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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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jlacosta
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USAMO 2002 Problem 3
MithsApprentice   20
N 39 minutes ago by Mathandski
Prove that any monic polynomial (a polynomial with leading coefficient 1) of degree $n$ with real coefficients is the average of two monic polynomials of degree $n$ with $n$ real roots.
20 replies
MithsApprentice
Sep 30, 2005
Mathandski
39 minutes ago
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NT equations make a huge comeback
MS_Kekas   3
N 42 minutes ago by RagvaloD
Source: Ukrainian Mathematical Olympiad 2024. Day 1, Problem 11.1
Find all pairs $a, b$ of positive integers, for which

$$(a, b) + 3[a, b] = a^3 - b^3$$
Here $(a, b)$ denotes the greatest common divisor of $a, b$, and $[a, b]$ denotes the least common multiple of $a, b$.

Proposed by Oleksiy Masalitin
3 replies
+1 w
MS_Kekas
Mar 19, 2024
RagvaloD
42 minutes ago
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functional equation interesting
skellyrah   8
N an hour ago by BR1F1SZ
find all functions IR->IR such that $$xf(x+yf(xy)) + f(f(x)) = f(xf(y))^2 + (x+1)f(x)$$
8 replies
skellyrah
Yesterday at 8:32 PM
BR1F1SZ
an hour ago
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Albanian IMO TST 2010 Question 1
ridgers   16
N an hour ago by ali123456
$ABC$ is an acute angle triangle such that $AB>AC$ and $\hat{BAC}=60^{\circ}$. Let's denote by $O$ the center of the circumscribed circle of the triangle and $H$ the intersection of altitudes of this triangle. Line $OH$ intersects $AB$ in point $P$ and $AC$ in point $Q$. Find the value of the ration $\frac{PO}{HQ}$.
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ridgers
May 22, 2010
ali123456
an hour ago
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Hardcore triangle geometry [A', B', C' on OI]
darij grinberg   7
N May 18, 2020 by matinyousefi
Source: 239MO 2000, classes 10-11, problem 8, by M. Sonkin, extended
The perpendicular bisectors of the sides AB and BC of a triangle ABC meet the lines BC and AB at the points X and Z, respectively. The angle bisectors of the angles XAC and ZCA intersect at a point B'. Similarly, define two points C' and A'. Prove that the points A', B', C' lie on one line through the incenter I of triangle ABC.

Extension: Prove that the points A', B', C' lie on the line OI, where O is the circumcenter and I is the incenter of triangle ABC.

Darij
7 replies
darij grinberg
Oct 7, 2004
matinyousefi
May 18, 2020
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Hardcore triangle geometry [A', B', C' on OI]
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Source: 239MO 2000, classes 10-11, problem 8, by M. Sonkin, extended
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darij grinberg
6555 posts
darij grinberg
#1 Oct 7, 2004, 6:42 AM • 2 Y
Y by Adventure10, Mango247
The perpendicular bisectors of the sides AB and BC of a triangle ABC meet the lines BC and AB at the points X and Z, respectively. The angle bisectors of the angles XAC and ZCA intersect at a point B'. Similarly, define two points C' and A'. Prove that the points A', B', C' lie on one line through the incenter I of triangle ABC.

Extension: Prove that the points A', B', C' lie on the line OI, where O is the circumcenter and I is the incenter of triangle ABC.

Darij
This post has been edited 1 time. Last edited by darij grinberg, Oct 7, 2004, 9:11 PM
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sprmnt21
279 posts
sprmnt21
#2 Oct 7, 2004, 3:59 PM • 2 Y
Y by Adventure10, Mango247
darij grinberg wrote:
Extension: Prove that the points A', B', C' lie on the line OI, where O is the circumcenter and I is the incenter of triangle ABC.

Darij

Actually this is a big hint :) .

For the moment I will give only a very concise sketch.

a) Is enough to prove that B',O and I are collinear.

b) One can prove (is not very difficult, indeed) that the bisectors (of both angles and sides) meet on c(ABC).

c) Then using Pascal theorem one can prove the claim.
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darij grinberg
6555 posts
darij grinberg
#3 Oct 7, 2004, 9:08 PM • 2 Y
Y by Adventure10, Mango247
This is highly interesting. Could you tell me some details of steps b) and c)? I cannot complete your solution. On the other hand, my own solution is very long.

Thanks!
Darij
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grobber
7849 posts
grobber
#4 Oct 7, 2004, 10:52 PM • 2 Y
Y by Adventure10, Mango247
What sprmnt is saying is, I think, that $OX$ and $AB'$ meet on $(ABC)$, and this is a simple angle chase (the same holds, of course, for $OZ$ and $B'C$). All we need to do is compute the angle between $AB'$ and the perp. bisector of $AB$. On the other hand, we know that the bisectors of $\angle A,\angle C$ meet the perpendicular bisectors of $BC,AB$ (respectively) on $(ABC)$.
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RaMlaF
83 posts
RaMlaF
#5 Oct 8, 2004, 12:19 AM • 2 Y
Y by Adventure10, Mango247
mmm i don't know if this is ok or not, because it seems to be quite easy... what i had thought is exactly what grobber said: $OX$ and $AB'$ meet on $(ABC)$ (let $M$ be that intersection), and the same holds for $OZ$ and $CB'$ (they meet in a point $N$, in $(ABC)$... let $P$ and $Q$ be the second intersections of $OX$ and $OZ$ with $(ABC)$ (i.e., the intersection of the perpendicular bisectors of $AB$ and $BC$ with the circumcircle), respectively. Now you just have to notice that in the cyclic hexagon $PCNQAM$ the intersections of the opposite sides lie on a line...and those intersections are $PC\cap AQ = I$, $CN\cap AM = B'$ and $NQ\cap MP = O$, so B' lies on the line OI and we are done :)
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sprmnt21
279 posts
sprmnt21
#6 Oct 8, 2004, 6:47 AM • 2 Y
Y by Adventure10, Mango247
darij grinberg wrote:
This is highly interesting. Could you tell me some details of steps b) and c)?
Darij

Tanks to Grobber and RamLaf, I sould have only to attach a picture.

BTW, here follow the arguments which prove the claims.

If K (opposite to A) and H are the common points to c(ABC) and the axis of BC, then AI pass through K. furtermore, as BCZ is isosceles, the angle bisector of <ZBA pass through H.

Similarly for all the other bisectors.


PS

Darij, what contest is 239MO?
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darij grinberg
6555 posts
darij grinberg
#7 Oct 8, 2004, 11:36 AM • 2 Y
Y by Adventure10, Mango247
Wow, this was a cook. Probably I should have thought about the problem for a longer time, and not at midnight. Anyway, all of your solutions are correct and nice. My own solution used nine-point centers, Kosnita points and isogonal conjugates and was so monstrous that I don't want even to mention it. A note to your post, Sprmnt21:
sprmnt21 wrote:
If K (opposite to A) and H are the common points to c(ABC) and the axis of BC, then AI pass through K. furtermore, as BCZ is isosceles, the angle bisector of <ZBA pass through H.

I guess <ZBA should be < ZCA. Again, your proofs are very nice. Now I have another synthetic proof, based on your ideas:

Let the lines AX and AB' meet the circumcircle of triangle ABC at the points U and M (apart from A). Since the line AB' bisects the angle XAC, we have < MAC = < UAM, and thus, replacing chordal angles by arcs on the circumcircle of triangle ABC, we have arc MC = arc UM. On the other hand, the point X lies on the perpendicular bisector of the segment AB, and thus < XBA = < BAX, or, in other words, < CBA = < BAU. In terms of arcs, this yields arc CA = arc BU. Together with arc MC = arc UM, this implies arc MA = arc MC + arc CA = arc UM + arc BU = arc BM, what yields that the point M is the midpoint of the arc ACB on the circumcircle of triangle ABC. In other words, the point M is the midpoint of the segment $I_aI_b$, where $I_a$, $I_b$, $I_c$ are the excenters of triangle ABC. Similarly, the point N where the line CB' meets the circumcircle of triangle ABC (apart from C) is the midpoint of the segment $I_bI_c$. Now, applying the Pappos theorem to the collinear point triplets (C, M, $I_a$) and (A, N, $I_c$), we see that the points $CN \cap AM$, $MI_c \cap NI_a$ and $I_aA \cap I_cC$ are collinear. But $CN \cap AM = B^{\prime}$. Further, $MI_c \cap NI_a$ is the point of intersection of the lines joining the vertices $I_c$ and $I_a$ of triangle $I_aI_bI_c$ with the midpoints M and N of the opposite sides $I_aI_b$ and $I_bI_c$; in other words, the point $MI_c \cap NI_a$ is the centroid of triangle $I_aI_bI_c$. Finally, the point $I_aA \cap I_cC$ is the point I, the orthocenter of triangle $I_aI_bI_c$. Hence, we have obtained that the point B' is collinear with the centroid and the orthocenter of triangle $I_aI_bI_c$. In other words, the point B' lies on the Euler line of triangle $I_aI_bI_c$. But this Euler line is the line OI. Hence, the point B' lies on the line OI. Similarly, we can show that the points C' and A' lie on the line OI, and the problem is solved.
sprmnt21 wrote:
Darij, what contest is 239MO?

The Open Olympiad of the 239th Mathematical Lyceum of St. Petersburg, Russia. This is a very special olympiad, organized by enthusiasts, and containing very hard problems.

Darij
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matinyousefi
499 posts
matinyousefi
#8 May 18, 2020, 4:16 AM
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The perpendicular bisectors of the sides $AB$ and $BC$ of a triangle $ABC$ meet the lines $BC$ and $AB$ at the points $X$ and $Z$, respectively. The angle bisectors of the angles $XAC$ and $ZCA$ intersect at a point $B'$. Similarly, define two points $C'$ and $A'$. Prove that the points $A'$, $B'$, $C'$ lie on one line through the incenter $I$ of triangle $ABC$.
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