Difference between revisions of "2012 AMC 12B Problems/Problem 24"
(→Solution) |
(→Solution) |
||
Line 25: | Line 25: | ||
<math>7^2 \cdot Q^3</math> could also work if <math>Q</math> is odd, but <math>7^2 \cdot 3^3 > 400</math> already. | <math>7^2 \cdot Q^3</math> could also work if <math>Q</math> is odd, but <math>7^2 \cdot 3^3 > 400</math> already. | ||
− | <math>f_1(11^2 \cdot 3) = 2^4 \cdot 3</math> does not work. | + | <math>f_1(11^2 \cdot 3) = 12 \cdot 4 = 2^4 \cdot 3</math>, which does not work. |
When prime <math>p\geq 13</math>, any odd multiple <math>p^2</math> other than itself is greater than <math>400</math>, and that <math>f_1(p^2)=p+1</math> could be a multiple of <math>32</math> only if <math>p\geq 31</math>, which is already beyond what we need to test. | When prime <math>p\geq 13</math>, any odd multiple <math>p^2</math> other than itself is greater than <math>400</math>, and that <math>f_1(p^2)=p+1</math> could be a multiple of <math>32</math> only if <math>p\geq 31</math>, which is already beyond what we need to test. | ||
In conclusion, there are <math>12+4+1=17</math> number of <math>N</math>'s ... <math>\framebox{C}</math>. | In conclusion, there are <math>12+4+1=17</math> number of <math>N</math>'s ... <math>\framebox{C}</math>. |
Revision as of 04:22, 6 December 2012
Problem 24
Define the function on the positive integers by setting and if is the prime factorization of , then For every , let . For how many in the range is the sequence unbounded?
Note: A sequence of positive numbers is unbounded if for every integer , there is a member of the sequence greater than .
Solution
First of all, notice that for any odd prime , the largest prime that divides is no larger than , therefore eventually the factorization of does not contain any prime larger than . Also, note that , when it stays the same but when it grows indefinitely. Therefore any number that is divisible by or any number such that is divisible by makes the sequence unbounded. There are multiples of within . Now let's look at the other cases.
Any first power of prime in a prime factorization will not contribute the unboundedness because . At least a square of prime is to contribute. So we test primes that are less than :
works, therefore any number that are divisible by works: there are of them.
could also work if is odd, but already.
does not work.
works. There are no other multiples of within .
could also work if is odd, but already.
, which does not work.
When prime , any odd multiple other than itself is greater than , and that could be a multiple of only if , which is already beyond what we need to test.
In conclusion, there are number of 's ... .