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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
Spring is in full swing and summer is right around the corner, what are your plans? At AoPS Online our schedule has new classes starting now through July, so be sure to keep your skills sharp and be prepared for the Fall school year! Check out the schedule of upcoming classes below.

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[*]April 22nd (Webinar), 4:00pm PT/7:00pm ET, Competitive Programming at AoPS (USACO).[/list]
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0 replies
jlacosta
Apr 2, 2025
0 replies
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4 var inequality
sqing   1
N 11 minutes ago by sqing
Source: https://bbs.emath.ac.cn/thread-39778-1-1.html
Let $ a,b,c,d>0 $ and $ a+b+c+d=4. $ Prove that$$a\sqrt{bc}+b\sqrt{cd}+c\sqrt{da}+d\sqrt{ab}\leq 2(1+\sqrt{abcd})$$Let $ a,b,c,d\geq -1 $ and $ a+b+c+d=0. $ Prove that$$ab+bc+cd\leq \frac{5}{4}$$
1 reply
sqing
19 minutes ago
sqing
11 minutes ago
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NT Tourism
B1t   2
N 18 minutes ago by B1t
Source: Mongolian TST 2025 P2
Let $a, n$ be natural numbers such that
\[ \frac{a^n - 1}{(a - 1)^n + 1} \]is a natural number.


1. Prove that $(a - 1)^n + 1$ is odd.
2. Let $q$ be a prime divisor of $(a - 1)^n + 1$.
Prove that
\[ a^{(q - 1)/2} \equiv 1 \pmod{q}. \]3. Prove that if a is prime and $a \equiv 1 \pmod{4}$, then
\[ 2^{(a - 1)/2} \equiv 1 \pmod{a}. \]
2 replies
B1t
3 hours ago
B1t
18 minutes ago
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easy functional
B1t   5
N 28 minutes ago by Haris1
Source: Mongolian TST 2025 P1.
Denote the set of real numbers by $\mathbb{R}$. Find all functions $f: \mathbb{R} \to \mathbb{R}$ such that for all $x, y, z \in \mathbb{R}$,
\[ f(xf(x+y)+z) = f(z) + f(x)y + f(xf(x)). \]
5 replies
B1t
3 hours ago
Haris1
28 minutes ago
J
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Easy Functional Inequality Problem in Taiwan TST
chengbilly   2
N 44 minutes ago by Korean_fish_Kaohsiung
Source: 2025 Taiwan TST Round 3 Mock P4
Let $a$ be a positive real number. Find all functions $f: \mathbb{R}^+ \to \mathbb{R}^+$ such that $af(x) - f(y) + y > 0$ and
\[ f(af(x) - f(y) + y) \leq x + f(y) - y, \quad \forall x, y \in \mathbb{R}^+. \]
proposed by chengbilly
2 replies
chengbilly
2 hours ago
Korean_fish_Kaohsiung
44 minutes ago
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No more topics!
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Sum of product of distances is constant
Tintarn   2
N Mar 23, 2021 by dikhendzab
Source: Bundeswettbewerb Mathematik 2020, Round 1 - Problem 3
Let $AB$ be the diameter of a circle $k$ and let $E$ be a point in the interior of $k$. The line $AE$ intersects $k$ a second time in $C \ne A$ and the line $BE$ intersects $k$ a second time in $D \ne B$.

Show that the value of $AC \cdot AE+BD\cdot BE$ is independent of the choice of $E$.
2 replies
Tintarn
Nov 17, 2020
dikhendzab
Mar 23, 2021
J
Sum of product of distances is constant
G H J
Reveal topic tags
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Source: Bundeswettbewerb Mathematik 2020, Round 1 - Problem 3
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Tintarn
9038 posts
Tintarn
#1 Nov 17, 2020, 3:31 PM • 2 Y
Y by Mango247, Mango247
Let $AB$ be the diameter of a circle $k$ and let $E$ be a point in the interior of $k$. The line $AE$ intersects $k$ a second time in $C \ne A$ and the line $BE$ intersects $k$ a second time in $D \ne B$.

Show that the value of $AC \cdot AE+BD\cdot BE$ is independent of the choice of $E$.
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RagvaloD
4911 posts
RagvaloD
#2 Nov 17, 2020, 6:24 PM
Y by
Let $EG \perp AB$ then $AC*AE= AB \cos \angle CAB * \frac{AG}{\cos \angle CAB}= AB*AG$
$BD*DE=AB*BG$
$AC \cdot AE+BD\cdot BE=AB^2$
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dikhendzab
108 posts
dikhendzab
#4 Mar 23, 2021, 12:57 PM
Y by
Quick trig solution for storage :)
Obviously $\angle ACB=\angle ADB=90^\circ$, so from triangle $ABC$ we have: $AC=AB\cdot\cos\angle BAE$ and from triangle $ABD$ we have: $BD=AB\cdot\cos\angle ABE$. $\angle AEB=180^\circ-\angle ABE-\angle BAE$, so $\sin\angle AEB=\sin(\angle BAE+\angle ABE)$. Now from sine law in triangle $ABE:$
$BE=\frac{AB\cdot\sin\angle BAE}{\sin(\angle BAE+\angle ABE)}$ and $AE=\frac{AB\cdot\sin\angle ABE}{\sin(\angle BAE+\angle ABE)}$, so finally:
$AC \cdot AE+BD\cdot BE=AB\cdot\cos\angle BAE\cdot\frac{AB\cdot\sin\angle ABE}{\sin(\angle BAE+\angle ABE)}+AB\cdot\cos\angle ABE\cdot\frac{AB\cdot\sin\angle BAE}{\sin(\angle BAE+\angle ABE)}=$
$AB^2(\frac{\cos\angle BAE\cdot\sin\angle ABE+\cos\angle ABE\cdot\sin\angle BAE}{\sin(\angle BAE+\angle ABE)})=AB^2\frac{\sin(\angle BAE+\angle ABE)}{\sin(\angle BAE+\angle ABE)}=AB^2$
So it does not depend on choosing point $E$.
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