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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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source own
Bet667   5
N 31 minutes ago by GeoMorocco
Let $x,y\ge 0$ such that $2(x+y)=1+xy$ then find minimal value of $$x+\frac{1}{x}+\frac{1}{y}+y$$
5 replies
Bet667
2 hours ago
GeoMorocco
31 minutes ago
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Cross-ratio Practice!
shanelin-sigma   3
N 33 minutes ago by MENELAUSS
Source: 2024 imocsl G3 (Night 6-G)
Triangle $ABC$ has circumcircle $\Omega$ and incircle $\omega$, where $\omega$ is tangent to $BC, CA, AB$ at $D,E,F$, respectively. $T$ is an arbitrary point on $\omega$. $EF$ meets $BC$ at $K$, $AT$ meets $\Omega$ again at $P$, $PK$ meets $\Omega$ again at $S$. $X$ is a point on $\Omega$ such that $S, D, X$ are colinear. Let $Y$ be the intersection of $AX$ and $EF$, prove that $YT$ is tangent to $\omega$.

Proposed by chengbilly
3 replies
1 viewing
shanelin-sigma
Aug 8, 2024
MENELAUSS
33 minutes ago
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Segment ratio
xeroxia   3
N 33 minutes ago by Blackbeam999
Let $B$ and $C$ be points on a circle with center $A$.
Let $D$ be a point on segment $AB$.
Let $F$ be one of the intersections of the circle with center $D$ and passing through $B$ and the circle with diameter $DC$.
Prove that $\dfrac {AD}{AC} = \dfrac {CF^2}{CB^2}$.
3 replies
xeroxia
Sep 11, 2024
Blackbeam999
33 minutes ago
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Iran second round 2025-q1
mohsen   1
N an hour ago by sami1618
Find all positive integers n>2 such that sum of n and any of its prime divisors is a perfect square.
1 reply
+1 w
mohsen
Today at 10:21 AM
sami1618
an hour ago
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Calculus BC help
needcalculusasap45   0
5 hours ago
So basically, I have the AP Calculus BC exam in less than a month, and I have only covered until Unit 6 or 7 of the cirriculum. I am self studying this course (no teacher) and have not had much time to study bc of 6 other APs. I need to finish 8, 9, and 10 in less than 2 weeks. What can I do ? I would appreciate any help or resources anyone could provide. Could I just learn everything from barrons and princeton? Also, I have not taken AP Calculus AB before.

0 replies
needcalculusasap45
5 hours ago
0 replies
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Inequalities
sqing   9
N 5 hours ago by sqing
Let $ a,b,c> 0 $ and $ \frac{a}{a^2+ab+c}+\frac{b}{b^2+bc+a}+\frac{c}{c^2+ca+b} \geq 1$. Prove that
$$ a+b+c\leq 3 $$
9 replies
sqing
Apr 4, 2025
sqing
5 hours ago
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Geometry
German_bread   1
N Today at 12:01 PM by vanstraelen
A semicircle k with radius r is constructed over the line segment ST. Let D be a point on the line segment ST that is different from S and T. The two squares ABCD and DEF G lie in the half-plane of the semicircle such that points B and F lie on the semicircle k and points S, C, D, E, and T lie on a straight line in that order. (Points A and/or G can also lie outside the semicircle if necessary.)
Investigate whether the sum of the areas of the squares ABCD and DEFG depends on the position of point D on the line segment ST.

German math olympiad, class 9, 2022
1 reply
German_bread
Today at 10:00 AM
vanstraelen
Today at 12:01 PM
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Indonesia Regional MO 2019 Part A
parmenides51   22
N Today at 10:43 AM by SomeonecoolLovesMaths
Indonesia Regional MO
Year 2019 Part A

Time: 90 minutes Rules


p1. In the bag there are $7$ red balls and $8$ white balls. Audi took two balls at once from inside the bag. The chance of taking two balls of the same color is ...


p2. Given a regular hexagon with a side length of $1$ unit. The area of the hexagon is ...


p3. It is known that $r, s$ and $1$ are the roots of the cubic equation $x^3 - 2x + c = 0$. The value of $(r-s)^2$ is ...


p4. The number of pairs of natural numbers $(m, n)$ so that $GCD(n,m) = 2$ and $LCM(m,n) = 1000$ is ...


p5. A data with four real numbers $2n-4$, $2n-6$, $n^2-8$, $3n^2-6$ has an average of $0$ and a median of $9/2$. The largest number of such data is ...


p6. Suppose $a, b, c, d$ are integers greater than $2019$ which are four consecutive quarters of an arithmetic row with $a <b <c <d$. If $a$ and $d$ are squares of two consecutive natural numbers, then the smallest value of $c-b$ is ...


p7. Given a triangle $ABC$, with $AB = 6$, $AC = 8$ and $BC = 10$. The points $D$ and $E$ lies on the line segment $BC$. with $BD = 2$ and $CE = 4$. The measure of the angle $\angle DAE$ is ...


p8. Sequqnce of real numbers $a_1,a_2,a_3,...$ meet $\frac{na_1+(n-1)a_2+...+2a_{n-1}+a_n}{n^2}=1$ for each natural number $n$. The value of $a_1a_2a_3...a_{2019}$ is ....


p9. The number of ways to select four numbers from $\{1,2,3, ..., 15\}$ provided that the difference of any two numbers at least $3$ is ...


p10. Pairs of natural numbers $(m , n)$ which satisfies $$m^2n+mn^2 +m^2+2mn = 2018m + 2019n + 2019$$are as many as ...


p11. Given a triangle $ABC$ with $\angle ABC =135^o$ and $BC> AB$. Point $D$ lies on the side $BC$ so that $AB=CD$. Suppose $F$ is a point on the side extension $AB$ so that $DF$ is perpendicular to $AB$. The point $E$ lies on the ray $DF$ such that $DE> DF$ and $\angle ACE = 45^o$. The large angle $\angle AEC$ is ...


p12. The set of $S$ consists of $n$ integers with the following properties: For every three different members of $S$ there are two of them whose sum is a member of $S$. The largest value of $n$ is ....


p13. The minimum value of $\frac{a^2+2b^2+\sqrt2}{\sqrt{ab}}$ with $a, b$ positive reals is ....


p14. The polynomial P satisfies the equation $P (x^2) = x^{2019} (x+ 1) P (x)$ with $P (1/2)= -1$ is ....


p15. Look at a chessboard measuring $19 \times 19$ square units. Two plots are said to be neighbors if they both have one side in common. Initially, there are a total of $k$ coins on the chessboard where each coin is only loaded exactly on one square and each square can contain coins or blanks. At each turn. You must select exactly one plot that holds the minimum number of coins in the number of neighbors of the plot and then you must give exactly one coin to each neighbor of the selected plot. The game ends if you are no longer able to select squares with the intended conditions. The smallest number of $k$ so that the game never ends for any initial square selection is ....
22 replies
parmenides51
Nov 11, 2021
SomeonecoolLovesMaths
Today at 10:43 AM
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Maximizing the Sum of Minimum Differences in Permutations
chinawgp   0
Today at 10:20 AM
Problem Statement

Given a positive integer n \geq 3 , consider a permutation \pi = (a_1, a_2, \dots, a_n) of \{1, 2, \dots, n\} . For each i ( 1 \leq i \leq n-1 ), define d_i as the minimum absolute difference between a_i and any subsequent element a_j ( j > i ), i.e.,
d_i = \min \{ |a_i - a_j| \mid j > i \}.

Let S_n denote the maximum possible sum of d_i over all permutations of \{1, \dots, n\} , i.e.,
S_n = \max_{\pi} \sum_{i=1}^{n-1} d_i.

Proposed Construction

I found a method to construct a permutation that seems to maximize \sum d_i :
1. Fix a_{n-1} = 1 and a_n = n .
2. For each i (from n-2 down to 1 ):
- Sort a_{i+1}, a_{i+2}, \dots, a_n in increasing order.
- Compute the gaps between consecutive elements.
- Place a_i in the middle of the largest gap (if the gap has even length, choose the smaller midpoint).

Partial Results

1. I can prove that 1 and n must occupy the last two positions. Otherwise, moving either 1 or n further right does not decrease \sum d_i .
2. The construction greedily maximizes each d_i locally, but I’m unsure if this ensures global optimality.

Request for Help

- Does this construction always yield the maximum S_n ?
- If yes, how can we rigorously prove it? (Induction? Exchange arguments?)
- If no, what is the correct approach?

Observations:
- The construction works for small n (e.g., n=3,4,5,...,12 ).
- The problem resembles optimizing "minimum gaps" in permutations.

Any insights or references would be greatly appreciated!
0 replies
chinawgp
Today at 10:20 AM
0 replies
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no of integer soultions of ||x| - 2020| < 5 - IOQM 2020-21 p5
parmenides51   9
N Today at 9:11 AM by AshAuktober
Find the number of integer solutions to $||x| - 2020| < 5$.
9 replies
parmenides51
Jan 18, 2021
AshAuktober
Today at 9:11 AM
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Geometry
German_bread   2
N Today at 8:31 AM by German_bread
Let P be a point in a square ABCD. The lengths of segments PA, PB, PC are 17, 11 and 5 respectively. Determine the area of the square and if it can’t be determined exactly, all possible values are to be listed.

German math Olympiad, Class 9, 2024

It’s my first time posting - please excuse any mistakes
2 replies
German_bread
Yesterday at 7:59 PM
German_bread
Today at 8:31 AM
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A Loggy Problem from Pythagoras
Mathzeus1024   6
N Today at 8:01 AM by Mathzeus1024
Prove or disprove: $\exists x \in \mathbb{R}^{+}$ such that $\ln(x), \ln(2x), \ln(3x)$ are the lengths of a right triangle.
6 replies
Mathzeus1024
Yesterday at 10:55 AM
Mathzeus1024
Today at 8:01 AM
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Nesbitt inequality
Mathskidd   1
N Today at 7:20 AM by sqing


$$ $$Would anyone tell me whether the number of ways for proving Nesbitt inequality more than one hundred ?
1 reply
Mathskidd
Today at 5:08 AM
sqing
Today at 7:20 AM
J
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Algebra Problems
ilikemath247365   10
N Today at 4:25 AM by lgx57
Find all real $(a, b)$ with $a + b = 1$ such that

$(a + \frac{1}{a})^{2} + (b + \frac{1}{b})^{2} = \frac{25}{2}$.
10 replies
ilikemath247365
Apr 14, 2025
lgx57
Today at 4:25 AM
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Reflection Concurrence implies Cyclic
mira74   2
N Jun 14, 2021 by aryabhata000
Source: 2020-2021 Winter SDPC #3
Let $ABCD$ be a quadrilateral, let $P$ be the intersection of $AB$ and $CD$, and let $O$ be the intersection of the perpendicular bisectors of $AB$ and $CD$. Suppose that $O$ does not lie on line $AB$ and $O$ does not lie on line $CD$. Let $B'$ and $D'$ be the reflections of $B$ and $D$ across $OP$. Show that if $AB'$ and $CD'$ meet on $OP$, then $ABCD$ is cyclic.
2 replies
mira74
Jan 13, 2021
aryabhata000
Jun 14, 2021
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Reflection Concurrence implies Cyclic
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Reveal topic tags
geometry
geometric transformation
reflection
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Source: 2020-2021 Winter SDPC #3
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mira74
1010 posts
mira74
#1 Jan 13, 2021, 11:13 PM
Y by
Let $ABCD$ be a quadrilateral, let $P$ be the intersection of $AB$ and $CD$, and let $O$ be the intersection of the perpendicular bisectors of $AB$ and $CD$. Suppose that $O$ does not lie on line $AB$ and $O$ does not lie on line $CD$. Let $B'$ and $D'$ be the reflections of $B$ and $D$ across $OP$. Show that if $AB'$ and $CD'$ meet on $OP$, then $ABCD$ is cyclic.
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cadaeibf
700 posts
cadaeibf
#2 Jan 13, 2021, 11:50 PM • 2 Y
Y by Mango247, Mango247
Let $X=AB'\cap CD'\cap OP$. Since $O$ lies on the axis of $AB'$ and on the angle bisector of $\angle APB'$, $O$ is the midpoint of the arc $AB$ in $(APB')$, and $X$ the foot of the angle bisector. Therefore, by inversion in $P$ with radius $\sqrt{PA\cdot PB'}$and simmetry across $OP$, which swaps $X$ and $O$, $PX\cdot PO=PA\cdot PB'=PA\cdot PB$, so $PA\cdot PB=PX\cdot PO=PC\cdot PD$ and thus $ABCD$ is cyclic.
This post has been edited 1 time. Last edited by cadaeibf, Jan 13, 2021, 11:52 PM
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aryabhata000
245 posts
aryabhata000
#3 Jun 14, 2021, 5:59 PM
Y by
I am sorry for restarting this thread (I just realized SDPC threads exist). Here was a solution I got after the contest ended (my in-contest solution was three pages long and mostly trig bash).

Solution sketch:
We use the following lemma (which follows from an angle chase):
Let $AB$ be a line that intersects line $\ell$. Let $A’$ be the reflection of $A$ over $\ell$. $O, Q \in \ell$ so that $O=BO$, $Q = A’B \cap \ell$. Then $ABOQ$ is cyclic.


Let $Q = AB'\cap CD'\cap OP$. Note that by the lemma, $ABOQ$ and $CDOQ$ are cyclic, and $OQ$ is the radical axis of the circumcircles of these two quadrilaterals. So, $PA*PB= PO*PQ=PC*PD$, and $ABCD$ is cyclic.
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