![Cardinality
Cardinality represent the number of elements in a
set. For example:
We have the set [1, 2, 3,]. What is the cardinality?
The Cardinality Is 3! There are three numbers in the
set, therefore, the cardinality is 3.
But now how will this apply to infinite sets.
More examples:
If we have [2, 4, 6, 8,] Cardinality is equal to 4
If we have [3, 4, 5,] Cardinality is equal to 3](https://image.slidesharecdn.com/howcantherebedifferentsizesofinfinity-120607102211-phpapp02/85/How-can-there-be-different-sizes-of-infinity-5-320.jpg)
How can there be different sizes of infinity
- 1. Is it really possible for there there be different sizes of infinity? Ricky Chubbs
- 2. Introduction I decided to take advantage of the sample topics and I found one that really caught my eye. Sizes of infinity? How can you compare two things that are infinite? How would you measure infinity? Is it really possible to have different sizes of infinity? ∞ - ∞ = 2? :S
- 3. What is infinite and finite? Infinity essentially means limitless, as oppose to it’s opposite anything finite, infinity is unbounded. Infinite can represent just about anything, but just to make things a little simpler we’ll just be treating infinity as a set of numbers. Infinity and well.....Not infinity :P
- 4. Georg Cantor Georg Cantor is one of the main contributors to the theory of having sizes of infinity. Instead of accepting the traditional theories concerning infinity, in the 19th century he and some other mathematicians formulated the set theory. The set theory suggests that the cardinality of different sets of infinity may differ. George Cantor invented a collection of transfinite ordinal and cardinal numbers that would describe the order type and a number set that doesn’t cover an absolute infinity.
- 5. Cardinality Cardinality represent the number of elements in a set. For example: We have the set [1, 2, 3,]. What is the cardinality? The Cardinality Is 3! There are three numbers in the set, therefore, the cardinality is 3. But now how will this apply to infinite sets. More examples: If we have [2, 4, 6, 8,] Cardinality is equal to 4 If we have [3, 4, 5,] Cardinality is equal to 3
- 6. Cardinal and Ordinal numbers I mentioned Georg Cantors Cardinal and Ordinal numbers earlier but I thought I improve of that just to help understanding. An ordinal number would be the order or way of counting the number within a set. A cardinal number is the number of elements within the set. Example using the positive set of integers (natural numbers) Ordinal number under the traditional order is: ω Cardinal number is: Aleph Null (unfortunately I couldn’t find the appropriate symbols)
- 7. Dedekind’s Approach Another very accomplished mathematician concerned with the set theory is Richard Dedekind. Dedekind’s approach takes place mainly by using one to one correspondence in order to formulate a size using the comparison of the 2 sets. The way I like to think about it is to think that you’re partnering each number up with itself then eliminating them. Which ever set has the most remaining cardinal numbers was the bigger size of infinity. Set 1: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20 Set 2: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23... Bigger
- 8. Still a little weird? Imagine having two enormous containers one holding apples and the other holding oranges. If you remove one apple and one orange at a time, at the end, we will either be left with apples, oranges, or nothing. Which ever crate contained more will have leftovers and it’s this set that will be greater in size. I know it’s a poor drawing :P Notice the same amount of apples and oranges are removed yet some oranges remain in the crate. This obviously shows that there were more oranges than apples.
- 9. Countably infinite? The are many different sets of infinity, the smallest one being the infinite set of natural numbers; (1, 2, 3, 4). The infinite set of natural numbers are a set of ordinal numbers that can easily be counted, although cardinality may not be a specific number this set could be counted one after another without a problem. One the other hand we also have sets of infinity that are too extensive to count. Few examples: Infinite set of natural numbers is countable Infinite set of both positive and negative integers is countable Infinite set of all the real numbers is uncountable.
- 10. Reals vs. Naturals As you may know both real numbers and natural numbers are sets of infinity when unbounded. Cantor used the argument that there is a higher cardinality for an infinite set of all real numbers than there are is for an infinite set of all natural numbers. Since the natural numbers miss both the rational numbers and the negative integers, the infinite set of real numbers is obviously greater in size the natural numbers. Just for the sake of saying it, there is an infinite amount of irrational numbers just between the numbers 1 and 0. And I think we just answered our question. So far the theory looks good, it makes sense and I personally agree, it could be possible to have different sizes of infinity.
- 11. Conclusion In conclusion we now have a basic understanding of how there can possibly be more than 1 size of infinity. All this theory points out that there are different ways to interpret infinity that will have different values. I understand think I’ve covered the basic concepts of the set theory of infinity, and I’ve discovered yes it is possible that there is more than one size of infinity.
- 12. Main Sources Browser: Internet Explorer Search Engine: Google Wikipedia: Infinity, finite, cardinality. http://www.math.grinnell.edu/~miletijo/museu m/infinite.html http://www.scientificamerican.com/article.cfm? id=strange-but-true-infinity-comes-in- different-sizes