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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.

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0 replies
jlacosta
Apr 2, 2025
0 replies
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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
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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
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Parallelograms and concyclicity
Lukaluce   21
N a few seconds ago by SimplisticFormulas
Source: EGMO 2025 P4
Let $ABC$ be an acute triangle with incentre $I$ and $AB \neq AC$. Let lines $BI$ and $CI$ intersect the circumcircle of $ABC$ at $P \neq B$ and $Q \neq C$, respectively. Consider points $R$ and $S$ such that $AQRB$ and $ACSP$ are parallelograms (with $AQ \parallel RB, AB \parallel QR, AC \parallel SP$, and $AP \parallel CS$). Let $T$ be the point of intersection of lines $RB$ and $SC$. Prove that points $R, S, T$, and $I$ are concyclic.
21 replies
Lukaluce
Yesterday at 10:59 AM
SimplisticFormulas
a few seconds ago
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Nepal TST 2025 DAY 1 Problem 1
Bata325   7
N 25 minutes ago by cursed_tangent1434
Source: Nepal TST 2025 p1
Consider a triangle $\triangle ABC$ and some point $X$ on $BC$. The perpendicular from $X$ to $AB$ intersects the circumcircle of $\triangle AXC$ at $P$ and the perpendicular from $X$ to $AC$ intersects the circumcircle of $\triangle AXB$ at $Q$. Show that the line $PQ$ does not depend on the choice of $X$.

(Shining Sun, USA)
7 replies
Bata325
Apr 11, 2025
cursed_tangent1434
25 minutes ago
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A game optimization on a graph
Assassino9931   1
N 44 minutes ago by ayeen_izady
Source: Bulgaria National Olympiad 2025, Day 2, Problem 6
Let \( X_0, X_1, \dots, X_{n-1} \) be \( n \geq 2 \) given points in the plane, and let \( r > 0 \) be a real number. Alice and Bob play the following game. Firstly, Alice constructs a connected graph with vertices at the points \( X_0, X_1, \dots, X_{n-1} \), i.e., she connects some of the points with edges so that from any point you can reach any other point by moving along the edges.Then, Alice assigns to each vertex \( X_i \) a non-negative real number \( r_i \), for \( i = 0, 1, \dots, n-1 \), such that $\sum_{i=0}^{n-1} r_i = 1$. Bob then selects a sequence of distinct vertices \( X_{i_0} = X_0, X_{i_1}, \dots, X_{i_k} \) such that \( X_{i_j} \) and \( X_{i_{j+1}} \) are connected by an edge for every \( j = 0, 1, \dots, k-1 \). (Note that the length $k \geq 0$ is not fixed and the first selected vertex always has to be $X_0$.) Bob wins if
\[ \frac{1}{k+1} \sum_{j=0}^{k} r_{i_j} \geq r; \]otherwise, Alice wins. Depending on \( n \), determine the largest possible value of \( r \) for which Bobby has a winning strategy.
1 reply
Assassino9931
Apr 8, 2025
ayeen_izady
44 minutes ago
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a,b,c,x,y,z (something interesting
SunnyEvan   1
N an hour ago by lbh_qys
Let $ a,b,c,x,y,z,k \in R^+ $ ,such that $ ax^2+by^2+cz^2=xyz. $ Prove that : $$ x+y+z \geq \frac{(1+ \sqrt{1+ka})(1+ \sqrt{1+kb})(1+ \sqrt{1+kc})}{k} $$Where $ k $ is a positive real number solution of equation : $ \frac{2}{1+ \sqrt{1+ka}}+ \frac{2}{1+ \sqrt{1+kb}}+ \frac{2}{1+ \sqrt{1+kc}} = 1 $
1 reply
+1 w
SunnyEvan
Yesterday at 2:15 PM
lbh_qys
an hour ago
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one cyclic formed by two cyclic
CrazyInMath   30
N an hour ago by GeoKing
Source: EGMO 2025/3
Let $ABC$ be an acute triangle. Points $B, D, E$, and $C$ lie on a line in this order and satisfy $BD = DE = EC$. Let $M$ and $N$ be the midpoints of $AD$ and $AE$, respectively. Suppose triangle $ADE$ is acute, and let $H$ be its orthocentre. Points $P$ and $Q$ lie on lines $BM$ and $CN$, respectively, such that $D, H, M,$ and $P$ are concyclic and pairwise different, and $E, H, N,$ and $Q$ are concyclic and pairwise different. Prove that $P, Q, N,$ and $M$ are concyclic.
30 replies
CrazyInMath
Sunday at 12:38 PM
GeoKing
an hour ago
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EGMO magic square
Lukaluce   14
N an hour ago by R9182
Source: EGMO 2025 P6
In each cell of a $2025 \times 2025$ board, a nonnegative real number is written in such a way that the sum of the numbers in each row is equal to $1$, and the sum of the numbers in each column is equal to $1$. Define $r_i$ to be the largest value in row $i$, and let $R = r_1 + r_2 + ... + r_{2025}$. Similarly, define $c_i$ to be the largest value in column $i$, and let $C = c_1 + c_2 + ... + c_{2025}$.
What is the largest possible value of $\frac{R}{C}$?

Proposed by Paulius Aleknavičius, Lithuania
14 replies
Lukaluce
Yesterday at 11:03 AM
R9182
an hour ago
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Playing cards 1
prof.   0
an hour ago
In how many ways can a deck of 52 cards be divided among 13 players, each with 4 cards, so that one player has all 4 suits and the others have one suit?
0 replies
prof.
an hour ago
0 replies
J
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hard problem
Cobedangiu   1
N an hour ago by lbh_qys
Let $x,y>0$ and $\dfrac{1}{x}+\dfrac{1}{y}+1=\dfrac{10}{x+y+1}$. Find max $A$ (and prove):
$A=\dfrac{x^2}{y}+\dfrac{y^2}{x}+\dfrac{1}{xy}$
1 reply
Cobedangiu
2 hours ago
lbh_qys
an hour ago
J
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IMO Problem 5
iandrei   23
N 3 hours ago by eevee9406
Source: IMO ShortList 2003, algebra problem 4
Let $n$ be a positive integer and let $x_1\le x_2\le\cdots\le x_n$ be real numbers.
Prove that

\[ \left(\sum_{i,j=1}^{n}|x_i-x_j|\right)^2\le\frac{2(n^2-1)}{3}\sum_{i,j=1}^{n}(x_i-x_j)^2. \]
Show that the equality holds if and only if $x_1, \ldots, x_n$ is an arithmetic sequence.
23 replies
iandrei
Jul 14, 2003
eevee9406
3 hours ago
J
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Turbo's en route to visit each cell of the board
Lukaluce   13
N 3 hours ago by MathLuis
Source: EGMO 2025 P5
Let $n > 1$ be an integer. In a configuration of an $n \times n$ board, each of the $n^2$ cells contains an arrow, either pointing up, down, left, or right. Given a starting configuration, Turbo the snail starts in one of the cells of the board and travels from cell to cell. In each move, Turbo moves one square unit in the direction indicated by the arrow in her cell (possibly leaving the board). After each move, the arrows in all of the cells rotate $90^{\circ}$ counterclockwise. We call a cell good if, starting from that cell, Turbo visits each cell of the board exactly once, without leaving the board, and returns to her initial cell at the end. Determine, in terms of $n$, the maximum number of good cells over all possible starting configurations.

Proposed by Melek Güngör, Turkey
13 replies
Lukaluce
Yesterday at 11:01 AM
MathLuis
3 hours ago
J
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equal angles
jhz   6
N 3 hours ago by aidan0626
Source: 2025 CTST P16
In convex quadrilateral $ABCD, AB \perp AD, AD = DC$. Let $ E$ be a point on side $BC$, and $F$ be a point on the extension of $DE$ such that $\angle ABF = \angle DEC>90^{\circ}$. Let $O$ be the circumcenter of $\triangle CDE$, and $P$ be a point on the side extension of $FO$ satisfying $FB =FP$. Line BP intersects AC at point Q. Prove that $\angle AQB =\angle DPF.$
6 replies
jhz
Mar 26, 2025
aidan0626
3 hours ago
J
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Very easy number theory
darij grinberg   101
N 4 hours ago by sharknavy75
Source: IMO Shortlist 2000, N1, 6th Kolmogorov Cup, 1-8 December 2002, 1st round, 1st league,
Determine all positive integers $ n\geq 2$ that satisfy the following condition: for all $ a$ and $ b$ relatively prime to $ n$ we have \[a \equiv b \pmod n\qquad\text{if and only if}\qquad ab\equiv 1 \pmod n.\]
101 replies
darij grinberg
Aug 6, 2004
sharknavy75
4 hours ago
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Looks difficult number mock#5
Physicsknight   1
N 4 hours ago by Physicsknight
Source: Vadilal factory
Consider $a_1,a_2,\hdots,a_b$ be distinct prime numbers. Let $\alpha_i=\sqrt{a}, \,\mathrm{A}=\mathbb{Q}[\alpha_1,\alpha_2,\hdots,\alpha_b]$
Let $\gamma=\sum\,\alpha_i$
[list]
[*] Prove that $[\mathrm{A}:\mathbb{Q}]=2^b$
[*] Prove that $\mathrm{A}=\mathbb{Q}[\gamma];$ and deduce that the minimum polynomial $f(X)$ of $\gamma$ over $\mathbb{Q}$ has degree $2^b.$
[*] Prove that $f(X)$ factors in $\mathbb{Z}_a[X]$ into a product of polynomials of degree $\leq 4 \,(a\ne 2)$ either of degree $\leq 8\,(a=2)$
[/list]
1 reply
Physicsknight
Yesterday at 1:51 PM
Physicsknight
4 hours ago
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Brocard angle
Rushil   4
N Oct 15, 2005 by yetti
Source: Indian Postal Coaching 2004
Three circles touch each other externally and all these cirlces also touch a fixed straight line. Let $A,B,C$ be the mutual points of contact of these circles. If $\omega$ denotes the Brocard angle of the triangle $ABC$, prove that $\cot{\omega}$ = 2.
4 replies
Rushil
Sep 23, 2005
yetti
Oct 15, 2005
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Brocard angle
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Reveal topic tags
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Source: Indian Postal Coaching 2004
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Rushil
1592 posts
Rushil
#1 Sep 23, 2005, 6:51 AM • 3 Y
Y by Adventure10, Mango247, and 1 other user
Three circles touch each other externally and all these cirlces also touch a fixed straight line. Let $A,B,C$ be the mutual points of contact of these circles. If $\omega$ denotes the Brocard angle of the triangle $ABC$, prove that $\cot{\omega}$ = 2.
This post has been edited 1 time. Last edited by Rushil, Oct 16, 2005, 1:25 AM
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yetti
2643 posts
yetti
#2 Oct 14, 2005, 3:03 AM • 1 Y
Y by Adventure10
At first, let $\triangle ABC$ be arbitrary. The Brocard point $Z_1$ is the concurrency point of 3 circles $(O_A), (O_B), (O_C)$. The circle $(O_A)$ is tangent to the line AB at A and passes through the opposite vertex C, the circle $(O_B)$ is tangent to the line BC at B and passes through the opposite vertex A, the circle $(O_C)$ is tangent to the line CA at C and passes through the opposite vertex B. Then $\omega = \angle Z_1BC = \angle Z_1CA = \angle Z_1AB$ is the Brocard angle of the triangle $\triangle ABC$. Similarly, the circles $(P_B), (P_C), (P_A)$ were tangent to the lines AB, BC, CA at the other vertices B, C, A, respectively, concur at the other Brocard point $Z_2$ and $\omega = \angle Z_2CB = \angle Z_1CA = \angle Z_2BA$ is the same Brocard angle of the triangle $\triangle ABC$. We consider the 1st case of $Z_1$.

Lemma 1: The triangle $\triangle O_AO_BO_C$ is spirally similar to the triangle $\triangle ABC$ with the similarity center $Z_1$ and rotation angle $\phi = \omega - 90^\circ$.

The angle $\angle AZ_1B$ s spanning the arc $\widehat {AZ_1B}$ of the circle $O_B$ is equal to $180^\circ = \angle ABC$, where $\angle ABC = \angle B$ is the angle formed by the chord AB and tangent BC of this circle at the triangle vertex B. The Brocard rays $AZ_1, BZ_1$ are the radical axes of the circle pairs $(O_B), (O_A)$ and $(O_B), (O_C)$. Hence, their center lines $O_BO_A, O_BO_C$ are perpendicular to these Brocard rays and they form the angle $\angle O_B = \angle O_AO_BO_C = 180^\circ - \angle AZ_1B = 180^\circ - (180^\circ - \angle B) = \angle B$. Similarly, the remaining 2 angles $\angle O_C, \angle O_A$ of the triangle $\triangle O_AO_BO_C$ are equal to $\angle O_C = \angle C, \angle O_A = \angle A$. Thus the triangles $\triangle O_AO_BO_C \sim \triangle ABC$ are similar. The angle $\angle Z_1O_BB$ is the central angle of the Brocard angle $\angle Z_1AB = \omega$ spanning the arc $\widehat {AZ_1B}$ of the circle $(O_B)$ , hence $\angle Z_1O_BB = 2 \omega$. Likewise, $\angle Z_1O_CC = \angle Z_1O_AA = 2\omega$. Consequently, the isosceles triangles $\triangle Z_1O_BB \sim \triangle Z_1O_CC \sim \triangle Z_1O_AA$ are all similar and

$\frac{Z_1O_B}{Z_1B} = \frac{Z_1O_C}{Z_1C} = \frac{Z_1O_A}{Z_1A}$,

$\angle O_BZ_1B = \angle O_CZ_1C = \angle O_AZ_1A = \frac{180^\circ - 2\omega}{2} = 90^\circ - \omega$,

which implies that the Brocard point $Z_1$ is the spiral similarity center of the triangles $\triangle O_AO_BO_C \sim \triangle ABC$. Since the oriented angle $\measuredangle O_BZ_1B$ ic clockwise for a triangle $\triangle ABC$ labeled counter-clockwise, the rotation angle is $\phi = - \angle O_BZ_1B = \omega - 90^\circ$.

Lemma 2: Let the normals to the Brocard rays $AZ_1, BZ_1, CZ_1$ at the point $Z_1$ meet the circles $(O_A), (O_B), (O_C)$ at points D, E, F, respectively, different from $Z_1$. The triangle $\triangle DEF$ is spirally similar to the triangle $\triangle ABC$ with the similarity center $Z_1$ and rotation angle $-90^\circ$. The similarity coefficient of these 2 triangles is equal to $\cot \omega$.

Since the angle $\angle AZ_1D = 90^\circ$ inscribed in the circle $(O_A)$ is right by definition, $AD$ is a diameter of this circle, its center $O_A$ is the midpoint of of this diameter and the points $A, O_A, D$ are collinear. Similarly, BE ia a diameter of the circle $(O_B)$ and the points $B, O_B, E$ are also collinear. Thus the angle $\angle BAE = 90^\circ$ is right. Since the circle $(O_A)$ is tangent to the line AB at the vertex A, the angle $\angle BAD = 90^\circ$ is also right. As a result, the points $D, O_A, A, E$ are all collinear and similarly, the points $E, O_B, B, F$ are collinear and the points $F, O_C, C, D$ are collinear. The angle $\angle DEF \equiv \angle AEB$ is spanning the arc $\widehat {AEB}$ of the circle $(O_B)$ opposite to the arc $\overarc{AZ1B}$, hence, $\angle DEF = 180^\circ - \angle AZ_1B = 180^\circ - (180^\circ - \angle B) = \angle B$ (see the proof of lemma 1). Likewise, $\angle EFD = \angle C, \angle FDE = \angle A$ and consequently, the triangles $\triangle DEF \sim \triangle ABC$ are similar. The angles $\angle Z_1EB = \angle Z_1AB = \omega$ spanning the same arc $Z_1B$ of the circle $(O_B)$ are equal. Likewise, $\angle Z_1FC = \angle Z_1BC = \omega$ and $\angle Z_1DA = \angle Z_1CA = \omega$. As a result, the isosceles triangles $\triangle Z_1O_BE \sim \triangle Z_1O_CF \sim \triangle Z_1O_AD$ are all similar and

$\frac{Z_1O_B}{Z_1E} = \frac{Z_1O_C}{Z_1F} = \frac{Z_1O_A}{Z_1D}$,

which implies that the Brocard point $Z_1$ is the common spiral similarity center of the triangles $\triangle DEF \sim \triangle O_AO_BO_C \sim \triangle ABC$. By definition, the rotation angle of the triangle $\triangle DEF$ with respect to the triangle $\triangle ABC$ is $90^\circ$ clockwise, i.e., $-90^\circ$ counter-clockwise. The similarity coefficient of the triangles $\triangle DEF \sim \triangle ABC$ is $\frac{Z_1E}{Z_1B}$. Since the angle $\angle BZ_1E = 90^\circ$ is right by definition and since we have shown that the angle $\angle Z_1EB = \omega$ is equal to the Brocard angle, $\frac{Z_1E}{Z_1B} = \cot \omega$.

To prove the problem proposition, we will use only lemma 1. (I got carried away before realizing that the problem was simpler that it seemed.)

(to be continued)
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#3 Oct 14, 2005, 3:04 AM • 1 Y
Y by Adventure10
Let $r_1, r_2$ be the radii of the 2 given externally tangent circles $(O_1), (O_2)$. Let A be the tangency point of these 2 circles and let KL be one of their common external tangents with the tangency points $K \in (O_1), L \in (O_2)$. We follow the usual construction of the circle $(O_3)$ tangent to the line KL and to the circles $(O_1), (O_2)$ at points B, C, i.e., we invert the circles $(O_1), (O_2)$ and the line KL in a circle (A) centered at their tangency point A lying on the center line $O_1O_2$. We choose the radius of the inversion circle (A) to be $r = \sqrt{r_1r_2}$. (We could also choose $r = \sqrt{2r_1r_2}$ or $r = 2 \sqrt{r_1r_2}$, but we will stick with the original choice. This is a known trick for problems related to Archimedes' arbelos.) Since the circles $(O_1), (O_2)$ both pass through the inversion center, they are carried into straight lines $o_1, o_2$ both perpendicular to the center line $O_1O_2$. Let the 2 circles intersect the center line $O_1O_2$ at points P, Q different from their tangency point A. Since $AP = 2r_1,\ AQ = 2r_2$, the points P, Q are carried into the points $P', Q' \in O_1O_2$, such that

$AP' = \frac{r^2}{AP} = \frac{r_1r_2}{2r_1} = \frac{r_2}{2}$

$AQ' = \frac{r^2}{AQ} = \frac{r_1r_2}{2r_2} = \frac{r_1}{2}$

The lines $o_1, o_2$, i.e., the inverted circles $(O_1), (O_2)$, are the normals to the center line $O_1O_2$ at the points P', Q', recpectively. Since the triangles $\triangle PKA \sim \triangle ALQ$ are similar and right, the angle $\angle KAL = 90^\circ$ is also right. The normal to the center line $O_1O_2$ at the tangency point A is the radical axis of the circles $(O_1), (O_2)$, hence, it cuts the tangent segment KL at its midpoint R and consequently, AR is the median of the right angle triangle $\triangle KAL$ equal to half of its hypotenuse $KL = 2 \sqrt{r_1r_2}$ (the external tangent distance of 2 externally tangent circles). Thus $AR = \frac{KL}{2} = \sqrt{r_1r_2} = r$. As a result, the inversion circle (A) with radius r cuts the common external tangent KL at the midpoint R (and at some other point S). Our inversion carries the line $t \equiv KL$ into a circle (T) passing through the inversion center A, through the points R, S, and tangent to the 2 parallel lines $o_1 \parallel o_2$ separated by the distance $P'Q' = AP' + AQ' = \frac{r_1 + r_2}{2}$. Thus the radius of the circle (T) is $\frac{P'Q'}{2} = \frac{r_1 + r_2}{4}$. The unknown circle $(O_3)$ tangent to the circles $(O_1), (O_2)$ at points B, C is carried into a circle $(O_3')$ also tangent to the parallel lines $o_1 \parallel o_2$ at points B', C' and to the circle (T). The tangency points B, C of the circle $(O_3)$ are the intersections of the rays AB', AC' with the circles $(O_1), (O_2)$. Thus we obtained the defined triangle $\triangle ABC$, which is all we need. Anyway, the tangency point U of the circle $(O_3)$ with the line $t \equiv KL$ is the intersection of the ray AU' with the line KL and $(O_3)$ is the circumcircle of the triangle $\triangle BCU$. Or, the center of the circle $(O_3)$ is the intersection of the perpendicular bisector of the segment BC with the ray $AO_3'$ (because a circle and its inverted image are centrally similar with the homothety center at the inversion center).

Because of the basic properties of inversion, the triangles $\triangle AC'B' \sim \triangle ABC$ are similar and consequently, they have the same Brocard angle. Thus we do not have to worry about the triangle $\triangle ABC$ at all and we can find the Brocard angle of the inverted triangle $\triangle AB'C'$ instead. Obviously, the side B'C' of this triangle is perpendicular to the parallel lines $o_1 \parallel o_2$ and from the rectangle P'Q'C'B', $B'C' = P'Q' = \frac{r_1 + r_2}{2}$. The other 2 sides of this rectangle are equal to

$P'B' = Q'C' = \frac{AR}{2} + TU' + U'O_3' = \frac{r_1 + r_2 + \sqrt{r_1r_2}}{2}$

because $TU' = U'O_3' = \frac{r_1 + r_2}{4}$ are radii of the congruent circles $(T), (O_3')$ and the circle (T) is centered on the perpendicular bisector of the segment $AR = \sqrt{r_1r_2}$ (see above). By Pythagorean theorem for the right angle triangles $\triangle AP'B', \triangle AQ'C'$ their hypotenuses AB', AC' are

$AB'^2 = AP'^2 + P'B'^2 = \frac{r_2^2 + \left(r_1 + r_2 + \sqrt{r_1r_2}\right)^2}{4}$

$AC'^2 = AQ'^2 + Q'C'^2 = \frac{r_1^2 + \left(r_1 + r_2 + \sqrt{r_1r_2}\right)^2}{4}$

Let $(O_B)$ be a circle tangent to the side B'C' of the triangle $\triangle AB'C'$ at the vertex B' an passing through the opposite vertex A. Since $B'C' \perp P'B'$, the circle $(O_B)$ is centered on the line $o_1 \equiv P'B'$, on its intersection with the perpendicular bisector of the segment AB'. Let $(O_C)$ be a circle tangent to the side AC' at the vertex C' and passing through the opposite vertex B'. The circle $(O_C)$ is centered on the perpendicular bisector of the segment B'C', which is parallel to the lines $o_1 \equiv P'B', o_2 \equiv Q'C'$. Similarly, we could define circle $(O_A)$, but we do not need it. According to lemma 1, the side B'C' of the triangle $AB'C'$ forms the angle $90^\circ - \omega$ with the side $O_BO_C$ of the triangle $\triangle O_AO_BO_C$ ($\omega$ is the Brocard angle). Therefore, the line $O_BO_C$ forms the angle $\omega$ with the perpendicular $o_1 \equiv P'B'$ to the line B'C'. Since $O_B \in P'B'$, the angle $\angle O_CO_BB' = \omega$ is the Brocard angle of the triangles $\triangle AB'C' \sim \triangle O_AO_BO_C$. Let a normal to the line $o_1 \equiv P'B' \equiv O_BB'$ through the point $O_C$ intersects this line at a point V. Then from the right angle triangle $\triangle O_BO_CV$, $\cot \omega = \frac{O_BV}{OC_V}$. We know one leg $O_CV = O_3'B' = \frac{r_1 + r_2}{4}$ of this triangle. Now we have to calculate the other leg.

Let M, N be the midpoints of the sides AB', B'C'. (Obviously, $N \equiv O_3$ is the center of the circle $(O_3')$.) The right angle triangles $\triangle O_BMB' \sim \triangle AP'B'$ are similar, having the angle at the vertex B' common. Hence,

$\frac{O_BB'}{MB'} = \frac{AB'}{P'B'}$

$O_BB' = \frac{MB' \cdot AB'}{P'B'} = \frac{AB'^2}{2P'B'} = \frac{r_2^2 + \left(r_1 + r_2 + \sqrt{r_1r_2}\right)^2}{4\left(r_1 + r_2 + \sqrt{r_1r_2}\right)}$

Likewise, the right angle triangles $\triangle C'NO_C \sim \triangle AQ'C'$ are similar, because the angle $\angle AC'O_C = 90^\circ$ is right due to the tangency of the circle $(O_C)$ to the line B'C' at the point C'. Therefore, the angles $\angle AC'N + \angle NC'O_C = 90^\circ$ add up to a right angle and $\angle NC'O_C = 90^\circ - \angle AC'N = 90^\circ - \angle C'AP' = \angle AC'P'$. Hence,

$\frac{O_CN}{NC'} = \frac{AQ'}{Q'C'}$

$O_CN = \frac{NC' \cdot AQ'}{Q'C'} = \frac{(r_1 + r_2)r_1}{4\left(r_1 + r_2 + \sqrt{r_1r_2}\right)}$

The other leg of the right angle triangle triangle $\triangle O_BO_CV$ and $\cot \omega$ are then

$O_BV = O_BB' + B'V = O_BB' + O_CN = \frac{(r_1 + r_2)r_1 + r_2^2 + \left(r_1 + r_2 + \sqrt{r_1r_2}\right)^2}{4\left(r_1 + r_2 + \sqrt{r_1r_2}\right)}$

$\cot \omega = \frac{O_BV}{O_CV} = \frac{(r_1 + r_2)r_1 + r_2^2 + \left(r_1 + r_2 + \sqrt{r_1r_2}\right)^2}{(r_1 + r_2)\left(r_1 + r_2 + \sqrt{r_1r_2}\right)} =$

(factoring out $r_1 + r_2$)

$= \frac{(r_1 + r_2)r_1 + r_2^2 + (r_1 + r_2)^2 + 2(r_1 + r_2) \sqrt{r_1r_2} + r_1r_2}{(r_1 + r_2)(r_1 + r_2 + \sqrt{r_1r_2})} =$

$= \frac{(r_1 + r_2)\left(r_1 + r_1 + r_2 + 2 \sqrt{r_1r_2}\right) + r_2(r_1 + r_2)}{(r_1 + r_2)\left(r_1 + r_2 + \sqrt{r_1r_2}\right)} =$

$= \frac{2r_1 + 2r_2 + 2 \sqrt{r_1r_2}}{r_1 + r_2 + \sqrt{r_1r_2}} = 2$

Q.E.D.
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#4 Oct 14, 2005, 8:45 AM • 2 Y
Y by Adventure10, Mango247
Excellent proofs!!!!1 :D :D :D


Can you tell me which program you used for the wonderful diagrams and where I can sownload them???
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#5 Oct 15, 2005, 2:15 PM • 2 Y
Y by Adventure10, Mango247
Tx. I use The Geometer's Sketchpad to make the drawings. This program is not available for a free download, but it is very nice and very cheap ($\$$40). See the last message in Geometrical problem for more info. The label "AGif UNREGISTERED" stands just for the Active GIF Creator, which is a graphics converter. Unregistered version (not purchased, just downloaded) puts this label into the GIF images. Search the web, I got many hits for "Active GIF Creator". Normally, I use Adobe Photoshop to export the Sketchpad drawings into the transparent GIF format, but I did not have it on the computer, which I used at this time.

Yetti.
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