New Competition Series: The Million!

by Mathdreams, Apr 2, 2025, 3:57 AM

Hello AOPS Community,

Recently, me and my friend compiled a set of the most high quality problems from our imagination into a problem set called the Million. This series has three contests, called the whun, thousand and Million respectively.

Unfortunately, it did not get the love it deserved on the OTIS discord. Hence, we post it here to share these problems with the AOPS community and hopefully allow all of you to enjoy these very interesting problems.

Good luck! Lastly, remember that MILLION ORZ!

Edit: We have just been informed this will be the Orange MOP series. Please pay close attention to these problems!

Attachments:

whun.pdf (54kb)

Thousand.pdf (77kb)

MILLION.pdf (164kb)

This post has been edited 2 times. Last edited by Mathdreams, Yesterday at 3:59 AM

fun problems

2025 USAMO Rubric

by plang2008, Apr 2, 2025, 1:33 AM

1. Let $k$ and $d$ be positive integers. Prove that there exists a positive integer $N$ such that for every odd integer $n>N$ , the digits in the base- $2n$ representation of $n^k$ are all greater than $d$ .

Rubric for Problem 1

2. Let $n$ and $k$ be positive integers with $k<n$ . Let $P(x)$ be a polynomial of degree $n$ with real coefficients, nonzero constant term, and no repeated roots. Suppose that for any real numbers $a_0,\,a_1,\,\ldots,\,a_k$ such that the polynomial $a_kx^k+\cdots+a_1x+a_0$ divides $P(x)$ , the product $a_0a_1\cdots a_k$ is zero. Prove that $P(x)$ has a nonreal root.

Rubric for Problem 2

3. Alice the architect and Bob the builder play a game. First, Alice chooses two points $P$ and $Q$ in the plane and a subset $\mathcal{S}$ of the plane, which are announced to Bob. Next, Bob marks infinitely many points in the plane, designating each a city. He may not place two cities within distance at most one unit of each other, and no three cities he places may be collinear. Finally, roads are constructed between the cities as follows: for each pair $A,\,B$ of cities, they are connected with a road along the line segment $AB$ if and only if the following condition holds:

For every city $C$ distinct from $A$ and $B$ , there exists $R\in\mathcal{S}$ such

that $\triangle PQR$ is directly similar to either $\triangle ABC$ or $\triangle BAC$ .

Alice wins the game if (i) the resulting roads allow for travel between any pair of cities via a finite sequence of roads and (ii) no two roads cross. Otherwise, Bob wins. Determine, with proof, which player has a winning strategy.

Note: $\triangle UVW$ is directly similar to $\triangle XYZ$ if there exists a sequence of rotations, translations, and dilations sending $U$ to $X$ , $V$ to $Y$ , and $W$ to $Z$ .

Rubric for Problem 3

4. Let $H$ be the orthocenter of acute triangle $ABC$ , let $F$ be the foot of the altitude from $C$ to $AB$ , and let $P$ be the reflection of $H$ across $BC$ . Suppose that the circumcircle of triangle $AFP$ intersects line $BC$ at two distinct points $X$ and $Y$ . Prove that $C$ is the midpoint of $XY$ .

Rubric for Problem 4

5. Determine, with proof, all positive integers $k$ such that $\frac{1}{n+1} \sum_{i=0}^n \binom{n}{i}^k$ is an integer for every positive integer $n$ .

Rubric for Problem 5

6. Let $m$ and $n$ be positive integers with $m\geq n$ . There are $m$ cupcakes of different flavors arranged around a circle and $n$ people who like cupcakes. Each person assigns a nonnegative real number score to each cupcake, depending on how much they like the cupcake. Suppose that for each person $P$ , it is possible to partition the circle of $m$ cupcakes into $n$ groups of consecutive cupcakes so that the sum of $P$ 's scores of the cupcakes in each group is at least $1$ . Prove that it is possible to distribute the $m$ cupcakes to the $n$ people so that each person $P$ receives cupcakes of total score at least $1$ with respect to $P$ .

Rubric for Problem 6

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AMC 10/AIME Study Forum

by PatTheKing806, Mar 27, 2025, 11:34 PM

Me (PatTheKing806) and EaZ_Shadow have created a AMC 10/AIME Study Forum! Hopefully, this forum wont die quickly. To signup, do /join or \join.

Click here to join! (or do some pushups)

People should join this forum if they are wanting to do well on the AMC 10 next year, trying get into AIME, or loves math!

This post has been edited 2 times. Last edited by PatTheKing806, Mar 27, 2025, 11:35 PM

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LMT Spring 2025 and Girls' LMT 2025

by vrondoS, Mar 27, 2025, 1:55 AM

The Lexington High School Math Team is proud to announce LMT Spring 2025 and our inaugural Girls’ LMT 2025! LMT is a competition for middle school students interested in math. Students can participate individually, or on teams of 4-6 members. This announcement contains information for BOTH competitions.

LMT Spring 2025 will take place from 8:30 AM-5:00 PM on Saturday, May 3rd at Lexington High School, 251 Waltham St., Lexington, MA 02421.

The competition will include two individual rounds, a Team Round, and a Guts Round, with a break for lunch and mini-events. A detailed schedule is available at https://lhsmath.org/LMT/Schedule.

There is a $15 fee per participant, paid on the day of the competition. Pizza will be provided for lunch, at no additional cost.

Register for LMT at https://lhsmath.org/LMT/Registration/Home.

Girls’ LMT 2025 will be held ONLINE on MathDash from 11:00 AM-4:15 PM EST on Saturday, April 19th, 2025. Participation is open to middle school students who identify as female or non-binary. The competition will include an individual round and a team round with a break for lunch and mini-events. It is free to participate.

Register for GLMT at https://www.lhsmath.org/LMT/Girls_LMT.

More information is available on our website: https://lhsmath.org/LMT/Home. Email lmt.lhsmath@gmail.com with any questions.

Attachments:

This post has been edited 1 time. Last edited by vrondoS, Mar 27, 2025, 5:18 AM

LMT

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Westford Academy to host Middle School Math Competition

by cyou, Mar 25, 2025, 9:43 PM

Hi AOPS community,

We are excited to announce that Westford Academy (located in Westford, MA) will be hosting its first ever math competition for middle school students (grades 5-8).

Based in Massachusetts, this tournament hosts ambitious and mathematically skilled students in grades 5–8 to compete against other middle school math teams while fostering their problem-solving skills and preparing them to continue enriching their STEM skills in high school and in the future.

This competition will be held on April 12, 2025 from 12:00 PM to 5:00 PM and will feature 3 rounds (team, speed, and accuracy). The problems will be of similar difficulty for AMC 8-10 and were written by USA(J)MO and AIME qualifiers.

If you are in the Massachusetts area and are curious about Mathematics, we cordially invite you to sign up by scanning the QR code on the attached flyer. Please note that teams consist of 4-6 competitors, but if you prefer to register as an individual competitor, you will be randomly placed on a team of other individual competitors. Feel free to refer the attached flyer and website as needed.

https://sites.google.com/westfordk12.us/wamt/home?authuser=2

Attachments:

middle school math contests

Competition

Double dose of cyanide on day 2

by brianzjk, Mar 23, 2023, 10:20 PM

Let $n\geq3$ be an integer. We say that an arrangement of the numbers $1$ , $2$ , $\dots$ , $n^2$ in a $n \times n$ table is row-valid if the numbers in each row can be permuted to form an arithmetic progression, and column-valid if the numbers in each column can be permuted to form an arithmetic progression. For what values of $n$ is it possible to transform any row-valid arrangement into a column-valid arrangement by permuting the numbers in each row?

This post has been edited 1 time. Last edited by brianzjk, Mar 23, 2023, 11:35 PM

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2016 Sets

by NormanWho, Apr 20, 2016, 9:30 PM

Find, with proof, the least integer $N$ such that if any $2016$ elements are removed from the set ${1, 2,...,N}$ , one can still find $2016$ distinct numbers among the remaining elements with sum $N$ .

This post has been edited 1 time. Last edited by NormanWho, Apr 20, 2016, 9:31 PM

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Vertices of a pentagon invariant: 2011 USAMO #2

by tenniskidperson3, Apr 28, 2011, 9:49 PM

An integer is assigned to each vertex of a regular pentagon so that the sum of the five integers is 2011. A turn of a solitaire game consists of subtracting an integer $m$ from each of the integers at two neighboring vertices and adding $2m$ to the opposite vertex, which is not adjacent to either of the first two vertices. (The amount $m$ and the vertices chosen can vary from turn to turn.) The game is won at a certain vertex if, after some number of turns, that vertex has the number 2011 and the other four vertices have the number 0. Prove that for any choice of the initial integers, there is exactly one vertex at which the game can be won.

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Permutations Part 1: 2010 USAJMO #1

by tenniskidperson3, Apr 29, 2010, 3:36 PM

A permutation of the set of positive integers $[n] = \{1, 2, . . . , n\}$ is a sequence $(a_1 , a_2 , \ldots, a_n )$ such that each element of $[n]$ appears precisely one time as a term of the sequence. For example, $(3, 5, 1, 2, 4)$ is a permutation of $[5]$ . Let $P (n)$ be the number of permutations of $[n]$ for which $ka_k$ is a perfect square for all $1 \leq k \leq n$ . Find with proof the smallest $n$ such that $P (n)$ is a multiple of $2010$ .

This post has been edited 2 times. Last edited by tenniskidperson3, Dec 22, 2015, 2:55 AM
Reason: Lolol latex was wrong for 5 years and nobody caught it

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Isosceles Triangulation

by worthawholebean, May 1, 2008, 4:57 PM

Let $\mathcal{P}$ be a convex polygon with $n$ sides, $n\ge3$ . Any set of $n - 3$ diagonals of $\mathcal{P}$ that do not intersect in the interior of the polygon determine a triangulation of $\mathcal{P}$ into $n - 2$ triangles. If $\mathcal{P}$ is regular and there is a triangulation of $\mathcal{P}$ consisting of only isosceles triangles, find all the possible values of $n$ .

This post has been edited 1 time. Last edited by worthawholebean, May 1, 2008, 8:54 PM

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Submit

thank you both wahoo
by Helena_Liang, Feb 16, 2025, 3:45 AM
nice css!!
by Moonlight11, Feb 16, 2025, 3:21 AM
whoa cool css!!
by contactbibliophile, Feb 16, 2025, 2:28 AM
you are peak
by Helena_Liang, Feb 15, 2025, 4:50 AM
peak css hehe
by mathical8, Feb 10, 2025, 8:27 AM
thank you sir but you should admit orz
by Helena_Liang, Jan 26, 2025, 2:22 AM
OMG I LOVE UR CSS!!!!!! very orz, very demure
by alice_inmathland, Jan 22, 2025, 7:49 PM
pls pls be active again :eyes:
by Hestu_the_Bestu, Nov 16, 2024, 12:45 AM
I have been inactive on aops
perhaps I'll be active again
by Helena_Liang, Oct 9, 2024, 3:10 AM
sirr when are u posting next lol
by mathical8, Sep 29, 2024, 8:12 PM
Do you have any tips for making AIME?
by TapiOrca, Sep 17, 2024, 10:38 PM
yea pls post smth again
by Hestu_the_Bestu, Sep 9, 2024, 9:15 PM
OMG helena ur blog is so popular :star_struck:
also u should post something
by alice_inmathland, Sep 7, 2024, 11:36 PM
contrib

1434 orz xooks
by ChromeRaptor777, Aug 30, 2024, 4:04 AM
@2 below ay yes sir I shall
@below indeed
by Helena_Liang, Aug 22, 2024, 1:34 AM
first as well $\text{[math]}$
by madeleinelee, Nov 21, 2023, 8:26 PM
sapphire's css skills are pro
by Helena_Liang, Nov 20, 2023, 5:14 PM
Unfortunately, first
by awesomeming327., Nov 20, 2023, 4:59 AM
Lol Helena and Emma I think your blogs are essentially the same as mine ha cant top that
by SapphireDolphin9, Nov 20, 2023, 4:28 AM
first $\text{[math]}$
by awesomeming327., Nov 20, 2023, 3:54 AM
this blog would not exist without helena
by flec, Nov 20, 2023, 3:35 AM
I agree with that statement
this blog would not be complete without flec
by Helena_Liang, Nov 20, 2023, 3:34 AM
i had very valuable edits
by flec, Nov 20, 2023, 1:38 AM
lol emma I think your blog css is essentially the same as ours (with edits)
by Helena_Liang, Nov 19, 2023, 11:46 PM
fifth!! also very nice css and blog idea :D $~$
by Beast_Academic_Emma, Nov 19, 2023, 10:28 PM
fourth!!
by mathical8, Nov 19, 2023, 6:49 PM
third ! $\text{[math]}$
by purplepenguin2, Nov 19, 2023, 1:41 AM
second : $\text{[math]}$ D
by Helena_Liang, Nov 18, 2023, 6:26 AM
obviously i take the first shout
by flec, Nov 18, 2023, 6:07 AM

70 shouts

two up, one down

by Mathdreams, Apr 2, 2025, 3:57 AM

by plang2008, Apr 2, 2025, 1:33 AM

by PatTheKing806, Mar 27, 2025, 11:34 PM

by vrondoS, Mar 27, 2025, 1:55 AM

by cyou, Mar 25, 2025, 9:43 PM

by brianzjk, Mar 23, 2023, 10:20 PM

by NormanWho, Apr 20, 2016, 9:30 PM

by tenniskidperson3, Apr 28, 2011, 9:49 PM

by tenniskidperson3, Apr 29, 2010, 3:36 PM

by worthawholebean, May 1, 2008, 4:57 PM