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
Wednesday at 3:18 PM
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
Wednesday at 3:18 PM
0 replies
J
H
D1018 : Can you do that ?
Dattier   1
N 11 minutes ago by Dattier
Source: les dattes à Dattier
We can find $A,B,C$, such that $\gcd(A,B)=\gcd(C,A)=\gcd(A,2)=1$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$.

For example :

$C=20$
$A=47650065401584409637777147310342834508082136874940478469495402430677786194142956609253842997905945723173497630499054266092849839$

$B=238877301561986449355077953728734922992395532218802882582141073061059783672634737309722816649187007910722185635031285098751698$

Can you find $A,B,C$ such that $A>3$ is prime, $C,B \in (\mathbb Z/A\mathbb Z)^*$ with $o(C)=(A-1)/2$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$?
1 reply
Dattier
Mar 24, 2025
Dattier
11 minutes ago
J
H
2025 Caucasus MO Juniors P3
BR1F1SZ   1
N 16 minutes ago by FarrukhKhayitboyev
Source: Caucasus MO
Let $K$ be a positive integer. Egor has $100$ cards with the number $2$ written on them, and $100$ cards with the number $3$ written on them. Egor wants to paint each card red or blue so that no subset of cards of the same color has the sum of the numbers equal to $K$. Find the greatest $K$ such that Egor will not be able to paint the cards in such a way.
1 reply
BR1F1SZ
Mar 26, 2025
FarrukhKhayitboyev
16 minutes ago
J
H
1 area = 2025 points
giangtruong13   0
33 minutes ago
In a plane give a set $H$ that has 8097 distinct points with area of a triangle that has 3 points belong to $H$ all $ \leq 1$. Prove that there exists a triangle $G$ that has the area $\leq 1 $ contains at least 2025 points that belong to $H$( each of that 2025 points can be inside the triangle or lie on the edge of triangle $G$)X
0 replies
giangtruong13
33 minutes ago
0 replies
J
H
Burak0609
Burak0609   0
40 minutes ago
So if $2 \nmid n\implies$ $2d_2+d_4+d_5=d_7$ is even it's contradiction. I mean $2 \mid n and d_2=2$.
If $3\mid n \implies d_3=3$ and $(d_6+d_7)^2=n+1,3d_6d_7=n \implies d_6^2-d_6d_7+d_7^2=1$,we can see the only solution is$d_6=d_7=1$ and it is contradiction.
If $4 \mid n d_3=4$ and $(d_6+d_7)^2-4d_6d_7=1 \implies d_7=d_6+1$. So $n=4d_6(d_6+1)$.İt means $8 \mid n$.
If $d_6=8 n=4.8.9=288$ but $3 \nmid n$.İt is contradiction.
If $d_5=8$ we have 2 option. Firstly $d_4=5 \implies 2d_2+d_4+d_5=17=d_7 d_6=16$ but $10 \mid n$ is contradiction. Secondly $d_4=7 \implies d_7=2.2+7+8=19 and d_6=18$ but $3 \nmid n$ is contradiction. I mean $d_4=8 \implies d_7=d_5+12, n=4(d_5+11)(d_5+12) and d_5 \mid n=4(d_5+11)(d_5+12)$. So $d_5 \mid 4.11.12 \implies d_5 \mid 16.11$. If $d_5=16 d_6=27$ but $3 \nmid n$ is contradiction. I mean $d_5=11,d_6=22,d_7=23$. The only solution is $n=2024$.
0 replies
Burak0609
40 minutes ago
0 replies
J
No more topics!
H
J
H
Concurrent Lines - Incenter and Circumcircles
rkm0959   9
N Jul 20, 2021 by primesarespecial
Source: 2015 Korean Junior MO P5
Let $I$ be the incenter of an acute triangle $\triangle ABC$, and let the incircle be $\Gamma$.
Let the circumcircle of $\triangle IBC$ hit $\Gamma$ at $D, E$, where $D$ is closer to $B$ and $E$ is closer to $C$.
Let $\Gamma \cap BE = K (\not= E)$, $CD \cap BI = T$, and $CD \cap \Gamma = L (\not= D)$.
Let the line passing $T$ and perpendicular to $BI$ meet $\Gamma$ at $P$, where $P$ is inside $\triangle IBC$.
Prove that the tangent to $\Gamma$ at $P$, $KL$, $BI$ are concurrent.
9 replies
rkm0959
Nov 1, 2015
primesarespecial
Jul 20, 2021
J
Concurrent Lines - Incenter and Circumcircles
G H J
Reveal topic tags
geometry
incenter
circumcircle
L
G H BBookmark kLocked kLocked NReply
Source: 2015 Korean Junior MO P5
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
rkm0959
1721 posts
rkm0959
#1 Nov 1, 2015, 1:54 PM • 2 Y
Y by Adventure10, Mango247
Let $I$ be the incenter of an acute triangle $\triangle ABC$, and let the incircle be $\Gamma$.
Let the circumcircle of $\triangle IBC$ hit $\Gamma$ at $D, E$, where $D$ is closer to $B$ and $E$ is closer to $C$.
Let $\Gamma \cap BE = K (\not= E)$, $CD \cap BI = T$, and $CD \cap \Gamma = L (\not= D)$.
Let the line passing $T$ and perpendicular to $BI$ meet $\Gamma$ at $P$, where $P$ is inside $\triangle IBC$.
Prove that the tangent to $\Gamma$ at $P$, $KL$, $BI$ are concurrent.
This post has been edited 1 time. Last edited by rkm0959, Nov 1, 2015, 1:55 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
gavrilos
233 posts
gavrilos
#2 Nov 1, 2015, 3:57 PM • 3 Y
Y by AlastorMoody, Adventure10, Mango247
Hello.

My solution.

[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 = -8.378501037528716, xmax = 15.436975594618492, ymin = -5.786275429739432, ymax = 7.68827055950176; /* image dimensions */ pen cqcqcq = rgb(0.7529411764705882,0.7529411764705882,0.7529411764705882); pen sqsqsq = rgb(0.12549019607843137,0.12549019607843137,0.12549019607843137); draw((4.544384825279955,5.614474881506733)--(0.,0.)--(7.,0.)--cycle, cqcqcq); /* draw figures */ draw((4.544384825279955,5.614474881506733)--(0.,0.), sqsqsq); draw((0.,0.)--(7.,0.), sqsqsq); draw((7.,0.)--(4.544384825279955,5.614474881506733), sqsqsq); draw(circle((4.047570756834408,1.9311608279995103), 1.9311608279995103)); draw(circle((3.5,-2.128456626571063), 4.096379817740814)); draw((0.,0.)--(5.846624887233488,1.2291733783298162)); draw((2.126820515953351,1.7309093467188044)--(7.,0.)); draw((0.,0.)--(4.047570756834408,1.9311608279995103)); draw((2.9872833404546406,1.4252807216478123)--(3.6472984772417685,0.041937642192849796)); draw((1.1824537764013,0.5641676331539184)--(5.411649841361985,0.5641676331539192)); draw((4.047570756834408,1.9311608279995103)--(7.,0.)); draw((4.047570756834408,1.9311608279995103)--(3.6472984772417685,0.041937642192849796)); draw((2.9872833404546406,1.4252807216478123)--(2.6834916723068294,0.5641676331539187)); draw((4.047570756834408,1.9311608279995103)--(5.411649841361985,0.5641676331539192)); draw((4.047570756834408,1.9311608279995103)--(2.6834916723068294,0.5641676331539187)); draw((0.,0.)--(2.126820515953351,1.7309093467188044)); draw((2.126820515953351,1.7309093467188044)--(4.047570756834408,1.9311608279995103)); draw((2.126820515953351,1.7309093467188044)--(1.1824537764013,0.5641676331539184)); draw((1.1824537764013,0.5641676331539184)--(3.6472984772417685,0.041937642192849796)); /* dots and labels */ dot((4.544384825279955,5.614474881506733),linewidth(3.pt) + dotstyle); label("$A$", (4.626002649762194,5.740952451422053), NE * labelscalefactor); dot((0.,0.),linewidth(2.pt) + dotstyle); label("$B$", (-0.20871817029776618,0.1675937282973736), NE * labelscalefactor); dot((7.,0.),linewidth(3.pt) + dotstyle); label("$C$", (7.267192727387542,0.10044482801876299), NE * labelscalefactor); dot((4.047570756834408,1.9311608279995103),linewidth(3.pt) + dotstyle); label("$I$", (4.0216625472546985,2.1149118363770807), NE * labelscalefactor); label("$\Gamma$", (2.5667697078848035,3.5026557754683663), NE * labelscalefactor); dot((2.126820515953351,1.7309093467188044),linewidth(3.pt) + dotstyle); label("$D$", (1.7385999377819399,1.8463162352626383), NE * labelscalefactor); dot((5.846624887233488,1.2291733783298162),linewidth(3.pt) + dotstyle); label("$E$", (6.0808954891320885,1.3091250330337536), NE * labelscalefactor); dot((2.6834916723068294,0.5641676331539187),linewidth(3.pt) + dotstyle); label("$K$", (2.5443867411252663,0.9286145981216269), NE * labelscalefactor); dot((5.411649841361985,0.5641676331539192),linewidth(3.pt) + dotstyle); label("$L$", (5.43178945310552,0.18997669505691045), NE * labelscalefactor); dot((2.9872833404546406,1.4252807216478123),linewidth(3.pt) + dotstyle); label("$T$", (2.94728014279693,1.5553376673886592), NE * labelscalefactor); dot((3.6472984772417685,0.041937642192849796),linewidth(3.pt) + dotstyle); label("$P$", (3.6187691455830353,-0.43674637421012175), NE * labelscalefactor); dot((1.1824537764013,0.5641676331539184),linewidth(3.pt) + dotstyle); label("$Q$", (0.8656642341600026,0.5257211964499634), NE * labelscalefactor); dot((4.397269948076022,0.9244662111480743),linewidth(3.pt) + dotstyle); label("$S$", (4.22310924809053,1.1300612989574588), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]

Suppose that $Q\equiv KL\cap BI$.Since $ID=IE$ we get $\angle{DBI}=\angle{IBE}\Rightarrow BD=BK$ which gives that

$IB$ is the perpendicular bisector of $DK$,hence $\angle{DIQ}=\angle{TIK} \ (1)$.Suppose that $S\equiv BE\cap CD$.

Then $\frac{SL}{SK}=\frac{SE}{SD}=\frac{SC}{SB}\Rightarrow KL\parallel BC$.Hence,$\angle{DIQ}=\angle{DCB}=\angle{DLQ} \ (2)$

yielding that $DILQ$ is cyclic.$(1),(2)\Rightarrow \angle{TIK}=\angle{DLQ}=\angle{TLK}\Rightarrow TILK$ is cyclic.

The latter gives $\angle{KTI}=180^{\circ}-\angle{ILK}=180^{\circ}-\angle{ILQ}=\angle{IDQ}\overset{(1)}\Rightarrow \triangle{DIQ}\simeq \triangle{TIK}$.

Hence,$\frac{DI}{TI}=\frac{IQ}{IK}\Rightarrow \frac{PI}{TI}=\frac{IQ}{PI} \ (3)$.

Since $\triangle{PIT},\triangle{PQI}$ also have a common angle ($\angle{PIQ}$),from $(3)$ we deduce that they are similar.

Thus $\angle{QPI}=\angle{PTI}=90^{\circ}$ which gives that $PQ$ is tangent to $\Gamma$ and we are done.
This post has been edited 2 times. Last edited by gavrilos, Nov 1, 2015, 4:00 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
FabrizioFelen
241 posts
FabrizioFelen
#3 Nov 1, 2015, 9:30 PM • 2 Y
Y by Adventure10, Mango247
My solution:
Let $X=BI\cap KL$ and $\angle EDC=\angle EBC=\angle EKL$ since $EDKL$ and $EDBC$ are cyclic $\Longrightarrow$ $KL\parallel BC$
$\Longrightarrow$ $DILX$ is cyclic since $\angle IDL=\angle IXL=\angle IBC$ $\Longrightarrow$ $\angle IDL=\angle IXD$ $\Longrightarrow$ $ID^2=IT.IX$
Let $P'$ be a point in incircle of $\triangle ABC$ such that $XP'$ is tangent to incircle of $\triangle ABC$ $\Longrightarrow$ $IP'^2=ID^2=IT.IX$
Then $P'T\perp BI$ $\Longrightarrow$ $P'=P$ $\Longrightarrow$ $KL,BI$ and the tangent of $P$ to incircle of $\triangle ABC$ are concurrent... :-D
This post has been edited 1 time. Last edited by FabrizioFelen, Nov 1, 2015, 9:32 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
suli
1498 posts
suli
#4 Nov 1, 2015, 11:54 PM • 2 Y
Y by Adventure10, Mango247
My solution:
Let $Q = BI \cap KL$. By angle chasing we have $\angle TLQ = \angle DEK = \angle TCB$, so $QL // BC$. Thus $\angle IQL = \angle IBC = \angle IDC$, so $DILQ$ is cyclic. Because $IK = IL = ID$ are equal radii of $\Gamma$, we have $\angle DQI = \angle LQI$ and furthermore
$$\angle KIQ = \angle IKL - \angle IQK = \angle ILK - \angle DLI = \angle DLQ.$$Thus $TILK$ is cyclic as well. Then by Power of a Point, $QT \cdot QI = QK \cdot QL$. Let $P'$ be the intersection point of the tangent from $Q$ to the circle $\Gamma$ with $P'$ in triangle $IBC$; then $QP'^2 = QK \cdot QL = QT \cdot QI$. Hence $QTP'$ and $QP'I$ are similar and so $\angle QTP' = 90^\circ$, which means $P = P'$, and so $BI, KL,$ and the tangent from $P$ to $\gamma$ are concurrent.
This post has been edited 3 times. Last edited by suli, Nov 2, 2015, 12:00 AM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Dukejukem
695 posts
Dukejukem
#5 Nov 2, 2015, 12:54 AM • 2 Y
Y by Adventure10, Mango247
Let the tangent to $\Gamma$ at $P$ cut $BI$ at $Q.$

From $ID = IE$, we deduce that $\measuredangle DBI = \measuredangle IBE = \measuredangle IBK.$ Together with $ID = IK$, it follows that $BI$ is the perpendicular bisector of $\overline{DK}.$

By Reim's Theorem, $KL \parallel BC \implies \measuredangle KLT = \measuredangle BCD = \measuredangle BID = \measuredangle KIT \implies I, T, K, L$ are concyclic. $(\star)$

On account of $QI \perp TP$, it follows that $Q, T$ are inverse points WRT $\Gamma.$ Then under inversion in $\Gamma, \; (\star) \implies Q, K, L$ are collinear. $\square$
This post has been edited 1 time. Last edited by Dukejukem, Nov 2, 2015, 12:54 AM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
rkm0959
1721 posts
rkm0959
#6 Nov 2, 2015, 11:43 AM • 3 Y
Y by khyeon, Adventure10, Mango247
800th Post!

Denote $l$ as the tangent to $\Gamma$ at $P$.
Let $Q_1=KL \cap IB$ and $Q_2=l \cap IB$. It suffices to show that $Q_1=Q_2$.

From $IP \perp l$ and $IT \perp TP$, we have $IT \cdot IQ_2 = r^2$.
From $\angle DCB = \angle DEB = \angle DLK$, we have $KL \parallel BC$.
Therefore, $\angle IQ_1L = \angle IBC = \angle IDL = \angle ILT$.
Now, $\triangle ITL \sim \triangle ILQ$, so $IT \cdot IQ_1=r^2$.
We now have $IQ_1=IQ_2$, so since they both lie on $IB$, we have $Q_1=Q_2$ as desired. $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
khyeon
583 posts
khyeon
#8 Oct 2, 2016, 12:37 PM • 2 Y
Y by Adventure10, Mango247
rkm0959 wrote:
800th Post!

Denote $l$ as the tangent to $\Gamma$ at $P$.
Let $Q_1=KL \cap IB$ and $Q_2=l \cap IB$. It suffices to show that $Q_1=Q_2$.

From $IP \perp l$ and $IT \perp TP$, we have $IT \cdot IQ_2 = r^2$.
From $\angle DCB = \angle DEB = \angle DLK$, we have $KL \parallel BC$.
Therefore, $\angle IQ_1L = \angle IBC = \angle IDL = \angle ILT$.
Now, $\triangle ITL \sim \triangle ILQ$, so $IT \cdot IQ_1=r^2$.
We now have $IQ_1=IQ_2$, so since they both lie on $IB$, we have $Q_1=Q_2$ as desired. $\blacksquare$

nice solution!
drawing was hard but solution was easy :-D
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
yunseo
163 posts
yunseo
#9 Nov 24, 2019, 7:51 PM • 2 Y
Y by Adventure10, Mango247
We want to show that when inverted around the incircle, N maps to T.
This is analogous to showing that TIKL cyclic. In other words, we wish to show that D is a reflection of K over BI.
This is true because $\triangle IDM$ and $\triangle IEM$ are congruent. Thus, $\angle DBI = \angle IBK$. We also know that $IK = ID$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Supercali
1260 posts
Supercali
#10 Nov 25, 2019, 2:19 AM • 2 Y
Y by Adventure10, Mango247
Let $KL$ meet $BI$ at $Q$. Let $BI$ meet $\Gamma$ at $M,N$. Note that $ID=IE$ implies $BI$ is the angle bisector of $\angle DBE$. Also, $\Gamma$ is symmetric about $BI$, so points $D$ and $K$ are symmetric about $MN$. Hence, $\square DMKN$ is harmonic. Taking a projection wet $L$ onto $BI$, we get $(Q,T;M,N)=-1$. Hence, $T$ lies on the polar of $Q$, and 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.
primesarespecial
364 posts
primesarespecial
#11 Jul 20, 2021, 12:22 PM
Y by
Let $H=LK\cap BI$.
Firstly we have that $\angle TIK=\angle TID=\angle BID=\angle BED=\angle KED=\angle KLD$,where the first equality just came from $T$ being the midpoint of $\widehat {DE}$ and $IK=ID$.
Now we have $TILK$ is cyclic,giving us
Let $P'$ be a point of tangency from $H$ inside $\triangle BIC$.
Now ,By power of a point
$HP^2=HK.HL=HT.HI$ and this gives $\triangle THP'$ similar to $\triangle P'HI$, thus giving $\angle P'TH=90$ and hence $P'=P$.
Z K Y
N Quick Reply
G
H
=
a