02-17-2005, 12:04 AM
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#1 (permalink) |
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Will power
 
Join Date: Nov 2002
Location: Hanoi and Munich
Posts: 401
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Prime number
What is the greatest integer that divides p^4 -1 for every prime number p greater than 5 ?
A. 12 B. 30 C. 48 D. 120 E. 240 Answer key: SPOILER: E
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02-17-2005, 01:12 AM
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#2 (permalink) |
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only Loeb spaces!
Moderator 
Join Date: Dec 2004
Posts: 2,075
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Re: Prime number
I have no idea about the problem. The phrase "for every" introduces too much difficulty for me. :-(
The only thing I figured out is that p^4 -1 is an even number (odd^4 = odd, odd -1 = even).
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"It's easy to have faith in yourself and have discipline when you're a winner, when you're number one. What you've got to have is faith and discipline when you're not yet a winner." Vince Lombardi How to write a lazy proof Teaching yourself how to prove |
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02-17-2005, 01:58 AM
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#3 (permalink) |
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Socratic realist
Join Date: Feb 2005
Location: Georgia, USA
Posts: 220
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Re: Prime number
Okay, this is tough to explain.
First note the theorem that x^(p-1) is congruent to 1 (mod p) where p and x are relatively prime. So, x^4 is congruent to 1 (mod 5), when x is a prime greater than 5; hence, x^4 - 1 is divisible by 5 (or p^4 - 1 is divisible by 5, in the notation used above). Next, note that p^4 -1 factors into (p^2 + 1)(p^2 - 1). As p is a prime greater than 5, p is odd, so p^2 + 1 is even and divisible by two. So far, we have independent factors of 5 and 2. Now, we'll show that p^2 - 1 is divisible by 24 = 3*4*2. Using the theorem above, we see that p^2 -1 is divisible by 3. Also, p^2 - 1 = (p + 1)(p - 1). Okay, now this is tricky. Since p is odd, both p + 1, p - 1 are even. But, one is divisible by 2, while the other is divisible by 4. So, we've shown that p^2 - 1 is divisible by 24. Therefore, we've shown that p^4 - 1 is divisible by 5*2*24 = 240. |
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02-17-2005, 08:04 AM
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#4 (permalink) |
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Within my grasp!
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Join Date: Nov 2004
Posts: 101
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Re: Prime number
That's a nice explanation!
I'd add only one comment: we don't even need Fermat Theorem (x^(p-1) is congruent to 1 (mod p) where p and x are relatively prime). Since f(p) := p^4 - 1 = (p^2 + 1)(p^2 - 1) = (p^2 + 1)(p + 1)(p - 1), and p>5, either (p-1) or (p+1) is divisible by 3. (Otherwise p would be, which is impossible.) In the same way: if neither (p-1) nor (p+1) is divisible by 5, the p must be congruent to +2 or -2 (mod 5), so (p^2+1) is congruent to 5 or 0 (mod 5). It's the same idea that Dragonfinity used to prove that f(p) is divisible by not only 4 but 8. Cheers, Md. |
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03-16-2008, 04:54 PM
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#5 (permalink) | |
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Trying to make mom and pop proud
Join Date: Mar 2008
Posts: 12
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Quote:
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03-20-2008, 03:00 AM
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#6 (permalink) |
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Trying to make mom and pop proud
Join Date: Mar 2008
Posts: 5
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Every number is -2,-1,0,1,2 mod 5. Since p>5, p is not 0 mod 5. If p-1 is not a multiple of 5, then p is not 1 mod 5. If p+1 is not a multiple of 5, then p is not -1 mod 5. So it has to be -2 or 2 mod 5. In both cases, p^2+1 will be 0 mod 5. So at least one of p-1,p+1,and p^2+1 must be divisible by 5.
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