[Self-Study] FNDMATH Module 1 Handout - Basic Algebra.pdf

Transcript

Lesson 1

FNDMATH

Lecture 1
Algebraic Expressions
Integer Exponents
Addition/Subtraction of Algebraic Expressions
Multiplication/Division of Algebraic Expressions

1

1

CONSTANTS AND VARIABLES
CONSTANT
Any symbol whether it be a number or a
letter which is used to represent a fixed
value
VARIABLE
A single letter may represent a set of real
numbers the values of which depend upon
the situation or problem being analyzed
The value of the letter is not fixed

2

FNDMATH 1
Lesson 1

ALGEBRAIC EXPRESSIONS
An expression involving constants/or variables
with all or some of the four algebraic operation
of addition, subtraction, multiplication and
division

example
2 xy 2 x3
Monomial

3

ALGEBRAIC EXPRESSIONS
TERM
Each monomial in an expression

BINOMIAL
An expression is composed only of two terms

MULTINOMIAL
An expression is composed of more than two terms

4

FNDMATH 2
Lesson 1

DEGREE OF MULTINOMIAL
DEGREE OF A TERM
With respect to a literal factor is the exponent of
that literal factor in the term

3x2 y3z
x = 2nd degree
y = 3rd degree
z = 1st degree

5

POWERS AND EXPONENTS
2 x3 y2 2  x3  y2
Factors of expressions
POWER
Composed of a base and an exponent

EXPONENT
Small number written at the upper right hand
corner of the base
It indicates how many times the base occurs as a
factor

6

FNDMATH 3
Lesson 1

POWERS AND EXPONENTS
For every b , n  R (n, a positive integer)

b n  b  b  b  b  b  b...b
bn is read as “nth power of b” or
“b raised to the nth power”

x 2 x y  x yz   2xxx y yz
 2 x3 y2z

7

RULES FOR POSITIVE INTEGRAL EXPONENTS

1. For every a , m , n  R (m, n a positive integer)

a m  a n  a mn

1. 2 x 2 y   3 x y 4

2. 4 w 2 z 3  2 wz  5 w3 z 2 

8

FNDMATH 4
Lesson 1

RULES FOR POSITIVE INTEGRAL EXPONENTS

2. For every a,m,n  R (m > n ) (a ≠ 0)

am
n
 a mn
a

27 x5z6w 7
1.
12 x2z 4w

9

RULES FOR POSITIVE INTEGRAL EXPONENTS

3. For every a,b,m  R (m> 0 )

a b 
m
 a mbm

1. 3 a b c 
3

10

FNDMATH 5
Lesson 1

RULES FOR POSITIVE INTEGRAL EXPONENTS

4. For every a,b,m  R (m> 0 ); (b ≠ 0)
m
 a  am
   m
 b  b

7
 x 
1. 
 yz 

11

RULES FOR POSITIVE INTEGRAL EXPONENTS

5. For every a,m,n  R (m,n > 0 )

a 
n
m
 a mn

1.  2 x 2 y 3 z 
3

12

FNDMATH 6
Lesson 1

EXAMPLES
Simplify the following expressions using the rules on positive
integer exponents. All exponents in the answers must be
positive

1. 25 x2 y 24 x5 y2 15 x2 y 4
6.
25x3 y
 3  r s 2t 4   3  r 4 s t 5
4 4
2.
3w 2v 2
7.
3. 4 3 n 1  8 5 n 1  1 2 w 5v 7

2 a n 6 a m   3 2 
2 2
4. x3 y5
8.
16 x5 y3
m
5. x  x 5m  x 2m
 3 a b c   4 a b c 
2 4 2 3

9.
2 4 a b c 
2 5 2 3

13

 3  rs 2t 4   3  r 4 s t 5 4 3 n 1  8 5 n 1
4 4
2. 3.

15x2 y4
6 a 
2
4. 2a n m 6.
25 x3 y

14

14

FNDMATH 7
Lesson 1

 3 2 
2
x3y5
8.
16 x5 y3

 3 a b c   4 a b c 
2 4 2 3

9.
2 4 a b c 
2 5 2 3

15

15

ADDITION AND SUBTRACTION OF ALGEBRAIC EXPRESSIONS
MONOMIALS
Addition and subtraction of monomials can be done only if
the monomials to be added are similar.
To add or subtract similar terms, use the reverse of the
distributive rule to factor out the common literal parts and
then add or subtract their numerical parts

Example: (ADD)

1. x2y  3x2y  9x2 y 5x2 y5z
 3x2 y5z
 7 x2 y5z

16

FNDMATH 8
Lesson 1

ADDITION AND SUBTRACTION OF ALGEBRAIC EXPRESSIONS
MONOMIALS
Example: (SUBTRACT)

3.  1 0 a 2b 4. 4x2 y  2 y 5x  x  3  6x  2x2 
  3a 2b

17

ADDITION AND SUBTRACTION OF ALGEBRAIC EXPRESSIONS
MULTINOMIAL
If the multinomial to be added or to be subtracted do not
contain any similar terms, no combination of terms among
the multinomial can be done.
Combination is made easier if similar terms are arranged
first, and then, the terms in each column are added or
subtracted

18

FNDMATH 9
Lesson 1

ADDITION AND SUBTRACTION OF ALGEBRAIC EXPRESSIONS
MULTINOMIAL
Example: (ADD)
2
1. 3 x y  2 x 2 y  x y 2  3;  2 x y  5 xy  6 x  4 x 2 y;
7  2 xy 2  4 x  2 xy

Arrange in descending power of x
2 x 2 y  3 xy 2  2 x  4

19

MULTIPLICATION OF ALGEBRAIC EXPRESSIONS
MULTINOMIAL BY A MONOMIAL
If the multinomial is to be multiplied by a monomial, the
distributive rule is used.
The product is the sum of all the products formed by
multiplying each term of the multinomial by monomial
multiplier

EXAMPLE: 1. 2 x y 2 3 x 2  2 y  5 

20

FNDMATH 10
Lesson 1

MULTIPLICATION OF ALGEBRAIC EXPRESSIONS
MULTINOMIAL BY A MULTINOMIAL
The distributive rule is once more used to multiply two
multinomial

EXAMPLE:
1. 2 x  3y  x 2  3 xy 

21

MULTIPLICATION OF ALGEBRAIC EXPRESSIONS
MULTINOMIAL BY MULTINOMIAL
EXAMPLE:
2.  3 m 3  m 2  2 m  5  m 2
 5m  6

3m 3
 m 2
 2m  5
m 2
 5m  6
3m 5
 m 4
 2m 3
 5m 2

15m 4
 5m 3
 10m 2
 25m
18m 3
 6m 2
 12m  30
3m 5
 14m 4
 25m 3
 m 2
 37m  30

22

FNDMATH 11
Lesson 1

DIVISION OF ALGEBRAIC EXPRESSIONS
MONOMIAL BY A MONOMIAL
Divide a monomial by another monomial use the
fundamental theorem fractions or rules of exponent.
Zero exponent
For each a  R a  0
a0  1

EXAMPLE:
16 x2 y 2 2  8 x 22
1. 
24 x2 y5 3  8 y 52
2x0 2
 3
or
3y 3y3

23

DIVISION OF ALGEBRAIC EXPRESSIONS
MUTLINOMIAL BY A MONOMIAL
To divide a multinomial by a monomial use the distributive
rule and rules on exponent
EXAMPLE:
1
1.
6 x 2 y 3  12 xy  4 xy 2 
3 xy
6 x 2
y 3  12 xy  4 xy 2 
3 xy
6x2y3 12 xy 4 xy 2
  
3 xy 3 xy 3 xy
4
 2 xy 2  4  y
3

24

FNDMATH 12
Lesson 1

DIVISION OF ALGEBRAIC EXPRESSIONS
MUTLINOMIAL BY A MONOMIAL
Step 1:
Arrange the terms of the multinomial according to
descending powers of a literal factor common to both
dividend and divisor
Step 2:
Divide the first term of the dividend by the first term of
the divisor by applying rules on exponent during the
process and proceeding the arithmetic division
Step 3:
Repeat step 2 until the remainder is of a lower
degree(with respect to the chosen literal factor) than of
the divisor

25

DIVISION OF ALGEBRAIC EXPRESSIONS
MUTLINOMIAL BY A MULTINOMIAL
EXAMPLE: 1. 4 x 3 y  8 x 2 y 2  x y 3  y 4
d iv id e b y
2x  y

26

FNDMATH 13
Lesson 1

EXERCISES:
Perform the indicated operations and simplify
2
y  2x2 y  4x2 y 7. Divide
1. Add: x
2. Subtract: 1 5 w v from 1 2 w v
 11x 2

y  5 x 3  3 y 3  10 xy 2 by

3. Add: 3 x  2 y  4 z 4 y  2 x  using powers of y as
basis*
2x  3y  3z
8. 1 6 x 3  4 x 2  1 9
4x  5 y  7 z
d iv id e by
4. Subtract: 5 x 3
 7x  3 from 4x  5
3x  x 2
 5
5. ( 2 x 2 y 3 ) (  3 y z 2 )

6. 4 x 2 y 3 ( 2 x y 3  3 x z 2
)

27

1. x2 y  2x2 y  4x2 y 2. Subtract: 5x3  7 x  3 from

3x  x2  5

3. 4 x 2 y 3 (2 xy 3  3 xz 2 ) 4. 16 x3  4 x2  19
d iv id e by
4x  5

28

28

FNDMATH 14
Lesson 1

4. 16 x3  4 x2  19
d iv id e by
4x  5

29

29

Challenging problem…
9 m 3n  3 2 m 3
 42m 6
 15n 2  6  n
d iv id e by
7m 3
 5n  3

30

30

FNDMATH 15