Difference between revisions of "A choose b"
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− | == Pascal's Triangle == | + | == Binomial Theorem and Pascal's Triangle == |
Pascal's triangle is an array of numbers that represent binomial coefficients. It looks something like this: | Pascal's triangle is an array of numbers that represent binomial coefficients. It looks something like this: | ||
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And on and on... | And on and on... | ||
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+ | You may ask the question: What does this have to do with a choose b. Well, this triangle is the same as this: | ||
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+ | <math>\binom{0}{0}</math> | ||
+ | <math>\binom{1}{0} \binom{1}{1}</math> | ||
+ | <math>\binom{2}{0} \binom{2}{1} \binom{2}{2}</math> | ||
+ | <math>\binom{3}{0} \binom{3}{1} \binom{3}{2} \binom{3}{3}</math> |
Revision as of 20:01, 15 June 2019
Here is the formula for a choose b: . This is assuming that of course .
Contents
Why is it important?
a choose b counts the number of ways you can pick b things from a set of a things. For example . More at https://artofproblemsolving.com/videos/counting/chapter4/64.
a choose 2
Here is a list of n choose 2's
These are triangle numbers! My proof uses induction (assuming something is true unless proofed true or not true). Then Simplify:
More Simplify:
So now we have proved it. If you don't get what I did on the second step go to Proof Without Words on this wiki.
Pascal's Identity
Pascal's Identity states that
Here is the proof:
Binomial Theorem and Pascal's Triangle
Pascal's triangle is an array of numbers that represent binomial coefficients. It looks something like this:
1 1 1 1 2 1 1 3 3 1 1 4 6 4 1
And on and on...
You may ask the question: What does this have to do with a choose b. Well, this triangle is the same as this: