Art of Problem Solving
AoPS Online AoPS Online
Math texts, online classes, and more
for students in grades 5-12.
Visit AoPS Online
Books for Grades 5-12 Online Courses
Beast Academy Beast Academy
Engaging math books and online learning
for students ages 6-13.
Visit Beast Academy
Books for Ages 6-13 Beast Academy Online
AoPS Academy AoPS Academy
Small live classes for advanced math
and language arts learners in grades 1-12.
Visit AoPS Academy
Find a Physical Campus Visit the Virtual Campus

Stay ahead of learning milestones! Enroll in a class over the summer!
No tags match your search
M
G
Topic
First Poster
Last Poster
H
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.

WOOT early bird pricing is in effect, don’t miss out! If you took MathWOOT Level 2 last year, no worries, it is all new problems this year! Our Worldwide Online Olympiad Training program is for high school level competitors. AoPS designed these courses to help our top students get the deep focus they need to succeed in their specific competition goals. Check out the details at this link for all our WOOT programs in math, computer science, chemistry, and physics.

Looking for summer camps in math and language arts? Be sure to check out the video-based summer camps offered at the Virtual Campus that are 2- to 4-weeks in duration. There are middle and high school competition math camps as well as Math Beasts camps that review key topics coupled with fun explorations covering areas such as graph theory (Math Beasts Camp 6), cryptography (Math Beasts Camp 7-8), and topology (Math Beasts Camp 8-9)!

Be sure to mark your calendars for the following events:
[list][*]April 3rd (Webinar), 4pm PT/7:00pm ET, Learning with AoPS: Perspectives from a Parent, Math Camp Instructor, and University Professor
[*]April 8th (Math Jam), 4:30pm PT/7:30pm ET, 2025 MATHCOUNTS State Discussion
April 9th (Webinar), 4:00pm PT/7:00pm ET, Learn about Video-based Summer Camps at the Virtual Campus
[*]April 10th (Math Jam), 4:30pm PT/7:30pm ET, 2025 MathILy and MathILy-Er Math Jam: Multibackwards Numbers
[*]April 22nd (Webinar), 4:00pm PT/7:00pm ET, Competitive Programming at AoPS (USACO).[/list]
Our full course list for upcoming classes is below:
All classes run 7:30pm-8:45pm ET/4:30pm - 5:45pm PT unless otherwise noted.

Introductory: Grades 5-10

Prealgebra 1 Self-Paced

Prealgebra 1
Sunday, Apr 13 - Aug 10
Tuesday, May 13 - Aug 26
Thursday, May 29 - Sep 11
Sunday, Jun 15 - Oct 12
Monday, Jun 30 - Oct 20
Wednesday, Jul 16 - Oct 29

Prealgebra 2 Self-Paced

Prealgebra 2
Sunday, Apr 13 - Aug 10
Wednesday, May 7 - Aug 20
Monday, Jun 2 - Sep 22
Sunday, Jun 29 - Oct 26
Friday, Jul 25 - Nov 21

Introduction to Algebra A Self-Paced

Introduction to Algebra A
Monday, Apr 7 - Jul 28
Sunday, May 11 - Sep 14 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Wednesday, May 14 - Aug 27
Friday, May 30 - Sep 26
Monday, Jun 2 - Sep 22
Sunday, Jun 15 - Oct 12
Thursday, Jun 26 - Oct 9
Tuesday, Jul 15 - Oct 28

Introduction to Counting & Probability Self-Paced

Introduction to Counting & Probability
Wednesday, Apr 16 - Jul 2
Thursday, May 15 - Jul 31
Sunday, Jun 1 - Aug 24
Thursday, Jun 12 - Aug 28
Wednesday, Jul 9 - Sep 24
Sunday, Jul 27 - Oct 19

Introduction to Number Theory
Thursday, Apr 17 - Jul 3
Friday, May 9 - Aug 1
Wednesday, May 21 - Aug 6
Monday, Jun 9 - Aug 25
Sunday, Jun 15 - Sep 14
Tuesday, Jul 15 - Sep 30

Introduction to Algebra B Self-Paced

Introduction to Algebra B
Wednesday, Apr 16 - Jul 30
Tuesday, May 6 - Aug 19
Wednesday, Jun 4 - Sep 17
Sunday, Jun 22 - Oct 19
Friday, Jul 18 - Nov 14

Introduction to Geometry
Wednesday, Apr 23 - Oct 1
Sunday, May 11 - Nov 9
Tuesday, May 20 - Oct 28
Monday, Jun 16 - Dec 8
Friday, Jun 20 - Jan 9
Sunday, Jun 29 - Jan 11
Monday, Jul 14 - Jan 19

Intermediate: Grades 8-12

Intermediate Algebra
Monday, Apr 21 - Oct 13
Sunday, Jun 1 - Nov 23
Tuesday, Jun 10 - Nov 18
Wednesday, Jun 25 - Dec 10
Sunday, Jul 13 - Jan 18
Thursday, Jul 24 - Jan 22

Intermediate Counting & Probability
Wednesday, May 21 - Sep 17
Sunday, Jun 22 - Nov 2

Intermediate Number Theory
Friday, Apr 11 - Jun 27
Sunday, Jun 1 - Aug 24
Wednesday, Jun 18 - Sep 3

Precalculus
Wednesday, Apr 9 - Sep 3
Friday, May 16 - Oct 24
Sunday, Jun 1 - Nov 9
Monday, Jun 30 - Dec 8

Advanced: Grades 9-12

Olympiad Geometry
Tuesday, Jun 10 - Aug 26

Calculus
Tuesday, May 27 - Nov 11
Wednesday, Jun 25 - Dec 17

Group Theory
Thursday, Jun 12 - Sep 11

Contest Preparation: Grades 6-12

MATHCOUNTS/AMC 8 Basics
Wednesday, Apr 16 - Jul 2
Friday, May 23 - Aug 15
Monday, Jun 2 - Aug 18
Thursday, Jun 12 - Aug 28
Sunday, Jun 22 - Sep 21
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

MATHCOUNTS/AMC 8 Advanced
Friday, Apr 11 - Jun 27
Sunday, May 11 - Aug 10
Tuesday, May 27 - Aug 12
Wednesday, Jun 11 - Aug 27
Sunday, Jun 22 - Sep 21
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

AMC 10 Problem Series
Friday, May 9 - Aug 1
Sunday, Jun 1 - Aug 24
Thursday, Jun 12 - Aug 28
Tuesday, Jun 17 - Sep 2
Sunday, Jun 22 - Sep 21 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Monday, Jun 23 - Sep 15
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

AMC 10 Final Fives
Sunday, May 11 - Jun 8
Tuesday, May 27 - Jun 17
Monday, Jun 30 - Jul 21

AMC 12 Problem Series
Tuesday, May 27 - Aug 12
Thursday, Jun 12 - Aug 28
Sunday, Jun 22 - Sep 21
Wednesday, Aug 6 - Oct 22

AMC 12 Final Fives
Sunday, May 18 - Jun 15

F=ma Problem Series
Wednesday, Jun 11 - Aug 27

WOOT Programs
Visit the pages linked for full schedule details for each of these programs!

MathWOOT Level 1
MathWOOT Level 2
ChemWOOT
CodeWOOT
PhysicsWOOT

Programming

Introduction to Programming with Python
Thursday, May 22 - Aug 7
Sunday, Jun 15 - Sep 14 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Tuesday, Jun 17 - Sep 2
Monday, Jun 30 - Sep 22

Intermediate Programming with Python
Sunday, Jun 1 - Aug 24
Monday, Jun 30 - Sep 22

USACO Bronze Problem Series
Tuesday, May 13 - Jul 29
Sunday, Jun 22 - Sep 1

Physics

Introduction to Physics
Wednesday, May 21 - Aug 6
Sunday, Jun 15 - Sep 14
Monday, Jun 23 - Sep 15

Physics 1: Mechanics
Thursday, May 22 - Oct 30
Monday, Jun 23 - Dec 15

Relativity
Sat & Sun, Apr 26 - Apr 27 (4:00 - 7:00 pm ET/1:00 - 4:00pm PT)
Mon, Tue, Wed & Thurs, Jun 23 - Jun 26 (meets every day of the week!)
0 replies
jlacosta
Apr 2, 2025
0 replies
J
H
k i Adding contests to the Contest Collections
dcouchman   1
N Apr 5, 2023 by v_Enhance
Want to help AoPS remain a valuable Olympiad resource? Help us add contests to AoPS's Contest Collections.

Find instructions and a list of contests to add here: https://artofproblemsolving.com/community/c40244h1064480_contests_to_add
1 reply
dcouchman
Sep 9, 2019
v_Enhance
Apr 5, 2023
J
H
k i Zero tolerance
ZetaX   49
N May 4, 2019 by NoDealsHere
Source: Use your common sense! (enough is enough)
Some users don't want to learn, some other simply ignore advises.
But please follow the following guideline:


To make it short: ALWAYS USE YOUR COMMON SENSE IF POSTING!
If you don't have common sense, don't post.


More specifically:

For new threads:


a) Good, meaningful title:
The title has to say what the problem is about in best way possible.
If that title occured already, it's definitely bad. And contest names aren't good either.
That's in fact a requirement for being able to search old problems.

Examples:
Bad titles:
- "Hard"/"Medium"/"Easy" (if you find it so cool how hard/easy it is, tell it in the post and use a title that tells us the problem)
- "Number Theory" (hey guy, guess why this forum's named that way¿ and is it the only such problem on earth¿)
- "Fibonacci" (there are millions of Fibonacci problems out there, all posted and named the same...)
- "Chinese TST 2003" (does this say anything about the problem¿)
Good titles:
- "On divisors of a³+2b³+4c³-6abc"
- "Number of solutions to x²+y²=6z²"
- "Fibonacci numbers are never squares"


b) Use search function:
Before posting a "new" problem spend at least two, better five, minutes to look if this problem was posted before. If it was, don't repost it. If you have anything important to say on topic, post it in one of the older threads.
If the thread is locked cause of this, use search function.

Update (by Amir Hossein). The best way to search for two keywords in AoPS is to input
[code]+"first keyword" +"second keyword"[/code]
so that any post containing both strings "first word" and "second form".


c) Good problem statement:
Some recent really bad post was:
[quote]$lim_{n\to 1}^{+\infty}\frac{1}{n}-lnn$[/quote]
It contains no question and no answer.
If you do this, too, you are on the best way to get your thread deleted. Write everything clearly, define where your variables come from (and define the "natural" numbers if used). Additionally read your post at least twice before submitting. After you sent it, read it again and use the Edit-Button if necessary to correct errors.


For answers to already existing threads:


d) Of any interest and with content:
Don't post things that are more trivial than completely obvious. For example, if the question is to solve $x^{3}+y^{3}=z^{3}$, do not answer with "$x=y=z=0$ is a solution" only. Either you post any kind of proof or at least something unexpected (like "$x=1337, y=481, z=42$ is the smallest solution). Someone that does not see that $x=y=z=0$ is a solution of the above without your post is completely wrong here, this is an IMO-level forum.
Similar, posting "I have solved this problem" but not posting anything else is not welcome; it even looks that you just want to show off what a genius you are.

e) Well written and checked answers:
Like c) for new threads, check your solutions at least twice for mistakes. And after sending, read it again and use the Edit-Button if necessary to correct errors.



To repeat it: ALWAYS USE YOUR COMMON SENSE IF POSTING!


Everything definitely out of range of common sense will be locked or deleted (exept for new users having less than about 42 posts, they are newbies and need/get some time to learn).

The above rules will be applied from next monday (5. march of 2007).
Feel free to discuss on this here.
49 replies
ZetaX
Feb 27, 2007
NoDealsHere
May 4, 2019
J
H
source own
Bet667   5
N a minute ago by GeoMorocco
Let $x,y\ge 0$ such that $2(x+y)=1+xy$ then find minimal value of $$x+\frac{1}{x}+\frac{1}{y}+y$$
5 replies
Bet667
2 hours ago
GeoMorocco
a minute ago
J
H
Cross-ratio Practice!
shanelin-sigma   3
N 4 minutes ago by MENELAUSS
Source: 2024 imocsl G3 (Night 6-G)
Triangle $ABC$ has circumcircle $\Omega$ and incircle $\omega$, where $\omega$ is tangent to $BC, CA, AB$ at $D,E,F$, respectively. $T$ is an arbitrary point on $\omega$. $EF$ meets $BC$ at $K$, $AT$ meets $\Omega$ again at $P$, $PK$ meets $\Omega$ again at $S$. $X$ is a point on $\Omega$ such that $S, D, X$ are colinear. Let $Y$ be the intersection of $AX$ and $EF$, prove that $YT$ is tangent to $\omega$.

Proposed by chengbilly
3 replies
shanelin-sigma
Aug 8, 2024
MENELAUSS
4 minutes ago
J
H
Segment ratio
xeroxia   3
N 4 minutes ago by Blackbeam999
Let $B$ and $C$ be points on a circle with center $A$.
Let $D$ be a point on segment $AB$.
Let $F$ be one of the intersections of the circle with center $D$ and passing through $B$ and the circle with diameter $DC$.
Prove that $\dfrac {AD}{AC} = \dfrac {CF^2}{CB^2}$.
3 replies
1 viewing
xeroxia
Sep 11, 2024
Blackbeam999
4 minutes ago
J
H
Iran second round 2025-q1
mohsen   1
N 31 minutes ago by sami1618
Find all positive integers n>2 such that sum of n and any of its prime divisors is a perfect square.
1 reply
mohsen
Today at 10:21 AM
sami1618
31 minutes ago
J
H
Not hard but rather tedious
Valiowk   15
N 34 minutes ago by john0512
Source: Singapore TST 2004
Find all functions $ f: \mathbb{R} \to \mathbb{R}$ satisfying
\[ f\left(\frac {x + y}{x - y}\right) = \frac {f\left(x\right) + f\left(y\right)}{f\left(x\right) - f\left(y\right)} \]
for all $ x \neq y$.
15 replies
Valiowk
May 10, 2004
john0512
34 minutes ago
J
H
Hard to approach it !
BogG   127
N 37 minutes ago by Nari_Tom
Source: Swiss Imo Selection 2006
Let $\triangle ABC$ be an acute-angled triangle with $AB \not= AC$. Let $H$ be the orthocenter of triangle $ABC$, and let $M$ be the midpoint of the side $BC$. Let $D$ be a point on the side $AB$ and $E$ a point on the side $AC$ such that $AE=AD$ and the points $D$, $H$, $E$ are on the same line. Prove that the line $HM$ is perpendicular to the common chord of the circumscribed circles of triangle $\triangle ABC$ and triangle $\triangle ADE$.
127 replies
BogG
May 25, 2006
Nari_Tom
37 minutes ago
J
H
The old one is gone.
EeEeRUT   8
N an hour ago by Dakernew192
Source: EGMO 2025 P2
An infinite increasing sequence $a_1 < a_2 < a_3 < \cdots$ of positive integers is called central if for every positive integer $n$ , the arithmetic mean of the first $a_n$ terms of the sequence is equal to $a_n$.

Show that there exists an infinite sequence $b_1, b_2, b_3, \dots$ of positive integers such that for every central sequence $a_1, a_2, a_3, \dots, $ there are infinitely many positive integers $n$ with $a_n = b_n$.
8 replies
EeEeRUT
Apr 16, 2025
Dakernew192
an hour ago
J
H
IMO Shortlist 2010 - Problem N2
Amir Hossein   30
N an hour ago by Adywastaken
Find all pairs $(m,n)$ of nonnegative integers for which \[m^2 + 2 \cdot 3^n = m\left(2^{n+1} - 1\right).\]

Proposed by Angelo Di Pasquale, Australia
30 replies
Amir Hossein
Jul 17, 2011
Adywastaken
an hour ago
J
H
Euler line of incircle touching points /Reposted/
Eagle116   4
N an hour ago by Captainscrubz
Let $ABC$ be a triangle with incentre $I$ and circumcentre $O$. Let $D,E,F$ be the touchpoints of the incircle with $BC$, $CA$, $AB$ respectively. Prove that $OI$ is the Euler line of $\vartriangle DEF$.
4 replies
1 viewing
Eagle116
3 hours ago
Captainscrubz
an hour ago
J
H
Interesting F.E
Jackson0423   5
N an hour ago by GreekIdiot
Show that there does not exist a function
\[ f : \mathbb{R}^+ \to \mathbb{R} \]satisfying the condition that for all \( x, y \in \mathbb{R}^+ \),
\[ f(x^2 + y) \geq f(x) + y. \]

~Korea 2017 P7
5 replies
Jackson0423
Yesterday at 4:12 PM
GreekIdiot
an hour ago
J
H
IMO ShortList 1998, combinatorics theory problem 1
orl   43
N an hour ago by Davdav1232
Source: IMO ShortList 1998, combinatorics theory problem 1
A rectangular array of numbers is given. In each row and each column, the sum of all numbers is an integer. Prove that each nonintegral number $x$ in the array can be changed into either $\lceil x\rceil $ or $\lfloor x\rfloor $ so that the row-sums and column-sums remain unchanged. (Note that $\lceil x\rceil $ is the least integer greater than or equal to $x$, while $\lfloor x\rfloor $ is the greatest integer less than or equal to $x$.)
43 replies
orl
Oct 22, 2004
Davdav1232
an hour ago
J
H
Reflected point lies on radical axis
Mahdi_Mashayekhi   3
N an hour ago by Mahdi_Mashayekhi
Source: Iran 2025 second round P4
Given is an acute and scalene triangle $ABC$ with circumcenter $O$. $BO$ and $CO$ intersect the altitude from $A$ to $BC$ at points $P$ and $Q$ respectively. $X$ is the circumcenter of triangle $OPQ$ and $O'$ is the reflection of $O$ over $BC$. $Y$ is the second intersection of circumcircles of triangles $BXP$ and $CXQ$. Show that $X,Y,O'$ are collinear.
3 replies
Mahdi_Mashayekhi
Today at 11:01 AM
Mahdi_Mashayekhi
an hour ago
J
H
Turkish MO 1994 P5
xeroxia   10
N 2 hours ago by AshAuktober
Source: Turkish Mathematical Olympiad 2nd Round 1994
Find the set of all ordered pairs $(s,t)$ of positive integers such that \[t^{2}+1=s(s+1).\]
10 replies
xeroxia
Sep 27, 2006
AshAuktober
2 hours ago
J
H
Cyclic points [variations on a Fuhrmann generalization]
shobber   24
N 2 hours ago by ali123456
Source: China TST 2006
$H$ is the orthocentre of $\triangle{ABC}$. $D$, $E$, $F$ are on the circumcircle of $\triangle{ABC}$ such that $AD \parallel BE \parallel CF$. $S$, $T$, $U$ are the semetrical points of $D$, $E$, $F$ with respect to $BC$, $CA$, $AB$. Show that $S, T, U, H$ lie on the same circle.
24 replies
shobber
Jun 18, 2006
ali123456
2 hours ago
J
H
J
H
Geometry with parallel lines.
falantrng   32
N Mar 23, 2025 by endless_abyss
Source: RMM 2018,D1 P1
Let $ABCD$ be a cyclic quadrilateral an let $P$ be a point on the side $AB.$ The diagonals $AC$ meets the segments $DP$ at $Q.$ The line through $P$ parallel to $CD$ mmets the extension of the side $CB$ beyond $B$ at $K.$ The line through $Q$ parallel to $BD$ meets the extension of the side $CB$ beyond $B$ at $L.$ Prove that the circumcircles of the triangles $BKP$ and $CLQ$ are tangent .
32 replies
falantrng
Feb 24, 2018
endless_abyss
Mar 23, 2025
J
Geometry with parallel lines.
G H J
Reveal topic tags
geometry
RMM
RMM 2018
auyesl
L
G H BBookmark kLocked kLocked NReply
Source: RMM 2018,D1 P1
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
falantrng
250 posts
falantrng
#1 Feb 24, 2018, 12:08 PM • 8 Y
Y by microsoft_office_word, itslumi, k12byda5h, mathematicsy, harshmishra, Adventure10, Rounak_iitr, cubres
Let $ABCD$ be a cyclic quadrilateral an let $P$ be a point on the side $AB.$ The diagonals $AC$ meets the segments $DP$ at $Q.$ The line through $P$ parallel to $CD$ mmets the extension of the side $CB$ beyond $B$ at $K.$ The line through $Q$ parallel to $BD$ meets the extension of the side $CB$ beyond $B$ at $L.$ Prove that the circumcircles of the triangles $BKP$ and $CLQ$ are tangent .
This post has been edited 1 time. Last edited by falantrng, Feb 24, 2018, 12:11 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
rmtf1111
698 posts
rmtf1111
#2 Feb 24, 2018, 12:10 PM • 5 Y
Y by microsoft_office_word, Euiseu, translate, Adventure10, cubres
Denote by $\omega$ the circumcircle of $ABCD$. Let $\{T\} = DQ \cap \omega$. By converse of Reim's Theorem on the parallel lines $PK \mid \mid CD$ and circle $\omega$ we have that $BDTK$ is cyclic. By converse of Reim's Theorem on the parallel lines $LQ \mid \mid BD$ and circle $\omega$ we have that $CQTL$ is cyclic. Now because $\angle{ACT}=\angle{ABT}$ we have that the lines tangent to the circumcircles of $QCT$ and $BDT$ at $T$ coincide, thus the circumcircles of the triangles $BKP$ and $CLQ$ are tangent at $T$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
GGPiku
402 posts
GGPiku
#3 Feb 24, 2018, 12:10 PM • 3 Y
Y by tbn456834678, Adventure10, cubres
Pretty easy problem compared to the ones from the last year. A bit too easy.
Let $DP$ intersect $(ABCD)$ in $D$ and $S$. We can easily observ that $S$ is on both circumcircles of $BKP$ and $CLQ$.
Indeed, $\angle PSB=180-\angle BCB=\angle PKB$, since $PK\parallel CD$, so $P,B,K,S$ are concyclic, and $\angle QSC=\angle DBC=\angle QLC$, so $Q,C,L,S$ are concyclic.
Now, for an easier explanation, if we let $d$ be the tangent in $S$ at $(BKP)$, and $R$ a point on $d$ such that $L,R$ are on opposite sides wrt $SB$, we'll have $\angle RSP=\angle ABS=\angle ACS=\angle QLS$, so $d$ is tangent in $S$ at $(CLQ)$. This concludes the tangency of $BKP$ and $CLQ$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
WizardMath
2487 posts
WizardMath
#4 Feb 24, 2018, 12:27 PM • 3 Y
Y by Adventure10, Mango247, cubres
The intersection of $PD$ and $(ABCD)$ is $X$. $\measuredangle PKB = \measuredangle PXB$, so $PKBX, CQLX$ are cyclic. Now $XK, XB$ are isogonal in $XLC$ so we are done.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
BarishNamazov
124 posts
BarishNamazov
#5 Feb 24, 2018, 12:42 PM • 4 Y
Y by tenplusten, Adventure10, Mango247, cubres
Too easy.Let $T=DP\cap \odot (ABCD) $.Easy angle-chasing implies that $CLTQ$,$BKTP $ are cyclic.Again chasing some angles $\angle LTK=\angle BAC=\angle CTB$ which yields that $TK,TB $ are isogonals wrt $TLC $ which finishes problem.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
randomusername
1059 posts
randomusername
#6 Feb 24, 2018, 6:05 PM • 2 Y
Y by Adventure10, cubres
Letting $O=DP\cap BC$ (assuming it exists), then Power of a Point wrt secants $OD,OC$ shows that $(BKPT)$ and $(CLQT)$ are cyclic, where $T=(ABCD)\cap OD$. (Since the diagram varies continuously as $P$ varies continuously, this proves they are cyclic even if $DP$ and $BC$ are parallel.)

To show tangency, note that by angle chasing $PTK\sim ATC$ and $ATB\sim QTL$. Hence there exist spiral similarities $\phi,\psi$ centered at $T$ with $\phi(PTK)=ATC$ and $\psi(ATB)=QTL$. Then $\phi\circ \psi$ maps $P\to Q$, hence it's a homothety, and circles $(PTK)$ and $(QTL)$ are homothetic (with center $T$), as desired.
This post has been edited 1 time. Last edited by randomusername, Feb 24, 2018, 6:07 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
trumpeter
3332 posts
trumpeter
#7 Feb 25, 2018, 7:29 AM • 2 Y
Y by Adventure10, cubres
Let $E=PD\cap\left(ABCD\right)$. Then \[\measuredangle{PEB}=\measuredangle{DEB}=\measuredangle{DCB}=\measuredangle{PKB},\]so $EPBK$ is cyclic. Similarly, $EQCL$ is cyclic.

Let $\ell_B,\ell_C$ be the tangents to $\left(EPBK\right),\left(EQCL\right)$ at $E$. Then \[\measuredangle{\left(\ell_B,ED\right)}=\measuredangle{EBP}=\measuredangle{EBA}=\measuredangle{ECA}=\measuredangle{ECQ}=\measuredangle{\left(\ell_C,ED\right)},\]so $\ell_B=\ell_C$ and hence $\left(BKP\right)$ and $\left(CLQ\right)$ are tangent.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
djmathman
7938 posts
djmathman
#8 Mar 17, 2018, 11:36 PM • 3 Y
Y by Adventure10, Mango247, cubres
asdf took way too long (and Geogebra help) for me to realize that phantom pointing basically kills this problem; time to draw better diagrams I guess :oops:

Let $X = PQD\cap\odot(ABCD)$. Note that \[\angle PXB \equiv\angle DXB = \angle DAB = \angle PKB,\]so $PBKX$ is cyclic. Similarly, $QCLX$ is cyclic. We can thus get rid of $K$ and $L$, since it suffices to show that the circles $\odot(BPX)$ and $\odot(CQX)$ are tangent to each other. But upon letting $O_B$ and $O_C$ be their respective centers, we obtain \[\angle O_BXP = 90^\circ - \angle XBP = 90^\circ - \angle XCQ = O_CXQ,\]so $X$, $O_B$, and $O_C$ are collinear, implying the tangency. $\blacksquare$
This post has been edited 2 times. Last edited by djmathman, Mar 17, 2018, 11:40 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Kala_Para_Na
28 posts
Kala_Para_Na
#9 May 16, 2018, 6:46 PM • 3 Y
Y by Adventure10, Mango247, cubres
$PD \cap \odot ABCD = \{ D,X \}$
By Reim's theorem, $X \in \odot BKP$ and $X \in \odot QLC$
Angle chasing yields, $\angle AXC = \angle PXK$ and $\angle AXB = \angle QXL$ which implies $K$ and $B$ are isogonal in $\triangle XLC$
it leads us to our conclusion.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Kagebaka
3001 posts
Kagebaka
#10 Jul 7, 2019, 1:16 PM • 3 Y
Y by AlastorMoody, Adventure10, cubres
huh no inversion?

Solution

also @post 2 I think you meant $BPTK$ cyclic not $BDTK$ cyclic
This post has been edited 1 time. Last edited by Kagebaka, Jul 7, 2019, 1:18 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
IndoMathXdZ
691 posts
IndoMathXdZ
#11 Nov 16, 2019, 7:36 AM • 2 Y
Y by Adventure10, cubres
Nice Problem :) Here is a boring solution.
Denote the intersection of $PQ$ with $(ABCD)$ as $G$, other than $D$.
We claim that the tangency point is $G$.

Claim 01. $G$ lies on both $(BKP)$ and $(CLQ)$. In other words, $BKGP$ and $CLGQ$ are both cyclic.
Proof. Notice that \[ \measuredangle BKP = \measuredangle BCD = \measuredangle BAD = \measuredangle BGD \equiv \measuredangle BGP\]Similarly,
\[ \measuredangle LQG = \measuredangle BDG = \measuredangle BCG \equiv \measuredangle LCG \]
Claim 02. Let $GK$ intersects $(CQL)$ at $H$. Then , $HQ \parallel PK$.
Proof. We'll prove this by phantom point. Notice that
\[ \measuredangle GHQ = \measuredangle GKP = \measuredangle GBP = \measuredangle GBA = \measuredangle GCA = \measuredangle GCQ \]which is what we wanted.
Therefore, $G$ sends $KP$ to $HQ$, which makes $G$ the tangency point of the two circle.
This post has been edited 1 time. Last edited by IndoMathXdZ, Nov 16, 2019, 7:36 AM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
AlastorMoody
2125 posts
AlastorMoody
#12 Dec 13, 2019, 7:40 PM • 4 Y
Y by a_simple_guy, Adventure10, Mango247, cubres
Solution (with PUjnk)
This post has been edited 2 times. Last edited by AlastorMoody, Dec 13, 2019, 7:41 PM
Reason: Give credit to poor PUjnk's soul... lol
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
amar_04
1915 posts
amar_04
#13 Mar 14, 2020, 6:03 PM • 5 Y
Y by mueller.25, GeoMetrix, BinomialMoriarty, Bumblebee60, cubres
Storage.
RMM 2018 Day 1 P1 wrote:
Let $ABCD$ be a cyclic quadrilateral an let $P$ be a point on the side $AB.$ The diagonals $AC$ meets the segments $DP$ at $Q.$ The line through $P$ parallel to $CD$ mmets the extension of the side $CB$ beyond $B$ at $K.$ The line through $Q$ parallel to $BD$ meets the extension of the side $CB$ beyond $B$ at $L.$ Prove that the circumcircles of the triangles $BKP$ and $CLQ$ are tangent .

Let $DP\cap\odot(ABC)=X$. Then $\angle KPX=\angle CDX=\angle XBK\implies X,K,B,P$ are concyclic. And $\angle XQL=\angle XDB=\angle XCL\implies L,C,Q,X$ are concyclic, Now $$\angle LXK=\angle LXQ-\angle KXP=(180^\circ-\angle BCA)-(180^\circ-\angle ABL)=\angle ABL-\angle BCA=\angle BAC=\angle BXC$$So, $\{XK,XB\}$ are isogonal WRT $\triangle LXC\implies\odot(BKP)$ and $\odot(CLQ)$ are tangent to each other at $X$. $\blacksquare$
This post has been edited 4 times. Last edited by amar_04, Mar 14, 2020, 9:16 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
itslumi
284 posts
itslumi
#14 Jul 6, 2020, 9:03 PM • 1 Y
Y by cubres
1)Let $(CLQ)n(ABCD)=X$ ,prove that $(BPXK)$-cyclic and $(BPXK)$ tangent to $(CLQ)$.

2)Prove that $X-Q-D$ collnear
$\angle CLQ=\angle CXQ$
but
$\angle CXD=\angle CAD$,which implies that $\angle CXD=\angle CXQ$,which implies the desired collinearity

3)Prove that $(BKXP)-cyclic$

$\angle DCY=\angle DAB=\angle BKP$
and
its obvious that $\angle BXP=\angle BAD$,which implies the desired claim

4)Let $\ell$ be a line that passes through $X$ and tangent to $(CQL)$.Prove that $\ell$ is tangent to $(KBPX)$ at $X$.
$\angle QLX=\angle QX=\angle QCX=\angle ACX=\angle ABX=\angle PKX$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
554183
484 posts
554183
#15 Aug 21, 2021, 10:08 AM • 1 Y
Y by cubres
:D
Let $PQ \cap \odot{ABCD}=E$. I claim that $E$ is the point of tangency.
First I will prove that $EQCL$ is cyclic
$$\angle{QLC}=\angle{DBC}=\angle{DEC}$$Similarly,
$$\angle{BKP}=180-\angle{DCB}=180-(180-\angle{DEB})=\angle{DEB}$$Hence $EPBK$ is cyclic.
To finish, we present the following claim :
Claim : $\angle{PBE}=\angle{QLE}$
Proof. $$\angle{QLE}=\angle{QCE}=\angle{ABE}=\angle{PBE}$$Now, draw a tangent to $\odot{BKP}$ at $E$. Let $G$ be an arbitrary point on the tangent inside $\odot{ABC}$. We see that
$$\angle{GEQ}=\angle{GEP}=\angle{EBP}=\angle{ELQ}$$So we are done $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
BVKRB-
322 posts
BVKRB-
#16 Sep 12, 2021, 7:48 AM • 1 Y
Y by cubres
Nice diagram = Problem done! :D (And this time it's on paper!)

Let $\odot(ABC) \cap \odot(LQC) = X$
We claim that $X$ is the desired tangency point

Claim: $D-Q-P-F$ are collinear
Proof

Hence One of $\odot(CLQ) \cap \odot(BKP)=X$

Now draw the line that is tangent to $\odot(LQC)$ at $T$ and name it $\ell$ and let a point on $\ell$ on the same side of $F$ as $L$ be $Y$
We know that $$\angle YFL= \angle XCL = \angle XQL = \angle XDB$$and after some easy angle chasing we get $\angle XPK = \angle XDC = \angle YXL + \angle CXB$ Therefore it suffices to show that $XK,XB$ are isogonal in $\triangle XLC$
This is true after some angle chasing which I am too lazy to write, just assume variables and calculate each angle, which finally gives the desired conclusion $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
HoRI_DA_GRe8
597 posts
HoRI_DA_GRe8
#17 Nov 22, 2021, 6:22 PM • 1 Y
Y by cubres
solution
This post has been edited 1 time. Last edited by HoRI_DA_GRe8, Nov 22, 2021, 6:24 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
REYNA_MAIN
41 posts
REYNA_MAIN
#18 Dec 20, 2021, 4:42 PM • 2 Y
Y by BVKRB-, cubres
Shortage
Just orsing BVKRB
HELP?
Attachments:
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
UI_MathZ_25
116 posts
UI_MathZ_25
#19 Dec 23, 2021, 11:00 PM • 1 Y
Y by cubres
The line $DP$ meets the circumcircle of triangle $CLQ$ at $R$. We get

$\angle RDB = \angle RQL = \angle RCL = \angle RCB \Rightarrow$ $R$ lie on $\odot(ABCD)$.

Since $PK \parallel CD$, by the Reim's Theorem we get that $RBKP$ is cyclic.

Finally, let $X$ be the intersection of the tangent to $\odot(CLQ)$ at $R$ with the line $CD$. Thus

$\angle XRQ = \angle RCQ = \angle RCA = \angle RBA = \angle RBP \Rightarrow$ $XR$ is tangent to$\odot (RBP)$.

Therefore, the circumcircles of the triangles $BKP$ and $CLQ$ are tangent to the line $XR$ at $R$ $\blacksquare$
Attachments:
This post has been edited 1 time. Last edited by UI_MathZ_25, Dec 23, 2021, 11:03 PM
Reason: Figure
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Mahdi_Mashayekhi
693 posts
Mahdi_Mashayekhi
#20 Apr 8, 2022, 1:12 PM • 1 Y
Y by cubres
Let $DQ$ meet $ABCD$ at $S$.
$\angle QLC = \angle DBC = \angle QSC \implies SLCQ$ is cyclic. $\angle BKP = \angle 180 - \angle BCD = \angle BSP \implies BKSP$ is cyclic. Let $L_1$ be line tangent to $SLCQ$ at $S$ we have $\angle SCQ = \angle SCA = \angle SBA = \angle SBP \implies L_1$ is tangent to $BKSP$ as well so our circles are tangent at $S$.
we're Done.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
SatisfiedMagma
458 posts
SatisfiedMagma
#21 May 8, 2022, 5:41 PM • 2 Y
Y by Rounak_iitr, cubres
Let $E= DQ \cap \odot(ABCD) \ne D$. We will prove that $E$ is the common point of tangency.

[asy] import graph; size(12cm); 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 = 1.9, xmax = 11.2, ymin = -2.5862804185721906, ymax = 5.031020679728067; /* image dimensions */ pen cqcqcq = rgb(0.7529411764705882,0.7529411764705882,0.7529411764705882); /* draw figures */ draw(circle((5.852809635608784,1.367535756966066), 3.5453838571445635), linewidth(0.8) + blue); draw((3.741438563859456,4.215668284058398)--(9.,3.), linewidth(0.8) + green); draw((9.,3.)--(6.68,-2.08), linewidth(0.8) + green); draw((6.68,-2.08)--(2.373492429373072,0.6862880245710273), linewidth(0.8) + green); draw((3.741438563859456,4.215668284058398)--(2.373492429373072,0.6862880245710273), linewidth(0.8) + green); draw((9.,3.)--(2.373492429373072,0.6862880245710273), linewidth(0.8) + green); draw(circle((8.003294213009466,3.084537618648431), 1.0002844769300214), linewidth(0.8) + red); draw((9.,3.)--(9.306489730729668,3.6711068241839295), linewidth(0.8) + green); draw((9.306489730729668,3.6711068241839295)--(4.739858471858444,2.07662144581455), linewidth(0.8) + green); draw((8.719877477199834,2.3866282690410148)--(7.070615206872309,3.4460329938583647), linewidth(0.8) + green); draw((4.739858471858444,2.07662144581455)--(8.141511444765205,4.075226788687628), linewidth(0.8) + green); draw((8.141511444765205,4.075226788687628)--(9.,3.), linewidth(0.8) + green); draw((2.373492429373072,0.6862880245710273)--(4.739858471858444,2.07662144581455), linewidth(0.8) + green); draw(circle((7.702470722917133,0.9283479023436838), 3.1773579402953915), linewidth(0.8) + red); draw((3.741438563859456,4.215668284058398)--(6.68,-2.08), linewidth(0.8) + green); draw((8.141511444765205,4.075226788687628)--(6.68,-2.08), linewidth(0.8) + green); /* dots and labels */ dot((3.741438563859456,4.215668284058398),dotstyle); label("$A$", (3.551178767049365,4.389270037746726), NE * labelscalefactor); dot((9.,3.),dotstyle); label("$B$", (9.14557023301717,2.8686000382692027), NE * labelscalefactor); dot((6.68,-2.08),dotstyle); label("$C$", (6.606469866917069,-2.4049161067078986), NE * labelscalefactor); dot((2.373492429373072,0.6862880245710273),dotstyle); label("$D$", (2.0584109693971078,0.5666683876839601), NE * labelscalefactor); dot((7.070615206872309,3.4460329938583647),dotstyle); label("$P$", (6.941296288820379,3.6219594875516457), NE * labelscalefactor); dot((4.739858471858444,2.07662144581455),linewidth(4.pt) + dotstyle); label("$Q$", (4.471951427283468,2.101289488074122), NE * labelscalefactor); dot((8.719877477199834,2.3866282690410148),linewidth(4.pt) + dotstyle); label("$K$", (8.852597113851774,2.198947194462587), NE * labelscalefactor); dot((9.306489730729668,3.6711068241839295),linewidth(4.pt) + dotstyle); label("$L$", (9.368787847619377,3.7893726985033), NE * labelscalefactor); dot((8.141511444765205,4.075226788687628),linewidth(4.pt) + dotstyle); label("$E$", (8.196895370957792,4.18000352405716), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); [/asy]

Claim: $E \in \odot(PBK)$ and $E \in \odot(CQL)$.

Proof: For $PBKE$ we have
\[ \measuredangle DEB = \measuredangle DCB = \measuredangle PKB. \]For $CQLE$ we have
\[ \measuredangle ECL = \measuredangle ECB = \measuredangle EDB = \measuredangle EQL. \]This shows the claim. $\square$

To finish it off, it suffices to show that $\measuredangle EBP = \measuredangle ECQ$ by considering a tangent to either $\odot(PBKE)$ or $\odot(CQLE)$ at $E$. This part is obviously true as
\[\measuredangle EBP = \measuredangle EBA = \measuredangle ECA = \measuredangle ECQ.\]So, we are done. $\blacksquare$
This post has been edited 1 time. Last edited by SatisfiedMagma, May 8, 2022, 6:07 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Mogmog8
1080 posts
Mogmog8
#22 May 8, 2022, 6:44 PM • 2 Y
Y by centslordm, cubres
Let $T=(ABC)\cap\overline{PQ}.$ Note $$\measuredangle TPK=\measuredangle PDC=\measuredangle TBC=\measuredangle TBK$$and $$\measuredangle CKQ=\measuredangle CBD=\measuredangle CTD$$so $T$ lies on $(BKP)$ and $(CLQ).$ Let $\ell$ be the line tangent to $(CLQ)$ at $T$; we claim $\ell$ is tangent to $(BKP)$ at $T.$ Indeed, $$\measuredangle (\overline{DT},\ell)=\measuredangle QCT=\measuredangle ACT=\measuredangle ABT.$$$\square$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
IAmTheHazard
5001 posts
IAmTheHazard
#23 Aug 7, 2022, 9:12 PM • 1 Y
Y by cubres
Neat. Let $X=\overline{DP} \cap (ABCD)$. Reim's implies that $BKPX$ and $CLQX$ are cyclic. Now, to show that the two circles are tangent at $X$, it is sufficient to prove that $\measuredangle XBP=\measuredangle XCQ$ reason. This follows by
$$\measuredangle XBP=\measuredangle XBA=\measuredangle XCA=\measuredangle XCQ.~\blacksquare$$
This post has been edited 1 time. Last edited by IAmTheHazard, Aug 12, 2022, 2:06 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
HamstPan38825
8857 posts
HamstPan38825
#24 Feb 2, 2023, 4:43 PM • 1 Y
Y by cubres
Let $E = \overline{DP} \cap (ABC)$. I claim that $E$ lies on both $(BKP)$ and $(CLQ)$. This is because $$\measuredangle PKB = \measuredangle DCK = \measuredangle DEB$$and similarly $\measuredangle QLC = \measuredangle DBC = \measuredangle DEC$. Thus it suffices to show that the tangent at $E$ to $(BKP)$ is also tangent to $(CLQ)$, which is equivalent to $\measuredangle EBP = \measuredangle ECQ$. This is evident.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
AwesomeYRY
579 posts
AwesomeYRY
#25 Mar 20, 2023, 2:00 AM • 1 Y
Y by cubres
Let $X = DP\cap \omega$. Then, note that

Claim 1: $X\in (PBK)$
Proof: Angle chase with the following directed angles:
\[\angle PKB = \angle DCB = \angle DAB = \angle DXB = \angle PXB\]
Claim 2: $X\in (QLC)$.
Proof: Angle chase:
\[\angle XQL = \angle XDB = \angle XCB = \angle XCL\]
Thus, $X = (PKB)\cap (QLC)$. Let $\ell_1$ be the tangent to $(PKB)$ at $X$ and $\ell_2$ be the tangent to $(QLC)$ at $X$. Then, we have
\[\angle (\ell_1, XP) = \angle XBP = \angle XBA = \angle XCA = \angle XCQ = \angle (\ell_2, XQ)\]Since $X,P,Q$ are collinear, this means that $\ell_1$ and $\ell_2$ are the same line, which means that $(PKB)$ and $(QLC)$ share a tangent line with the same orientation at $X$, and therefore the two circles are tangent. $\blacksquare$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
SQTHUSH
154 posts
SQTHUSH
#26 Mar 20, 2023, 12:27 PM • 1 Y
Y by cubres
Let $T= \odot(PKB)\cap \odot(ABCD), S=\odot(QLC)\cap \odot(ABCD$
Since $PK//DC\Rightarrow \angle PKB=\angle PTB=\angle DAB$
So $T,P,D$ is collinear
Similarly, $S,Q,D$ is collinear
It shows that$T=S$
Finally,suppose $l_{1},l_{2}$ through point $T$,and tangent to $\odot(PKB)$,$\odot(QLC)$ respectively
$\measuredangle (l_{1},TK) = \angle TDC= \angle TDB+ \angle BDC= \angle LTK+ \angle TCL=\measuredangle (l_{2},TK)\Rightarrow l_{1}=l_{2}$
Which meas that $\odot(PKB)$and $\odot(QLC)$ are tangent.
This post has been edited 2 times. Last edited by SQTHUSH, Mar 20, 2023, 12:28 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
SHZhang
109 posts
SHZhang
#28 Jun 29, 2023, 9:25 AM • 1 Y
Y by cubres
Let $E = (ABCD) \cap DP$. Then \[\angle EPK = \angle EDC = 180^\circ - \angle EBC = \angle EBK,\]so $(EPBK)$ is cyclic. Similarly \[\angle EQL = \angle EDB = \angle ECB = \angle ECL\]gives $(EQCL)$ cyclic.

Now invert at $E$; in the inverted diagram, we have $ABCD$ collinear, $PEQD$ collinear, $(ABEP)$ cyclic, and $(ACQE)$ cyclic. Then $\angle ACQ = 180^\circ - \angle AEQ = \angle AEP = \angle ABP$, so $BP \parallel CQ$. Inverting back gives $(EPB) = (BKP)$ tangent to $(ECQ) = (CLQ)$, as desired.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
thdnder
194 posts
thdnder
#29 Dec 22, 2023, 5:52 AM • 1 Y
Y by cubres
Let $DP$ meets $(ABCD)$ at $T$. Then Reim implies $BKPT$ and $CLQT$ are cyclic. Now by homothety centered $T$, it suffices to show that $\angle TBP = \angle TCQ$, which follows from $\angle TBP = \angle TBA = \angle TCA = \angle TCQ$. $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Mathandski
738 posts
Mathandski
#30 Aug 22, 2024, 11:02 PM • 2 Y
Y by ehuseyinyigit, cubres
All directed angles

Rating (MOHs): 0
Attachments:
This post has been edited 1 time. Last edited by Mathandski, Aug 23, 2024, 9:30 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Saucepan_man02
1322 posts
Saucepan_man02
#31 Nov 1, 2024, 2:01 AM • 1 Y
Y by cubres
Angle-Chase:

Let $X=DQ \cap (ABC)$. Then: $$\angle XQL = \angle XDB = \angle XCB = \angle XCL \implies X \in (CQL)$$$$\angle PXB = \angle DXB = 180^\circ - \angle DCB = 180^\circ - \angle BKP \implies X \in (BKP).$$Let $T$ be a point on $CD$ such that $TX$ is tangent. Then: $$\angle TXQ=\angle TXP = \angle XBP = \angle XBA = \angle XCA = \angle XCQ$$which implies $XT$ is also tangent to $(CQL)$ and we are done.
This post has been edited 1 time. Last edited by Saucepan_man02, Nov 18, 2024, 6:28 AM
Reason: EDIT
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
math004
23 posts
math004
#32 Jan 1, 2025, 10:20 AM • 1 Y
Y by cubres
Let $X=(DP)\cap (ABCD)$ other than $D.$ $(PK)\parallel CD$ so by Reim's theorem, we have $XPBK$ is cyclic. Similarily, $(QL) \parallel (BD)$ implies, by Reim's theorem, that $(XQCL)$ is cyclic. Thus, it suffices to prove that $\angle XBP=\angle XCQ.$ Indeed,
\[\angle XBP= \angle XBA=\angle XCA=\angle XCQ.\]

[asy] 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 = -28.672699506166545, xmax = 30.304799479546876, ymin = -13.213124589216047, ymax = 15.349276752032559; /* image dimensions */ pen ffdxqq = rgb(1,0.8431372549019608,0); pen ffqqtt = rgb(1,0,0.2); pen wwqqcc = rgb(0.4,0,0.8); pen ffzzqq = rgb(1,0.6,0); pen ccffww = rgb(0.8,1,0.4); draw(circle((-4.374514807706929,4.554578946863126), 7.441362978795981), linewidth(0.8) + ffdxqq); draw(circle((-10.265245927810327,1.1410398077282977), 2.971023698496136), linewidth(0.8) + ffzzqq); draw(circle((-7.480815345801481,-3.611376349266896), 8.479064456814383), linewidth(0.8) + ccffww); /* draw figures */ draw((-8.56658899673541,10.702781690419702)--(0.584132797532879,-0.9939070546732326), linewidth(0.8)); draw((-8.56658899673541,10.702781690419702)--(-8.787977427241902,-1.4366839156862143), linewidth(0.8)); draw((2.9926105352026013,3.5060813722090263)--(-8.694970695175076,3.6631852259780002), linewidth(0.8)); draw((0.584132797532879,-0.9939070546732326)--(2.9926105352026013,3.5060813722090263), linewidth(0.8) + ffqqtt); draw((0.584132797532879,-0.9939070546732326)--(-8.787977427241902,-1.4366839156862143), linewidth(0.8)); draw((-8.787977427241902,-1.4366839156862143)--(2.9926105352026013,3.5060813722090263), linewidth(0.8) + wwqqcc); draw((-15.75661080980647,-1.7659106896656425)--(-8.787977427241902,-1.4366839156862143), linewidth(0.8)); draw((-15.75661080980647,-1.7659106896656425)--(-2.9993751879215687,3.586625329960073), linewidth(0.8) + wwqqcc); draw((-8.694970695175076,3.6631852259780002)--(-11.49291255479232,-1.5644761264366276), linewidth(0.8) + ffqqtt); draw((-11.767160966015583,3.7044814464317337)--(-8.787977427241902,-1.4366839156862143), linewidth(0.8)); draw((-8.694970695175076,3.6631852259780002)--(-11.767160966015583,3.7044814464317337), linewidth(0.8)); /* dots and labels */ dot((-8.56658899673541,10.702781690419702),linewidth(4pt) + dotstyle); label("$A$", (-9.721160237851564,10.678938154341909), NE * labelscalefactor); dot((-8.787977427241902,-1.4366839156862143),linewidth(4pt) + dotstyle); label("$B$", (-9.25798616204753,-2.5601208457233233), NE * labelscalefactor); dot((0.584132797532879,-0.9939070546732326),linewidth(4pt) + dotstyle); label("$C$", (0.9704413452915136,-1.9425554113179482), NE * labelscalefactor); dot((2.9926105352026013,3.5060813722090263),linewidth(4pt) + dotstyle); label("$D$", (3.1319203657103305,3.808522696582109), NE * labelscalefactor); dot((-8.694970695175076,3.6631852259780002),linewidth(4pt) + dotstyle); label("$P$", (-9.605366718900555,4.117305413784797), NE * labelscalefactor); dot((-2.9993751879215687,3.586625329960073),linewidth(4pt) + dotstyle); label("$Q$", (-2.850744780091752,3.8857183758827807), NE * labelscalefactor); dot((-11.49291255479232,-1.5644761264366276),linewidth(4pt) + dotstyle); label("$K$", (-11.419465182466347,-2.6759143646743313), NE * labelscalefactor); dot((-15.75661080980647,-1.7659106896656425),linewidth(4pt) + dotstyle); label("$L$", (-16.63017353526171,-2.6373165250239956), NE * labelscalefactor); dot((-11.767160966015583,3.7044814464317337),linewidth(4pt) + dotstyle); label("$X$", (-12.615998211626763,3.847120536232445), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); [/asy]
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Ilikeminecraft
348 posts
Ilikeminecraft
#33 Feb 8, 2025, 3:16 AM • 1 Y
Y by cubres
Let $E = DP \cap (ABCD)$ that isn't $D.$ By the given conditions, $\angle EBK = \angle EDC = \angle EPK$ and $\angle QEC = \angle DBC = \angle QLC,$ which tells us $BKEP, CLEQ$ are both concyclic. To finish, note that $EBAC$ is concyclic, so $\angle EBP = \angle ECA.$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
endless_abyss
41 posts
endless_abyss
#34 Mar 23, 2025, 4:43 PM • 1 Y
Y by cubres
The parallel condition is practically begging us to angle chase.

Claim - The tangency point is none other than the intersection of $P Q$ and the circumcircle of $A B C D$

Note that -
Let $T$ denote the intersection of $P Q$ and the circumcircle of $A B C D$
$\angle B A D = \angle B K P = \angle B T D$
and
$\angle D T C = \angle M L C$

$\square$

:starwars:
Z K Y
N Quick Reply
G
H
=
a