Difference between revisions of "2021 IMO Problems/Problem 1"
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− | ==Problem== | + | == Problem == |
− | Let <math>n \ | + | Let <math>n \geq 100</math> be an integer. Ivan writes the numbers <math>n, n+1, \ldots, 2 n</math> each on different cards. He then shuffles these <math>n+1</math> cards, and divides them into two piles. Prove that at least one of the piles contains two cards such that the sum of their numbers is a perfect square. |
− | ==Video Solutions== | + | == Video Solutions == |
https://youtu.be/cI9p-Z4-Sc8 [Video contains solutions to all day 1 problems] | https://youtu.be/cI9p-Z4-Sc8 [Video contains solutions to all day 1 problems] | ||
Line 9: | Line 9: | ||
https://www.youtube.com/watch?v=a3L9O7b1WYg [disclaimer: only a sketch of the solution] | https://www.youtube.com/watch?v=a3L9O7b1WYg [disclaimer: only a sketch of the solution] | ||
− | ==Solution== | + | == Video Solutions(中文解说)in Chinese but subtitle in English == |
+ | https://youtu.be/rnSRjcEfVCU | ||
+ | |||
+ | == Solution 1 == | ||
If we can guarantee that there exist <math>3</math> cards such that every pair of them sum to a perfect square, then we can guarantee that one of the piles contains <math>2</math> cards that sum to a perfect square. Assume the perfect squares <math>p^2</math>, <math>q^2</math>, and <math>r^2</math> satisfy the following system of equations: | If we can guarantee that there exist <math>3</math> cards such that every pair of them sum to a perfect square, then we can guarantee that one of the piles contains <math>2</math> cards that sum to a perfect square. Assume the perfect squares <math>p^2</math>, <math>q^2</math>, and <math>r^2</math> satisfy the following system of equations: | ||
<cmath>\usepackage{amsmath} | <cmath>\usepackage{amsmath} | ||
Line 42: | Line 45: | ||
~Mathdreams | ~Mathdreams | ||
+ | == Solution 2 == | ||
+ | For the statement to be true, there must be at least three pairs whose sum is each a perfect square. There must be p,q,r such that | ||
+ | |||
+ | <math>p+q = x^2</math> and <math>q+r = y^2</math>, <math>p+r = z^2</math>. | ||
+ | |||
+ | WLOG <math>n \le p \le q \le r \le 2n </math> ... Equation <math>1</math> | ||
+ | |||
+ | <math>p = \frac{(x^2 + z^2 – y^2)}{2}</math> | ||
+ | <math>q = \frac{(x^2 + y^2 – z^2)}{2}</math> | ||
+ | <math>r = \frac{(y^2 + z^2 – x^2)}{2}</math> | ||
+ | |||
+ | by equation 1 | ||
+ | |||
+ | <math>2n \le x^2 + z^2 – y^2 \le 4n</math> ...(1) | ||
+ | <math>2n \le x^2 + y^2 – z^2 \le 4n</math> ...(2) | ||
+ | <math>2n \le y^2 + z^2 – z^2 \le 4n</math> ...(3) | ||
+ | |||
+ | if we add (2) and (3) to (1), | ||
+ | |||
+ | (1) + (2) + (3) <math>\Rightarrow</math> | ||
+ | |||
+ | <math>6n \le x^2 + y^2 + z^2 \le 12n</math> | ||
+ | |||
+ | if we assume that x, y, and z is close enough, | ||
+ | |||
+ | <math>6n \le 3x^2 \le 12n</math> | ||
+ | <math>2n \le x^2 \le 4n</math> | ||
+ | <math>\sqrt{(2n)} \le x \le 2\sqrt{n}</math> | ||
+ | |||
+ | At this time <math>100 \le n</math>, so let's put <math>n = 100</math> to this | ||
+ | |||
+ | <math>10\sqrt{2} \le (x,y,z) \le 20</math> | ||
+ | <math>15 \le (x,y,z) \le 20</math> | ||
+ | |||
+ | where | ||
+ | <math>2|x^2 + y^2 - z^2</math> | ||
+ | <math>2|x^2 + z^2 - y^2</math> | ||
+ | <math>2|y^2 + z^2 - z^2</math> | ||
+ | <math>x = 16, y = 18, z = 20</math> fits perfectly | ||
− | + | therefore the minimum of <math>n</math> fits the proposition so the proposition is true | |
− | + | ~Mathhyhyhy | |
− | + | ~Kingfireboy | |
− | + | == Solution 3 == | |
− | + | Claim: If <math>n \geq 100</math>, then there exist at least three perfect squares between <math>n/2 + 1</math> and <math>n + 1</math> inclusive. | |
− | + | Proof: If <math>100 \leq n \leq 125</math>, then the perfect squares <math>64</math>, <math>81</math>, and <math>100</math> are between <math>n/2 + 1</math> and <math>n + 1</math>. | |
− | + | What if <math>n \geq 126</math>? Let <math>f(t) = \sqrt{t + 1} - \sqrt{t/2 + 1}</math>. Note that | |
− | + | <cmath> f(126) = \sqrt{127} - \sqrt{64} > 11 - 8 = 3. </cmath> | |
− | + | Moreover, <math>f</math> is increasing because | |
− | + | <cmath>f'(t) = \frac{1}{\sqrt{4t + 4}} - \frac{1}{\sqrt{8t + 16}} > 0.</cmath> | |
+ | So <math>f(n) \geq f(126) > 3</math>. Thus there are at least three distinct integers between <math>\sqrt{n/2 + 1}</math> and <math>\sqrt{n + 1}</math>, and their squares will lie between <math>n/2 + 1</math> and <math>n + 1</math>. This proves the claim. | ||
− | + | Now given any <math>n \geq 100</math>, it follows from the claim that there exist three consecutive squares <math>(k - 1)^2</math>, <math>k^2</math>, and <math>(k + 1)^2</math> such that | |
− | + | <cmath>\frac{n}{2} + 1 \leq (k - 1)^2, k^2, (k + 1)^2 \leq n + 1,</cmath> | |
− | |||
− | + | and therefore | |
− | + | <cmath>n \leq 2k^2 - 4k, 2k^2 + 1, 2k^2 + 4k \leq 2n.</cmath> | |
− | + | The three numbers <math>2k^2 - 4k</math>, <math>2k^2 + 1</math>, and <math>2k^2 + 4k</math> have the property that the sum of any two of them is a perfect square: | |
− | + | \begin{align*} | |
+ | (2k^2 - 4k) + (2k^2 + 1) &= (2k - 1)^2, \\ | ||
+ | (2k^2 - 4k) + (2k^2 + 4k) &= (2k)^2, \\ | ||
+ | (2k^2 + 1) + (2k^2 + 4k) &= (2k + 1)^2. | ||
+ | \end{align*} | ||
− | + | By the pigeonhole principle, cards showing two of these numbers will end up in the same pile, and the sum of those cards’ numbers will be a perfect square. | |
+ | |||
+ | == See also == | ||
+ | {{IMO box|year=2021|before=First Problem|num-a=2}} | ||
− | + | [[Category:Olympiad Number Theory Problems]] | |
− | |||
− | |||
− | |||
− |
Latest revision as of 23:19, 13 November 2024
Contents
Problem
Let be an integer. Ivan writes the numbers each on different cards. He then shuffles these cards, and divides them into two piles. Prove that at least one of the piles contains two cards such that the sum of their numbers is a perfect square.
Video Solutions
https://youtu.be/cI9p-Z4-Sc8 [Video contains solutions to all day 1 problems]
https://www.youtube.com/watch?v=a3L9O7b1WYg [disclaimer: only a sketch of the solution]
Video Solutions(中文解说)in Chinese but subtitle in English
Solution 1
If we can guarantee that there exist cards such that every pair of them sum to a perfect square, then we can guarantee that one of the piles contains cards that sum to a perfect square. Assume the perfect squares , , and satisfy the following system of equations: where , , and are numbers on three of the cards. Solving for , , and in terms of , , and tells us that , , and . We can then substitute , , and to cancel out the s in the denominatior, and simplifying gives , , and . Now, we have to prove that there exists three numbers in these forms between and when . Notice that will always be the least of the three and will always be the greatest of the three. So it is sufficient to prove that there exists numbers in the form and between and .
For two numbers in the form of and to be between and , the inequalities
must be satisfied. We can then expand and simplify to get that
Then, we can complete the square on the left sides of both inequalities and isolate to get that
Notice that must be an integer, so there must be an integer between and . If and differ by at least , then we can guarantee that there is an integer between them (and those integers are the possible values of ). Setting up the inequality and solving for tells us that always works. Testing the remaining numbers ( to ) manually tells us that there is an integer between and when . Therefore, there exists a triplet of integers with when such that every pair of the numbers sum to a perfect square. By the pigeonhole principle, we know that of the numbers must be on cards in the same pile, and hence, when , there will always be a pile with numbers that sum to a perfect square.
~Mathdreams
Solution 2
For the statement to be true, there must be at least three pairs whose sum is each a perfect square. There must be p,q,r such that
and , .
WLOG ... Equation
by equation 1
...(1) ...(2) ...(3)
if we add (2) and (3) to (1),
(1) + (2) + (3)
if we assume that x, y, and z is close enough,
At this time , so let's put to this
where
fits perfectly
therefore the minimum of fits the proposition so the proposition is true
~Mathhyhyhy
~Kingfireboy
Solution 3
Claim: If , then there exist at least three perfect squares between and inclusive.
Proof: If , then the perfect squares , , and are between and .
What if ? Let . Note that
Moreover, is increasing because
So . Thus there are at least three distinct integers between and , and their squares will lie between and . This proves the claim.
Now given any , it follows from the claim that there exist three consecutive squares , , and such that
and therefore
The three numbers , , and have the property that the sum of any two of them is a perfect square:
\begin{align*} (2k^2 - 4k) + (2k^2 + 1) &= (2k - 1)^2, \\ (2k^2 - 4k) + (2k^2 + 4k) &= (2k)^2, \\ (2k^2 + 1) + (2k^2 + 4k) &= (2k + 1)^2. \end{align*}
By the pigeonhole principle, cards showing two of these numbers will end up in the same pile, and the sum of those cards’ numbers will be a perfect square.
See also
2021 IMO (Problems) • Resources | ||
Preceded by First Problem |
1 • 2 • 3 • 4 • 5 • 6 | Followed by Problem 2 |
All IMO Problems and Solutions |