Prove that
Y by Adventure10, Mango247
A ball moves endlessly on a circular billiard table. When it hits the edge it is reflected. Show that if it passes through a point on the table three times, then it passes through it infinitely many times.
G
Topic
First Poster
Last Poster
k a May Highlights and 2025 AoPS Online Class Information
jlacosta 0
May is an exciting month! National MATHCOUNTS is the second week of May in Washington D.C. and our Founder, Richard Rusczyk will be presenting a seminar, Preparing Strong Math Students for College and Careers, on May 11th.
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0 replies
Sum of whose elements is divisible by p
nntrkien 46
N
by Jackson0423
Source: IMO 1995, Problem 6, Day 2, IMO Shortlist 1995, N6
Let 
be an odd prime number. How many -element subsets 
of 
are there, the sum of whose elements is divisible by ?
be an odd prime number. How many -element subsets 
of 
are there, the sum of whose elements is divisible by ?
46 replies
Graph Theory
achen29 4
N
by ABCD1728
Are there any good handouts or even books in Graph Theory for a beginner in it? Preferable handouts which are extensive!
4 replies
Guess period of function
a1267ab 10
N
by cosmicgenius
Source: USA TST 2025
Let 
be a positive integer. Ana and Banana play a game. Banana thinks of a function 
and a prime number 
. He tells Ana that 
is nonconstant, 
, and 
for all integers 
. Ana's goal is to determine the value of . She writes down integers 
. After seeing this list, Banana writes down 
in order. Ana wins if she can determine the value of from this information. Find the smallest value of for which Ana has a winning strategy.
Anthony Wang
be a positive integer. Ana and Banana play a game. Banana thinks of a function 
and a prime number 
. He tells Ana that 
is nonconstant, 
, and 
for all integers 
. Ana's goal is to determine the value of . She writes down integers 
. After seeing this list, Banana writes down 
in order. Ana wins if she can determine the value of from this information. Find the smallest value of for which Ana has a winning strategy.Anthony Wang
10 replies
number theory problem
danilorj 1
N
by solidgreen
Let 
be an integer, show that there are infinite perfect squares of the form 
be an integer, show that there are infinite perfect squares of the form 
1 reply
2023 Putnam B2
giginori 13
N
by pie854
For each positive integer , let 
be the number of ones in the binary representation of 
. What is the minimum value of ?
, let 
be the number of ones in the binary representation of 
. What is the minimum value of ?
13 replies
D1040 : A general and strange result
Dattier 0
Source: les dattes à Dattier
Let ![$f \in C([0,1];[0,1])$](//latex.artofproblemsolving.com/4/7/5/475518b7db0b787dd90b93f602c7b912c663fba3.png)
bijective, 
and ![$(a_k) \in [0,1]^\mathbb N$](//latex.artofproblemsolving.com/a/d/8/ad8a80d847c60ee8e916a1f9b08b7b03ec17c814.png)
with 
converge.
Is it true that
converge?
![$f \in C([0,1];[0,1])$](http://latex.artofproblemsolving.com/4/7/5/475518b7db0b787dd90b93f602c7b912c663fba3.png)
bijective, 
and ![$(a_k) \in [0,1]^\mathbb N$](http://latex.artofproblemsolving.com/a/d/8/ad8a80d847c60ee8e916a1f9b08b7b03ec17c814.png)
with 
converge.Is it true that
converge?
0 replies
Trigo or Complex no.?
hzbrl 6
N
by GreenKeeper
(a) Let 
, where 
. Verify by direct substitution that 
satisfies the quadratic equation 
and deduce that the value of is 
.
(b) Let
. Show that 
(c) If
, show that the value of 
is 
.
I could solve (a) and (b). Can anyone help me with the 3rd part please?
, where 
. Verify by direct substitution that 
satisfies the quadratic equation 
and deduce that the value of is 
.(b) Let
. Show that 
(c) If
, show that the value of 
is 
.I could solve (a) and (b). Can anyone help me with the 3rd part please?
6 replies
Handouts/Resources on Limits.
Saucepan_man02 0
Could anyone kindly share some resources/handouts on limits?
0 replies
IMC 1994 D2 P1
j___d 13
N
by krigger
Let ![$f\in C^1[a,b]$](//latex.artofproblemsolving.com/8/4/8/848da12534d564560fe1cb016142159234be98b4.png)
, 
and suppose that 
, 
, is such that
for all ![$x\in [a,b]$](//latex.artofproblemsolving.com/7/8/d/78d9dcd969a2c45f7cc9234aa1377b6ec1c2d5d3.png)
. Is it true that 
for all ?
![$f\in C^1[a,b]$](http://latex.artofproblemsolving.com/8/4/8/848da12534d564560fe1cb016142159234be98b4.png)
, 
and suppose that 
, 
, is such that
for all ![$x\in [a,b]$](http://latex.artofproblemsolving.com/7/8/d/78d9dcd969a2c45f7cc9234aa1377b6ec1c2d5d3.png)
. Is it true that 
for all ?
13 replies
Aproximate ln(2) using perfect numbers
YLG_123 5
N
by ei_killua_
Source: Brazilian Mathematical Olympiad 2024, Level U, Problem 1
A positive integer 
is called perfect if the sum of its positive divisors 
is twice , that is, 
. For example, 
is a perfect number since the sum of its positive divisors is 
, which is twice . Prove that if is a positive perfect integer, then:
![\[
\sum_{p|n} \frac{1}{p + 1} < \ln 2 < \sum_{p|n} \frac{1}{p - 1}
\]](//latex.artofproblemsolving.com/0/c/0/0c08f527e87f7aae4ca5226f19bd084249551fe3.png)
where the sums are taken over all prime divisors 
of .
is called perfect if the sum of its positive divisors 
is twice , that is, 
. For example, 
is a perfect number since the sum of its positive divisors is 
, which is twice . Prove that if is a positive perfect integer, then:![\[
\sum_{p|n} \frac{1}{p + 1} < \ln 2 < \sum_{p|n} \frac{1}{p - 1}
\]](http://latex.artofproblemsolving.com/0/c/0/0c08f527e87f7aae4ca5226f19bd084249551fe3.png)
where the sums are taken over all prime divisors 
of .5 replies
Quadruple Binomial Coefficient Sum
P162008 4
N
by vmene
Source: Self made by my Elder brother
4 replies
IMC 1994 D1 P5
j___d 5
N
by krigger
a) Let ![$f\in C[0,b]$](//latex.artofproblemsolving.com/8/9/8/898aec0300888e562794b7a551be34f5c2676236.png)
, 
and let 
be periodic with period 
. Prove that 
has a limit as 
and
b) Find
![$f\in C[0,b]$](http://latex.artofproblemsolving.com/8/9/8/898aec0300888e562794b7a551be34f5c2676236.png)
, 
and let 
be periodic with period 
. Prove that 
has a limit as 
and
b) Find
5 replies
Putnam 2019 A1
awesomemathlete 33
N
by cursed_tangent1434
Source: 2019 William Lowell Putnam Competition
Determine all possible values of 
where 
, 
, and 
are nonnegative integers.
where 
, 
, and 
are nonnegative integers.
33 replies
reflections on a circular billiard table, 3 times through same point
parmenides51 4
N
by wasikgcrushedbi
Source: Brazilian Mathematical Olympiad 1986 P1
A ball moves endlessly on a circular billiard table. When it hits the edge it is reflected. Show that if it passes through a point on the table three times, then it passes through it infinitely many times.
4 replies
reflections on a circular billiard table, 3 times through same point
G
H
G
H
Source: Brazilian Mathematical Olympiad 1986 P1
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Y by khan.academy, ThE-dArK-IOrD, kiyoras_2001, Adventure10, Mango247
Nice P1.
Suppose the ball passes through point
three times. Not hard to show that all the chords of the circle that is part of the trajectory of the ball have equal fixed length, called 
. Then, one can easily prove that, there exists at most two chords that pass through and have length . This means there's a chord that the ball passes twice, so the angle subject to the chord is rational multiple of 
, and so the trajectory will pass this chord infinitely many times, done.
Suppose the ball passes through point
three times. Not hard to show that all the chords of the circle that is part of the trajectory of the ball have equal fixed length, called 
. Then, one can easily prove that, there exists at most two chords that pass through and have length . This means there's a chord that the ball passes twice, so the angle subject to the chord is rational multiple of 
, and so the trajectory will pass this chord infinitely many times, done.
Z
K
Y
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Y by
Let O be the centre of the given circle and P be the point through which it passes thrice along chords 
, 
and 
Let D, E and F be their midpoints respectively, i.e, the foot of perpendiculars from O.
Clearly, due to the nature of reflection, O must be equidistant from all the chords along which the ball passes.
(As O must lie on the normals at the points of reflection implying that it must lie on the angle bisector of consecutive chords and hence must be equidistant to all of these chords along which the ball moves.)
Hence, DO = EO = FO but
PDO = PEO = PFO = 
which implies that D,E and F are all points lying on a circle with diameter PO (let this circle be 
).
But there can be at most 2 such points.
(Since any such point a distance R from O must lie on another circle with centre O and radius R and must also lie on which can only intersect each other at at most 2 points (O lies on means that the 2 circles cannot coincide as O is the centre of one.))
Therefore, some 2 of these 3 points must be the same, WLOG let D
E, this must imply that . Hence, the ball must move along the same chord at least twice meaning it will then reiterate its path continuing in this manner passing along the same chord and hence through P (lying on this chord), infinitely many times and we are done.
, 
and 
Let D, E and F be their midpoints respectively, i.e, the foot of perpendiculars from O.
Clearly, due to the nature of reflection, O must be equidistant from all the chords along which the ball passes.
(As O must lie on the normals at the points of reflection implying that it must lie on the angle bisector of consecutive chords and hence must be equidistant to all of these chords along which the ball moves.)
Hence, DO = EO = FO but
PDO = PEO = PFO = 
which implies that D,E and F are all points lying on a circle with diameter PO (let this circle be 
).But there can be at most 2 such points.
(Since any such point a distance R from O must lie on another circle with centre O and radius R and must also lie on
which can only intersect each other at at most 2 points (O lies on means that the 2 circles cannot coincide as O is the centre of one.))Therefore, some 2 of these 3 points must be the same, WLOG let D
E, this must imply that . Hence, the ball must move along the same chord at least twice meaning it will then reiterate its path continuing in this manner passing along the same chord and hence through P (lying on this chord), infinitely many times and we are done.This post has been edited 8 times. Last edited by Gypsy_S, Jan 10, 2021, 4:00 PM
Z
K
Y
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and 
be two successive chords in the ball’s path. Let 
be the centre of the circular table.
.
and 
are isosceles.
.
.
be a chord containing 
and 
.
,
.
or 
.
and 
.
is a rational multiple of 
and hence the path will traverse
The post below has been deleted. Click to close.
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Y by Mango247
ThE-dArK-lOrD wrote:
so the angle subject to the chord is rational multiple of , and so the trajectory will pass this chord infinitely many times, done.
, and so the trajectory will pass this chord infinitely many times, done.can someone please explain whats meant by this line
Z
K
Y
N Quick Reply
G
H
