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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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Factor sums of integers
Aopamy   2
N 6 minutes ago by cadaeibf
Let $n$ be a positive integer. A positive integer $k$ is called a benefactor of $n$ if the positive divisors of $k$ can be partitioned into two sets $A$ and $B$ such that $n$ is equal to the sum of elements in $A$ minus the sum of the elements in $B$. Note that $A$ or $B$ could be empty, and that the sum of the elements of the empty set is $0$.

For example, $15$ is a benefactor of $18$ because $1+5+15-3=18$.

Show that every positive integer $n$ has at least $2023$ benefactors.
2 replies
1 viewing
Aopamy
Feb 23, 2023
cadaeibf
6 minutes ago
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Least integer T_m such that m divides gauss sum
Al3jandro0000   33
N 10 minutes ago by NerdyNashville
Source: 2020 Iberoamerican P2
Let $T_n$ denotes the least natural such that
$$n\mid 1+2+3+\cdots +T_n=\sum_{i=1}^{T_n} i$$Find all naturals $m$ such that $m\ge T_m$.

Proposed by Nicolás De la Hoz
33 replies
Al3jandro0000
Nov 17, 2020
NerdyNashville
10 minutes ago
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Estonian Math Competitions 2005/2006
STARS   2
N 12 minutes ago by jasperE3
Source: Juniors Problem 4
A $ 9 \times 9$ square is divided into unit squares. Is it possible to fill each unit square with a number $ 1, 2,..., 9$ in such a way that, whenever one places the tile so that it fully covers nine unit squares, the tile will cover nine different numbers?
2 replies
STARS
Jul 30, 2008
jasperE3
12 minutes ago
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Sum of whose elements is divisible by p
nntrkien   43
N 24 minutes ago by lpieleanu
Source: IMO 1995, Problem 6, Day 2, IMO Shortlist 1995, N6
Let $ p$ be an odd prime number. How many $ p$-element subsets $ A$ of $ \{1,2,\dots,2p\}$ are there, the sum of whose elements is divisible by $ p$?
43 replies
nntrkien
Aug 8, 2004
lpieleanu
24 minutes ago
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No more topics!
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Geometry with incenter
Vlados021   12
N Apr 1, 2025 by Bonime
Source: 2017 Belarus Team Selection Test 3.1
Let $I$ be the incenter of a non-isosceles triangle $ABC$. The line $AI$ intersects the circumcircle of the triangle $ABC$ at $A$ and $D$. Let $M$ be the middle point of the arc $BAC$. The line through the point $I$ perpendicular to $AD$ intersects $BC$ at $F$. The line $MI$ intersects the circle $BIC$ at $N$.
Prove that the line $FN$ is tangent to the circle $BIC$.
12 replies
Vlados021
Mar 31, 2019
Bonime
Apr 1, 2025
J
Geometry with incenter
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Reveal topic tags
geometry
incenter
circumcircle
geometry solved
mixtilinear incircle
tangent
poles and polars
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Source: 2017 Belarus Team Selection Test 3.1
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Vlados021
184 posts
Vlados021
#1 Mar 31, 2019, 5:57 PM • 4 Y
Y by GeometryWorld, HWenslawski, Adventure10, lian_the_noob12
Let $I$ be the incenter of a non-isosceles triangle $ABC$. The line $AI$ intersects the circumcircle of the triangle $ABC$ at $A$ and $D$. Let $M$ be the middle point of the arc $BAC$. The line through the point $I$ perpendicular to $AD$ intersects $BC$ at $F$. The line $MI$ intersects the circle $BIC$ at $N$.
Prove that the line $FN$ is tangent to the circle $BIC$.
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AlastorMoody
2125 posts
AlastorMoody
#2 Mar 31, 2019, 6:15 PM • 3 Y
Y by hansu, SenatorPauline, Adventure10
Solution
This post has been edited 7 times. Last edited by AlastorMoody, Aug 24, 2020, 2:11 PM
Reason: nothing is NICEEE in this WARUDOOO, everything SUCKKKKKKKSSSSS
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Synthetic_Potato
114 posts
Synthetic_Potato
#3 Mar 31, 2019, 6:21 PM • 3 Y
Y by AlastorMoody, Pluto1708, Adventure10
Notice that since $\angle DBM= \angle DCM = 90^\circ$ $MB,MC$ are tangent to $\odot (BIC)$. Also it is easy to show that $FI$ is tangent to $\odot (BIC)$. Let $FN'$ be the other tangent from $F$ to $\odot (BIC)$. From la hire's theorem see that since $F$ lies on polar of $M$ WRT $\odot (BIC)$, $M\in IN'$. So $N=N'$. $\blacksquare$.
This post has been edited 1 time. Last edited by Synthetic_Potato, Mar 31, 2019, 6:22 PM
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khanhnx
1618 posts
khanhnx
#4 Apr 1, 2019, 11:06 AM • 2 Y
Y by Adventure10, Mango247
Since: $MB$, $MC$ tangent ($BIC$) at $B$, $C$, we have: $BICN$ is harmonic quadrilateral
So: tangents at $I$, $N$ of ($BIC$) and $BC$ concurrent or $FN$ tangents ($BIC$) at $N$
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EulersTurban
386 posts
EulersTurban
#5 Mar 20, 2020, 3:06 PM
Y by
https://i.imgur.com/s8jk4pc.png

Please note that point $A'$ isn't needed at all.

So let's first of define an inversion ,$\psi(\Gamma_{\triangle BIC})$.
Now we have the following $B \xrightarrow{\psi} B$, $C \xrightarrow{\psi} C$, $I \xrightarrow{\psi} I $
$\Gamma_{\triangle ABC} \xrightarrow{\psi} \overline{BC}$ and $M \xrightarrow{\psi} M'$, $F \xrightarrow{\psi} F'$
The center of $\Gamma_{\triangle BIC} $ is obviously $D$
So let's start with the angle-chase:
We have the following $\angle DF'M = \angle DM'F = 90$ and $\angle DF'I = \angle DIF = 90$,
thus the points $M,I,F',N$ are all collinear,thus
$ 90 = \angle DF'N = \angle DNF $
Thus the line $FN$ is tangent to $\Gamma_{\triangle BIC} $..... :D
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ironball
110 posts
ironball
#6 Mar 21, 2020, 6:22 AM
Y by
Notice that $M$ is the polar point of $BC$ and $FI$ is tangent to $\odot BIC$
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lahmacun
259 posts
lahmacun
#7 Mar 26, 2020, 4:42 PM
Y by
Since $M, I, N$ are collinear and $MB$ and $MC$ are tangent to $(BIC), BICN$ is harmonic which implies that $FN$ is tangent to $(BIC$)
This post has been edited 1 time. Last edited by lahmacun, Apr 3, 2020, 1:01 PM
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MathLuis
1500 posts
MathLuis
#8 Sep 6, 2021, 12:40 AM
Y by
By incenter-excenter lemma $D$ is center of $(BIC)$ thus $FI$ its tangent to $(BIC)$ and we take polars w.r.t.$(BIC)$
Clearly $\mathcal P_M=BC$ and $\mathcal P_I=FI$ thus by la'hire since $M,I,N$ are colinear we have that $BC, FI, \mathcal P_N$ are concurrent thus $\mathcal P_N=NF$ as desired...
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luosw
47 posts
luosw
#9 Sep 6, 2021, 1:22 AM
Y by
Oh, how to use tikz in AoPS?
This post has been edited 1 time. Last edited by luosw, Sep 6, 2021, 1:32 AM
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ike.chen
1162 posts
ike.chen
#10 Sep 6, 2021, 1:23 AM • 1 Y
Y by jhu08
Let the $A$-mixtilinear incircle touch $(ABC)$ at $T$. It's well-known that $T \in MI$ and $TI = TN$.

By the Incenter-Excenter Lemma, $D$ is the center of $(BIC)$. Because $\angle FID = 90^{\circ}$, it follows that $FI$ is tangent to $(BIC)$.

Since $\angle DTI = \angle DTM = 90^{\circ}$, we know $T$ lies on the circle with diameter $DI$. Hence, the Radical Axis Theorem on $(DTI), (BIC), (ABC)$ implies $II \equiv IF, DT, BC$ are concurrent at $IF \cap BC = F$.

Thus, $F$ lies on $DT$, which is obviously the perpendicular bisector of $IN$. But this implies $FI = FN$, which clearly suffices. $\blacksquare$


Remark: The article linked below contains all of the well-known facts I cited in this solution.
https://www.awesomemath.org/wp-pdf-files/math-reflections/mr-2020-02/mr_2_2020_mixtilinear.pdf

GeoGebra: https://www.geogebra.org/geometry/nwmgedzz.
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luosw
47 posts
luosw
#11 Sep 6, 2021, 1:48 AM • 1 Y
Y by jhu08
https://i.loli.net/2021/09/06/bporku3sjqNn87w.png

We can easily find that $MB,MC$ is tangent to the circle $\varGamma$. So quadrilateral $BICN$ is a harmonic quadrilateral. So $B,C;S,F$ are harmonic points. So $MN$ is the polar of $F$. $\boxed{}$
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primesarespecial
364 posts
primesarespecial
#12 Sep 6, 2021, 11:18 AM • 1 Y
Y by jhu08
We have that $MB,MC$ are tangent to$(BIC)$.
Now, $F$ lies on the polar of $M$,so by La Hire's theorem,$M$ lies on the polar of $F$.
Now,by construction $FI$ is tangent to $(BIC)$.
So $IM$ is the polar of $F$ and hence $N$ is the other tangency point from $F$.
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Bonime
36 posts
Bonime
#13 Apr 1, 2025, 1:14 PM
Y by
By IE-lemma, $FI$ is tangent to $(BIC)$. If $N*$ is the other tangency point of $F$ in $(BIC)$, since $F \in m$ we get that $M \in f$ (wrt to $(BIC)$) so $M - I - N*$ and we´re done. $\blacksquare$
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