Difference between revisions of "1982 USAMO Problems/Problem 4"
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Note that <cmath>k\equiv 1\text{ (mod }3,5,7,17,257,65537,6700417)</cmath> and that <cmath>k\equiv -1\text{ (mod }641)</cmath> | Note that <cmath>k\equiv 1\text{ (mod }3,5,7,17,257,65537,6700417)</cmath> and that <cmath>k\equiv -1\text{ (mod }641)</cmath> | ||
− | Also, <cmath>\text{ord}_3(2)=2</cmath><cmath>\text{ord}_5(2)=4</cmath><cmath>\text{ord}_{17}(2)=8</cmath><cmath>\text{ord}_{257}(2)=16</cmath><cmath>\text{ord}_{65537}(2)=32</cmath><cmath>\text{ord}_{6700417}(2) | + | Also, <cmath>\text{ord}_3(2)=2</cmath><cmath>\text{ord}_5(2)=4</cmath><cmath>\text{ord}_{17}(2)=8</cmath><cmath>\text{ord}_{257}(2)=16</cmath><cmath>\text{ord}_{65537}(2)=32</cmath><cmath>\text{ord}_{6700417}(2)=\text{ord}_{641}(2)=64</cmath> |
Revision as of 21:29, 11 May 2017
Contents
Problem
Prove that there exists a positive integer such that is composite for every integer .
Solution 1
Let be a prime number that divides and be a whole number less than such that If is a multiple of , then, for some integer , This simplifies to This implies that . Thus we conclude that there exists an integer such that is composite for all integral .
Solution 2
I claim that works
Consider the primes
Note that and that
Also,
Take to be an odd integer.
It is well known (and not hard to prove) that
Consider some cases:
When we have
When we have
When we have
When we have
When we have
When we have
When we have , since
And furthermore, so these numbers need be composite.
But this covers all cases; we are done
See Also
1982 USAMO (Problems • Resources) | ||
Preceded by Problem 3 |
Followed by Problem 5 | |
1 • 2 • 3 • 4 • 5 | ||
All USAMO Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.