Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Section 1.8
Document related concepts
Law of large numbers wikipedia , lookup
History of logarithms wikipedia , lookup
Foundations of mathematics wikipedia , lookup
Ethnomathematics wikipedia , lookup
Location arithmetic wikipedia , lookup
Infinitesimal wikipedia , lookup
Mathematics of radio engineering wikipedia , lookup
Georg Cantor's first set theory article wikipedia , lookup
Positional notation wikipedia , lookup
Surreal number wikipedia , lookup
Bernoulli number wikipedia , lookup
Large numbers wikipedia , lookup
Proofs of Fermat's little theorem wikipedia , lookup
Transcript
Section 1.8
The numbers that make up the set of Real
Numbers can be classified as
counting numbers
whole numbers
integers
rational numbers
irrational numbers
Each is said to be a subset of the real numbers.
Subsets of Real Numbers
The counting numbers are the numbers with which
we count. They are the numbers 1, 2, 3, and so on.
The notation we use to specify a group of numbers
like this is called set notation.
We use the curly braces { } to enclose the members
of the set.
We express the set of Counting Numbers as:
Counting numbers = {1, 2, 3, . . . }
Which of the numbers in the following set are not
counting numbers?
{–3, 0,
, 1, 1.5, 3}
The numbers –3, 0, , and 1.5 are not counting
numbers.
The whole numbers include the counting numbers and
the number 0.
Whole numbers = {0, 1, 2, . . . }
The set of integers includes the whole numbers and
the opposites of all the counting numbers.
Integers = { . . . , –3, –2, –1, 0, 1, 2, 3, . . . }
When we refer to positive integers, we are referring to
the numbers 1, 2, 3, . . . . Likewise, the negative integers
are –1, –2, –3, . . . . The number 0 is neither positive
nor negative.
The set of rational numbers is the set of numbers
commonly called “fractions” together with the
integers.
The set of rational numbers is difficult to list in the
same way we have listed the other sets, so we will
use a different kind of notation:
Rational numbers = {
| a and b are integers (b ≠ 0)}
If a number can be put in the form , where a and
b are both from the set of integers, then the number
is called a rational number.
So think of a rational numbers as:
Show why each of the numbers in the following set is a
rational number.
{–3,
, 0, 0.333 . . . , 0.75}
The number –3 is a rational number because it can be
written as the ratio of –3 to 1; that is,
The number
–2 to 3
can be thought of as the ratio of
The number 0 can be thought of as the ratio of 0 to 1
0
1
Any repeating decimal, such as 0.333 . . . (the dots
indicate that the 3's repeat forever), can be written
as the ratio of two integers.
0.333 . . . is the same as the fraction
Finally, any decimal that terminates after a certain
number of digits can be written as the ratio of two
integers.
The number 0.75 is equal to the fraction
therefore a rational number.
and is
There are other numbers that can be associated with
a point on the real number line, but cannot be
written as the ratio of two integers.
In decimal form these numbers never terminate and
never repeat.
They are called irrational numbers (because they are
not rational):
Irrational numbers = {non-repeating, nonterminating decimals}
Irrational numbers can’t be written in a form that
is familiar to us.
Irrational numbers cannot be written as the ratio
of two integers.
One example of an irrational number is π.
It is not 3.14. Rather, 3.14 is an approximation to π.
We use this approximation because we cannot
write π as a terminating decimal number.
Other representations for irrational numbers are
and, in general, the square root of any number
that is not itself a perfect square.
Every real number is either rational or irrational. (It
cannot be both!)
The set of Real Numbers is the set of all rational and
irrational numbers
Real numbers = {all rational numbers and all
irrational numbers}
Prime Numbers and Factoring
The following diagram shows the relationship
between multiplication and factoring:
When we read the problem from left to right, we say
the product of 3 and 4 is 12. Or we multiply 3 and 4 to
get 12.
When we read the problem in the other direction, from
right to left, we say we have factored 12 into 3 times 4,
or 3 and 4 are factors of 12.
The number 12 can be factored still further:
12 = 4 3
=223
= 22 3
The numbers 2 and 3 are called prime factors of 12
because neither of them can be factored any
further.
Here is a list of the first few prime numbers.
Prime numbers = {2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, . . . }
When a number is not prime, we can factor it into the
product of prime numbers.
To factor a number into the product of primes, we simply
factor it until it cannot be factored further.
What is the prime factorization of 210?
We can use a factor tree to factor 210 into a product of
primes
210 = 2 3 5 7
Factor the number 60 into the product of prime
numbers.
We begin by writing 60 as the product of any two
positive integers whose product is 60, like 6 and 10:
60 = 6 10
We then factor these numbers:
60 = 6 10 = (2 3) (2 5)
=2235
= 22 3 5
Reducing to Lowest Terms
Fractions can be reduced to lowest terms by
dividing the numerator and denominator by the
same number.
We will use the prime factorization of numbers to
help us reduce fractions with large numerators
and denominators.
Reduce
to lowest terms.
First we factor 210 and 231 into the product of
prime factors (using factor trees)
Factor the numerator and denominator completely
Then we reduce to lowest terms by dividing the
numerator and denominator by any factors they
have in common.
Divide the numerator and denominator by 3 7
Section 1.8
Page 85-88
# 1-10 All
# 19, 21, 23, 25, 29, 33, 37, 41, 45, 49
