Difference between revisions of "2022 IMO Problems/Problem 5"
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Find all triples <math>(a,b,p)</math> of positive integers with <math>p</math> prime and | Find all triples <math>(a,b,p)</math> of positive integers with <math>p</math> prime and | ||
<cmath>a^p = b! + p</cmath> | <cmath>a^p = b! + p</cmath> | ||
+ | |||
+ | ==Video solution== | ||
+ | https://youtu.be/d09PtqRSOuA | ||
+ | |||
+ | https://www.youtube.com/watch?v=-AII0ldyDww [Video contains solutions to all day 2 problems] | ||
==Solution== | ==Solution== | ||
− | + | ||
+ | '''Case 1:''' <math>b < p</math> | ||
+ | |||
+ | * Since <math>b!</math> is indivisible by <math>p</math>, then <math>a</math> must also be indivisible by <math>p</math>. | ||
+ | |||
+ | * If <math>a \le b</math>, then <math>a^p-b!</math> is divisible by <math>a</math>, so <math>a</math> must be a divisor of <math>p</math>, but <math>a=1</math> obviously has no solutions and we ruled out <math>a=p</math> already. For <math>a > b</math>, let's show that there are no solutions using simple inequalities. | ||
+ | |||
+ | * If <math>b < a < p</math>, then <math>b! \le (a-1)! \le (a-1)^{a-1}</math> and <math>a^p = (a-1+1)^p \ge (a-1)^p + p (a-1)^{p-1}</math> by throwing away the remaining (non-negative) terms of binomial theorem. For any solution, <math>(a-1)^p + p (a-1)^{p-1} \le a^p = b!+p \le (a-1)^{a-1} + p</math>, which is impossible for <math>a-1 > 1</math>. That leaves us with <math>a=2</math> and <math>b=1</math>, but <math>2^n > n+1</math> for any integer <math>n \ge 2</math> (proof by induction), so there are no solutions. | ||
+ | |||
+ | * If <math>b < p < a</math>, RHS is at most <math>(p-1)^{p-1}+p</math> and LHS is at least <math>(p+1)^p \ge p^p+p</math> (again from binomial theorem), which gives no solutions as well. | ||
+ | |||
+ | '''Case 2:''' <math>p \le b < 2p</math> | ||
+ | |||
+ | * Since <math>b!</math> is divisible by <math>p</math>, then <math>a</math> must also be divisible by <math>p</math>. | ||
+ | |||
+ | * In addition, RHS is at most <math>(2p-1)!+p = p \prod_{i=1}^{p-1} (p-i)(p+i) + p < p^{2p-1} + p \le p^{2p}</math>, so <math>a < p^2</math>. We may write <math>a=pc</math>, where <math>1 \le c < p</math>. | ||
+ | |||
+ | * Since <math>c</math> is a divisor of <math>a^p</math> and <math>b!</math> it must also be a divisor of <math>p</math>, so <math>c=1</math> and <math>a=p</math>. We're looking for solutions of <math>p^{p-1}-1 = b!/p</math>. | ||
+ | |||
+ | * Let's factorise <math>p^{p-1}-1</math>: if <math>p-1 = 2^k \cdot n</math> with <math>n</math> odd and <math>k > 0</math>, it's | ||
+ | |||
+ | <cmath>(p^n-1) \cdot (p^n+1) \cdot (p^{2n}+1) \cdot \ldots \cdot (p^{2^{k-1} n}+1) = (p-1) \cdot (1+p+\ldots+p^{n-1}) \cdot (p+1) \cdot (1-p+\ldots-p^{n-2}+p^{n-1}) \cdot (p^{2n}+1) \cdot \ldots \cdot (p^{2^{k-1} n}+1) \,.</cmath> | ||
+ | |||
+ | * Since <math>(1+p+\ldots+p^{n-1})</math> and <math>(1-p+\ldots-p^{n-2}+p^{n-1})</math> contain an odd number of odd terms (remember the assumption <math>k > 0</math> aka <math>p \neq 2</math>), they're odd. Also, <math>p^2 \equiv 1</math> modulo <math>4</math>, so <math>(p^{2n}+1)</math> and each following term is even but indivisible by <math>4</math>. The highest power of <math>2</math> dividing <math>p^{p-1}-1</math> is therefore <math>2^{k + l + k-1}</math> where <math>2^l</math> is the highest power dividing <math>p+1</math>. | ||
+ | |||
+ | * In comparison, <math>(p+1)!/p</math> has factors <math>(p+1)</math>, <math>(2^k n)</math> <math>(2^{k-1} n)</math> etc (up to <math>2n</math>), and <math>(p-1)/2-k</math> other even factors, so it's divisible at least by <math>2^{l+k(k+1)/2+(p-1)/2-k}</math>. Since <math>l+k(k+1)/2+(p-1)/2-k > l+2k-1</math> for <math>p \ge 7</math>, the only possible solutions have <math>p < 7</math> or <math>b = p</math>. | ||
+ | |||
+ | * If <math>b=p</math>, we reuse the inequalities <math>p^{p-1} \ge (p-1)^{p-1}+p-1</math> and <math>b!/p \le (p-1)^{p-1}</math> to show that there are no solutions for <math>p > 2</math>. | ||
+ | |||
+ | * Finally, <math>5^5-5 = 3120</math> isn't a factorial, <math>3^3-3 = 24 = 4!</math> and <math>2^2-2 = 2 = 2!</math>. | ||
+ | |||
+ | '''Case 3:''' <math>2p \le b</math> | ||
+ | |||
+ | Just like in case 2, <math>b!</math> is divisible by <math>p</math> so <math>a</math> must also be divisible by <math>p</math>. However, <math>b!</math> and <math>a^p</math> are also both divisible by <math>p^2</math>, so remainders modulo <math>p^2</math> tell us that no solutions exist. | ||
+ | |||
+ | '''Conclusion:''' | ||
+ | |||
+ | The only solutions are <math>(a,b,p) = (2,2,2), (3,4,3)</math>. | ||
+ | |||
+ | ==Solution 2== | ||
+ | |||
+ | |||
+ | I considered the cases: | ||
+ | |||
+ | 1) If \(a\) is even, then it must: | ||
+ | 1.a) \(b \neq 1\) and \(p > 2\) | ||
+ | 1.b) \(b!\) is even and \(p = 2\) | ||
+ | |||
+ | 2) If \(a\) is odd, then it must: | ||
+ | 2.a) \(b \neq 1\) and \(p = 2\) | ||
+ | 2.b) \(b!\) is even and \(p > 2\) | ||
+ | |||
+ | Examining 1.a), we end up with an equation of the form \(a^p = p+1\), which has no integer solutions. | ||
+ | |||
+ | In case 1.b), \(b!\) can take values: 2, 6, 24, 120, 720, ..., so \(b!+2\) takes values: 4, 8, 26, 122, 722, .... We observe that the only perfect square is 4 among the possible cases, as for \(b \geq 5\), the result ends in 2, which is not a perfect square. Therefore, we have the triple \((2,2,2)\). | ||
+ | |||
+ | Case 2.a) yields \(a^2 = 3\), which is rejected. | ||
+ | |||
+ | Examining the last case 2.b), we have for \(b!\) the values: 2, 6, 24, 120, 720, 5040, | ||
+ | i) \(b! = 2\), then \(a^p = 2+p\), which is rejected. | ||
+ | ii) \(b! = 6\), then \(a^p = 6+p\), also does not give integer solutions. | ||
+ | iii) \(b! = 24\), then \(a^p = 24+p\), giving a solution for \(p=3\). Thus, we have the triple \((3,4,3)\). | ||
+ | iv) \(b \geq 5\): | ||
+ | \(a^3 = b! + 3\), so \(a\) must end in 3 or 7, which does not give solutions. | ||
+ | \(a^5 = b! + 5\), so \(a\) must end in 5, also not giving solutions. | ||
+ | \(a^7 = b! + 7\), so \(a\) must end in 3, again not giving solutions. | ||
+ | \(a^{11} = b! + 11\), no \(a \in \mathbb{Z^+}\) satisfies this. | ||
+ | \(a^{19} = b! + 19\), similarly, no solutions. | ||
+ | Other prime exponents reduce to these, as their last digit is one of \(\{1,3,7,9\}\) | ||
+ | |||
+ | The analysis of the last case is incomplete, which is why I wasn't initially sure about the number of triples. Therefore, with this approach (which is not strictly documented), we find the triples: \((2,2,2), (3,4,3)\). | ||
+ | |||
+ | ==See Also== | ||
+ | |||
+ | {{IMO box|year=2022|num-b=4|num-a=6}} |
Latest revision as of 08:24, 6 September 2024
Problem
Find all triples of positive integers with prime and
Video solution
https://www.youtube.com/watch?v=-AII0ldyDww [Video contains solutions to all day 2 problems]
Solution
Case 1:
- Since is indivisible by , then must also be indivisible by .
- If , then is divisible by , so must be a divisor of , but obviously has no solutions and we ruled out already. For , let's show that there are no solutions using simple inequalities.
- If , then and by throwing away the remaining (non-negative) terms of binomial theorem. For any solution, , which is impossible for . That leaves us with and , but for any integer (proof by induction), so there are no solutions.
- If , RHS is at most and LHS is at least (again from binomial theorem), which gives no solutions as well.
Case 2:
- Since is divisible by , then must also be divisible by .
- In addition, RHS is at most , so . We may write , where .
- Since is a divisor of and it must also be a divisor of , so and . We're looking for solutions of .
- Let's factorise : if with odd and , it's
- Since and contain an odd number of odd terms (remember the assumption aka ), they're odd. Also, modulo , so and each following term is even but indivisible by . The highest power of dividing is therefore where is the highest power dividing .
- In comparison, has factors , etc (up to ), and other even factors, so it's divisible at least by . Since for , the only possible solutions have or .
- If , we reuse the inequalities and to show that there are no solutions for .
- Finally, isn't a factorial, and .
Case 3:
Just like in case 2, is divisible by so must also be divisible by . However, and are also both divisible by , so remainders modulo tell us that no solutions exist.
Conclusion:
The only solutions are .
Solution 2
I considered the cases:
1) If \(a\) is even, then it must:
1.a) \(b \neq 1\) and \(p > 2\) 1.b) \(b!\) is even and \(p = 2\)
2) If \(a\) is odd, then it must:
2.a) \(b \neq 1\) and \(p = 2\) 2.b) \(b!\) is even and \(p > 2\)
Examining 1.a), we end up with an equation of the form \(a^p = p+1\), which has no integer solutions.
In case 1.b), \(b!\) can take values: 2, 6, 24, 120, 720, ..., so \(b!+2\) takes values: 4, 8, 26, 122, 722, .... We observe that the only perfect square is 4 among the possible cases, as for \(b \geq 5\), the result ends in 2, which is not a perfect square. Therefore, we have the triple \((2,2,2)\).
Case 2.a) yields \(a^2 = 3\), which is rejected.
Examining the last case 2.b), we have for \(b!\) the values: 2, 6, 24, 120, 720, 5040,
i) \(b! = 2\), then \(a^p = 2+p\), which is rejected. ii) \(b! = 6\), then \(a^p = 6+p\), also does not give integer solutions. iii) \(b! = 24\), then \(a^p = 24+p\), giving a solution for \(p=3\). Thus, we have the triple \((3,4,3)\). iv) \(b \geq 5\): \(a^3 = b! + 3\), so \(a\) must end in 3 or 7, which does not give solutions. \(a^5 = b! + 5\), so \(a\) must end in 5, also not giving solutions. \(a^7 = b! + 7\), so \(a\) must end in 3, again not giving solutions. \(a^{11} = b! + 11\), no \(a \in \mathbb{Z^+}\) satisfies this. \(a^{19} = b! + 19\), similarly, no solutions. Other prime exponents reduce to these, as their last digit is one of \(\{1,3,7,9\}\)
The analysis of the last case is incomplete, which is why I wasn't initially sure about the number of triples. Therefore, with this approach (which is not strictly documented), we find the triples: \((2,2,2), (3,4,3)\).
See Also
2022 IMO (Problems) • Resources | ||
Preceded by Problem 4 |
1 • 2 • 3 • 4 • 5 • 6 | Followed by Problem 6 |
All IMO Problems and Solutions |