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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
J
H
powers sums and triangular numbers
gaussious   4
N 6 minutes ago by kiyoras_2001
prove 1^k+2^k+3^k + \cdots + n^k \text{is divisible by } \frac{n(n+1)}{2} \text{when} k \text{is odd}
4 replies
gaussious
Yesterday at 1:00 PM
kiyoras_2001
6 minutes ago
J
H
complex bashing in angles??
megahertz13   2
N 10 minutes ago by ali123456
Source: 2013 PUMAC FA2
Let $\gamma$ and $I$ be the incircle and incenter of triangle $ABC$. Let $D$, $E$, $F$ be the tangency points of $\gamma$ to $\overline{BC}$, $\overline{CA}$, $\overline{AB}$ and let $D'$ be the reflection of $D$ about $I$. Assume $EF$ intersects the tangents to $\gamma$ at $D$ and $D'$ at points $P$ and $Q$. Show that $\angle DAD' + \angle PIQ = 180^\circ$.
2 replies
megahertz13
Nov 5, 2024
ali123456
10 minutes ago
J
H
number theory
Levieee   1
N 34 minutes ago by Lil_flip38
Idk where it went wrong, marks was deducted for this solution
$\textbf{Question}$
Show that for a fixed pair of distinct positive integers \( a \) and \( b \), there cannot exist infinitely many \( n \in \mathbb{Z} \) such that
\[ \sqrt{n + a} + \sqrt{n + b} \in \mathbb{Z}. \]
$\textbf{Solution}$

Let
\[ x = \sqrt{n + a} + \sqrt{n + b} \in \mathbb{N}. \]
Then,
\[ x^2 = (\sqrt{n + a} + \sqrt{n + b})^2 = (n + a) + (n + b) + 2\sqrt{(n + a)(n + b)}. \]So:
\[ x^2 = 2n + a + b + 2\sqrt{(n + a)(n + b)}. \]
Therefore,
\[ \sqrt{(n + a)(n + b)} \in \mathbb{N}. \]
Let
\[ (n + a)(n + b) = k^2. \]Assume \( n + a \neq n + b \). Then we have:
\[ n + a \mid k \quad \text{and} \quad k \mid n + b, \]or it could also be that \( k \mid n + a \quad \text{and} \quad n + b \mid k \).

Without loss of generality, we take the first case:
\[ (n + a)k_1 = k \quad \text{and} \quad kk_2 = n + b. \]
Thus,
\[ k_1 k_2 = \frac{n + b}{n + a}. \]
Since \( k_1 k_2 \in \mathbb{N} \), we have:
\[ k_1 k_2 = 1 + \frac{b - a}{n + a}. \]
For infinitely many \( n \), \( \frac{b - a}{n + a} \) must be an integer, which is not possible.

Therefore, there cannot be infinitely many such \( n \).
1 reply
Levieee
an hour ago
Lil_flip38
34 minutes ago
J
H
f(x+y+f(y)) = f(x) + f(ay)
the_universe6626   5
N 44 minutes ago by deduck
Source: Janson MO 4 P5
For a given integer $a$, find all functions $f:\mathbb{Z}\rightarrow\mathbb{Z}$ such that
\[f(x+y+f(y))=f(x)+f(ay)\]holds for all $x,y\in\mathbb{Z}$.

(Proposed by navi_09220114)
5 replies
the_universe6626
Feb 21, 2025
deduck
44 minutes ago
J
No more topics!
H
J
H
Another config geo with concurrent lines
a_507_bc   15
N Apr 5, 2025 by E50
Source: BMO SL 2023 G5
Let $ABC$ be a triangle with circumcenter $O$. Point $X$ is the intersection of the parallel line from $O$ to $AB$ with the perpendicular line to $AC$ from $C$. Let $Y$ be the point where the external bisector of $\angle BXC$ intersects with $AC$. Let $K$ be the projection of $X$ onto $BY$. Prove that the lines $AK, XO, BC$ have a common point.
15 replies
a_507_bc
May 3, 2024
E50
Apr 5, 2025
J
Another config geo with concurrent lines
G H J
Reveal topic tags
geometry
AZE BMO TST
TST
L
G H BBookmark kLocked kLocked NReply
Source: BMO SL 2023 G5
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a_507_bc
676 posts
a_507_bc
#1 May 3, 2024, 10:19 AM • 2 Y
Y by lian_the_noob12, Rounak_iitr
Let $ABC$ be a triangle with circumcenter $O$. Point $X$ is the intersection of the parallel line from $O$ to $AB$ with the perpendicular line to $AC$ from $C$. Let $Y$ be the point where the external bisector of $\angle BXC$ intersects with $AC$. Let $K$ be the projection of $X$ onto $BY$. Prove that the lines $AK, XO, BC$ have a common point.
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bin_sherlo
700 posts
bin_sherlo
#2 May 3, 2024, 11:54 AM • 3 Y
Y by Om245, farhad.fritl, At777
$XO\cap BC=S$. Let $A'$ be the antipode of $A$ in $(ABC)$. $X,A',C$ are collinear. Let the tangents at $B,C$ to $(ABC)$ intersect at $T$.

Claim $1$: $X\in (BOC)$.
Proof: $\angle OXC=\angle SXB=\angle XSB-\angle XCS=\angle B-(90-\angle C)=90-\angle A=\angle OBC$ which gives that $X\in (BOC)$.$\square$

$\angle BXO=90-\angle A=\angle OXC$ thus $OX$ is the interior angle bisector of $\angle BXC\implies OX\perp XY$

Claim $2$: $K\in (ABC)$.
Proof: $\angle BKC=180-\angle CKY=180-\angle CXY=90+\angle OXC=180-\angle A$ Hence $ABCK$ is cyclic.$\square$

Claim $2$ gives that $X,K,B'$ are collinear where $B'$ is the antipode of $B$ on $(ABC)$.

Finishing Claim: $A,S,K$ are collinear.
Proof: Pascal at $A'AKB'BC$ gives that $O,AK\cap BC,X$ are collinear $\iff AK\cap BC=S$ as desired.$\blacksquare$
Z K Y
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VicKmath7
1388 posts
VicKmath7
#3 May 3, 2024, 12:30 PM
Y by
Solution
Z K Y
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Orestis_Lignos
555 posts
Orestis_Lignos
#4 May 3, 2024, 2:53 PM • 1 Y
Y by parmenides51
Proposed by Jason Prodromidis and Minos Margaritis, Greece :)
Z K Y
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squarc_rs3v2m
46 posts
squarc_rs3v2m
#5 May 4, 2024, 1:09 AM • 2 Y
Y by Scilyse, ohiorizzler1434
All of the above solutions are incorrect, because the problem is false.

The official solution assumes that $XO$ internally bisects $\angle BXC$, but this does not hold in general (see attached image below) and while $BOCX$ is necessarily cyclic, $O$ is an arc midpoint but not necessarily the midpoint of the arc $BC$ not containing $X$.

This failure can also occur when $\angle B$, $\angle C$ are acute and $\angle A$ is obtuse. However, the problem is fine when $\triangle ABC$ is constrained to be acute overall.

https://cdn.discordapp.com/attachments/799475903569592340/1236120831638372483/image.png?ex=6636dabc&is=6635893c&hm=51afb14d812cad898d8a0f488476759f38c60ee3a953d0ae583cdf57c69c1f1d&
Z K Y
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Tellocan
35 posts
Tellocan
#6 May 4, 2024, 10:44 AM
Y by
squarc_rs3v2m wrote:
All of the above solutions are incorrect, because the problem is false.

The official solution assumes that $XO$ internally bisects $\angle BXC$, but this does not hold in general (see attached image below) and while $BOCX$ is necessarily cyclic, $O$ is an arc midpoint but not necessarily the midpoint of the arc $BC$ not containing $X$.

This failure can also occur when $\angle B$, $\angle C$ are acute and $\angle A$ is obtuse. However, the problem is fine when $\triangle ABC$ is constrained to be acute overall.

https://cdn.discordapp.com/attachments/799475903569592340/1236120831638372483/image.png?ex=6636dabc&is=6635893c&hm=51afb14d812cad898d8a0f488476759f38c60ee3a953d0ae583cdf57c69c1f1d&

İ agree, the problem statement must include the triangle being acute.
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matematica007
17 posts
matematica007
#7 May 4, 2024, 1:24 PM
Y by
How $\angle XKY=\angle XCY=90^{\circ}$ we have that $XKCY$ is cyclic.
Point $X$ is the intersection of the parallel line from $O$ to $AB$ with the perpendicular line to $AC$ from $C$ so $\angle OXC=90^{\circ}-\angle A=\angle OBC=\angle OCB$ so $OBXC$ is cyclic. This implies that $\angle BXC=180^{\circ}-2\angle A$ so $\angle YXC=\angle YKC=\angle A$ so $\angle BKC= 180^{\circ}-\angle A$ so $ABKC$ is cyclic.

We will prove that $AOKX$ is cyclic. After some easy angle chasing we have $\angle XKA=90^{\circ}+\angle C= \angle XOA $ so $AOKX$ is cyclic.

New we have that $AK$ is radical axis of circles $(ABKC)$ and $(XKOA)$ , $XO$ is radical axis of circles $(XBOC)$ and $(XKOA)$ and $BC$ is radical axis of circles $(ABKC)$ and $(XBOC)$.So the lines $AK, XO, BC$ have a common point.
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motannoir
171 posts
motannoir
#8 May 4, 2024, 1:44 PM • 1 Y
Y by Assassino9931
Sketch: Let $S=XO\cap BC$ ;prove by angles that $BOCX$ is cyclic ,then it is trvial that $XKCY$ is cyclic,use this to prove $K\in (ABC)$ and now prove(again by angles) that $AOKX$ is cyclic.Now use radical axes on $AOKX,ABKC,BOCX$ to get that $AK,OX,BC$ are concurrent
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Z4ADies
63 posts
Z4ADies
#9 May 10, 2024, 7:22 AM
Y by
It is very trivial problem for G5
$\angle CAO=\angle OCA= x$
$\angle OBC=\angle OCB=y$
$\angle OAB=\angle OBA=90-x-y$
From parallelity of $OX,AB$ $\implies$ $\angle ABO=\angle BOX=90-x-y$
Similarly from perpendicularity of $AC,AX$ $\implies$ $\angle BCX=90-x-y$
Thus, $BOCX$ is cyclic that will be our hint to prove concurrency with radical axes are concurr at some point.
We have to deduce $ABKC$ and $AOKX$ cyclic.
$(.....1)$ $KXYC$ is cyclic because $XK$ is perpendicular to $BY$ and $AY$ is perpendicular to $XC$
From $(.....1)$ $\angle CXY=\angle CKY=90-y$ and we have $\angle BAC=90-y$ thus $ABKC$ cyclic.
Let $\angle OXK= z$ $\implies$ $\angle KXC=y-z$ from $(.....1)$ $\angle KYA=y-z$ , $\angle AKY=180-x-y$ , and $\angle YAO=x$ it gives us $\angle KAO=z$ which means $AOXK$ cyclic.
We are done.
This post has been edited 3 times. Last edited by Z4ADies, May 10, 2024, 12:25 PM
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NuMBeRaToRiC
15 posts
NuMBeRaToRiC
#10 Jun 26, 2024, 7:21 PM
Y by
By easy angle chasing we get that $XBOC$ cyclic. Let $XO\cap BC=D$, $AK\cap XD=M$ and . By BMO 2022 G2 we get that $M$ midpoint of $XD$. Incenter $I$ and excenter $I'$ of triangle $BXC$ lies on $ABC$. From $(X,D;I,I')=-1$ so $MX^2=MD^2=MI\cdot MI'$ so $\angle XCD=\angle FKD$. By easy angle chasing we get that $\angle FCB=90$.So $\angle FKD=\angle XCD=\angle FCA=\angle FKA$, from this we get that $K, D, A$ collinear.We are done.
This post has been edited 2 times. Last edited by NuMBeRaToRiC, Jun 26, 2024, 7:22 PM
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Ihatecombin
58 posts
Ihatecombin
#11 Dec 30, 2024, 8:30 AM
Y by
Nice problem, had a fun time doing it.
[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(10cm); real labelscalefactor = 0.5; /* changes label-to-point distance */ pen dps = linewidth(0.7) + fontsize(10); defaultpen(dps); /* default pen style */ pen dotstyle = black; /* point style */ real xmin = -5.974725338137207, xmax = 30.033727935533033, ymin = -11.465676723098179, ymax = 12.099250581265741; /* image dimensions */ /* draw figures */ draw(circle((5,5), 5), linewidth(0.4)); draw((3.322736366511161,9.71028520408009)--(0.6972183465910291,2.4532235977441674), linewidth(0.4)); draw((0.6972183465910291,2.4532235977441674)--(9.302781653408971,2.4532235977441674), linewidth(0.4)); draw((9.302781653408971,2.4532235977441674)--(3.322736366511161,9.71028520408009), linewidth(0.4)); draw((0.6972183465910291,2.4532235977441674)--(1.859615688652539,-3.6801774895883588), linewidth(0.4)); draw((0.6972183465910291,2.4532235977441674)--(19.665169827022172,-10.122013838908856), linewidth(0.4)); draw((1.859615688652539,-3.6801774895883588)--(4.329421138984925,0.04517164866836985), linewidth(0.4)); draw((0.6972183465910291,2.4532235977441674)--(6.677263633488835,0.2897147959199078), linewidth(0.4)); draw((4.078606783358132,2.4532235977441683)--(6.677263633488835,0.2897147959199078), linewidth(0.4)); draw((4.078606783358132,2.4532235977441683)--(4.329421138984925,0.04517164866836985), linewidth(0.4)); draw((4.329421138984925,0.04517164866836985)--(6.677263633488835,0.2897147959199078), linewidth(0.4)); draw((4.329421138984925,0.04517164866836985)--(3.6872409900399328,1.3714691968320367), linewidth(0.4)); draw((3.322736366511161,9.71028520408009)--(6.677263633488835,0.2897147959199078), linewidth(0.4)); draw((0.6972183465910251,7.5467764022558255)--(3.6872409900399328,1.3714691968320367), linewidth(0.4)); draw((0.6972183465910251,7.5467764022558255)--(6.677263633488835,0.2897147959199078), linewidth(0.4)); draw((0.6972183465910251,7.5467764022558255)--(9.302781653408971,2.4532235977441674), linewidth(0.4)); draw((5,5)--(1.859615688652539,-3.6801774895883588), linewidth(0.4)); draw((1.859615688652539,-3.6801774895883588)--(9.302781653408971,2.4532235977441674), linewidth(0.4)); draw((19.665169827022172,-10.122013838908856)--(1.859615688652539,-3.6801774895883588), linewidth(0.4)); draw((9.302781653408971,2.4532235977441674)--(19.665169827022172,-10.122013838908856), linewidth(0.4)); draw(circle((1.2784170176217802,-0.6134769459221007), 3.1212888555420335), linewidth(0.6) + green); draw(circle((5.377935208423484,1.3714691968320383), 1.6906942183835514), linewidth(0.6) + red); /* dots and labels */ dot((5,5),linewidth(3pt) + dotstyle); label("$O$", (5.094827972055157,5.151615248405972), NE * labelscalefactor); dot((3.322736366511161,9.71028520408009),linewidth(3pt) + dotstyle); label("$A$", (3.4356911761481044,9.869785511765965), NE * labelscalefactor); dot((0.6972183465910291,2.4532235977441674),linewidth(3pt) + dotstyle); label("$B$", (0.7914419076712397,2.6110620296736675), NE * labelscalefactor); dot((9.302781653408971,2.4532235977441674),linewidth(3pt) + dotstyle); label("$C$", (9.398214036439073,2.6110620296736675), NE * labelscalefactor); dot((1.859615688652539,-3.6801774895883588),linewidth(3pt) + dotstyle); label("$X$", (1.9580224672933857,-3.5329289176687406), NE * labelscalefactor); dot((19.665169827022172,-10.122013838908856),linewidth(3pt) + dotstyle); label("$Y$", (19.76781901085815,-9.962084001807632), NE * labelscalefactor); dot((4.329421138984925,0.04517164866836985),linewidth(3pt) + dotstyle); label("$K$", (4.420803648717916,0.20012887312158348), NE * labelscalefactor); dot((4.078606783358132,2.4532235977441683),linewidth(3pt) + dotstyle); label("$D$", (4.187487536793487,2.6110620296736675), NE * labelscalefactor); dot((6.677263633488835,0.2897147959199078),linewidth(3pt) + dotstyle); label("$A'$", (6.779888780398257,0.4334449850459787), NE * labelscalefactor); dot((3.6872409900399328,1.3714691968320367),linewidth(3pt) + dotstyle); label("$M$", (3.798627350252772,1.5222535073598231), NE * labelscalefactor); dot((0.6972183465910251,7.5467764022558255),linewidth(3pt) + dotstyle); label("$C'$", (0.7914419076712397,7.692168467138275), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
Sketch of solution
We now begin with the proof. All points not found in the problem statement are defined in the sketch of the solution. We begin with a small claim.
Claim 1: $XC \cap (ABC) = A'$
Proof
Claim 2: $OX$ bisects $\angle BDA'$ and $\angle BXA'$
Proof
Claim 3: $BMKX$ is cyclic
Proof
Claim 3: $MKA'D$ is cyclic
Proof
Now we are done, just notice that by claim $4$ we have $\angle DKA' = \angle DMA' = 90$, however we also have $\angle AKA' = 90$, thus it must be true that $A-D-K$.
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Nari_Tom
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Nari_Tom
#12 Jan 30, 2025, 5:37 AM
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Similar sketch.

Let $OX\cap BC=X'$. Let $\omega$ be the center with the diameter $OX'$. Let $Z', Y'$ be the intersection of $(AOB),(AOC)$ with $\omega$. Let $Y,Z$ be the intersections of $OY', OZ'$ with $AB,AC$, respectively. We will get that $X$ is the foot of the altitude of $\triangle OYZ$. Let $ZC \cap BY=K$. Then $K$ lies on the $(ABC)$.

Let $BC \cap ZY=D$ and $M$ be the midpoint of $BC$. Then we have that $(AD,AK;AB,AC)=-1$. We want to show that $A-X'-K$. So it's suffices to prove $(B,C;D,X')=-1$.

Since $ZY$ is the radical axis of $(ABC),\omega$ and $D$ lies on it we will get that $DB*DC=DX'*DM$ which only happens when $(B,C;D,X')=-1$, and we are done.
This post has been edited 1 time. Last edited by Nari_Tom, Jan 30, 2025, 5:40 AM
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SimplisticFormulas
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SimplisticFormulas
#13 Jan 30, 2025, 5:50 PM
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Draq
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Draq
#14 Feb 24, 2025, 9:06 AM
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Let $\angle CAB =x \angle CBA=y \angle ACB=z$ $\because AB $is parallel to $DX$ $\therefore \angle ABD= \angle BDX $
which is equal to y and $\because AC$ is perpendicular to $ XC$ $\angle ACB = 90- \angle BCX $ $ \therefore$ $ \angle BCX=90-z$
İn triangle $ DCX$ $\angle BDX=\angle DXC+ \angle DCX$ $\therefore$ $\angle DXC = 90-x=\angle OXC= \angle OBC $ $OBXC$ is cyclic
$\angle XCY =\angle XKY =90$ also $\angle OXB=\angle OCB=90-x$ $XD$ angle bisector also $XY$ external angle bisector so $XD$ is perpendicular to $XY$ so $\angle CXY =x$ then $\angle CKY=x$ which means $ABKC $ is cyclic then $\angle AKB=\angle ACB=z$ so $\angle AKX=90+z$ and $ \angle OAK=90-z$ because of parallel $\angle AOX=90+z$ so AOKX cyclic and by radical axis theorem AK BC XO are concurrent at point $D$
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optimusprime154
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optimusprime154
#15 Mar 10, 2025, 1:08 PM
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claim 1: \(BXOC\) concyclic:
proof: we know that \(\angle XOB = \angle OBA = 90 - \angle C\) and also \(\angle XCB = 90 - \angle C\) finishing the claim.
from now on, let \(S\) = \(OX \cap BC\) and \(K\) = \(XY \cap AB\) , \(R\) = \(CX \cap BK'\) and \(T\) = \(KC \cap BY\) first notice that \(OX \perp KY\) since \(OX\) is the bisector of \(\angle BXC\) , we know \(BXAY\) cyclic because \(\angle K'XB = \angle A\) we also know \(K'XCA\) cyclic for obvious reasons.
claim 2: \(BTXK'\) cyclic.
this just follows from the fact that \(\angle XBT = \angle XBY = \angle XAY = \angle XAC = \angle XK'C = \angle XK'T\)
this means \(\angle K'TB = \angle K'XB = \angle A\) meaning \(T\) lies on the circle \(ABC\) . we Also got \(\angle XTB = \angle XK'B = 90\) so \(T\) is the foot from \(X\) to \(BY\)
claim 3: \(A, S, T\) collinear.
we first prove that \(XTOA\) is cyclic. which just follows from \(\angle XTA = \angle XTB + \angle BTA = 90 + \angle C = \angle XOA\)
now we let \(S'\) denote \(AT \cap BC\) we know that \(X, S', O\) must be collinear by PoP on \(ABTC\), \(XBOC\) , \(XTOA\) , since we know \(T\) is the foot from \(X\) to \(BY\), And \(AT\) \(BC\) \(OK\) concur At \(S\) so we're done!
This post has been edited 1 time. Last edited by optimusprime154, Mar 10, 2025, 3:29 PM
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E50
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E50
#16 Apr 5, 2025, 6:31 AM
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Claim 1 : $O,B,X,C$ concyclic

Proof : Let $Z=OX \cap BC$. Then $\angle OXC = \angle ZXC =90^\circ -\angle XZC = 90^\circ - \angle BAC = \frac{180^\circ -\angle BOC}{2}=\angle OBC \Longrightarrow O,B,X,C $ concyclic.

Claim 2 : $A,B,K,C$ concyclic.

Proof : Since $\angle XKY=90^\circ = \angle XCY \Longrightarrow X,K,C,Y$ cincyclic. Since $OB =OC$ and $O,B,X,C$ concyclic ; $\angle BXO = \angle CXO \Longrightarrow \angle CKY = \angle CXY =90^\circ - \angle OXC = \angle BAC \Longrightarrow A,B,K,C$ concyclic.

Claim 3 : $A,O,K,X$ concyclic.

Proof : Let $\angle ACB = \alpha$. Then $\angle AKX = 90^\circ + \alpha$, $\angle BOX = \angle BCX = 90^\circ - \alpha$, $\angle AOB = 2\angle ACB = 2\alpha \Longrightarrow \angle AOX = 90^\circ+\alpha \Longrightarrow \angle AKX = \angle AOX \Longrightarrow A,O,K,X $ concyclic.

And by Radical Axis Concurrence Theorem on $(AOKX),(ABKC),(OBXC)$ we obtain $AK,XO,BC$ have a common point as desired.
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