GED03 Chapter 2 (part1) PDF

Summary

This document is about mathematical language and symbols. It defines mathematical expressions and sentences used to communicate mathematical ideas, such as operations, terms, variables, and numerical coefficients.

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Chapter II

Mathematical
Language and
Symbols
GNED 03
MATHEMATICS IN THE MODERN WORLD
Intended
Learning
Outcome discuss the language, symbols, and
AFTER THE STUDENTS HAVE GONE THROUGH conventions of mathematics
THIS CHAPTER, THEY SHOULD BE ABLE TO: explain the nature of mathematics as a
language
perform operations on mathematical
expressions correctly; and
acknowledge that mathematics is a useful
language
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
 Language
THE SYSTEM OF WORDS, SIGNS
AND SYMBOLS WHICH PEOPLE USE
TO EXPRESS IDEAS, THOUGHTS
AND FEELINGS

Mathematical Language and Symbols | GNED03
 Mathematical
language
THE SYSTEM USED TO COMMUNICATE
MATHEMATICAL IDEAS INCLUDES A LARGE
COMPONENT OF LOGIC, NUMBERS,
MEASUREMENT, SHAPES, SPACES, FUNCTIONS,
PATTERNS, DATA, AND ARRANGEMENTS.

Mathematical Language and Symbols | GNED03
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
CHARACTERISTICS
OF MATHEMATICAL
LANGUAGE

mathematical language is non-temporal.
mathematical language is devoid of
emotional content
mathematical language is precise

Mathematical Language and Symbols | GNED03
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
MATHEMATICAL EXPRESSIONS
AND SENTENCES

Math words, expressions and sentences can help students explain what they think.

Addition, subtraction, multiplication, and division are
operations that can make up a mathematical expression
 MATHEMATICAL EXPRESSION MATHEMATICAL SENTENCE

Expresses an incomplete thought Expresses a complete thought

Contains no relation symbol Contains a relation symbol

A mathematical expression is only A mathematical sentence is
simplified simplified and solved

Mathematical Language and Symbols | GNED03
MATHEMATICAL EXPRESSION MATHEMATICAL SENTENCE
 Multivariate mathematical expressions
have more than one variable.

x
THIS SYMBOL IS RARELY USED
TO SHOW MULTIPLICATION

example
5xy + 9x – 12
31abc
y / 3x
 MATHEMATICAL EXPRESSIONS

TERMS VARIABLE NUMERICAL
(LITERAL COEFFICIENT) COEFFICIENT CONSTANT
separated from other
terms with either plus represents the unknown and The number with the Any single number
or minus signs makes use of letters variable
 CONSTANT
NUMERICAL COEFFICIENT

10x + 11
LITERAL COEFFICIENT
MONOMIAL 2a
BINOMIAL 5x + 12y
TRINOMIAL 3x + 2y – 36
A MATHEMATICAL EXPRESSION
POLYNOMIAL
WITH MORE THAN TWO TERMS
 MATHEMATICAL
SENTENCE
COMBINES TWO MATHEMATICAL EXPRESSIONS USING A COMPARISON OPERATOR
EQUAL, NOT EQUAL, GREATER THAN, GREATER THAN OR EQUAL TO, LESS THAN, AND LESS THAN OR EQUAL TO

RELATION SYMBOLS EQUATION INEQUALITY
the signs which convey a mathematical a mathematical
equality or inequality expression containing the expression containing the
equal sign inequality sign
EXAMPLES OF EQUATIONS EXAMPLES OF INEQUALITIES:

4x + 3 = 19 15x – 5 < 3y
6y – 5 = 55 18 > 16.5
10 + 1 = m 99 < x
(x+y+z) / 2 = 3 1 < x < 10
58 – q = 25 a + b + c ≤ 999
 open sentence
IT USES VARIABLES, MEANING THAT IT IS NOT KNOWN WHETHER THE
MATHEMATICAL SENTENCE IS TRUE OR FALSE

closed sentence
A MATHEMATICAL SENTENCE THAT IS KNOWN TO BE EITHER TRUE
OR FALSE
EXAMPLES OF OPEN SENTENCE:
▪ 2xy < 3y
▪ 18w > 16.5
▪ 3(m + n) = 100
▪ 8ab – c = 1 ▪ 4 – 3 = v
▪x+y=5 ▪ The obtuse angle is N degrees.
▪ 25m = n
▪ abc = 4
▪ 3x + 3y – 4z = 11
EXAMPLES OF TRUE CLOSED SENTENCE:
▪ 2(x + y) = 2x + 2y
▪ 18 (2) > 16.5
▪ 3(m + n) = (m + n) + (m + n) + (m + n)
▪ 8c – c = 7c
▪ 9 is an odd number.
▪ √25 = 5
▪ 10 – 1 = 9
▪6–6=0
▪ The square root of 4 is 2.
▪ g + g + 100 = 2g + 100
EXAMPLES OF FALSE CLOSED SENTENCE:
▪ 9 is an even number.
▪4+4=5
▪ 10 – 1 = 8
▪6–6=–1
▪ The square root of 4 is 1. ▪ d + 2d = 2d2
▪ y 0 = 2 ▪ (xyz)2 = 2xyz
▪ x + 2x + 3x = 10x
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
 CONVENTIONS IN THE
MATHEMATICAL LANGUAGE

CONTEXT CONVENTION
refers to the particular topics being studied and a technique used by mathematicians, engineers,
it is important to understand the context to scientists in which each particular symbol has
understand mathematical symbols. particular meaning
 GREEK AND LATIN LETTERS ARE USED AS SYMBOLS FOR
PHYSICAL QUANTITIES AND SPECIAL FUNCTIONS; AND
FOR VARIABLES REPRESENTING CERTAIN QUANTITIES

THE POSITION OF NUMBERS AND SYMBOLS IN RELATION
TO EACH OTHER HAS A BEARING ON THEIR MEANINGS.
USAGE OF SUBSCRIPTS AND SUPERSCRIPTS IS ALSO AN
IMPORTANT CONVENTION.
GUIDELINES IN TRANSLATING
STATEMENTS TO MATHEMATICAL
EXPRESSION/SENTENCE

READ AND UNDERSTAND THE
PROBLEM/TEXT ENTIRELY
SET VARIABLES FOR THE UNKNOWN
VALUES
LOOK FOR “KEYWORDS” ASSOCIATED
WITH MATHEMATICAL OPERATIONS
FAMILIARIZE YOURSELF WITH COMMONLY
USED MATHEMATICAL OPERATORS AND
SYMBOLS
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
VARIABLE
sometimes thought of as a mathematical
"John Doe" because you can use it as a
placeholder when you want to talk about
something but either you imagine that has
one or more values but you don't know
what they are.
 EXAMPLE
Is there a number with
following property: doubling
it and adding 3 gives the
same result as squaring it?
 EXAMPLE
Is there a number with
following property: doubling
it and adding 3 gives the
same result as squaring it?

Is there a number x with
property that 2x + 3 = x²?
 EXAMPLE
No matter what number
might be chosen, if it is
greater than 2, then its
square is greater than 4.
 EXAMPLE
No matter what number
might be chosen, if it is
greater than 2, then its
square is greater than 4.
No matter what number n might
be chosen, if n is greater than 2,
n² is greater than 4
Exercise
USE VARIABLES TO REWRITE THE
FOLLOWING SENTENCES MORE
FORMALLY.
ARE THERE NUMBERS WITH THE ARE THERE NUMBER A
PROPERTY THAT THE SUM OF THEIR AND B SUCH THAT A²
SQUARE EQUALS THE SQUARE OF + B² = (A+B)²?
THEIR SUM?
GIVEN ANY REAL NUMBER, ITS
FO R ANY REAL
SQUARE IS NONNEGATIVE
NUMBER R, R²≥0
 Set
A WELL-DEFINED COLLECTION
OF DISTINCT OBJECTS

The set of vowels in the English Alphabet
The set of counting numbers less than 20
The set of all letters in the word “Philippines”
 ELEMENTS
Objects or components that make up a set

Examples:
Let A be a set containing all the vowels in the English Alphabet. With this, the following
statements must be true:
Letter “u” is an element of set A since letter “u” is a vowel. In symbols, we can
express this as u∈A. The same applies to the letters “a”, “e”, “i”, and “o” since all of
these are vowels in the English Alphabet.
Letter “d” is not an element of set A since letter “d” is a consonant. In symbols, we
can express this as d ∉ A. "This applies, as well, to other consonants in the English
Alphabet.
 CARDINALITY OF A SET
refers to the number of elements a set has

Examples:
Consider the following sets:
Set G contains all the “ber” months
Set H contains all distinct letters in the word “MATHEMATICS”
Set I contains all perfect square numbers less than 100
THERE ARE TWO WAYS TO DESCRIBE A SET,
NAMELY:

Roster/Tabular
Method the elements in the given set are
listed or enumerated, separated by
a comma, inside a pair of braces.

Examples:
Let B be a set containing all the prime numbers between 1 and 10

B= {2, 3, 5, 7}
THERE ARE TWO WAYS TO DESCRIBE A SET,
NAMELY:

Rule/Descriptive
Method the common characteristics of the
elements are defined. This method
uses set builder notation where x is
used to represent any element of
the given set

Examples:
Let B be a set containing all the prime numbers between 1 and 10

B= {x|x is a prime number between 1 and 10}
TWO METHODS OF DESCRIBING SETS

Try to answer the following:

Let C be a set containing all months with 31 days. Express this set using
roster method
Let D be a set containing the elements red, yellow, and blue. Express
this set using rule method
Let E be a set containing the elements 2, 4, 6, and 8. Express this set
using rule method
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World
 FINITE SETS
sets with a limited number of elements; the last
element is specified

Examples:
The set of counting numbers less than 5
The set of all letters in the English alphabet
V= {a, e, i, o, u}
 INFINITE SETS
sets with an unlimited/infinite number of
elements; the last element cannot be specified

Examples:
The set of the stars in the sky
The set of all real numbers
E = {2, 4, 6, 8, 10, …}
EMPTY SET/NULL
SET/VOID SET
set that has no elements. It is expressed using the
symbols { } or ∅
 UNIVERSAL SET
the set of all possible elements at a given
situation

Examples:
Let a set be created containing all the possible
outcomes generated from rolling a die. With this, we
can say that:
U= {1, 2, 3, 4, 5, 6}
Let a set containing all the possible colors a student
can pick from a standard deck of cards be created.
With this, we can express the set as:
U= {red, black}
SET RELATIONS
 SUBSET
for any arbitrary sets A and B, set A is a subset of
B if every element of A is an element of B

SUPERSET
we can also say that B is a superset of A since B
contains every element of A.
 IMPROPER SUBSET
a subset containing all the elements of a given set
A is an improper subset of B
A ⊆ B

PROPER SUBSET
a subset containing elements of a given set
A is an proper subset of B
A ⊂ B
Examples:
Consider the following sets:
V= {a, e, i, o, u},
W= {a, e, i}, &
X= {x|x is a vowel in the English alphabet}.

W ⊂V W ⊂X V ⊆X X ⊆V
 EQUAL SETS
are sets containing the same elements

EQUIVALENT SETS
are sets with the same number of elements

Examples:
Consider the following sets:
A= {x|x is an odd number between 1 and 9}
B={a, b, c}
C={3, 5, 7}
 JOINT SETS
sets with at least one common element.

DISJOINT SETS
sets with no common elements

Examples:
Consider the following sets:
A={1, 3, 5}
B={2, 4, 6}
C={2, 3, 4}
 UNION
Union of Sets A and B (denoted by A ∪ B) is the
union of two sets A and B is the set of all elements
belonging to either set A or set B
In symbol: A ∪ B = {x | x ∈A or x ∈ B}

INTERSECTION
Intersection of sets A and B (denoted by A ∩
B) is
the intersection of two sets A and B is the set of
all elements belonging to both set A and set B.
In symbol: A ∩ ∈
B = {x | x A and x ∈B}
EXAMPLES
Consider the following sets:
P={1, 3, 5}
Q={2, 4, 7}
Evaluate the following set operations:
R={3, 5, 7} ∪
1. P Q
2. P∪R
3. P∩R
4. Q∩R
5. P∪Q∪R
6. P∩Q∩R
 DIFFERENCE
Difference of sets A and B (denoted by A – B) is a set
whose elements are found in Set A but not in Set B.
In symbol: {x | x ∈ A and x ∉
B}

COMPLEMENT
Complement of SetA (denoted by A’) is a set whose
elements are found in the universal set but not in Set A.
In symbol: A’ = {x | x ∈U and x ∉ A}
EXAMPLES
Consider the following sets:
U={0, 1, 2,3 , 4, 5, 6, 7, 8, 9}
M={1, 3, 5, 7, 9}
Evaluate the following set operations:
N={0, 6, 7, 8, 9} 1. M′
2. N′
3. M-N
4. N-M
∪
5. (M N)′
6. (M∩N)′
Venn-Euler Diagrams
(Venn Diagrams)
A-B B-A ∪∪
A B C

A′ B′ ∩∩
A B C
 USING VENN DIAGRAM IN SOLVING
PROBLEMS INVOLVING SETS
1. Seventy-five (75) students were asked about their preference over Math and English
subjects. It was found out that 40 of them prefers Math, 50 prefers English, and 28 prefers both
subjects. Determine the number of students who:
a. prefer Math only
b. prefer English only
c. prefer neither Math nor English subject

In order to solve the given problem using Venn Diagram, consider the
following steps:

1. Construct a
Venn diagram 2. Fill in the Venn Diagram with
appropriate values 3. Solve the problem
1. Construct a
Venn diagram

How many sets are there in the problem?
Are the sets given joint or disjoint?
1. Construct a
Venn diagram

How many sets are there in the problem?
Are the sets given joint or disjoint?

2. Fill in the Venn Diagram with
appropriate values

What is the cardinality of the universe (U)?
What are the given values which can
provide information about the cardinality
of each set?
What values should be placed in each
region in the Venn Diagram?
1. Construct a
Venn diagram

How many sets are there in the problem?
Are the sets given joint or disjoint?

2. Fill in the Venn Diagram with
appropriate values

What is the cardinality of the universe (U)?
What are the given values which can provide information
about the cardinality of each set?
What values should be placed in each region in the Venn
Diagram?

3. Solve the problem
How many students prefer Math only?
How many students prefer English only?
How many students prefer neither Math nor English?
Mathematical
Language and Symbols
CHAPTER II
GNED 03 | Mathematics in the Modern World