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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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0 replies
jlacosta
Apr 2, 2025
0 replies
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one cyclic formed by two cyclic
CrazyInMath   8
N a few seconds ago by MathLuis
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.
8 replies
+5 w
CrazyInMath
3 hours ago
MathLuis
a few seconds ago
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GCD of sums of consecutive divisors
Lukaluce   3
N 2 minutes ago by MuradSafarli
Source: EGMO 2025 P1
For a positive integer $N$, let $c_1 < c_2 < ... < c_m$ be all the positive integers smaller than $N$ that are coprime to $N$. Find all $N \ge 3$ such that
\[gcd(N, c_i + c_{i + 1}) \neq 1\]for all $1 \le i \le m - 1$.
3 replies
Lukaluce
2 hours ago
MuradSafarli
2 minutes ago
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sequence infinitely similar to central sequence
InterLoop   4
N 3 minutes ago by Marius_Avion_De_Vanatoare
Source: EGMO 2025/2
An infinite increasing sequence $a_1 < a_2 < a_3 < \dots$ 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 $a_n = b_n$.
4 replies
+2 w
InterLoop
3 hours ago
Marius_Avion_De_Vanatoare
3 minutes ago
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Hard number theory
truongngochieu   7
N 6 minutes ago by truongngochieu
Find all integers $a,b$ such that $a^2+a+1=7^b$
7 replies
+1 w
truongngochieu
2 hours ago
truongngochieu
6 minutes ago
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No more topics!
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angle MBC is equal to angle FC iff ABC is equilateral
orl   2
N Jul 24, 2005 by darij grinberg
Source: Moldova TST 2005 for JBMO, day 2, problem 1
Let $ABC$ be an acute-angled triangle, and let $F$ be the foot of its altitude from the vertex $C$. Let $M$ be the midpoint of the segment $CA$. Assume that $CF=BM$. Then the angle $MBC$ is equal to angle $FCA$ if and only if the triangle $ABC$ is equilateral.
2 replies
orl
Apr 11, 2005
darij grinberg
Jul 24, 2005
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angle MBC is equal to angle FC iff ABC is equilateral
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Reveal topic tags
trigonometry
geometry
circumcircle
angle bisector
trig identities
Law of Sines
perpendicular bisector
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G H BBookmark kLocked kLocked NReply
Source: Moldova TST 2005 for JBMO, day 2, problem 1
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orl
3647 posts
orl
#1 Apr 11, 2005, 5:53 PM • 2 Y
Y by Adventure10, Mango247
Let $ABC$ be an acute-angled triangle, and let $F$ be the foot of its altitude from the vertex $C$. Let $M$ be the midpoint of the segment $CA$. Assume that $CF=BM$. Then the angle $MBC$ is equal to angle $FCA$ if and only if the triangle $ABC$ is equilateral.
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Mildorf
785 posts
Mildorf
#2 Apr 11, 2005, 7:30 PM • 2 Y
Y by Adventure10, Mango247
One direction is very easy. I will prove the other direction.

Let $m\angle{FCA} = \alpha = m\angle{CBM}$. Let $m\angle{CBA} = \beta$, and $x = m\angle{BMA}$. Now, by the Law of Sines, $\frac{\sin{90-\beta+\alpha}}{\sin{90-\alpha}} = \frac{AB}{BC} = \frac{\frac{AB}{AM}}{\frac{BC}{MC}} = \frac{\frac{\sin{x}}{\sin{\beta-\alpha}}}{\frac{\sin{180-x}}{\sin{\alpha}}} = \frac{\sin{\alpha}}{\sin{\beta-\alpha}}$. That is, $\cos{(\beta-\alpha)}\sin{(\beta-\alpha)} = \cos{\alpha}\sin{\alpha}$. This gives $\beta = 2\alpha$ or $\beta = 90$. Only the first is valid. But then the angle bisector bisects the opposite side, giving $AB = BC$. Then basic trigonometry completes the problem.
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darij grinberg
6555 posts
darij grinberg
#3 Jul 24, 2005, 2:28 PM • 2 Y
Y by Adventure10, Mango247
Why use trigonometry? There is a short synthetic solution:

We have to show that < MBC = < FCA holds if and only if triangle ABC is equilateral. Well, one direction is obvious: If triangle ABC is equilateral, then both the median BM and the altitude CF are actually medians, so that M and F are the midpoints of the sides CA and AB, respectively, and then < MBC = < FCA = 30° is clear from symmetry. So, it remains to prove the other direction: If < MBC = < FCA, then we have to show that triangle ABC is equilateral.

In the right-angled triangle AFC, we have < FCA = 90° - < FAC, so that < MBC = < FCA = 90° - < FAC = 90° - A.

If O is the circumcenter of triangle ABC, then BO = CO on the one hand, so that triangle BOC is isosceles, while on the other hand, the central angle theorem yields < BOC = 2 < BAC = 2A; thus, the base angle of the isosceles triangle BOC is $\measuredangle OBC=\frac{180^{\circ}-\measuredangle BOC}{2}=\frac{180^{\circ}-2A}{2}=90^{\circ}-A$. Thus, < OBC = MBC. Hence, the points B, O and M lie on one line l.

Now, if the points O and M would coincide, then it would follow that the circumcenter O of triangle ABC lies on its side CA, so that triangle ABC is right-angled at B; this would contradict the assumption that triangle ABC is acute-angled. So the points O and M cannot coincide. Now, the points O and M both lie on the perpendicular bisector of the segment CA (since O is the circumcenter of triangle ABC and M is the midpoint of the segment CA). Hence, the line l, passing through the points O and M, must be the perpendicular bisector of the segment CA. And thus, since the point B lies on this line l, we have BC = BA, so that a = c. So the triangle ABC is isosceles, and since M is the midpoint of its base CA, we have < BMC = 90°. On the other hand, < CFA = 90°. Thus, < BMC = < CFA. Also, we know that < MBC = < FCA and BM = CF. Hence, the triangles BMC and CFA are congruent, and thus BC = CA. In other words, a = b. Together with a = c, this yields a = b = c, and thus the triangle ABC is equilateral. Proof complete.

EDIT: See also http://www.mathlinks.ro/Forum/viewtopic.php?t=1118 for the second direction.

darij
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