Mathematical Language and Symbols (1) PDF

Summary

This document provides a presentation on mathematical language and symbols. It defines expressions, sentences, and various types of numbers. Different topics include unary and binary operations, propositions, truth tables, and quantifiers. The document also contains sections on logical connectives and implications.

Full Transcript

MATHEMATICAL
LANGUAGE AND
SYMBOLS
6.53

Chapter 2
LEARNING OBJECTIVES

Discuss the language, Evaluate mathematical
symbols, and conventions expressions correctly.
used in mathematics.

Explain the nature of Recognize that
mathematics as a language. mathematics is a useful
language.

2
KEYWORDS
Expressions vs.
Sentences
Sets
Logical
Functions Connectives
Relations Quantifiers
Unary and Negation
Binary
Operations Free and Bound
Variables
Propositions
Converse
Inverse
Contrapositive

3
 ENGLISH
NOUN SENTENCE
(name given to object of interest) (must state a complete thought)
SOMETIMES TRUE /
PERSON PLACE THING TRUE (T) FALSE (F)
SOMETIMES FALSE

Carol Manila Dog The capital of the The capital of
The dog is
Philippines is the Philippines is
black.
Manila Makati

MATHEMATICS
EXPRESSION SENTENCE
(name given to mathematical object (must state a complete thought)
of interest)
SOMETIMES TRUE /
TRUE (T) FALSE (F)
SOMETIMES FALSE
NUMBER SET FUNCTION MATRIX ORDERED PAIR
1+1=2 1 + 1 = 11 x=1
{8} f(x) 1 4 (x,y)
8 −2 3
THE LANGUAGE OF
MATHEMATICS
Mathematical language is precise
which means it is able to make very fine
distinctions or definitions among a set of
mathematical symbols.
It is concise because a
mathematician can express otherwise long
expositions or sentences briefly by using the
language of mathematics.
The mathematical language is
powerful, that is, one can express complex
thoughts with relative ease.
 EXPRESSIONS VS. SENTENCES
A sentence must contain a complete thought. In the English language an
ordinary sentence must contain a subject and a predicate. The subject contains a
noun or a whole clause.
“Manila” for example is a proper noun but is not in itself a sentence because it
does not state a complete thought. Similarly, a mathematical sentence must state a
complete thought.
An expression is a name given to a mathematical object of interest.
The term “1 + 2” is a mathematical expression but not a mathematical sentence.

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 EXPRESSIONS VS. SENTENCES

A mathematical expression is the mathematical analogue of an
English noun. That is, it is a correct arrangement of mathematical
symbols used to represent a mathematical object of interest (Burns,
n.d). It does not state a complete thought and it does not make sense to
ask if an expression is true or false. In mathematics areas, such as
Algebra, the most common expressions are numbers, sets, and
functions.

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 EXPRESSIONS VS. SENTENCES

A mathematical sentence is the mathematical analogue of an English
sentence. That is, it is a correct arrangement of mathematical symbols
that state a complete thought. Hence, it makes sense to ask if a
sentence is true, false, sometimes true, or sometimes false.

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CARDINAL ORDINAL NOMINAL
NUMBERS NUMBERS NUMBERS
CARDINAL NUMBERS

Used for counting and answer the question “how many?”
Cardinal Numbers Examples
The cardinality of a group represents the number of objects available in that group.
1. There are 6 clothes in the cupboard.
2. 4 cars are driving in a lane.
3. Anusha has 2 dogs and 1 cat as pets in her house.
In the above three examples, the numbers 6, 4, 2 and 1 are the cardinal numbers.
So basically it denotes the quantity of something, irrespective of its order. It defines
the measure of the size of a set but does not take account of the order.
ORDINAL NUMBERS

Tell the position of a thing in terms of first, second, third, etc.
Examples:
1. Anil came to 3rd position in a running competition.
2. The 6th chair is broken in a hall.
If several objects are mentioned in a list, the order of the objects is defined by
ordinal numbers. The adjective terms which are used to denote the order of
something are 1st, 2nd, 3rd, 4th, 5th, 6th, and so on.
Cardinal Numbers Ordinal Numbers

They are used to denote the rank or position or order
They are used for counting purposes
of something or someone

Examples: 1, 2, 3, 5, 6, 10, etc. Examples: 1st, 2nd, 5th, 6th, 9th, etc

Question: ‘Where’ or ‘Which’
Question type: ‘How many?’
For example: Where is this located in the field? Or
For example: How many balls are there?
Which position does it hold in the ground?
NOMINAL NUMBERS

Used only as a name, or to identify something (not as an actual value or position).
Examples:
1. The number at the back of Michael Jordan is “23”.
2. The postal zip code of Apalit is 2016.
3. The plate number of the car is EBX 528.
It is not for representing the quantity or the position of an object.
UNARY AND BINARY OPERATIONS
 UNARY OPERATIONS

The plus and minus signs may
not mean addition or subtraction
when they are attached before a
single number. Instead, they are
read as positive and negative signs.
When written this way, they are
called unary operations.

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 UNARY OPERATIONS

The positive sign is very much like
the addition operation but has a
different meaning when attached to
only one number.

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 UNARY OPERATIONS

For example;

+4 (read as ‘positive four’).
It does not really mean ‘add
four’. The value of four represented by
the number 4 is considered as a single
operand by the unary operator, ‘+’, and
that operation produces a value of
positive four.

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 UNARY OPERATIONS

The negative, (or opposite), sign is a
unary operator.

Consider this expression: -4. Technically
here, the negative sign operator
accepts a value of four as its operand
and produces a value of negative four.

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 UNARY OPERATIONS

In summary, unary operations involve
only one value.

Examples:

-5
sin x
cos 45˚
π
tan
3

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BINARY OPERATIONS
When “+” and “-” can act on two
operands, then it is called a binary operation.
Consider this expression:
3 – (-2)
in this expression, two operations are
present using the symbol ‘-’
the first symbol (left most), is the binary
subtraction operation.
the other (right before the integer 2) is
the unary negative sign operator.
BINARY OPERATIONS

An operation is binary if it takes two real
numbers as arguments to produce
another real number.
BINARY OPERATIONS

Examples:
Addition. 4 + 5 = 9
Subtraction. 10 – 8 = 2
Multiplication. 4 x 6 = 24
PROPERTIES of Two Binary Operations,
Addition and Multiplication, over the Set of
Real Numbers
PROPERTIES

Closure of Binary Operations

The product and the sum of any two real
numbers is also a real number.
PROPERTIES

Commutativity of Binary Operations

addition and multiplication of any two real
numbers is commutative.
PROPERTIES

Associativity of Binary Operations

given any three real numbers you may take
away two and perform addition or multiplication
as the case maybe and you will end with the
same answer.
PROPERTIES

Distributivity of Binary Operations

distributivity applies when multiplication is
performed on a group of two numbers added or
subtracted together.
PROPERTIES

Identity Elements of Binary Operations

the identity is the number that you add or
multiply to any real number and the result will be
the same real number.
PROPERTIES

Inverses of Binary Operations

the number that you add or multiply to get
the identity element.
 SOME FUNDAMENTALS OF LOGIC

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 While “logic” may simply refer to valid
reasoning
in everyday life, it is also one of the oldest and
most
foundational branches of mathematics, often
blurring the boundaries between mathematics and
philosophy.

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 Logic is the study of Truth and how we can
obtain universal Truths through mathematical
deduction. It is the most basic language of
mathematics, and the underlying principle of proof.

Mathematical logic and reasoning dates back
many thousand years, to ancient Egyptian architects
and Babylonian astronomers. Logical thinking also
developed independently in India and China.

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PROPOSITION
A proposition is a statement which is either True (T)
or False (F).
It must be one or the other and it cannot be both.
A proposition is the basic building block of logic. It is
defined as a declarative sentence that is either True or
False, but not both.

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PROPOSITION

Each of the following statements is a proposition:
1. The sun rises in the East and sets in the West.
2. 1 + 1 = 2
3. ‘b’ is a vowel.
All of the above sentences are propositions, where the first two are
Valid(True) and the third one is Invalid(False). Some sentences that do not
have a truth value or may have more than one truth value are not
propositions.

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TRUTH VALUE

Truth value is the attribute of the proposition as to
whether the proposition is true or false.

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TRUTH TABLE

A table that shows the truth value of a compound
statement for all possible truth values of its simple
statements.

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NEGATION

A statement is a negation of another if the word is not introduced
in the negative statement.

The action or logical operation of negating or making negative

Let P be a proposition. The negation of P is “not P” or ¬𝑃.
NEGATION

P ¬𝑃
T F
F T
LOGICAL CONNECTIVES

It is the mathematical equivalent of a conjunction in English.

“and” ∧

“or” ∨

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LOGICAL CONNECTIVES

If two statements are joined like P and Q, denoted by 𝑃 ∧ 𝑄, then
𝑃 ∧ 𝑄 is a statement that is true if and only if both P and Q are
true.

The statement 𝑃 ∨ 𝑄 is true if and only if P is true or Q is true, and
when they are both true.

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LOGICAL CONNECTIVES

P Q 𝑃∧𝑄 𝑃∨𝑄
F F F F
F T F T
T F F T
T T T T

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IMPLICATIONS

A relationship between two propositions in which the second is a
logical consequence of the first.

Suppose P and Q are propositions. The proposition 𝑃 ⇒ 𝑄 (read
as “if P, then Q”) is called an implication.

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IMPLICATIONS

P is called the premise and Q is called the conclusion.

“If it rains, then I bring my umbrella” is an implication.
“If it rains” is P or the premise
“I bring my umbrella” is Q or the conclusion.

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IMPLICATIONS

P implies Q

Q if P

Q is implied by P

Q only if P

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IMPLICATIONS

P Q 𝑃⇒𝑄
F F T
F T T
T F F
T T T

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IMPLICATIONS

A more complicated form of implication is the bi implication or
the biconditional denoted by the symbol ⇔.

The statement 𝑃 ⟺ 𝑄 is true if and only if both P and Q are
either both true or both false

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CONVERSE

Suppose P and Q are propositions. Given the
implication 𝑃 ⇒ 𝑄. Its Converse is Q ⇒ 𝑃.
INVERSE

Suppose P and Q are propositions. Given the
implication 𝑃 ⇒ 𝑄. Its Inverse is ¬𝑃 ⇒ ¬𝑄.
CONTRAPOSITIVE

Suppose P and Q are propositions. Given the
implication 𝑃 ⇒ 𝑄. Its Contrapositive is ¬𝑄 ⇒ ¬𝑃.
CONVERSE, INVERSE, CONTRAPOSITIVE
That is,
Given: If P then Q.

Inverse: If not P then not Q.
Converse: If Q then P.
Contrapositive: If not Q then not P.
P Q 𝑃⇒𝑄 Inverse Converse Contrapositive

¬𝑃 ⇒ ¬𝑄 Q⇒𝑃 ¬𝑄 ⇒ ¬𝑃

F F T T T T

F T T F F T

T F F T T F

T T T T T T
 A conditional statement consists of two parts, a
hypothesis/premise in the “if” clause and a conclusion in
the “then” clause.
For instance, “If it rains, then they cancel school.”

"It rains" is the hypothesis/premise.
"They cancel school" is the conclusion.
To form the converse of the conditional statement,
interchange the premise and the conclusion.

The converse of "If it rains, then they cancel
school" is "If they cancel school, then it rains."
To form the inverse of the conditional statement, take the
negation of both the premise and the conclusion.

The inverse of “If it rains, then they cancel school” is “If
it does not rain, then they do not cancel school.”
To form the contrapositive of the conditional statement,
interchange the premise and the conclusion of the inverse
statement.

The contrapositive of "If it rains, then they cancel
school" is "If they do not cancel school, then it does not
rain."
Statement If two angles are congruent, then they have the same measure.

Converse If two angles have the same measure, then they are congruent.

If two angles are not congruent, then they do not have the same
Inverse
measure.

If two angles do not have the same measure, then they are not
Contrapositive
congruent.
 If a quadrilateral is a rectangle, then it has two pairs of
Statement
parallel sides.

If a quadrilateral has two pairs of parallel sides, then it is a
Converse
rectangle. (FALSE!)

If a quadrilateral is not a rectangle, then it does not have
Inverse
two pairs of parallel sides. (FALSE!)

If a quadrilateral does not have two pairs of parallel sides,
Contrapositive
then it is not a rectangle.
QUANTIFIERS
Quantifiers are used to describe the variable(s) in a
statement.

Quantifiers are words, expressions, or phrases that
indicate the number of elements that a statement
pertains to. In mathematical logic, there are two
quantifiers: 'there exists' and 'for all.
UNIVERSAL QUANTIFIER

Is usually written in the English language as “for all” or “for
every”.
EXISTENTIAL QUANTIFIER

Is expressed in words as “there exists” or “for some”
https://calcworkshop.com/reasoning-proof/conditional-
statement/#:~:text=Example,as%20Math%20Planet%20accurately%20states.
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