Difference between revisions of "2019 AMC 10A Problems/Problem 11"

(Solution 2)
(Solution 2)
Line 19: Line 19:
  
 
Case 1: The factor is 3^n
 
Case 1: The factor is 3^n
 +
 
Then, we would have n = 2, 3, 4, 6, 8, and 9.  
 
Then, we would have n = 2, 3, 4, 6, 8, and 9.  
  
 
Case 2: The factor is 67^n  
 
Case 2: The factor is 67^n  
 +
 
Same as case 1
 
Same as case 1
  
 
Case 3: The factor is some combination
 
Case 3: The factor is some combination
 +
 
This would be easy if we could just have any combination, as that would be simply 6*6. However, we must pair the numbers that generate squares with the numbers that generate squares and the same for cubes. In simpler terms, let's organize our n values.
 
This would be easy if we could just have any combination, as that would be simply 6*6. However, we must pair the numbers that generate squares with the numbers that generate squares and the same for cubes. In simpler terms, let's organize our n values.
 +
 
n = 2 is a "square" because it would be a factor of this number that is a perfect square. More generally, it is even.
 
n = 2 is a "square" because it would be a factor of this number that is a perfect square. More generally, it is even.
 +
 
n = 3 is a "cube" because it would be a factor of this number that is a perfect cube. More generally, it is a multiple of 3.
 
n = 3 is a "cube" because it would be a factor of this number that is a perfect cube. More generally, it is a multiple of 3.
 +
 
n = 4 is a "square"
 
n = 4 is a "square"
 +
 
n = 6 is interesting, since its both a "square" and a "cube". Don't count this as either because it's double function would double count the numbers if we counted them simply as a "square" or as a "cube", so we will count them in another case.
 
n = 6 is interesting, since its both a "square" and a "cube". Don't count this as either because it's double function would double count the numbers if we counted them simply as a "square" or as a "cube", so we will count them in another case.
 +
 
n = 8 is a "square"
 
n = 8 is a "square"
 +
 
n = 9 is a "cube".
 
n = 9 is a "cube".
  
Line 36: Line 45:
  
 
Subcase 1: The squares are with each other.
 
Subcase 1: The squares are with each other.
 +
 
Since we have 3 square terms, and they would pair with 3 other square terms, we get 3*3 = 9 cases
 
Since we have 3 square terms, and they would pair with 3 other square terms, we get 3*3 = 9 cases
  
 
Subcase 2: The cubes are with each other.
 
Subcase 2: The cubes are with each other.
 +
 
Since we have 2 cube terms, and they would pair with 2 other cube terms, we get 2*2 = 4 cases
 
Since we have 2 cube terms, and they would pair with 2 other cube terms, we get 2*2 = 4 cases
  
 
Subcase 3: A number pairs with n=6.
 
Subcase 3: A number pairs with n=6.
 +
 
Since any number can pair with n=6 since it's a square AND cube, there are 6 cases. Remember however that there can be two different bases (3 and 67), and they would produce different results. Thus, there are 6*2 = 12 cases
 
Since any number can pair with n=6 since it's a square AND cube, there are 6 cases. Remember however that there can be two different bases (3 and 67), and they would produce different results. Thus, there are 6*2 = 12 cases
  

Revision as of 20:14, 11 February 2019

Problem

How many positive integer divisors of $201^9$ are perfect squares or perfect cubes (or both)?

${\textbf{(A) }32} \qquad {\textbf{(B) }36} \qquad {\textbf{(C) }37} \qquad {\textbf{(D) }39} \qquad {\textbf{(E) }41}$

Solution 1

Prime factorizing $201^9$, we get $3^9\cdot67^9$. A perfect square must have even powers of its prime factors, so our possible choices for our exponents of a perfect square are $0, 2, 4, 6, 8$ for both $3$ and $67$. This yields $5\cdot5 = 25$ perfect squares.

Perfect cubes must have multiples of $3$ for each of their prime factors' exponents, so we have either $0, 3, 6$, or $9$ for both $3$ and $67$, which yields $4\cdot4 = 16$ perfect cubes, for a total of $25+16 = 41$.

Subtracting the overcounted powers of six ($3^0\cdot67^0$ , $3^0\cdot67^6$ , $3^6\cdot67^0$, and $3^6\cdot67^6$), we get $41-4 = \boxed{\textbf{(C) }37}$.

Solution by Aadileo

Solution 2

201 = 67 * 3. Split the answers into cases:

Case 1: The factor is 3^n

Then, we would have n = 2, 3, 4, 6, 8, and 9.

Case 2: The factor is 67^n

Same as case 1

Case 3: The factor is some combination

This would be easy if we could just have any combination, as that would be simply 6*6. However, we must pair the numbers that generate squares with the numbers that generate squares and the same for cubes. In simpler terms, let's organize our n values.

n = 2 is a "square" because it would be a factor of this number that is a perfect square. More generally, it is even.

n = 3 is a "cube" because it would be a factor of this number that is a perfect cube. More generally, it is a multiple of 3.

n = 4 is a "square"

n = 6 is interesting, since its both a "square" and a "cube". Don't count this as either because it's double function would double count the numbers if we counted them simply as a "square" or as a "cube", so we will count them in another case.

n = 8 is a "square"

n = 9 is a "cube".

Now let's do subcases:

Subcase 1: The squares are with each other.

Since we have 3 square terms, and they would pair with 3 other square terms, we get 3*3 = 9 cases

Subcase 2: The cubes are with each other.

Since we have 2 cube terms, and they would pair with 2 other cube terms, we get 2*2 = 4 cases

Subcase 3: A number pairs with n=6.

Since any number can pair with n=6 since it's a square AND cube, there are 6 cases. Remember however that there can be two different bases (3 and 67), and they would produce different results. Thus, there are 6*2 = 12 cases

Thus, we add up the cases, to get 6+6+9+4+12 = 37.

iron

See Also

2019 AMC 10A (ProblemsAnswer KeyResources)
Preceded by
Problem 10
Followed by
Problem 12
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25
All AMC 10 Problems and Solutions

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