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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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A property of divisors
rightways   11
N 8 minutes ago by clarkculus
Source: Kazakhstan NMO 2016, P1
Prove that one can arrange all positive divisors of any given positive integer around a circle so that for any two neighboring numbers one is divisible by another.
11 replies
1 viewing
rightways
Mar 17, 2016
clarkculus
8 minutes ago
J
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Inspired by giangtruong13
sqing   0
26 minutes ago
Source: Own
Let $ a,b,c,d\geq 0 ,a-b+d=21 $ and $ a+3b+4c=101 $. Prove that
$$ 61\leq a+b+2c+d\leq \frac{265}{3}$$$$- \frac{2121}{2}\leq ab+bc-2cd+da\leq \frac{14045}{12}$$$$\frac{519506-7471\sqrt{7471}}{27}\leq ab+bc-2cd+3da\leq 33620$$
0 replies
sqing
26 minutes ago
0 replies
J
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ineq.trig.
wer   14
N 33 minutes ago by mpcnotnpc
If a, b, c are the sides of a triangle, show that: $\frac{a}{b+c}+\frac{b}{c+a}+\frac{c}{a+b}+\frac{r}{R}\le2$
14 replies
wer
Jul 5, 2014
mpcnotnpc
33 minutes ago
J
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Synthetic Geometry Olympiad
kooooo   1
N 36 minutes ago by kaede_Arcadia
Source: yyaa(me) and kaede_Arcadia
We are posting the problems of the Synthetic Geometry Olympiad, which was recently concluded and hosted by kaede_Arcadia and myself.

Problem 1
Let \( \triangle ABC \) be a triangle with its 9-point center \( N \) and excentral triangle \( \triangle I_A I_B I_C \). Denote the tangency points of the \( A \)-excircle with sides \( BC \), \( CA \), and \( AB \) as \( D_A, D_B, D_C \), respectively. Similarly, define \( E_A, E_B, E_C \) and \( F_A, F_B, F_C \) for the \( B \)- and \( C \)-excircles.
Let \( E_CE_A \cap F_AF_B = X \), \( F_AF_B \cap D_BD_C = Y \), and \( D_BD_C \cap E_CE_A = Z \). Let \( T \) be the radical center of the circles \( \odot(D_AYZ) \), \( \odot(E_BZX) \), and \( \odot(F_CXY) \).
Prove that the lines \( I_AX \), \( I_BY \), \( I_CZ, NT \) are concurrent.

Problem 2
Let \( \triangle ABC \) be a triangle with circumcenter \( O \), incenter \( I \) and incentral triangle \( \triangle DEF \). Let the line \( AI \) intersect \( \odot(AEF) \) again at \( X \). Similarly, define \( Y \) and \( Z \).
Let \( N_1 \) and \( N_2 \) be the 9-point centers of \( \triangle DEF \) and \( \triangle XYZ \), respectively.
Prove that the points \( O, I \), \( N_1, N_2 \) are collinear.

Problem 3
Let \( \triangle ABC \) be a triangle, and let \( (P, Q) \) be an isogonal conjugate pair. Suppose the line through \( P \) and perpendicular to \( AP \) intersects \( \odot(PBC) \) again at \( P_A \). Similarly, define \( P_B, P_C \). Suppose the line through \( Q \) and perpendicular to \( AQ \) intersects \( \odot(QBC) \) again at \( Q_A \). Similarly, define \( Q_B, Q_C \).
Let \( H_P \) and \( H_Q \) be the orthocenters of \( \triangle P_AP_BP_C \) and \( \triangle Q_AQ_BQ_C \), respectively. Define \( T = BP_B \cap CP_C \) and \( U = BQ_B \cap CQ_C \). Let \( T' \) and \( U' \) be the isogonal conjugates of \( T \) and \( U \) with respect to \( \triangle P_AP_BP_C \) and \( \triangle Q_AQ_BQ_C \), respectively.
Prove that the lines \( P_AQ_A, P_BQ_B, P_CQ_C, H_PH_Q, TU, T'U' \) are concurrent.
1 reply
kooooo
Feb 11, 2025
kaede_Arcadia
36 minutes ago
J
No more topics!
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Sum of face angles of a tetrahedron - ISL 1986
Amir Hossein   2
N Jun 14, 2013 by duanby
Prove that the sum of the face angles at each vertex of a tetrahedron is a straight angle if and only if the faces are congruent triangles.
2 replies
Amir Hossein
Aug 31, 2010
duanby
Jun 14, 2013
J
Sum of face angles of a tetrahedron - ISL 1986
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Reveal topic tags
geometry
3D geometry
tetrahedron
trigonometry
congruent triangles
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Amir Hossein
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Amir Hossein
#1 Aug 31, 2010, 10:33 AM • 1 Y
Y by Adventure10
Prove that the sum of the face angles at each vertex of a tetrahedron is a straight angle if and only if the faces are congruent triangles.
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JGU
8 posts
JGU
#2 Jun 13, 2013, 3:14 PM • 2 Y
Y by Adventure10, Mango247
If the faces of tetrahedron $ABCD$ are congruent triangles,
then $AB = CD$, $AC = BD$, $AD = BC$

$ \triangle BCD \cong \triangle ADC \cong \triangle DAB \cong \triangle CBA $

sum of the face angles at $A$ : $ \angle BAC + \angle CAD + \angle DAB = \angle CDB + \angle DBC + \angle BCD = \pi $
similarly $ \angle ABC + \angle CBD + \angle DBA = \pi $, $ \angle ACB + \angle BCD + \angle DCA = \pi $, $ \angle ADB + \angle BDC + \angle CDA = \pi $

Conversely, if the sum of the face angles at each vertex of tetrahedron $ABCD$ is $\pi$
$ \angle BAC + \angle CAD + \angle DAB = \pi $,
$ \angle ABC + \angle CBD + \angle DBA = \pi $,
$ \angle ACB + \angle BCD + \angle DCA = \pi $,
$ \angle ADB + \angle BDC + \angle CDA = \pi $

1. by trihedral angle theorem, $ \angle CAD + \angle DAB > \angle BAC $, then we have $ \angle BAC < \pi/2 $
this holds for all 12 angles above, that is, they are acute angles. Note if $\theta$ and $\psi$ are acute angles, then $\theta \ge \psi$ if and only if sin $\theta \ge $ sin $\psi$

2. denote the circumradius of $ \triangle BCD $ as $R_A$, the circumradius of $ \triangle ADC $ as $R_B$, the circumradius of $ \triangle DAB $ as $R_C$, the circumradius of $ \triangle CBA $ as $R_D$

without loss of generality, assume $R_A$ is the largest

by law of sines $2R_A$ sin $ \angle BDC = BC = 2R_D $ sin $ \angle BAC $, and since $ R_A \ge R_D $, then

$ \angle BAC \ge \angle BDC $ and similarly we can deduce
$ \angle CAD \ge \angle CBD $
$ \angle DAB \ge \angle DCB $
adding above we get $ \pi \ge \pi $ so all inequality are equality, $R_A = R_B = R_C = R_D$ and

$ \angle BAC = \angle BDC $,
$ \angle CAD = \angle CBD $,
$ \angle DAB = \angle DCB $,

by law of sines again $2R_B$ sin $ \angle DCA = DA = 2R_C $ sin $ \angle DBA $, and since $ R_B = R_C $, then

$ \angle DCA = \angle DBA $, and similarly
$ \angle ACB = \angle ADB $,
$ \angle ABC = \angle ADC $

3. now we know the 12 angles are in 6 pairs, then since all 12 angles add to $4\pi$, picking one angle in each pair:

$ \angle BAC + \angle CAD + \angle DAB + \angle DBA + \angle ADB + \angle ABC = 2\pi $

substract $ \angle BAC + \angle CAD + \angle DAB = \pi $, we have $ \angle DBA + \angle ADB + \angle ABC = \pi $

compare to angles of $\triangle ABD$ results $ \angle ABC = \angle BAD $

then $ AC = 2R_D$ sin $ \angle ABC = 2R_C $ sin $ \angle BAD = BD $

similarly we can deduce $AB=CD$, $AD=BC$

so $ \triangle BCD \cong \triangle ADC \cong \triangle DAB \cong \triangle CBA $ (SSS)
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duanby
76 posts
duanby
#3 Jun 14, 2013, 4:49 AM • 2 Y
Y by Adventure10, Mango247
The if part is obvious
the only if part:
make the faces on a plane,that is on plane
ABC let D1,D2,D3 be the point that BCD1 congruent to BCA
D2,D3 the same way
Then D2D3A are collinear so ABC is the midpoint triangle of
D1D2D3 then we get the result
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