Difference between revisions of "2023 AIME I Problems/Problem 7"
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Because the LCM of all of the numbers we are dividing by is 60, we know that all of the remainders are 0 again at 60, meaning that we have a cycle that repeats itself every 60 numbers. | Because the LCM of all of the numbers we are dividing by is 60, we know that all of the remainders are 0 again at 60, meaning that we have a cycle that repeats itself every 60 numbers. | ||
− | After listing all of the remainders up to 60, we find that 35, 58, and 59 are extra-distinct. So, we have 3 numbers every 60 which are extra-distinct. <math>60\cdot16</math> = 960 and <math>3\cdot16</math> = 48, so we have 48 extra-distinct numbers in the first 960 numbers. Because of our pattern, we know that the numbers from 961-1000 will act the same as 1-40, where we have 1 | + | After listing all of the remainders up to 60, we find that 35, 58, and 59 are extra-distinct. So, we have 3 numbers every 60 which are extra-distinct. <math>60\cdot16</math> = 960 and <math>3\cdot16</math> = 48, so we have 48 extra-distinct numbers in the first 960 numbers. Because of our pattern, we know that the numbers from 961-1000 will act the same as 1-40, where we have 1 extra-distinct number (35). 48 + 1 = <math>\boxed{49}</math>. |
-Algebraik | -Algebraik |
Revision as of 21:32, 8 February 2023
Problem
Call a positive integer extra-distinct if the remainders when is divided by and are distinct. Find the number of extra-distinct positive integers less than .
Solution 1
can either be or mod .
Case 1:
Then, , which implies . By CRT, , and therefore . Using CRT again, we obtain , which gives values for .
Case 2:
is then . If , then by CRT, , a contradiction. Thus, , which by CRT implies . can either be , which implies that , cases; or , which implies that , cases.
.
~mathboy100
Solution 2
.
We have . This violates the condition that is extra-distinct. Therefore, this case has no solution.
.
We have . This violates the condition that is extra-distinct. Therefore, this case has no solution.
.
We have . This violates the condition that is extra-distinct. Therefore, this case has no solution.
.
The condition implies , .
Because is extra-distinct, for is a permutation of . Thus, .
However, conflicts . Therefore, this case has no solution.
.
The condition implies and .
Because is extra-distinct, for is a permutation of .
Because , we must have . Hence, .
Hence, . Hence, .
We have . Therefore, the number extra-distinct in this case is 16.
.
The condition implies and .
Because is extra-distinct, and are two distinct numbers in . Because and is odd, we have . Hence, or 4.
, , .
We have .
We have . Therefore, the number extra-distinct in this subcase is 17.
, , .
.
We have . Therefore, the number extra-distinct in this subcase is 16.
Putting all cases together, the total number of extra-distinct is .
~Steven Chen (Professor Chen Education Palace, www.professorchenedu.com)
Solution 3
Because the LCM of all of the numbers we are dividing by is 60, we know that all of the remainders are 0 again at 60, meaning that we have a cycle that repeats itself every 60 numbers.
After listing all of the remainders up to 60, we find that 35, 58, and 59 are extra-distinct. So, we have 3 numbers every 60 which are extra-distinct. = 960 and = 48, so we have 48 extra-distinct numbers in the first 960 numbers. Because of our pattern, we know that the numbers from 961-1000 will act the same as 1-40, where we have 1 extra-distinct number (35). 48 + 1 = .
-Algebraik
See also
2023 AIME I (Problems • Answer Key • Resources) | ||
Preceded by Problem 6 |
Followed by Problem 8 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.