Difference between revisions of "2025 USAMO Problems/Problem 5"

Revision as of 08:39, 28 June 2025

Problem

Determine, with proof, all positive integers $k$ such that $\frac{1}{n+1} \sum_{i=0}^n \binom{n}{i}^k$ is an integer for every positive integer $n.$

Solution 1

https://artofproblemsolving.com/wiki/index.php/File:2025_USAMO_PROBLEM_5_1.jpg

https://artofproblemsolving.com/wiki/index.php/File:2025_USAMO_PROBLEM_5_2.jpg

Solution 2 (q-analogue via q-Chu–Vandermonde)

Throughout this proof we work in the polynomial ring $\mathbb Z[q]$ .

For any $n\ge1$ set

$[n]_q = 1 + q + \cdots + q^{n-1},$

$[n]_q! = \prod_{i=1}^n [i]_q,$

$\binom ni_q = \frac{[n]_q!}{[i]_q!\,[n-i]_q!}.$

Then

$[n+1]_q = 1 + q + \cdots + q^n = \frac{1 - q^{n+1}}{1 - q} = \prod_{d\mid(n+1)} \Phi_d(q).$

Define

$S_k(n;q) = \sum_{i=0}^n \binom ni_q^k.$

We must show

$A_k(n) = \frac1{n+1} \sum_{i=0}^n \binom ni^k \in \mathbb Z \quad\Longleftrightarrow\quad k \text{ even}.$

It suffices to prove that for even $k=2m$ , one has $[n+1]_q \mid S_{2m}(n;q)$ in $\mathbb Z[q]$ , and that for odd $k$ there exists some $n$ for which $\tfrac1{n+1}\sum_i\binom ni^k\notin\mathbb Z$ .

Case $m=1$

By the $q$ -Chu–Vandermonde identity,

$\sum_{i=0}^n \binom ni_q^2 = \binom{2n}{n}_q = \frac{[2n]_q!}{[n]_q!^2} = \frac{[n+1]_q\,[2n]_q!}{[n+1]_q\,[n]_q!^2} = [n+1]_q \, Q_{n,1}(q),$

with $Q_{n,1}(q)\in\mathbb Z[q]$ .

Inductive step

Assume for some $m\ge1$ ,

$S_{2m}(n;q) = [n+1]_q \, Q_{n,m}(q), \quad Q_{n,m}(q)\in\mathbb Z[q].$

Then

$S_{2(m+1)}(n;q) = \sum_{i=0}^n \binom ni_q^2 \,\binom ni_q^{2m} = \sum_{i=0}^n \binom ni_q^2 \,[n+1]_q \, Q_{n,m}(q).$

Another application of $q$ -Chu–Vandermonde yields

$\sum_{i=0}^n \binom ni_q^2 \, Q_{n,m}(q) = [n+1]_q \, Q_{n,m+1}(q), \quad Q_{n,m+1}(q)\in\mathbb Z[q],$

so $[n+1]_q\mid S_{2(m+1)}(n;q)$ .

Case $k$ odd

Take $n=2$ . Then

$A_k(2) = \frac{1 + 2^k + 1}{3} = \frac{2 + 2^k}{3}.$

If $k$ is odd then $2^k \equiv 2 \pmod 3$ , so $2+2^k \equiv 4 \equiv 1\pmod3$ and hence $3\nmid(2+2^k)$ . Thus $A_k(2)\notin\mathbb Z$ .

Conclusion

For even $k$ we have $[n+1]_q\mid S_k(n;q)$ and specializing $q=1$ gives

$\frac1{n+1}\sum_{i=0}^n \binom ni^k \in \mathbb Z.$

For odd $k$ the example $n=2$ yields a noninteger, so integrality fails.

This completes the proof.

@@ Line 33: / Line 33: @@
 [n+1]_q = 1 + q + \cdots + q^n
 = \frac{1 - q^{n+1}}{1 - q}
-= \prod_{d \mid (n+1)} \Phi_d(q).
+= \prod_{d\mid(n+1)} \Phi_d(q).
 </cmath>
@@ Line 50: / Line 50: @@
 </cmath>
-It suffices to prove that for even <math>k=2m</math>, one has <math>[n+1]_q \mid S_{2m}(n;q)</math> in <math>\mathbb Z[q]</math>, and that for odd <math>k</math> there is some divisor of <math>n+1</math> at which <math>S_k(n;q)\neq0</math>.
+It suffices to prove that for even <math>k=2m</math>, one has <math>[n+1]_q \mid S_{2m}(n;q)</math> in <math>\mathbb Z[q]</math>, and that for odd <math>k</math> there exists some <math>n</math> for which <math>\tfrac1{n+1}\sum_i\binom ni^k\notin\mathbb Z</math>.
 Case <math>m=1</math>
@@ Line 97: / Line 97: @@
 Case <math>k</math> odd
-Let <math>k=2m+1</math> and pick a prime <math>p>2</math> with <math>p\nmid k</math>.  Take <math>n=p-1</math> and let <math>\zeta</math> be a primitive <math>p</math>-th root of unity.  Then
+Take <math>n=2</math>.  Then
 <cmath>
-S_k(p-1;\zeta)
+A_k(2) = \frac{1 + 2^k + 1}{3} = \frac{2 + 2^k}{3}.
-= \sum_{i=0}^{p-1} \binom{p-1}{i}_\zeta^k
-= \sum_{i=0}^{p-1} (-1)^{ik} \,\zeta^{-k\,i(i+1)/2}
-= \zeta^a \sum_{l\!\!\!\!\pmod p} \zeta^{-k\,l^2},
 </cmath>
-for some integer <math>a</math>.  The inner sum is a quadratic Gauss sum of magnitude <math>\sqrt p \neq 0</math>, so <math>S_k(p-1;\zeta)\neq0</math>.  Hence <math>\Phi_p(q)\nmid S_k(n;q)</math> and <math>[n+1]_q\nmid S_k(n;q)</math>.
+If <math>k</math> is odd then <math>2^k \equiv 2 \pmod 3</math>, so <math>2+2^k \equiv 4 \equiv 1\pmod3</math> and hence <math>3\nmid(2+2^k)</math>.  Thus <math>A_k(2)\notin\mathbb Z</math>.
 Conclusion
-For even <math>k</math> we have <math>[n+1]_q\mid S_k(n;q)</math>, and specializing <math>q=1</math> gives
+For even <math>k</math> we have <math>[n+1]_q\mid S_k(n;q)</math> and specializing <math>q=1</math> gives
 <cmath>
-\frac1{n+1} \sum_{i=0}^n \binom ni^k \in \mathbb Z.
+\frac1{n+1}\sum_{i=0}^n \binom ni^k \in \mathbb Z.
 </cmath>
-For odd <math>k</math> we exhibited a <math>p\mid(n+1)</math> with <math>S_k(n;q)\neq0</math>, so integrality fails.
+For odd <math>k</math> the example <math>n=2</math> yields a noninteger, so integrality fails.
-This completes the proof. ~Lopkiloinm
+This completes the proof.
 ==See Also==
 {{USAMO newbox|year=2025|num-b=4|num-a=6}}
 {{MAA Notice}}

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Difference between revisions of "2025 USAMO Problems/Problem 5"

Revision as of 08:39, 28 June 2025

Contents

Problem

Solution 1

Solution 2 (q-analogue via q-Chu–Vandermonde)

See Also