Difference between revisions of "2024 USAMO Problems/Problem 4"
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Exactly all positive integers <math>m</math> and <math>n</math> with <math>m \leq n + 1</math>; these are all possible ordered pairs <math>(m, n)</math>. | Exactly all positive integers <math>m</math> and <math>n</math> with <math>m \leq n + 1</math>; these are all possible ordered pairs <math>(m, n)</math>. | ||
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+ | ~[https://artofproblemsolving.com/wiki/index.php/User:Athmyx Athmyx] | ||
==Video Solution== | ==Video Solution== | ||
https://youtu.be/ZcdBpaLC5p0 [video contains problem 1 and problem 4] | https://youtu.be/ZcdBpaLC5p0 [video contains problem 1 and problem 4] |
Latest revision as of 01:50, 15 November 2024
Let and be positive integers. A circular necklace contains beads, each either red or blue. It turned out that no matter how the necklace was cut into blocks of consecutive beads, each block had a distinct number of red beads. Determine, with proof, all possible values of the ordered pair .
Solution 1
We need to determine all possible positive integer pairs such that there exists a circular necklace of beads, each colored red or blue, satisfying the following condition:
No matter how the necklace is cut into blocks of consecutive beads, each block has a distinct number of red beads.
Necessary Condition:
1. Maximum Possible Distinct Counts: In a block of beads, the number of red beads can range from to . Therefore, there are possible distinct counts of red beads in a block. Since we have blocks, the maximum number of distinct counts must be at least . Thus, we must have:
Sufficient Construction:
We will show that for all positive integers and satisfying , such a necklace exists.
1. Construct Blocks: Create blocks, each containing beads. Assign to each block a unique number of red beads, ranging from to .
2. Design the Necklace: Arrange these blocks in a fixed order to form the necklace. Since the necklace is circular, cutting it at different points results in cyclic permutations of the blocks.
3. Verification: In any cut, the sequence of blocks (and thus the counts of red beads) is a cyclic shift of the original sequence. Therefore, in each partition, the blocks will have distinct numbers of red beads.
Example:
Let's construct a necklace for and :
Blocks: Block 1: red beads (BB) Block 2: red bead (RB) Block 3: red beads (RR)
Necklace Arrangement: Place the blocks in order: BB-RB-RR.
Verification: Any cut of the necklace into blocks of beads will have blocks with red bead counts of , , and .
Conclusion:
All ordered pairs where satisfy the condition. Therefore, the possible values of are all positive integers such that .
Final Answer:
Exactly all positive integers and with ; these are all possible ordered pairs .
Video Solution
https://youtu.be/ZcdBpaLC5p0 [video contains problem 1 and problem 4]