Binomial theorem: Difference between revisions
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imported>Jitse Niesen (delete popular culture section; also see talk page) |
imported>Gaurav Banga (proof) |
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One way to prove this identity is by [[mathematical induction]]. | One way to prove this identity is by [[mathematical induction]]. | ||
'''Proof''': | |||
'''Base case''': n = 0 | |||
: <math> (x + y)^0 = \sum_{k=0}^0 {0 \choose k} x^{0-k} y^k = 1 </math> | |||
'''Induction case''': Now suppose that it is true for n : <math> (x + y)^n = \sum_{k=0}^n {n \choose k} x^{n-k} y^k, </math> and prove it for n + 1. | |||
:<math> (x+y)^{n+1} = (x+y)(x+y)^n \,</math> | |||
::::<math> = (x+y) \sum_{k=0}^n {n \choose k} x^{n-k} y^k \,</math> | |||
::::<math> = \sum_{k=0}^n {n \choose k} x^{n+1-k} y^k + \sum_{j=0}^n {n \choose j} x^{n-j} y^{j+1} \,</math> | |||
::::<math> = \sum_{k=0}^n {n \choose k} x^{n+1-k} y^k + \sum_{j=0}^n {n \choose {(j+1) -1}} x^{n-j} y^{j+1} \,</math> | |||
::::<math> = \sum_{k=0}^n {n \choose k} x^{n+1-k} y^k + \sum_{k=1}^{n+1} {n \choose {k -1}} x^{n+1-k} y^k \,</math> | |||
::::<math> = \sum_{k=0}^{n+1} {n \choose k} x^{n+1-k} y^k - {n \choose {n+1}} x^0 y^{n+1}+ \sum_{k=0}^{n+1} {n \choose {k -1}} x^{n+1-k} y^k - {n \choose {-1}}x^{n+1} y^0 \,</math> | |||
::::<math> = \sum_{k=0}^{n+1} \left[ {n \choose k} + {n \choose {k -1}} \right] x^{n+1-k} y^k \,</math> | |||
::::<math> = \sum_{k=0}^{n+1} {{n+1} \choose k} x^{n+1-k} y^k, </math> | |||
and the proof is complete. | |||
== The first several cases == | == The first several cases == |
Revision as of 03:00, 15 August 2008
In elementary algebra, the binomial theorem is the identity that states that for any non-negative integer n,
or, equivalently,
where
One way to prove this identity is by mathematical induction.
Proof:
Base case: n = 0
Induction case: Now suppose that it is true for n : and prove it for n + 1.
and the proof is complete.
The first several cases
Newton's binomial theorem
There is also Newton's binomial theorem, proved by Isaac Newton, that goes beyond elementary algebra into mathematical analysis, which expands the same sum (x + y)n as an infinite series when n is not an integer or is not positive.