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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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0 replies
jlacosta
Apr 2, 2025
0 replies
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Strategy game based modulo 3
egxa   1
N 12 minutes ago by Euler8038
Source: All Russian 2025 9.7
The numbers \( 1, 2, 3, \ldots, 60 \) are written in a row in that exact order. Igor and Ruslan take turns inserting the signs \( +, -, \times \) between them, starting with Igor. Each turn consists of placing one sign. Once all signs are placed, the value of the resulting expression is computed. If the value is divisible by $3$, Igor wins; otherwise, Ruslan wins. Which player has a winning strategy regardless of the opponent’s moves?
1 reply
egxa
24 minutes ago
Euler8038
12 minutes ago
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Continuity of function and line segment of integer length
egxa   0
13 minutes ago
Source: All Russian 2025 11.8
Let \( f: \mathbb{R} \to \mathbb{R} \) be a continuous function. A chord is defined as a segment of integer length, parallel to the x-axis, whose endpoints lie on the graph of \( f \). It is known that the graph of \( f \) contains exactly \( N \) chords, one of which has length 2025. Find the minimum possible value of \( N \).
0 replies
2 viewing
egxa
13 minutes ago
0 replies
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Find the maximum value of x^3+2y
BarisKoyuncu   8
N 16 minutes ago by Primeniyazidayi
Source: 2021 Turkey JBMO TST P4
Let $x,y,z$ be real numbers such that $$\left|\dfrac yz-xz\right|\leq 1\text{ and }\left|yz+\dfrac xz\right|\leq 1$$Find the maximum value of the expression $$x^3+2y$$
8 replies
BarisKoyuncu
May 23, 2021
Primeniyazidayi
16 minutes ago
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Woaah a lot of external tangents
egxa   0
16 minutes ago
Source: All Russian 2025 11.7
A quadrilateral \( ABCD \) with no parallel sides is inscribed in a circle \( \Omega \). Circles \( \omega_a, \omega_b, \omega_c, \omega_d \) are inscribed in triangles \( DAB, ABC, BCD, CDA \), respectively. Common external tangents are drawn between \( \omega_a \) and \( \omega_b \), \( \omega_b \) and \( \omega_c \), \( \omega_c \) and \( \omega_d \), and \( \omega_d \) and \( \omega_a \), not containing any sides of quadrilateral \( ABCD \). A quadrilateral whose consecutive sides lie on these four lines is inscribed in a circle \( \Gamma \). Prove that the lines joining the centers of \( \omega_a \) and \( \omega_c \), \( \omega_b \) and \( \omega_d \), and the centers of \( \Omega \) and \( \Gamma \) all intersect at one point.
0 replies
egxa
16 minutes ago
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Point in a triangle, with angle constraints
mavropnevma   6
N Oct 1, 2021 by rafaello
Source: Tuymaada 2012, Problem 3, Day 1, Seniors
Point $P$ is taken in the interior of the triangle $ABC$, so that
\[\angle PAB = \angle PCB = \dfrac {1} {4} (\angle A + \angle C).\]
Let $L$ be the foot of the angle bisector of $\angle B$. The line $PL$ meets the circumcircle of $\triangle APC$ at point $Q$. Prove that $QB$ is the angle bisector of $\angle AQC$.

Proposed by S. Berlov
6 replies
mavropnevma
Jul 21, 2012
rafaello
Oct 1, 2021
J
Point in a triangle, with angle constraints
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Reveal topic tags
geometry
circumcircle
symmetry
trapezoid
incenter
geometric transformation
reflection
L
G H BBookmark kLocked kLocked NReply
Source: Tuymaada 2012, Problem 3, Day 1, Seniors
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mavropnevma
15142 posts
mavropnevma
#1 Jul 21, 2012, 9:38 PM • 6 Y
Y by Adventure10, Mango247, and 4 other users
Point $P$ is taken in the interior of the triangle $ABC$, so that
\[\angle PAB = \angle PCB = \dfrac {1} {4} (\angle A + \angle C).\]
Let $L$ be the foot of the angle bisector of $\angle B$. The line $PL$ meets the circumcircle of $\triangle APC$ at point $Q$. Prove that $QB$ is the angle bisector of $\angle AQC$.

Proposed by S. Berlov
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S.E.Louridas
71 posts
S.E.Louridas
#2 Jul 23, 2012, 3:06 PM • 2 Y
Y by Adventure10, Mango247
Dear friend from the beautiful Montevideo, one quick thought:

♦ All in this figure is symmetric, with symmetry axis the line (e) which is defined by the bisector of the angle $B$.
$L$ is the polar of point $B$ with respect of the circle (g).
Hence, this point is also the meeting point of the diagonals of the isosceles trapezium $TSQ_1Q_2$, with $S$ the midpoint of the arc $CSA$ and $T$ the midpoint of the arc $A_1TC_1$.
We have here:
$\angle CQ_1 S = \angle SQ_1 A,\;\;A_1 T = TC_1 \Rightarrow \angle TCB$ $ = \angle TAB = \frac{{\angle A + \angle C}} {4}\; \Rightarrow T \equiv P,\;\;Q_1 \equiv Q,$
because $\angle ATC = 90^ \circ + \frac{{\angle B}} {2}$
Attachments:
art.pdf (237kb)
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Lawasu
212 posts
Lawasu
#3 Jul 24, 2012, 10:24 AM • 2 Y
Y by Adventure10, Mango247
WLOG $AB>BC$. By the hypothesis we get $\widehat{PAC}+\widehat{PCA}=\dfrac{1}{2}\cdot (\widehat{A}+\widehat{C})$, so $\widehat{APC}=90^\circ +\widehat{B}/2$.
Therefore $AIPC$ is cyclic where $I$ is the incenter of $\triangle ABC$. We know that $[BL$ passes through the center $W$ of circle $(AIC)$.
Hence, the reflection $M$ of $A$ about $BL$ lies on the circle $(AIC)$ and on the line $BC$.
The reflection $N$ of $C$ about $BL$ also lies on the circle $(AIC)$ and on the line $AB$.
Let $R$ be the reflection of $P$ about line $BL$. By the symmetry we get $\widehat{RMC}=\widehat{PAN}=\widehat{PCB}$.
Therefore $PC\parallel RM$, so $arc\ RP=arc\ CM$ and it follows that $\overarc{AR}=\overarc{RC}$ since $AM\parallel CN\parallel PR$.
Hence $R$ is the midpoint of arc $AC$ and $P$ is the midpoint of the arc $MN$. Let $I_b$ be the $B$-excenter of $\triangle ABC$.
The division $(I,I_n,B,L)$ is harmonic, so $L$ lies on the polar of $B$ with respect to the circle $(AIC)$.
Now take $R_1\in BR\cap (AIC),\ R_1\neq R$ and $P_1\in BP\cap (AIC),\ P_1\neq P$. Take $K\in RP_1\cap PR_1$.
Obviously $K$ lies on $BL$ and it's well known that $K$ lies on the polar of $RR_1\cap PP_1$ with respect to the circle $(AIC)$.
Hence $K=L$ and it follows that $R_1=Q$ since $Q\in PL\cap (AIC)$. Now, obviously $[QB$ is the bisector of $\widehat{AQC}$ since $B,Q,R$ are collinear.
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leader
339 posts
leader
#4 Jul 24, 2012, 11:30 AM • 1 Y
Y by Adventure10
Find a point $X$ in the plane such that $\angle ABX=\angle CBP$ (where the line $BX$ cuts segment $AC$) and $\angle AXB=\angle PCB$, and prove $X\equiv Q$.
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nima1376
111 posts
nima1376
#5 Apr 26, 2014, 4:37 PM • 2 Y
Y by Adventure10, Mango247
o(center of circumcircle of triangle APL) is midpoint of AC in circumcircle of ABC.
let angle bisector of B meet AC at T. OT.TB=AT.CT=PT.TQ ----> OPBQ is cycle
now it is easy by play with angle.
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junioragd
314 posts
junioragd
#6 Aug 28, 2014, 2:22 PM • 2 Y
Y by Adventure10, Mango247
Let $M$ be the midpoint of the arc $AC$.Now,it is easy to obtain $LA*LC=LB*LM=LP*LQ$,so we obtain $BPMQ$ is a cyclic and the rest is easy angle chasing.
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rafaello
1079 posts
rafaello
#7 Oct 1, 2021, 4:00 PM
Y by
Claim: Let $C'$ be the reflection of $C$ over the angle bisector of $\angle ABC$. Then, $BPCC'$ is cyclic.
Proof.Indeed, \begin{align*} \measuredangle PCC'&=\measuredangle ACC'+\measuredangle PCA=\frac{\measuredangle B+\measuredangle C}{2}-\frac{\measuredangle B+\measuredangle C}{4}\\&=\frac{\measuredangle B+\measuredangle C}{4}=\measuredangle PBA=\measuredangle PBC'.\,\square \end{align*}
Let $Q'$ be image of $P$ of inversion at $B$ with radius $\sqrt{ac}$ followed by the reflection over the angle bisector of $\angle ABC$. Thus, $Q'B$ is the angle bisector of $\angle CQ'A$ and $APCQ'$ is cyclic quadrilateral. Now, all we need is to show that $P,L,Q'$ are collinear.
By ratio lemma,\begin{align*} \frac{AL}{LC}=\frac{AB}{BC}=\frac{AB}{BC}\cdot \frac{\sin{\angle ABP}}{\sin{\angle PBC}}\cdot \frac{\sin{\angle ABQ'}}{\sin{\angle Q'BC}}=\frac{AP}{PC}\cdot \frac{AQ'}{Q'C}, \end{align*}we are done. $\blacksquare$
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