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        riddles >> putnam exam (pure math) >> Binomial Theorem for Primes
        
(Message started by: Sir Col on Jun 5^th, 2004, 9:59am)

Title: Binomial Theorem for Primes
Post by Sir Col on Jun 5^th, 2004, 9:59am

Consider the following results,
7⁵ = 16807 [equiv] 2 mod 5
3⁵+4⁵ = 1267 [equiv] 2 mod 5

11⁷ = 19487171 [equiv] 4 mod 7
3⁷+8⁷ = 2099339 [equiv] 4 mod 7

Given that p is prime, and a,b[in][bbn], prove that in general, (a+b)^p [equiv] a^p+b^p mod p.

Title: Re: Binomial Theorem for Primes
Post by Grimbal on Jun 5^th, 2004, 6:34pm

Title: Re: Binomial Theorem for Primes
Post by Sir Col on Jun 6^th, 2004, 3:02am

on 06/05/04 at 18:34:35, Grimbal wrote:

Eh? I must have missed the lectures on "Proof by Smilies".

Title: Re: Binomial Theorem for Primes
Post by Grimbal on Jun 7^th, 2004, 3:00am

It seems to me you are obfuscating a much simpler equation. My smile says: I know.

::[hide]For p prime, a^p [equiv] a mod p.[/hide]::

Title: Re: Binomial Theorem for Primes
Post by Sir Col on Jun 7^th, 2004, 4:41am

The problem is not quite that trivial. Fermats Little Theorem only demonstrates that (a+b)^p is congruent with a+b modulo p.

However, you are correct, I was partially obfuscating the problem, namely: except for the first and last terms in the expansion of (a+b)ⁿ, show that n divides the coefficients of each term iff n is prime.

Title: Re: Binomial Theorem for Primes
Post by towr on Jun 7^th, 2004, 5:10am

For the original question
::[hide](a+b)^p % p [equiv] (a+b) % p [equiv] [a % p + b % p] % p [equiv] [a^p % p + b^p % p] % p [equiv] [a^p + b^p] % p [/hide]::
?

Title: Re: Binomial Theorem for Primes
Post by Sir Col on Jun 7^th, 2004, 12:23pm

Nicely done, towr! I had not anticipated such a simple solution.

Apologies, Grimbal, for doubting your clever insight! :-[

Okay...
Quote:

Except for the first and last terms in the expansion of (a+b)ⁿ, show that n divides the coefficients of each term iff n is prime.

And it is not sufficient to use F.L.T. to demonstrate that the sum of coefficients must be divisible by n; although I hadn't realised that until you clever twosome demonstrated it. Consider the following:
(a+b)² = a² + 2ab + b²
(a+b)³ = a³ + 3a²b + 3ab² + b³
(a+b)⁴ = a⁴ + 4a³b + 6a²b² + 4ab³ + b⁴

Clearly 2|2, 3|3, and 4|(4+6+4), but 4 does not divide 6.