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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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jlacosta
Apr 2, 2025
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Don't bite me for this straightforward sequence
Assassino9931   5
N 44 minutes ago by MathLuis
Source: Bulgaria National Olympiad 2025, Day 1, Problem 1
Determine all infinite sequences $a_1, a_2, \ldots$ of real numbers such that
\[ a_{m^2 + m + n} = a_{m}^2 + a_m + a_n\]for all positive integers $m$ and $n$.
5 replies
Assassino9931
Yesterday at 1:47 PM
MathLuis
44 minutes ago
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Cyclic Points
IstekOlympiadTeam   38
N an hour ago by eg4334
Source: EGMO 2017 Day1 P1
Let $ABCD$ be a convex quadrilateral with $\angle DAB=\angle BCD=90^{\circ}$ and $\angle ABC> \angle CDA$. Let $Q$ and $R$ be points on segments $BC$ and $CD$, respectively, such that line $QR$ intersects lines $AB$ and $AD$ at points $P$ and $S$, respectively. It is given that $PQ=RS$.Let the midpoint of $BD$ be $M$ and the midpoint of $QR$ be $N$.Prove that the points $M,N,A$ and $C$ lie on a circle.
38 replies
IstekOlympiadTeam
Apr 8, 2017
eg4334
an hour ago
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2025 Caucasus MO Seniors P3
BR1F1SZ   1
N 2 hours ago by iliya8788
Source: Caucasus MO
A circle is drawn on the board, and $2n$ points are marked on it, dividing it into $2n$ equal arcs. Petya and Vasya are playing the following game. Petya chooses a positive integer $d \leqslant n$ and announces this number to Vasya. To win the game, Vasya needs to color all marked points using $n$ colors, such that each color is assigned to exactly two points, and for each pair of same-colored points, one of the arcs between them contains exactly $(d - 1)$ marked points. Find all $n$ for which Petya will be able to prevent Vasya from winning.
1 reply
BR1F1SZ
Mar 26, 2025
iliya8788
2 hours ago
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RGB chessboard
BR1F1SZ   0
2 hours ago
Source: 2025 Argentina TST P3
A $100 \times 100$ board has some of its cells coloured red, blue, or green. Each cell is coloured with at most one colour, and some cells may remain uncoloured. Additionally, there is at least one cell of each colour. Two coloured cells are said to be friends if they have different colours and lie in the same row or in the same column. The following conditions are satisfied:
[list=i]
[*]Each coloured cell has exactly three friends.
[*]All three friends of any given coloured cell lie in the same row or in the same column.
[/list]
Determine the maximum number of cells that can be coloured on the board.
0 replies
BR1F1SZ
2 hours ago
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an easy geometry from iran tst
Etemadi   8
N Mar 29, 2025 by amirhsz
Source: Iranian TST 2018, third exam day 1, problem 1
Two circles $\omega_1(O)$ and $\omega_2$ intersect each other at $A,B$ ,and $O$ lies on $\omega_2$. Let $S$ be a point on $AB$ such that $OS\perp AB$. Line $OS$ intersects $\omega_2$  at $P$ (other than $O$). The bisector of $\hat{ASP}$ intersects  $\omega_1$ at $L$ ($A$ and $L$ are on the same side of the line $OP$). Let $K$ be a point on $\omega_2$ such that $PS=PK$ ($A$ and $K$ are on the same side of the line $OP$). Prove that $SL=KL$.

Proposed by Ali Zamani
8 replies
Etemadi
Apr 18, 2018
amirhsz
Mar 29, 2025
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an easy geometry from iran tst
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Reveal topic tags
geometry
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Iranian TST
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Source: Iranian TST 2018, third exam day 1, problem 1
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Etemadi
24 posts
Etemadi
#1 Apr 18, 2018, 3:32 PM • 2 Y
Y by Adventure10, Mango247
Two circles $\omega_1(O)$ and $\omega_2$ intersect each other at $A,B$ ,and $O$ lies on $\omega_2$. Let $S$ be a point on $AB$ such that $OS\perp AB$. Line $OS$ intersects $\omega_2$  at $P$ (other than $O$). The bisector of $\hat{ASP}$ intersects  $\omega_1$ at $L$ ($A$ and $L$ are on the same side of the line $OP$). Let $K$ be a point on $\omega_2$ such that $PS=PK$ ($A$ and $K$ are on the same side of the line $OP$). Prove that $SL=KL$.

Proposed by Ali Zamani
This post has been edited 2 times. Last edited by Etemadi, Apr 21, 2018, 3:42 PM
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achen29
561 posts
achen29
#2 Apr 18, 2018, 4:52 PM • 2 Y
Y by Adventure10, Mango247
Okay so this thing took me like 10 minutes to draw lol. Wording kinda threw me off

After some angle chasing; this reduces to: show that $\angle LKP =45 $ deg

We let the intersection point of lines SL and KP be X; and that of KL and SP be Y. This transforms the problem into showing that quadrilateral $SKXY$ is cyclic. Anyone can pick up?
This post has been edited 1 time. Last edited by achen29, Apr 18, 2018, 4:52 PM
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Yaghi
412 posts
Yaghi
#3 Apr 18, 2018, 5:50 PM • 3 Y
Y by brokendiamond, Adventure10, Mango247
Let $PK \cap AB=T$ and let $L'$ be the foot of tangent from $T$ to $w_1$ such that $L',P$ lie on the same side of $AB$.Obviously,$O,S,L',K,T$ are on a circle with diameter $OT$,Also,by POP:
$$PK.PT=PS.PO \implies PO=PT$$Again,by POP for $T$:
$$TA.TB=TK.TP=OP.OS=OA^2 \implies TL'=OA=OL' \implies \angle TOL'=\angle L'TO=45=\angle L'SP$$and since $L'$ is on $w_1$,we deduce that $L' \equiv L$.This ends the problem because $L$ is the midpoint of arc $SK$ in $(OSLKT)$ so $LK=LS$.
This post has been edited 1 time. Last edited by Yaghi, Apr 18, 2018, 5:53 PM
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Flash_Sloth
230 posts
Flash_Sloth
#4 May 31, 2019, 2:02 AM • 1 Y
Y by Adventure10
Let $C = OK\cap AB$, draw the line $PC$ intersect $\odot O$ at $L'$ and $D$, we will prove that $L'$ coincide with $L$. First, by power of point at $C$, we have
\[ CK \cdot CO = CA \cdot CB = CD \cdot CL' \]Thus $K,D,O,L'$ concyclic. Moreover, $PA$ is tangent to $\odot O$ since $O \in \omega_2$, yielding $PL' \cdot PD = PA^2 = PS \cdot PO$, thus $D,O,S,L'$ concyclic as well, meaning that $K,D,O,S,L',$ lies on the same circle.

Now remarking that $\angle CKP = \angle CSP = 90^\circ$ and $PK=PS$, we have $PC$ is the orthogonal bisector of $KS$. Thus $\angle L'SC = \angle L'KC =\angle L'DO =\angle L'SP$, implying that $L'S$ bisects the angle $\angle ASL$, thus $L'$ coincides with $L$ which means $L$ lies $PC$, the orthogonal bisector of $KS$.
Attachments:
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AlastorMoody
2125 posts
AlastorMoody
#5 May 31, 2019, 1:13 PM • 2 Y
Y by Adventure10, Mango247
Iran TST #3 2018 P1 wrote:
Two circles $\omega_1(O)$ and $\omega_2$ intersect each other at $A,B$ ,and $O$ lies on $\omega_2$. Let $S$ be a point on $AB$ such that $OS\perp AB$. Line $OS$ intersects $\omega_2$  at $P$ (other than $O$). The bisector of $\hat{ASP}$ intersects  $\omega_1$ at $L$ ($A$ and $L$ are on the same side of the line $OP$). Let $K$ be a point on $\omega_2$ such that $PS=PK$ ($A$ and $K$ are on the same side of the line $OP$). Prove that $SL=KL$.
Solution: Let $C \in (O)$, such, $\angle CSP=\angle ASC=45^{\circ}$. Let $CP \cap (O)=D$. Since, $\angle OAP=90^{\circ}$
$$-1=( D, ~C ; ~ B, ~A ) \overset{A}{=} ( D, ~C ; AB ~ \cap ~ DP , ~ P) \implies D \equiv L$$Let $L', K'$ be reflections of $L, K$ over $OP$.
$$\angle LSO=\angle CSP=\angle L'SO \implies L' - S - C$$Let $C'$ be the reflection of $C$ over $OP$ $\implies$ $L - S - C'$ and $L' - C' - P$
$$\angle LOC=2\angle LL'S=\angle LSC \implies LOSC \text{ and similarly, } L'OSC' \text{ are cyclic}$$Also, $\angle OKP=\angle OK'P=90^{\circ}$ $\implies$ $OK, OK'$ are tangent to $\odot (P)$ with radius $PS=PK$. Let $LC', L'C$ $\cap$ $\odot (P)$ $=$ $D', D$, then, $D'$ is the reflection of $D$ over $OS$ and $\angle DSD'=90^{\circ}$ $\implies$ $D - P - D'$. Let $LP$ $\cap$ $\odot (AOP)$ $=$ $E$, then by Radical Axes Theorem, $EO$ $\cap$ $AB$ $=$ $G$ lies on tangent at $L$ to $(O)$. By some simple congruency, $E$ is the center of $\odot (LOSCG)$. Suppose, $PE$ $\cap$ $AB$ $=$ $M$ $\implies$ $M$ is the orthocenter WRT $\Delta OGP$ ($OP=OG$). Let $GP$ $\cap$ $\odot (AOP)$ $=$ $K'$ $\implies$ $O - M - K'$, but then, $PS$ $=$ $PK'$ $\implies$ $K' \equiv K$ $\implies$ $K$ lies on $\odot (LOSCG)$ $\implies$ $LP$ is the perpendicular bisector of $SK$
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Kagebaka
3001 posts
Kagebaka
#6 Jan 2, 2020, 7:32 PM • 2 Y
Y by AlastorMoody, Adventure10
Let $\omega$ be the circumcircle of $\triangle KSO$ and $D=PK\cap AB.$ First, observe that $PK=PS\implies \triangle SDP\cong \triangle KOP$ by LL, so $ODKS$ is an isosceles trapezoid and $D\in\omega.$ Since $DS\cap OK$ is the radical center of $\omega,\omega_1,\omega_2,$ the perpendicular bisector of $OD$ is the radical axis of $\omega,\omega_1.$ Now note that since the the intersection of the angle bisector of $\angle ASP$ with $\omega$ lies on the perpendicular bisector of $SK,$ it must lie on $\omega_1$ as well so this point must be $L.$ $\blacksquare$
This post has been edited 2 times. Last edited by Kagebaka, Mar 12, 2020, 3:29 PM
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HamstPan38825
8857 posts
HamstPan38825
#7 Sep 3, 2022, 6:29 PM
Y by
As $$OL^2=OA^2=OS \cdot OP$$we have the similarity $$\triangle OSL \sim \triangle OLP,$$so $\angle OLP = 135^\circ$.

Let $K' = (OSL) \cap (OP)$. Then $\angle OK'L = 45^\circ$ and $\overline{K'L}$ thus bisects $\angle OK'P$. But as $$\angle OLP = 135^\circ= 90^\circ + \frac 12 \angle OK'P,$$$L$ is in fact the incenter of $\triangle OK'P$. Thus, $\angle K'PL = \angle PLS$, so $$\triangle K'LP \cong \triangle SLP.$$This means $PK' = PS$, so $K'=K$; but this congruence also implies $LK=LS$, so we are done.
This post has been edited 1 time. Last edited by HamstPan38825, Sep 3, 2022, 6:29 PM
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demmy
133 posts
demmy
#8 Dec 11, 2023, 7:16 AM • 1 Y
Y by Tung_HP
Coord bash :(
This post has been edited 2 times. Last edited by demmy, Dec 11, 2023, 7:17 AM
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amirhsz
18 posts
amirhsz
#9 Mar 29, 2025, 12:03 PM
Y by
Let $X$ be the intersection of $OK$ and $AS$. We know $XKP= XSP = 90$ so $XSPK$ is cyclic. $XK$ and $XS$ are tangent to the circle with centred on $P$ and radious $PK$ so $XS=XK$ so $XP$ is the perpendicular bisector of $KS$. Let $L'$ be the intersection of $XP$ and $w_1$. Now we have $OAP=90$ and $ASP=90$ so $OA^2=OS.OP=OL'^2$ so $OL'S=OPL= XKS$ so $OSL'K$ Is cyclic. so $L'KO=L'SP=L'KP$ because $L'$ lies on perpendicular bisector of $KS$. And we have $OKP=90$ so $OKL'=OKP/2=45=L'SP$ so $L'$ is the $L$ and lies on perpendicular bisector of $KS$.
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