Numbers


I greet you this day,

First: Review the Notes/eText.
Second: View the Videos/Multimedia Resources.
Third: Practice questions and see instant feedback. NO Calculators allowed.
Fourth: Solve the questions/solved examples.
Fifth: Check your solutions with my thoroughly-explained solved examples.
Sixth: Check your answers with the calculators as applicable.

I wrote the codes for the calculators using JavaScript, a client-side scripting language and AJAX, a JavaScript library. Please use the latest Internet browsers. The calculators should work.
Comments, ideas, areas of improvement, questions, and constructive criticisms are welcome.

Samuel Dominic Chukwuemeka (SamDom For Peace) B.Eng., A.A.T, M.Ed., M.S


Objectives

Students will:


(1.) Define natural numbers.

(2.) Define whole numbers.

(3.) Define integers.

(4.) Define fractions.

(5.) Define decimals.

(6.) Define rational numbers.

(7.) Define irrational numbers.

(8.) Define real numbers.

(9.) Define complex numbers.

(10.) Define even numbers.

(11.) Define odd numbers.

(12.) Define prime numbers.

(13.) Define composite numbers.

(14.) Define perfect squares.

(15.) Define perfect cubes.

(16.) Define perfect numbers.

(17.) Define abundant numbers.

(18.) Write the symbols for some set of numbers.

(19.) Discuss the notations for representing real numbers.

(20.) Write whole numbers as rational numbers.

(21.) Write mixed numbers as rational numbers.

(22.) Determine if a given rational number is a repeating decimal.

(23.) Determine if a given rational number is a terminating decimal.

(24.) Order real numbers from least to greatest.

(25.) Order real numbers from greatest to least.

(26.) Add, subtract, multiply, and divide numbers.

(27.) Perform the order of operations involving numbers.

(28.) Solve applied problems involving numbers.


Skills Measured/Acquired


(1.) Use of prior knowledge

Ask students to list all the types of numbers they have ever used.
In what ways have they used these numbers? What did they use the numbers to do?

(2.) Critical Thinking

Ask students to list any other types of numbers they think that exists.
What other ways do they think they might use these numbers?
Why have they not used those numbers yet?
Some students may ask you to explain complex numbers.
Of what use are complex numbers? Are they "ever gonna" ever going to use complex numbers?
What disciplines of life may use complex numbers (the imaginary part of complex numbers)?
Can all real numbers be written as complex numbers?

(3.) Interdisciplinary connections/applications

Ask students to list their disciplines.
What kinds of numbers would they use primarily in their respective disciplines?
Why would they use those kinds of numbers?
In what way would those numbers be used?

(4.) Technology

Ask students if they could write programs that can list the different kinds of numbers.
Based on their responses, determine the next questions to ask. Would they be interested in writing such programs as independent class projects?
Another use of technology would be to write a program that tells the kind of number when a user inputs a number.

(5.) Active participation through direct questioning

Encourage students to ask questions. If they do not ask, ask them.
Please answer any questions students ask. If you do not know the answer, inform them you will get back with them after finding the answers.

(6.) Student collaboration in Final Project

Depending on the "student population", the final project may be independent project, or group project.


Vocabulary Words


natural number, counting number, whole number, fraction, numerator, denominator, proper fraction, improper fraction, rational number, integer, mixed number, decimal, terminating decimal, exact decimal, repeating decimal, recurring decimal, irrational number, real number, complex number, arithmetic, arithmetic operators, sum, difference, product, quotient, augend, addend, minuend, subtrahend, multiplier, multiplicand, factor, dividend, divisor, positive, negative, nonpositive, nonnegative, constant, number, variable, term, add, subtract, multiply, divide, expression, equation, equal, equality, inequality, left hand side (LHS), right hand side (RHS), end points, set notation, interval notation, braces, brackets, parenthesis, even number, odd number, prime number, perfect squares, perfect cubes, perfect number, abundant number, excessive number



Symbols and Meanings




Definitions


A natural number is any positive integer.

It is also known as a counting number. It is a number you can count.

It does not include zero.

It does not include the negative integers.

It is not a fraction.

It is not a decimal.


A whole number is any nonnegative integer.

It includes zero and the positive integers.

It does not include the negative integers.

It is not a fraction.

It is not a decimal.


An integer is any whole number or its opposite.

Integers include the whole numbers and the negative values of the whole numbers.

Ask students to explain:
(1.) The difference between a positive integer and a nonnegative integer
(2.) The difference between a negative integer and a nonpositive integer


A positive integer does not include zero but a nonnegative integer includes zero.
Nonnegative integers are the positive integers and zero.

A negative integer does not include zero but a nonpositive integer includes zero.
Nonpositive integers are the negative integers and zero.


A rational number is any number that can be written as a fraction where the denominator is not equal to zero.

You can also say that a rational number is a ratio of two integers where the denominator is not equal to zero.

A rational number is a number that can be written as:

$\dfrac{c}{d}$ where $c, d$ are integers and $d \neq 0$

A rational number can be an integer.

It can be a terminating decimal. Why?

It can be a repeating decimal. Why?

It cannot be a non-repeating decimal. Why?

Ask students to tell you what happens if the denominator is zero.


An irrational number is a number that cannot be expressed as a fraction, terminating decimal, or repeating decimal.

When you compute irrational numbers, they are non-repeating decimals.


A real number is any rational or irrational number.

It includes all numbers that can be found on the real number line.


A complex number is a number that can be expressed in the form of $a + bi$ where $a \:and\: b$ are real numbers, and $i$ is an imaginary number equal to the square root of $-1$.


An even number is any integer that is divisible by $2$ without a remainder.
These includes zero and numbers that are multiples of $2$.
Examples include: $2, 4, 6, 8, 10, 12, 70, 84$, etc.

Student: Is zero an even number?
Teacher: Yes, $0$ is an even number because it is divisible by $2$ without a remainder.
$0 \div 2 = 0$

In most contexts, we see even numbers as positive numbers. However, even numbers can also be negative.
Examples include: $-2, -4, -6, -8, -10, -12, -70, -84$, etc.


An odd number is any integer that is not a multiple of $2$.
Examples include: $1, 3, 5, 7, 9, 75$, etc.
In most contexts, we see odd numbers as positive numbers. However, odd numbers can also be negative.
Examples include: $-1, -3, -5, -7, -9, -75$, etc.


A prime number is a whole number greater than $1$, which is divisible by only $1$ and itself without a remainder.

Let us look at a prime number in another way...in terms of Factors and Multiples

$ Say: \\[3ex] 2 * 3 = 6 \\[3ex] 2\:\:is\:\:a\:\:factor\:\:of\:\:6 \\[3ex] 3\:\:is\:\:a\:\:factor\:\:of\:\:6 \\[3ex] 6\:\:is\:\:a\:\:multiple\:\:of\:\:2 \\[3ex] 6\:\:is\:\:a\:\:multiple\:\:of\:\:3 \\[3ex] NOTE: \\[3ex] 1\:\:is\:\:a\:\:factor\:\:of\:\:Everything \\[3ex] Everything\:\:is\:\:a\:\:multiple\:\:of\:\:1 \\[3ex] $ A prime number is a number whose factors are only $1$ and itself.
In other words, for a prime number: the only factors are $1$ and that number. No other number is a factor.

Examples include: $2, 3, 5, 7, 11, 13, 17, 19$, etc.


A perfect square is the square of a rational number.
Examples include: $1, 4, 9, 16, 25, 36$, etc.

$ 1^2 = 1 \\[3ex] 2^2 = 4 \\[3ex] 5^2 = 25 $


A perfect cube is the cube of a rational number.
Examples include: $1, 8, 27, 64, 125$, etc.

$ 1^3 = 1 \\[3ex] 2^3 = 8 \\[3ex] 5^3 = 125 $


A perfect number is a positive integer that is equal to the sum of its proper positive divisors.
Proper positive divisors refers to all divisors excluding that number.
Examples include: $6, 28$, etc.

$ Proper\:\: divisors\:\: of\:\: 6 = 1, 2, 3 \\[3ex] 1 + 2 + 3 = 6 \\[3ex] Proper\:\: divisors\:\: of\:\: 28 = 1, 2, 4, 7, 14 \\[3ex] 1 + 2 + 4 + 7 + 14 = 28 $


An abundant number is a positive integer in which the sum of its proper positive divisors is greater than the number.
Proper positive divisors refers to all divisors excluding that number.
An abundant number is also called an excessive number.
Examples include: $12, 18$, etc.

$ For\:\: 12 \\[3ex] Proper\:\: divisors\:\: of\:\: 12 = 1, 2, 3, 4, 6 \\[3ex] Sum = 1 + 2 + 3 + 4 + 6 = 16 \\[3ex] 16 \gt 12 \\[5ex] For\:\: 18 \\[3ex] Proper\:\: divisors\:\: of\:\: 18 = 1, 2, 3, 6, 9 \\[3ex] Sum = 1 + 2 + 3 + 6 + 9 = 21 \\[3ex] 21 \gt 18 $


Two numbers are amicable (amicable numbers) if each is the sum of the proper divisors of the other.
Examples are: $220\:\:and\:\:284$, $5050\:\:and\:\:5564$, etc.

$ Proper\:\:divisors\:\:of\:\:\color{red}{220} = 1, 2, 4, 5, 10, 11, 20, 22, 44, 55, 110 \\[3ex] 1 + 2 + 4 + 5 + 10 + 11 + 20 + 22 + 44 + 55 + 110 = \color{red}{284} \\[3ex] Proper\:\:divisors\:\:of\:\:\color{blue}{284} = 1, 2, 4, 71, 142 \\[3ex] 1 + 2 + 4 + 71 + 142 = \color{blue}{220} $


A fraction is a part of a whole.

It is the part of something out of a whole thing.

It is also seen as a ratio.

It is also seen as a quotient.

The numerator is the part.

It is the "top" part of the fraction.

The denominator is the whole.

It is the "bottom" part of the fraction.

A proper fraction is a fraction whose numerator is less than the denominator.

An improper fraction is a fraction whose numerator is greater than or equal to the denominator.


A mixed number is a combination of an integer and a proper fraction.


A decimal is a linear array of digits that represent a real number, expressed in a decimal system with a decimal point; and in which every decimal place indicates a multiple of negative power of 10.

A terminating decimal is a decimal with a finite number of digits.

A terminating decimal is also known as an exact decimal.

A repeating decimal is a decimal in which one or more digits is repeated indefinitely in a pattern or sequence.

A repeating decimal is also known as a recurring decimal.

A non-repeating decimal is a decimal in which there is no sequence of repeated digits indefinitely.

A non-repeating decimal is also known as a non-recurring decimal.


The basic arithmetic operators are the addition symbol, $+$, the subtraction symbol, $-$, the multiplication symbol, $*$, and the division symbol, $\div$

Augend is the term that is being added to. It is the first term.

Addend is the term that is added. It is the second term.

Sum is the result of the addition.

$$3 + 7 = 10$$ $$3 = augend$$ $$7 = addend$$ $$10 = sum$$

Minuend is the term that is being subtracted from. It is the first term.

Subtrahend is the term that is subtracted. It is the second term.

Difference is the result of the subtraction.

$$3 - 7 = -4$$ $$3 = minuend$$ $$7 = subtrahend$$ $$-4 = difference$$

Multiplier is the term that is multiplied by. It is the first term.

Multiplicand is the term that is multiplied. It is the second term.

Product is the result of the multiplication.

$$3 * 10 = 30$$ $$3 = multiplier$$ $$10 = multiplicand$$ $$30 = product$$

Dividend is the term that is being divided. It is the numerator.

Divisor is the term that is dividing. It is the denominator.

Quotient is the result of the division.

Remainder is the term remaining after the division.

$$12 \div 7 = 1 \:R\: 5$$ $$12 = dividend$$ $$10 = divisor$$ $$1 = quotient$$ $$5 = remainder$$


A constant is something that does not change. In mathematics, numbers are usually the constants.


A variable is something that varies (changes). In Mathematics, alphabets are usually the variables.


A mathematical expression is a combination of variables and/or constants using arithmetic operators.


A mathematical equation is an equality of two terms - the term or expression on the LHS (Left Hand Side) and the term or expression on the RHS (Right Hand Side).
This implies that we should always check the solution of any equation that we solve to make sure the LHS is equal to the RHS.
Whenever we solve for the variable in "any" equation, how do we know we are correct? CHECK!



Classify Numbers


Classify these numbers accordingly.

Questions Answers (Click "Answers:" to show/hide answers)
30
Answers:
$\dfrac{2}{5}$
Answers:
$\dfrac{5}{2}$
Answers:
$3\dfrac{2}{5}$
Answers:
−30
Answers:
0
Answers:
2.25
Answers:
1.3333333
Answers:
1.3333333...
Answers:
$1.\bar{3}$
Answers:
0.4527272727...
Answers:
$0.45\overline{27}$
Answers:
0.23759456287...
Answers:
$\dfrac{22}{7}$
Answers:
π
Answers:
3 + 7i
Answers:


Student: Mr. C, you wrote that $\dfrac{22}{7}$ is a rational number and $\pi$ is an irrational number.

Is the value of π not equal to $\dfrac{22}{7}$?

Teacher: The value of &pi is approximately equal to $\dfrac{22}{7}$

That is the approximate value.
It is not the exact value.
$\dfrac{22}{7}$ is a rational number because it a ratio of two numbers.

Any number that can be expressed as a ratio of two numbers is a rational number.


Add and Subtract Integers


NOTE:
$(1.)$ positive, add, plus mean the same thing. There is no difference.
$(2.)$ negative, subtract, minus mean the same thing. There is no difference.

Clear all confusions.
$2 + 3$ is read as: two plus three, two added to three, the sum of two and three

$2 + -3$ = $2 + (-3)$ is read as: two plus negative three, two plus minus three (not "two plus-minus three" $2\pm3$), two added to negative three, two added to minus three, the sum of two and minus three, the sum of two and negative three

$2 - 3$ is read as: two minus three, two subtract three, three subtracted from two, the difference between two and three

$2 - - 3$ = $2 - (-3)$ is read as: two minus minus three, two minus negative three, negative three subtracted from two, two subtract negative three, two subtract minus three, the difference between two and negative three, the difference between two and minus three

$-2 - 3$ is read as: minus two minus three, negative two negative three, negative two minus three, minus two negative three, three subtracted from negative two, three subtracted from minus two, minus two subtract three, negative two subtract three, the difference between negative two and three, the difference between minus two and positive three

$-2 - -3$ = $-2 - (-3)$ is read as: minus two minus minus three, negative two minus negative three, negative two minus minus three, negative three subtracted from negative two, negative two subtract negative three, the difference between minus two and minus three, the difference between negative two and negative three, the difference between minus two and negative three

First Method: Basic Rules
Single Sign Between Integers

First Case: For two integers with "same/common" signs (positive-positive or negative-negative);
Add the integers
Put the common sign.

Example 1

$(1.)\:\: 2 + 3$
This is the same as saying $+2 + 3$
Add the two integers. $2 + 3 = 5$
Put their common sign. Their common sign is $+$
So, the answer is $+5$ = $5$

Example 2

$(2.)\:\: -2 - 3$
Add the two integers. $2 + 3 = 5$
Put their common sign. Their common sign is $-$
So, the answer is $-5$

Second Case: For two integers with "different" signs (positive-negative or negative-positive);
Subtract the smaller integer from the bigger integer
Put the sign of the bigger integer.

Example 3

$(3.)\:\: 2 - 3$
This is the same as saying $+2 - 3$
Smaller integer = $2$
Bigger integer = $3$
Subtract $2$ from $3$ means $3 - 2= 1$
Put the sign of $3$. The sign of $3$ is $-$. That is the sign before $3$
So, the answer is $-1$

Example 4

$(4.)\:\: -2 + 3$
Smaller integer = $2$
Bigger integer = $3$
Subtract $2$ from $3$ means $3 - 2= 1$
Put the sign of $3$. The sign of $3$ is $+$. That is the sign before $3$
So, the answer is $+1$ = $1$


Second Method: Samuel Chukwuemeka's (SamDom For Peace) Method
Method of "have" and "owe"

Single Sign Between Integers
$+$ = "have"
$-$ = "owe"

Examples

$(1.)\:\: 2 + 3 = +2 + 3$
Say you had $2 yesterday and you have $3 today.
So, altogether; you have $5
$2 + 3 = 5$

$(2.)\:\: 2 - 3 = +2 - 3$
Say you have $2, but you owe someone $3
The person asks you to pay back. You gave the person the $2 and said that was all you had.
Are you still owing the person, or do you have anything with you?
You still owe! That means the answer must be $-$ because you still "owe".
How much are you still owing? $1
$2 - 3 = -1$

$(3.)\:\: -2 + 3 = -2 + 3$
Say you owe someone $2, but you have $3
The person asks you to pay back. You gave the person the $2.
Are you still owing the person, or do you have anything with you?
You still have something left - a dollar! That means the answer must be $+$ because you still "have".
How much do you have? $1
$-2 + 3 = 1$

$(4.)\:\: -2 - 3$
Say you owe Mr. $A$ $2 yesterday and you owe Mr. $B$ $3.
So, altogether; you owe both of them. That means the answer must be $-$ because you still "owe".
How much do you owe altogether?
$5
$-2 - 3 = -5$

NOTE: These rules apply to the Addition and Subtraction of Numbers (not just Integers).

Ask students their preferred method. What are the reason(s) for that preferred method?
Ask them if they have any other method that could be used to add and subtract numbers.

What about Double Signs Between Integers?

Whenever you see double signs between integers, change it to a single sign first.

Then, solve it as we solved single signs between integers.
Change Double Signs Between Integers to a Single Sign:
(Please excuse me to use the word, "hate" to explain this.)
$+$ = "love"
$-$ = "hate"

$+(+) = ++ = love-love$: When you love to love someone, you love the person

$+(-) = +- = love-hate$: When you love to hate someone, you hate the person

$-(+) = -+ = hate-love$: When you hate to love someone, you hate the person

$-(-) = -- = hate-hate$: When you hate to hate someone, you love the person

This means that:

$ +(+) = ++ = + \\[3ex] +(-) = +- = - \\[3ex] -(+) = -+ = - \\[3ex] -(-) = -- = + \\[3ex] $ NOTE: These same rules apply to the Multiplication of Numbers.

$ + * + = + \\[3ex] + * - = - \\[3ex] - * + = - \\[3ex] - * - = + \\[3ex] $ NOTE: These same rules apply to the Division of Numbers.

$ + / + = + \div + = + \\[3ex] + / - = + \div - = - \\[3ex] - / + = - \div + = - \\[3ex] - / - = - \div - = + \\[3ex] $ Examples

$ (1.)\:\: -2 + (-3) = -2 - 3 = -5 \\[3ex] (2.)\:\: -2 - (-3) = -2 + 3 = 1 \\[3ex] (3.)\:\: -3 -(-2) = -3 + 2 = -1 $




Practice with That Quiz


Practice what you just learned.
Calculators are NOT allowed.

(1.) Visit the website: That Quiz

(2.) Under Integers, click Arithmetic

(3.) Set the Length to $50$

(4.) Set the Level to $50$

(5.) Check the boxes:
Addition
Subtraction
Negatives
Parenthesis

(6.) Go back to (4.) and set the Level to $100$



Scientific Notation


Scientific notation is a format in which a number is expressed as a number between 1 and 10 multiplied by a power of 10.
It is useful:
(1.) for writing large and small numbers because it offers a way to save space and avoid errors in calculations.
(2.) in making approximations because it provides a quick and easy way to decide if calculated values are reasonable.

For example:
(1.) What is the mass of an electron?
(Source: https://physics.nist.gov/cgi-bin/cuu/Value?me)
(a.) Write the exact value (standard notation). Can you really write it? 😊
(b.) Write the approximate value in scientific notation.

(2.) How far is the Earth from the Sun?
(Source: https://www.space.com/17081-how-far-is-earth-from-the-sun.html)
(a.) Write the exact astronomical unit.
(b.) Write the approximate astronomical unit in scientific notation.

Do you see the importance of using scientific notation?




Numbers Calculator (Answers are in Integers or Fractions)


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Numbers Calculator (Answers are in Integers or Decimals)


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