Example of cardinal number


Cardinal Numbers - Meaning, Examples, Sets

Cardinal numbers are numbers that are used for counting. They are also known as natural numbers or cardinals. A set of cardinal numbers starts from 1 and it goes on up to infinity. We use cardinal numbers to answer the question "how many?". For example, how many students are going to the school picnic? The answer could be any number like 20, 23, 30, etc. So, all these numbers come in the category of cardinal numbers. In this article, we will explore the world of cardinal numbers and understand the difference between cardinal and ordinal numbers.

1. What are Cardinal Numbers?
2. Difference Between Cardinal and Ordinal Numbers
3. List of Cardinal Numbers from 1 to 100
4. Cardinal Numbers of a Set
5. FAQs on Cardinal Numbers

What are Cardinal Numbers?

A cardinal number describes or represents how many of something are present. Example 2 apples, 5 flowers, etc. It quantifies an object. It does not have values as fractions or decimals. Cardinal numbers are counting numbers, they help to count the number of items. Let's have a look at cardinal numbers examples. Ana wants to count the number of people standing in a queue at a billing counter. Can you help her? Ana started to count using Natural numbers.

Ana counted 1, 2, 3, 4, and 5. There are 5 people standing in a queue at the billing counter. Counting numbers are cardinal numbers! Now, Let's consider another example, Noah kept eight apples in a basket. The number eight denotes how many apples are there in the basket, irrespective of their order.

Examples of cardinal numbers are 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, and so on. The smallest cardinal number is 1 as 0 is not used for counting, so it is not a cardinal number.

Difference Between Cardinal and Ordinal Numbers

All the natural numbers are also referred to as cardinal numbers. Cardinal numbers are used for counting. While an ordinal number is a number that denotes the position or place of an object. Example: 1st, 2nd, 3rd, 4th, 5th, etc. Ordinal numbers are used for ranking. Here is an example that explains cardinal and ordinal numbers:

In the above image, we can see a team of 4 workers on the construction site. This is an example of cardinal numbers.

In the above image, we can see the position of the runners in the running event. First, second, third, and so on. This is an example of ordinal numbers. Let's discuss ordinal and cardinal number differences in the table below:

Cardinal Numbers Ordinal Numbers
They are counting numbers that represent quantity. They are based on the rank or position of an object in a given list or order.
Cardinal numbers give us the answer of 'how many?'. Ordinal numbers give us the answer of 'where'. For instance, where does the object lies in the list?
Examples are 1, 2, 3, 4, 5, 10, etc. Examples are 1st, 2nd, 3rd, 4th, 5th, 10th, etc.

List of Cardinal Numbers from 1 to 100

Given below are the basic and most important cardinal numbers, which form the base for other counting numbers.

1 - One 6 - Six
2 - Two 7 - Seven
3 - Three 8 - Eight
4 - Four 9 - Nine
5 - Five 10 - Ten
10 - Ten 60 - Sixty
20 - Twenty 70 - Seventy
30 - Thirty 80 - Eighty
40 - Forty 90 - Ninety
50 - Fifty 100 - Hundred

Given below is the list of all cardinal numbers from 1 to 100. It will also help you to see how we write cardinal numbers in words like 21- twenty-one.

Cardinal Numbers of a Set

In the case of a set, the cardinal number is the total number of elements present in it. In other words, the number of distinct elements present in a set is the cardinal number of the set. The cardinal number of a set A is represented as n(A). For example, the cardinal number of set W = {1, 3, 5, 7, 9} is n(W)=5, as there are 5 elements in it.

Think Tank:

  • Maria wrote January 1, 2020, as today’s date in her notebook. Does the number 1 in the date, represent a cardinal number?
  • There are _______ people in the line ahead of me. I am the 7th person in the line.

Important Notes:

  • Cardinal numbers help us to count the number of things or people in or around a place or a group.
  • The collection of all the ordinal numbers can be denoted by the cardinal.
  • Cardinal numbers can be written as words such as one, two, three, etc.
  • Cardinal numbers tell how many items, whereas ordinal numbers show position or ranking.

Related Articles

Check out these interesting articles to know more about cardinal numbers and its related articles.

  • Ordinal Numbers
  • Whole Numbers
  • Natural Numbers
  • Difference Between Natural and Whole Numbers

 

Cardinal Numbers Examples

  1. Example 1: Kate has a list of numbers as shown - 7, 8th, 10, Two, Fourth, 2nd. Identify the cardinal numbers.

    Solution:

    7, 10 and two help us in counting, whereas 8th, fourth and 2nd helps us in identifying the position. Thus, 7, 10, and two are cardinal numbers.

  2. Example 2: Help Ryan, to calculate the number of vowels in "NUMBERS". Also, identify the number of alphabets used to form this word.

    Solution:

    (i) We know that a, e, i, o, and u are the vowels and in the given word u and e are used. Therefore, 2 vowels are used to form this number (2 is the required cardinal number).

    (ii) We start counting from N to S, we see that "Numbers" has 7 alphabets in all. Therefore, a total of 7 alphabets are required to form the given word and here 7 is a cardinal number.

go to slidego to slide

Breakdown tough concepts through simple visuals.

Math will no longer be a tough subject, especially when you understand the concepts through visualizations with Cuemath.

Book a Free Trial Class

Practice Questions on Cardinal Numbers

 

go to slidego to slidego to slide

FAQs on Cardinal Numbers

What is a Cardinal Number Example?

Cardinal numbers are used for counting. Some examples of cardinal numbers are 1, 2, 3, 4, 5, 10, 15, 20, 30, 40, 50, 100, etc. In our daily life, we use cardinal numbers a lot. Even a small child uses this mathematical concept without knowing the term for it. They do count how many toys they have, how many people are there around them, how many friends they have, how many subjects do they study at school, etc.

What is the Smallest Cardinal Number?

The smallest cardinal number is 1 (one) as whenever we count, we always start from 1.

How do you Find Cardinal Numbers?

Cardinal numbers can be found by counting. We start by 1 and then go on as per the number sequence.

How is Cardinal Number Different from the Ordinal Number?

Cardinal numbers are numbers that represent the number of items(quantity) while ordinal numbers represent the rank or position of an item in the given list.

What is a Cardinal Number in Sets?

In set A, if there are a total of 25 elements then 25 is the cardinal number of set A represented by n(A).

Can Cardinal Numbers Negative?

No, cardinal numbers cannot be negative. They are positive integers or natural numbers, as we always count the number of items starting from number 1, and then it goes up to infinity.

Is Zero a Cardinal Number?

No, 0 is not a cardinal number as cardinal numbers represent quantity, and 0 means nothing or no quantity.

What is the Biggest Cardinal Number?

There are infinite natural numbers. Therefore, there are as many cardinal numbers as natural numbers. There can be no generalization of the biggest natural number and so does for the biggest cardinal number.

Cardinal Numbers - Explanation, Solved Examples and FAQs

What Are Cardinal Numbers?

Cardinal numbers are the generalization of natural numbers as it consists of all the counting numbers starting from one. Cardinal numbers are also called cardinals. The term cardinal numbers or cardinal was coined to represent the size of a set called cardinality (size) of sets. Cardinality is the number of elements present in a finite set which usually describes the size of the sets. For example, let us take two sets - Set A = {2, 4, 6, 8} and set B = {1, 2, 3, 5, 7}. The cardinality of set A is 4 as there are 4 elements present in set A whereas the number of elements present in set B is 5 so the cardinality of set B is 5. Cardinal tells us how many of something is present such as one, two, three, four, five, etc. 

Apart from cardinal numbers, there are two other numbers that are ordinal and nominal. Cardinal number tells us how many of something is present, ordinal number describes the position of things and nominal number usually represents the name. For example, there were 11 players playing a game where each player has a number printed on the shirt that represents him. Suppose player number 33 comes first. Then, in this case, the cardinal number is 11 because there are a total of eleven players, the ordinal number of the player who won is 1st and the nominal number is 33 as it represents the player who one. 

Summary

  • Cardinal Number (How many): 11

  • Ordinal Number (Position): 1st

  • Nominal Number (Name): 33

How Many Cardinal Numbers are There?

Cardinal numbers are used as counting numbers. Counting can be of less number of things or more number of things. For example, we can count the number of fans in a house, the number of sheep on the farm, the number of hairs in our head, or the number of stars in the sky. All can be counted by using numbers like one, two, three, four, and so on. The counting can go on to infinity but there are a limited number of digits used. Basically there are 10 digits used to represent any number and those digits are 1, 2, 3, 4, 5, 6, 7, 8, 9 and 0. Zero (0) alone is not a cardinal number. But zero can be used with other digits to represent numbers like 10, 20, 30, 700, 9000, etc.  The combination of numbers is used in series 1, 2, 3, 4, 5, 6, 7, 8, 9, 0. Once the number becomes double-digit, we change the ones of the number following the series. Example, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19. Here, the digit in tens place remains constant while the digit in one place follows the series. 

Once the series in one place reaches the end (i. e, 9), the digit in ten’s place is changed to a number of higher-order and the pattern is followed. Example, 20, 21, 22, 23, 24, 25, 26 27, 28, 29. The pattern is followed until one’s reaches 99. After all the numbers in two digits are over, three-digit numbers are followed. The three-digit number starts from 100 and goes on till 999. Three-digit numbers are followed by four-digit numbers and so on. Therefore, there is no limit to the cardinal numbers. 

Solved Examples

Example 1: Show how you can coordinate cardinal numbers with ordinal numbers?

Solution: Cardinal numbers and ordinal numbers can be coordinated as shown below:

Cardinals

Ordinals

Cardinals

Ordinals

1, One

1st, First

11, Eleven

11th, Eleventh

2, Two

2nd, Second

12, Twelve

12th, Twelfth

3, Three

3rd, Third

13, Thirteen

13th, Thirteenth

4, Four

4th, Fourth

14, Fourteen

14th, Fourteenth

5, Five

5th, Fifth

15, Fifteen

15th, Fifteenth

6, Six

6th, Sixth

16, Sixteen

16th, Sixteenth

7, Seven

7th, Seventh

17, Seventeen

17th, Seventeenth

8, Eight

8th, Eighth

18, Eighteen

18th, Eighteenth

9, Nine

9th, Ninth

19, Nineteen

19th, Nineteenth

10, Ten

10th, Tenth

20, Twenty

20th, Twentieth

Cardinal number | it's.

.. What is a cardinal number?

Aleph-zero, the smallest infinite cardinal.

Cardinal number or shortly cardinal in set theory is an object that characterizes the cardinality of a set. The cardinal number of any set A is denoted as | A | or Card A .

For a finite set A, the cardinal number |A| is a natural number, which means the number of elements of this set. For infinite sets, the cardinal number is a generalization of the concept of the number of elements.

Although the cardinal numbers of infinite sets are not reflected in natural numbers, they can be compared. Let A and B be infinite sets, then the following four cases are logically possible:

  1. A ~ B and | A |=| B |.
  2. There is a one-to-one correspondence between the set A and some own subset B' of set B . Then we say that the cardinality of the set A is not greater than the cardinality of the set B and write | A |≤| B |.
  3. The set A is equivalent to some subset of the set B , and vice versa, the set B is equivalent to some subset of the set A , that is, A ~ B' ⊆ B0009 B ~ A' A . According to the Cantor-Bernstein theorem, in this case, A ~ B is fulfilled, i.e. | A |=| B |.
  4. There is no one-to-one correspondence between set A and any subset of set B and there is also no one-to-one correspondence between set B and any subset of set A . It follows from this that the cardinalities of the sets A and B are not comparable.

However, deeper research in set theory has shown that, relying on the axiom of choice, it is possible to prove the impossibility of the existence of the fourth case.

Thus, the cardinalities of any two sets A and B are always comparable. That is, for cardinal numbers | A | and | B | arbitrary sets A and B , one of the three relations holds: | A |=|B|, | A |≤| B | or | B |≤| A |. If | A |≤| B |, but the set A is not equivalent to the set B , then | A |<| B |.

Contents

  • 1 Aleph numbers
  • 2 Continuum hypothesis
  • 3 See also
  • 4 Links

Aleph numbers

Cardinal number of set N all natural numbers (and hence any countable set) are denoted by (read "aleph-zero"). The cardinal number of continuum sets is denoted c or ("aleph-one"). The following cardinal numbers in ascending order denote Cantor proved that there is no set of the greatest cardinality, that is, there is no greatest cardinal number.

The Continuum Hypothesis

The Continuum Hypothesis states that there is no set whose cardinal number lies between the cardinal number of the set of natural numbers and the cardinal number of the set of real numbers , that is, < < .

See also

  • Power of set
  • Ordinal number
  • Cantor-Bernstein theorem
  • Continuum hypothesis

References

  • Hans Hahn, Infinity , Part IX, Chapter 2, Volume 3 of The World of Mathematics . New York: Simon and Schuster, 1956.
  • Paul Halmos, Naive set theory . Princeton, NJ: D. Van Nostrand Company, 1960. Reprinted by Springer-Verlag, New York, 1974. ISBN 0-387--6 (Springer-Verlag edition).
  • Weisstein, Eric W. Cardinal Number at Wolfram MathWorld .
  • Cardinality at ProvenMath formal proofs of the basic theorems on cardinality.
  • Undergraduate Set Theory more proofs about cardinality - includes proof of infinite cardinal addition in Section 4.2.

Power of the set, cardinal number (cardinal) of the set Discrete Mathematics....

Hi, You will learn about the power of the set, Let's analyze its main types and features of use. There will be many more detailed examples and descriptions. In order to better understand what is cardinality of a set, cardinal number of a set, cardinal number, cardinal, I highly recommend reading everything from the Discrete Mathematics category. Set Theory. Graph Theory. Combinatorics..

set cardinality , the cardinal number of a set (lat. cardinalis ← cardo “the main circumstance; basis; heart”) is a characteristic of sets (including infinite ones), generalizing the concept of the number (number) of elements of a finite set.

This concept is based on natural ideas about comparing sets:

  1. Any two sets, between whose elements a one-to-one correspondence (bijection) can be established, contain the same number of elements (have the same cardinality, are equivalent).
  2. Conversely, equivalent sets must allow such a one-to-one correspondence.
  3. Part of the set does not exceed the full set in cardinality (that is, in the number of elements).

Before the construction of the theory of cardinality of sets, sets differed in terms of features: empty/non-empty and finite/infinite, and finite sets also differed in the number of elements. Infinite sets could not be compared.

Cardinality of sets allows infinite sets to be compared. For example, countable sets are the "smallest" infinite sets.

The cardinality of a set is denoted by . Sometimes there are notations , and .

block diagram of the algorithm for determining the cardinality of a set

In set theory, the cardinal number or cardinal is called an object that characterizes the cardinality of a set. The cardinal number of any set A is denoted as | A | or Card A .

For a finite set A, the cardinal number |A| is a natural number, which means the number of elements of this set. For infinite sets, the cardinal number is a generalization of the concept of the number of elements.

Although the cardinal numbers of infinite sets are not reflected in natural numbers, they can be compared. Let A and B be infinite sets, then the following four cases are logically possible:

  1. A ~ B and | A |=| B |.
  2. There is a one-to-one correspondence between the set A and some own subset B' of the set B . Then they say that the cardinality of the set A is not greater than the cardinality of the set B and write | A |≤| B |.
  3. The set A is equivalent to some subset of the set B , and vice versa, the set B is equivalent to some subset of the set A , that is, A ~ B' B0242 and B ~ A' A . According to the Cantor-Bernstein theorem, in this case, A ~ B is fulfilled, i.e. | A |=| B |.
  4. There is no one-to-one correspondence between set A and any subset of set B , and there is also no one-to-one correspondence between set B and any subset of set A . It follows from this that the cardinalities of the sets A and B are not comparable.

However, deeper research in set theory has shown that, relying on the axiom of choice, it is possible to prove the impossibility of the existence of the fourth case.

Thus, the cardinalities of any two sets A and B are always comparable. That is, for cardinal numbers | A | and | B | arbitrary sets A and B , one of the three relations holds: | A |=|B|, | A |≤| B | or | B |≤| A |. If | A |≤| B |, but the set A is not equivalent to the set B , then | A |<| B |.

Definition

Assuming the axiom of choice to be true, the cardinality of a set is formally defined as the smallest ordinal number , under which a bijective correspondence can be established between and. This definition is also called the von Neumann distribution of cardinal numbers.

If the axiom of choice is not accepted, then a different approach is required. The very first definition of the cardinality of a set (it is implicit in Cantor's work and explicitly stated in Frege, as well as in Principia Mathematica) is the class of all sets that are equivalent in cardinality. In axiomatic systems based on the theory of ZFC, such a definition is inapplicable, since for non-empty such a collection is too large to fit the definition of a set. More precisely, if , then there is an injective mapping of the universal set into , under which each set goes to , whence, by virtue of the axiom of the size restriction, it follows that is a proper class. This definition can be used in type theory and "new foundations" [en] , as well as in related axiomatic systems. In the case of ZFC, the definition can be used by restricting the collection to the lowest-ranking equivalent sets (this trick, proposed by Dana Scott, works because the collection of objects that have a given rank is a set).

The formal order among cardinal numbers is introduced as follows: means that the set can be injectively mapped to . According to the Cantor-Bernstein theorem, it follows from the pair of inequalities and that . The axiom of choice is equivalent to the statement that for any sets and , at least one of the inequalities or .

A set is called Dedekind infinite [en] if it has a proper subset such that . Otherwise, the set is called Dedekind finite. Finite cardinal numbers coincide with ordinary natural numbers - in other words, the set is finite if and only if for some natural . All other sets are infinite. Subject to the axiom of choice, one can prove that the Dedekind definitions coincide with the standard ones. In addition, it can be proved that the cardinality of the set of natural numbers (alef-zero, or aleph-0 - the name is derived from the first letter of the Hebrew alphabet) is the smallest infinitely large cardinal number, that is, in any infinite set there is a subset of cardinality. The cardinal number next in order is denoted, and so on, the number of alephs is infinite. Any ordinal number corresponds to a cardinal number, and in this way any infinitely large cardinal number can be described.

Related definitions

  • The cardinality of the set of natural numbers is denoted by the symbol ("aleph-zero"). A set is called infinite if its cardinality is (not less than the cardinality of the set of natural numbers), so countable sets are the "smallest" of infinite sets. The next cardinal numbers in ascending order are denoted (where the index runs through all ordinal numbers). Among the cardinal numbers, there is no largest: for any set of cardinal numbers, there is a cardinal number that is greater than all elements of this set.
  • Sets that are equivalent to the set of all real numbers are said to have the cardinality of the continuum, and the cardinality of such sets is denoted by the symbol . The assumption that , is called the continuum hypothesis.
  • For powers, as in the case of finite sets, there are concepts: "equality", "greater", "less". That is, for any sets and only one of the three is possible:
    1. , or and are equivalent;
    2. , or is more powerful than , that is, it contains a subset that is equally powerful, but not equally powerful;
    3. , or more powerful - in this case, contains a subset that is equivalent to , but not equally powerful.
    • The situation in which and are not equivalent and none of them has a part that is equivalent to the other is impossible. This is indicated by the site https://intellect.icu. This follows from Zermelo's theorem. Otherwise, this would mean the existence of incomparable powers (which is possible in principle if one does not accept the axiom of choice).
    • The situation in which and is impossible by the Cantor-Bernstein theorem.
  • Sets and are called equivalent to if there exists a one-to-one mapping of a set onto a set .

Examples

  • A set is called finite if it is equivalent to a segment of the natural series for some non-negative integer . The number expresses the number of elements in the finite set. For , the set contains no elements (empty set). If , then there is no injective mapping from to (the Dirichlet principle), and hence there is no bijection between them. Therefore, the sets and have different cardinalities.
  • A set is called countable if it is equivalent to the set of all natural numbers. The countable sets are:
    • Set for any natural . Conformity: .
    • Set of . Conformity: .
    • The set of integers . Correspondence is obtained by comparing the terms of the series with its partial sums (the terms of the series are taken without taking into account the sign).
    • Set of pairs of natural numbers .
    • The set of rational numbers is mapped injectively into a set (an irreducible fraction of the form corresponds to a pair of numbers ). Therefore, the set of rational numbers is at most countable. But since it contains the set of natural numbers, it is at least countable. By the Cantor-Bernstein theorem, it is countable.
  • Infinite sets not equivalent to the set are called uncountable. According to Cantor's theorem, the set of infinite sequences composed of the digits 0 and 1 is uncountable. The cardinality of this set is called the continuum.
  • The cardinality of the set of real numbers is equal to the continuum.

Properties

  • Two finite sets are equivalent if and only if they consist of the same number of elements. That is, for a finite set, the concept of power coincides with the usual concept of quantity.
  • For infinite sets, the cardinality of the set can be the same as the cardinality of its own subset, for example .
  • Moreover, a set is infinite if and only if it contains an equally powerful proper (that is, not coinciding with the main set) subset.
  • Any infinite set is equivalent to the set of all its finite subsets.
  • Cantor's theorem The set of all subsets of the set A has more power than A , or .
    • In particular, there exists a set more powerful than any given one.
  • Using the Cantor square, one can also prove the following useful statement: The Cartesian product of an infinite set A with itself is equivalent to A .
  • Cartesian product power:

  • Inclusion-exclusion formula for two and three sets:

  • Power of the symmetric difference of two and three sets:

Arithmetic of cardinal numbers

Ordinary arithmetic operations on natural numbers can be generalized to the case of cardinal numbers. It can also be shown that in the case of finite cardinal numbers these operations coincide with the corresponding arithmetic operations on numbers. In addition, operations on cardinal numbers retain many of the properties of ordinary arithmetic operations.

The next cardinal number

Subject to the axiom of choice, for each cardinal number it is possible to determine the number following it, and there are no other cardinal numbers between and. If of course, then the next cardinal number is the same as . In the case of infinite, the next cardinal number is different from the next ordinal number.

Addition of cardinal numbers

If the sets and have no common elements, then the sum of cardinalities is determined by the cardinality of their union. If there are common elements, the original sets can be replaced by non-intersecting sets of the same cardinality — for example, by replacing with , and with .

Neutrality of zero regarding the addition:

Association:

CommetTativity:

Monotony (failure) addition to both arguments:

The sum of two infinite cardinal numbers can be easily calculated with the observation of the axiom of the choice . If one of the numbers or is infinite, then

Subtraction

Subject to the axiom of choice for any infinite cardinal number and arbitrary cardinal number, the existence of , for which , is equivalent to the inequality . This is unique (and coincides with ) if and only if .

Multiplication of fundamental numbers

The work of two cardinal numbers is expressed through the decartion of the sets:

Octos of zero:

Unit relative to multiplication:

9000 (non-decreasing) multiplication with respect to both arguments:

Distributivity of multiplication with respect to addition:

By analogy with addition, the product of two infinite cardinal numbers can be easily calculated if the axiom of choice is observed. If the numbers and are nonzero and at least one of them is infinite, then

Division

Subject to the axiom of choice, for any pair of cardinal numbers and , where is infinite and not equal to zero, the existence of , for which , is equivalent to the inequality . This is unique (and coincides with ) if and only if .

Exponentiation of cardinal numbers

Exponentiation is defined as follows:

,

where denotes the set of all functions from to .

(in particular), see the empty function

Monotony:

We note that it is the power of Bulean and, therefore, for any set (see Cantor's Diagonal Method). This implies that among the cardinal numbers there is no largest (since for any cardinal number, a larger number can be specified). In fact, the class of all cardinal numbers is proper (although in some axiomatizations of the theory, the set of this cannot be proved - such, for example, is the system of "New Foundations" [en]).

All subsequent statements in this section rely on the axiom of choice.

If and are finite numbers greater than 1, and is an infinite cardinal number, then If the cardinal number is infinite, and finitely different from zero, then .

If and , and at least one of them is infinite, then

.

Using Koenig's theorem, we can prove that for any infinite cardinal number the following inequalities hold:

,

where denotes confinality .

Extracting roots

Subject to the axiom of choice, for any infinite cardinal and finite cardinal there exists a cardinal number such that , and .

Logarithms

Subject to the axiom of choice, a cardinal number that satisfies the condition , given infinite and finite , does not always exist. If such exists, then it is infinite and less than , and any finite cardinal number will also satisfy the equality .

The logarithm of an infinite cardinal number is the smallest cardinal number that satisfies the condition. Despite the fact that the logarithms of infinitely large cardinal numbers lack some of the properties that are characteristic of the logarithms of positive real numbers, they turn out to be useful in certain areas of mathematics - in particular, in the study of cardinal invariants of topological spaces.

Continuum hypothesis

According to the continuum hypothesis, there are no other cardinal numbers between and. The cardinal number is also denoted and represents the cardinality of the continuum (that is, the set of real numbers). In this case . The generalized continuum hypothesis denies the existence of cardinal numbers strictly between and for any infinite set of . The continuum hypothesis is independent of the standard axiomatization of set theory, i.e. the Zermelo-Fraenkel axiom system combined with the axiom of choice (see Zermelo-Fraenkel set theory).

See also

  • Ordinal number
  • TRANSFINITE NUMBER

In general, my friend, you have overcome reading this article about the cardinality of the set.


Learn more


Wave

North Coast Community Services
710 Fraser Street, Prince Rupert, BC V8J 1P9
Ph: 250.627.7166 | Fx: 250.627.7482

© All Rights Reserved | powered by ExpressionEngine