than or
equal to
 Greater than or
equal to
= Equal
 Not equal to



1.
2.
3.
4.
Inequalities
Mouth “eats” larger number
Represent numbers on a number line. The
number to the right is always greater
–7 –6
0
6 7
Convert numbers so everything is “the same” –
e.g. all decimals, all fractions with common
denominators, etc.
1.4.
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7>6
6<7
–7 <– 6
–6 > –7
–5/3 ? –.01
–.67 < –.01
–4/2 ? –10/4
–8/4 > –10/4
Rounding
Locate the digit to the right of the given place value
If the digit is  5, add 1 to the digit in the given place value
If the digit is < 5, the digit in the given place value remains
Zero/drop remaining digits
Round to the
nearest hundreds:
1220  1200
1255.12  1300
Round to the
nearest hundredths:
25.1254  25.13
25.1230  25.12
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
1.5.
Divisibility Tests
2
3
If last digit is 0,2,4,6, or 8
If sum of digits is divisible by 3
4
5
6
9
If number created by the last 2 digits is
divisible by 4
If last digit is 0 or 5
If divisible by 2 & 3
If sum of digits is divisible by 9
10
If last digit is 0
1.6.
Page 5 of 22
1/19/12
22, 30, 50, 68, 1024
123 is divisible by 3 since 1 + 2 + 3 = 6 (and 6 is
divisible by 3)
864 is divisible by 4 since 64 is divisible by 4
5, 10, 15, 20, 25, 30, 35, 2335
522 is divisible by 6 since it is divisible by 2 & 3
621 is divisible by 9 since 6 + 2 + 1 = 9 (and 9 is
divisible by 9)
10, 20, 30, 40, 50, 5550
Properties of Real Numbers
Commutative a + b = b + a
a – bb – a
For
Multiplication
ab = ba
Associative
(a+b)+c = a+(b+c)
(a–b)–c  a–(b–c)
(ab)c = a(bc)
(a  b)  c  a  (b  c)
Identity
0+a = a & a+0 = a
a + (–a) = 0 &
(–a) + a = 0
a–0=a
a  1=a & 1  a=a
1/a  a = 1 &
a  1/a =1 if a  0
a 1 = a
a(b + c) = ab + ac
a(b – c) = ab – ac
For Addition
Inverse
Distributive
Property
For Subtraction
a–a=0
1.7.
For Division
a/b  b/a
a  a = 1 if a  0
–a(b + c) = –ab – ac –a(b – c) = –ab + ac
Properties of Equality
Addition Property of Equality
If a = b then a + c = b + c
Multiplication Property of Equality
If a = b then ac = bc
Multiplication Property of 0
0  a = 0 and a  0 = 0
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
1.8.
Page 6 of 22
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Order of Operations
 SIMPLIFY ENCLOSURE SYMBOLS:
Absolute value , parentheses ( ), or brackets  
 If multiple enclosure symbols, do innermost 1st
 If fraction, pretend it has ( ) around its
numerator and ( ) around its denominator
3 2  12
2  3( 2  1) 
3  2  12
2( 3(3))
6  12

2( 9)

18
18
 1
Evaluate x 2 for x  5
(means the base is  5, not 5!
It's very helpful to put the value
of the variable in parentheses)
x 2  ( 5) 2  ( 5)( 5)  25

 CALCULATE EXPONENTS
(Left to Right)
( 5) 2  ( 5)( 5)  (25)  25
5  52  25
2
5  52  25
2
 PERFORM MULTIPLICATION & DIVISION
5  2  10  30  10  2
(Left to Right)
 5  20  3  2
 PERFORM ADDITION & SUBTRACTION
 5  20  6
(Left to Right)
 5  ( 20)  6
 15  6
 9
 SIMPLIFY FRACTIONS
5
5
1
24 6  2  2 2


36 6  3  2 3
30 3  10 10
1


OR 3
9
3  3
3
3
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
Page 7 of 22
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2. Real Numbers
2.1.
Absolute
Value
x
Addition
+
Subtraction
_
Operations
 The DISTANCE (which is always
positive) of a number from zero on
the number line
 If the signs of the numbers are the
SAME, ADD absolute values
 If the signs of the numbers are
DIFFERENT, SUBTRACT absolute
values
 The answer has the sign of the
number with the largest absolute
value
 Change subtraction to ADDITION OF
THE OPPOSITE NUMBER
 ADD numbers AS ABOVE
Multiplication  MULTIPLY the numbers
 DETERMINE THE SIGN OF THE

ANSWER

Division

(Divisors
 zero)
If the number of negative signs
is EVEN, the answer is POSITIVE
 If the number of negative signs
is ODD, the answer is NEGATIVE
 DIVIDE the numbers
 DETERMINE THE SIGN of the answer
by using the MULTIPLICATION SIGN
RULES AS ABOVE
2 2
 2  2
2  2
 2  2
0 0
 2   (2  2)  4
2
3  ( 2)  1
addend addend sum
2  3  1
3  ( 2)  5
3  ( 2)  1
3  2  3  ( 2)  1
minuend subtrahend difference
2  ( 3)  2  3
3  2  3  ( 2)
3  ( 2)  3  2
3  2  3  2  (3)(2)  6
factor factor product
( 3)( 2)  6
3  2  3  ( 2)  (3)( 2)  6
( 3)( 2)( 2)  12
( 12)  ( 2)  6
dividend divisor quotient
(  12)/2  6
2 12  6
Exponential
Notation



Double
Negative
A exponent is a shorthand way to
show how many times a number
(the base) is multiplied by itself
An exponent applies only to the
base
Any number to the zero power is 1
 The opposite of a negative is
30  1
31  3
32  3  3  9
2  52  2  5  5
( 2  5)2  2  2  5  5
22  2  2 (base is 2)
( 2) 2  2  2 (base is  2)
(  x )  1( 1  x )  x
POSITIVE
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
Page 8 of 22
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3. Fractions
3.1.
Fractions
Proper fraction
Improper fraction
Mixed number
Factor
Prime Number
Composite Number
Prime Factorization
Factor Tree
Lowest Terms
3
1
or 1
2
2
Equivalent
1 5

2 10
Definitions
 Numerator/denominator
o Numerator < Denominator
2/7
o Numerator > Denominator
–7/2
 Integer + fraction
–3 ½
 A whole number that divides into another
Factors of 18:
number
1, 2, 3, 6, 9, & 18
 A whole number > 1 whose only factors are 1
2, 3, 5, 7, 11, 13…
and itself
 A whole number > 1 that is not prime
4, 6, 8, 9, 10…
 A composite number written as a product of
18  2  3  3
prime numbers
 A method for determining prime factorization
18
of a number
3 6
2 3
 Numerator and denominator have NO
12
26
1


COMMON FACTORS other than 1. Reduce
36 2  3  6 3
fractions by cancelling common factors.
4 x  8y
 If the numerator and/or denominator has
NO!!
4
addition or subtraction, it is not in factored
form. No cancelling of factors
 Numbers that represent the same point on a
2 x

number line
3 27
 Multiplying a number by any fraction equal
 2   9  x 18
    

to 1 does not change the value of the number
3   9  27 27

(see Multiplication Identity)
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
3.2.
Least Common
Multiple (LCM)
(Smallest number that
the given numbers will
divide into)
Least Common Denominators
 METHOD 1 (USE THE LARGEST NUMBER)
Ex. Find the LCM of 4,6,9
1. Start with the largest number. Do the
other numbers divide into it?
2. If yes, you’re done!
3. If no, double the largest number. Do the
other numbers divide into it?
4. If yes, you’re done!
5. If no, triple the largest number. Do the
other numbers divide into it?
6. Keep going until you’re done
 METHOD 2 (PRIME FACTORIZATION)
1. Determine the prime factorization of
each number
2. The LCM will have every prime factor
that appears in each number. Each
prime factor will appear the number of
times as it appears in the number which
has the most of that factor.
 METHOD 3 (L METHOD)
Least Common
Denominator (LCD)
Page 9 of 22
1/19/12
1. Find a number that divides into at least
two of the numbers
2. Perform the division
3. Repeat steps 1 & 2 until there are no
more numbers that divide into at least
two of the numbers
4. Multiple the leftmost and bottommost
numbers together
 The smallest positive number divisible by
all the denominators. The LCD is also the
LCM of the denominators.
9, no
18, no
27, no
36, YES

Ex. Find the LCM of 4,6,9
4
6
9
2 2
2 3
3 3
LCM = 2  2  3  3
= 36
Ex. Find the LCM of 4,6,9
34 6 9
2423
2 13
LCM = 3  2  2  1  3 = 36
1 1
,
,
4 6
LCD = 36
Ex.
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9
Part 1 - Pre-Algebra Summary
3.3.
Page 10 of 22
1/19/12
Operations
Convert mixed numbers to improper fractions & solve as fractions
Denominator  0; Always write final answer in lowest terms
 If the DENOMINATORS are the SAME:
Addition/
1 2 1
 
 COMBINE NUMERATORS
Subtraction
4 4 4
 Write answer over common denominator
+–
 If the DENOMINATORS are DIFFERENT:
1 1

LCD = 4
 Write an equivalent expression using the
4 2
LEAST COMMON DENOMINATOR
1 1  2  1 2 1
     
 ADD/SUBTRACT (see “If the
4 22 4 4 4
DENOMINATORS are the SAME”)
 FACTOR numerators and denominators
Multiplication
2 25 2  5  5 5



 Write problem as one big fraction

5 6 5  2  3 3
 CANCEL common factors
 MULTIPLY top  top & bottom  bottom
 RECIPROCATE (flip) the divisor
Division
2
5  2  6  2  25
 MULTIPLY the fractions (See Multiplication)

6
5 25 5 6
25
1. Numerator  Denominator
7
Converting an

2. Whole-number part of the quotient is the
Improper
2
whole-number part of the mixed number.
Fraction to a
 ( 7)  2
Mixed Number
Remainder
is the fractional part.
 3 remainder 1
Divisor
1
 3
2
1. If the mixed number is negative, ignore the sign
Converting a
1
3
in step 2 and add the sign back in step 3
Mixed Number
2
to an Improper 2. (Denominator  whole-number part) +
2  31  7
numerator
Fraction
7
Answer to step 2

3.
2
Original denominator
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
Page 11 of 22
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4. Decimals
4.1.
Addition/
Subtraction
+–
Multiplication

Operations
 LINE UP the decimals
 “Pad” with 0’s
 Perform operation as though they were whole
numbers
 Remember, the decimal point come straight down
into the answer
 Multiply the decimals as though they were whole
numbers
 Take the results and position the decimal point so the
number of decimal places is equal to the SUM OF THE
NUMBER OF DECIMAL PLACES IN THE ORIGINAL
PROBLEM
 If the DIVISOR contains a DECIMAL POINT
 MOVE THE DECIMAL POINT TO THE RIGHT so that
the divisor is a whole number
 MOVE THE DECIMAL POINT IN THE DIVIDEND THE
Division

SAME NUMBER OF DECIMAL PLACES TO THE RIGHT
 Divide the decimals as though they were whole
numbers
 The decimal point in the answer should BE STRAIGHT
ABOVE THE DECIMAL POINT IN THE DIVIDEND
To Multiply by
Powers of 10
(shortcut)
To Divide by
Powers of 10
(shortcut)
 Move the DECIMAL POINT TO THE RIGHT the same
number of places as there are zeros in the power of 10
 Move to the right because the number should get
bigger (Add zeros if needed)
 Move the DECIMAL POINT TO THE LEFT the same
number of places as there are zeros in the power of 10
 Move to the left because the number should get
smaller (Add zeros if needed)
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
1.5  .02  .4
 1.50
.02
.40
1.92
1.4  1.5
 14  15
 210.
 2.1
.02 .25
12.5
2 25.0
2
05
4
10
10
0
67.6  100
 67.60
 6760.
67.6 / 1000
 067.6
 .0676
Part 1 - Pre-Algebra Summary
Page 12 of 22
1/19/12
5. Conversions
5.1.
Percent to Decimal to Fractions
To Percent*
From
Percent*
To Decimal
Drop the % sign & divide
by 100. (move the decimal
point 2 digits to the left)
123%
1.23
To Fraction
Write the % value over 100.
Always reduce. 123/100
 If there is a decimal
point, multiply
numerator &
denominator by a power
of 10 to eliminate it.
90.5 90.5 10 905 181



100 100 10 1000 200

If there is a fraction part,
write the percent value
as an improper fraction
5
5
5
35 1
35
5 %= 6 

6
100 6 100 600
From
Decimal
Multiply by 100 (move the
decimal point 2 digits to the
right) & attach the % sign
1.234
123.4%
From
Fraction
Method 1 - To express as a Perform long division
mixed number – multiply by
0.1666
100
6 1.0000
.167
50
6
1 100 1  100
40


36
6 1
6
3
40
2
36
 16 %
40
3
36
Method 2 - To express as a
4
decimal – convert to
decimal & multiply by 100
.167  100 = 16.7%
1
6
Write number part. Put
decimal part over place
value of right most digit.
Always reduce.
234
117
1
1
1000
500
“%” means “per hundred”
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
Page 13 of 22
1/19/12
6. Algebra
6.1.
Constant
Variable
Coefficient
Term




Like Terms

Linear Expression




Linear Equation
Definitions
A NUMBER
A LETTER which represents a number
A NUMBER associated with variable(s)
A COMBINATION of coefficients and variable(s), or a
constant
Each variable (including the exponent) of the terms is
exactly the same, but they don’t have to be in the same
order
One or more terms put together by a “+” or “–“
The variable is to the first power
Has an equals sign
The variable is to the first power
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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5
x
3x
–3x
–3x & 2x
–3x2 & 2x2
–3xy & 2xy
–3x + 3
–3x+ 3 = 1
Part 1 - Pre-Algebra Summary
6.2.
Page 14 of 22
1/19/12
Operations of Algebra
Addition/
Subtraction
+–
(Combining Like
Terms)
Only COEFFICIENTS of LIKE TERMS are
combined
 Underline terms (or use box &
circle ) as they are combined
4 x  3x  x
Multiplication/
Division

COEFFICIENTS AND VARIABLES of ALL
TERMS are combined
(4 x )( 3 x )  12 x 2
 3 x y  2 x y  3  5 x y  3
2 xyz  3xy Can't be combined
2 y2  y
Can't be combined
( 3xy )( 2 xy )(3)  18 x 2 y 2
(2 xyz )(3 xy )  6 x 2 y 2 z
(2 y 2 )( y )  2 y 3
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
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Part 1 - Pre-Algebra Summary
6.3.
Solving Equations with 1 Variable
ELIMINATE FRACTIONS

Multiply both sides of the equation by the LCD
REMOVE ANY GROUPING SYMBOLS SUCH AS PARENTHESES

Use Distributive Property
SIMPLIFY EACH SIDE

Combine like terms
GET VARIABLE TERM ON ONE SIDE & CONSTANT TERM ON OTHER SIDE

Use Addition Property of Equality (moves the WHOLE term)
ELIMINATE THE COEFFICIENT OF THE VARIABLE

2x  1
x0
3
 3   (2 x  1)

 3
 x   0 
 
 1  3

1
2 x  1  3x  0
Ex. Solve
2 x  1  3x  0
2 x  1  3x  0
x 1  0
x 11  0 1
 x  1
 1 (  x )  ( 1)  1
x 1
Use Multiplication Property of Equality (eliminates PART of a
term)
CHECK ANSWER 

Page 15 of 22
1/19/12
Substitute answer for the variable in the original equation
2(1)  1
 (1)  0
3
00
Note: Occasionally, when solving an equation, the variable “cancels out”:
 If the resulting equation is true (e.g. 5 = 5), then all real numbers are solutions.
 If the resulting equation is false (e.g. 5 = 4), then there are no solutions.
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
6.4.
Solving for a Specified Variable
CIRCLE THE SPECIFIED VARIABLE
TREAT THE SPECIFIED VARIABLE AS THE
ONLY VARIABLE IN THE EQUATION & USE THE
STEPS FOR SOLVING LINEAR EQUATIONS
1.
2.
3.
4.
Page 16 of 22
1/19/12
Eliminate fractions
Remove parenthesis
Simplify each side
Get variable term on one side & constant
term on other side (use
addition/subtraction)
5. Eliminate the coefficient of the variable
(use multiplication/division)
6. Check answer 
5
TC +32
9
for TC , where TC is the temperature is Celsius
and TFis the temperature in Fahrenheit
5
TF -32= TC +32-32
9
9
9 5
   TF -32  =   TC
5
5 9
Ex. Solve TF =
9
   TF -32  = TC
5
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
6.5.
Definition
Equivalent
Expand
Opposite of factoring –
rewrite without parenthesis
Factor
Opposite of expanding –
rewrite as a product of smaller
expressions
Cancel
Only within a fraction in
factored form
Expressions vs. Equations
Expressions
Equations
One or more terms put together by Expression=Expression
a “+” or “–“
Ex. x 2  2 x  1  0
Ex. x 2  2 x  1
Same solution
Evaluate both for x = 2 & get
same answer
Ex. x 2  2 x  1  0  2
2
Ex. x  2 x  1
2 x2  4 x  2  0
2
 x  3x  x  1
Ex. 2( x  1)
Often used in solving equations
 2x  2
Ex. 2 x  2
Often used in solving equations
 2( x  1)
2 ( x  2)
3
2
 x23
Cancelling common factors (top
Simplify/
& bottom) & collecting like terms
Evaluate/
Add/Subtract/
2 ( x  2)
Ex.
3
Multiply/Divide
42
An equalivent expression with
x 2 6 x 8

 
a smaller number of parts
2
2
2
~denominators stay when adding
fractions
Ex. Evaluate
Evaluate for a number
Substitute the given number
x 2 for x  2
(put it in parenthesis) &
 base is  2, not 2!
simplify
( 2) 2
Ex.
= (  2)  (  2)
4
Solve
Page 17 of 22
1/19/12
Often used in solving equations
Often used in solving equations
~denominators are eliminated
when simplifying equations
Used to check answers
Ex. Evaluate
0  x  2 for x  2
0  ( 2)  2
00
so  2 is a solution
Find all possible values of the
Ex. x  2  0
variable(s)
x  2
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
Page 18 of 22
1/19/12
7. Word Problems
7.1.
Addition
Subtraction
Multiplication
Division
General
Percent Word
Problems





















Vocabulary
The sum of a and b
The total of a, b, and c
8 more than a
a increased by 3
a subtracted from b
The difference of a and b
8 less than a
a decreased by 3
1/2 of a
The product of a and b
twice a
a times 3
The quotient of a and b
8 into a
a divided by 3
Variable words
Multiplication words
Equals words
50% of 60 is what
50% of what is 30
What % of 60 is 30
a+b
a+b+c
a+8
a+3
b–a
a–b
a–8
a–3
(1/2)a
ab
2a
3a
a b
a/8
a/3
what, how much, a number
of
is, was, would be
50%  60 = a
50%  a = 30
(a%)  60 = 30
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
7.2.
Commission
Sales Tax
Total Price
Amount of Discount
Sale Price
Simple Interest
Percent increase/decrease







Formulas
Page 19 of 22
1/19/12
Commission = commission rate  sales amount
Sales tax = sales tax rate  purchase price
Total price = purchase price + Sales tax
Amount of discount = discount rate  original price
Sale price = original price – Amount of discount
Simple interest = principal  interest rate  time
 amount of increase/decrease 
Percent increase/decrease = 
  100
original amount


Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
7.3.
 UNDERSTAND THE PROBLEM
 As you use information, cross it out or
underline it.
 Remember units!
 NAME WHAT x IS
Steps for Solving
Kevin’s age is 3 years more than twice Jane’s age.
The sum of their ages is 39. How old are Kevin
and Jane?
Let x = Jane’s age (years)
 Start your LET statement
 x can only be one thing
 When in doubt, choose the smaller thing
 DEFINE EVERYTHING ELSE IN TERMS OF x
 WRITE THE EQUATION
 SOLVE THE EQUATION
 ANSWER THE QUESTION
 Answer must include units!
 CHECK
Page 20 of 22
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2x + 3 = Kevin’s age
Kevin's age + Jane's age = 39
2 x  3  x  39
3 x  3  39
( 3 )  3 x  3  39  ( 3)
 1  3x 36  1 

 
 
1  3
 3 1
x  12
Jane’s age = 12 years
Kevin’s age = 2(12) + 3
= 27 years
12  27  39 
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
Part 1 - Pre-Algebra Summary
7.4.
Ratios & Proportions
Rate
Ratio


The quotient of two quantities
Used to compare different kinds of rates
Proportion

A statement that TWO RATIOS or RATES are
EQUAL

Cross
Product
(shortcut)



Page 21 of 22
1/19/12
On a map 50 miles is represented by 25 inches.
10 miles would be represented by how many
inches?
Method for solving for x in a proportion
Multiply diagonally across a proportion
If the cross products are equal, the proportion is
true. If the cross products are not equal, the
proportion is false
1 person
2 gallons
,
100 people 50 miles
10 (miles) 50 (miles)

x (inches) 25 (inches)
10 50

x 25
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]
10  25  50  x
250  50 x
250
x
50
5 x
Part 1 - Pre-Algebra Summary
7.5.
Terminology
Formulas
Perimeter/
Circumference
Area

Surface Area

Volume

Square
s


l



Rectangle
w

Parallelogram



Trapezoid


Geometry
Measures the length around the outside of the figure (RIM);
the answer is in the same units as the sides
Measures the size of the enclosed region of the figure; the
answer is in square units
Measures the outside area of a 3 dimensional figure; the
answer is in square units
Measures the enclosed region of a 3 dimensional figure; the
answer is in cubic units
PERIMETER: P = 4s
AREA: A = s2
(s = side)
PERIMETER: P = 2l + 2w
AREA: A = lw
(l = length, w = width)
DEFINITION: a four-sided figure with two pairs of parallel
sides.
PERIMETER: P = 2h + 2b
AREA: A = hb
(h = height, b = base)
DEFINITION: a four-sided figure with one pair of parallel
sides
PERIMETER: P = b1 + b2 + other two sides
AREA: A = ((b1 + b2) / 2)h
(h = height, b = base)
Rectangular Solid


SURFACE AREA: A =2hw + 2lw + 2lh
VOLUME: V = lwh
(l = length, w = width, h = height)
Circle


CIRCUMFERENCE: C = 2  r
AREA: A =  r2

SURFACE AREA: A =  d 2
4
VOLUME: V =  r 3
3
d
r
Sphere


Triangle a
c
h
b

Page 22 of 22
1/19/12
 r = radius, d = diameter, r  12 d 
PERIMETER: P = a + b + c
1
AREA: A  bh
2
Copyright © 2006-2012 Sally C. Zimmermann. All rights reserved.
[email protected]