Difference between revisions of "G285 2021 Summer Problem Set"
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<math>16</math> people are attending a hotel conference, <math>8</math> of which are executives, and <math>8</math> of which are speakers. Each person is designated a seat at one of <math>4</math> round tables, each containing <math>4</math> seats. If executives must sit at least one speaker and executive, there are <math>N</math> ways the people can be seated. Find <math>\left \lfloor \sqrt{N} \right \rfloor</math>. Assume seats, people, and table rotations are distinguishable. | <math>16</math> people are attending a hotel conference, <math>8</math> of which are executives, and <math>8</math> of which are speakers. Each person is designated a seat at one of <math>4</math> round tables, each containing <math>4</math> seats. If executives must sit at least one speaker and executive, there are <math>N</math> ways the people can be seated. Find <math>\left \lfloor \sqrt{N} \right \rfloor</math>. Assume seats, people, and table rotations are distinguishable. | ||
− | <math>\textbf{(A)}\ 720 \qquad\textbf{(B)}\ 1440 \qquad\textbf{(C)}\ 2520 \qquad\textbf{(D)}\ | + | <math>\textbf{(A)}\ 720 \qquad\textbf{(B)}\ 1440 \qquad\textbf{(C)}\ 2520 \qquad\textbf{(D)}\ 5760\qquad\textbf{(E)}\ 6172</math> |
[[G285 2021 Summer Problem Set Problem 4|Solution]] | [[G285 2021 Summer Problem Set Problem 4|Solution]] | ||
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==Problem 12== | ==Problem 12== | ||
− | Suppose the function <cmath>P(a,b,c)=a^2b^4+b^2c^4+c^2a^4+8c+8b+8a+8a^3+8b^3+8c^3-3\sqrt[3]{abc}-21</cmath>. If <math>P(a)+P(b)+P(c)=P(a,b,c)=P(k)</math>, and <math>P(k)</math> contains the points <math>( | + | Suppose the function <cmath>P(a,b,c)=a^2b^4+b^2c^4+c^2a^4+8c+8b+8a+8a^3+8b^3+8c^3-3\sqrt[3]{abc}-21</cmath>. If <math>P(a)+P(b)+P(c)=P(a,b,c)=P(k)</math>, and the polynomial <math>P(k)</math> contains the points <math>(P(k),P(k)+1)</math>,<math>(P(k)+3,P(k)+5)</math>, and <math>(P(k)+8,11)</math>, find the smallest value of <math>P(23)</math> for which <math>P(P(P(a,b,c))=abc(P(a)+P(b)+P(c))</math> |
[[G285 2021 Summer Problem Set Problem 12|Solution]] | [[G285 2021 Summer Problem Set Problem 12|Solution]] | ||
+ | |||
+ | ==Problem 13== | ||
+ | Let circles <math>O_1</math>,<math>O_2</math>, and <math>O_3</math> concur at <math>E</math>, where <math>EP</math> is the common chord shared by <math>\{O_1,O_3 \}</math>, <math>QE</math> is the common chord shared by <math>\{O_1,O_2 \}</math>, and <math>E</math> lies on the common internal tangent of <math>\{O_2,O_3 \}</math>. Let the extension of <math>PE</math> and <math>QE</math> intersect <math>O_2</math> and <math>O_3</math> again at <math>F</math> and <math>G</math> respectively. If <math>\overline{CF} \cap \overline{BG} \in D</math>, prove <math>ABDC</math> is a parallelogram. | ||
+ | |||
+ | [[G285 2021 Summer Problem Set Problem 13|Solution]] | ||
+ | |||
+ | ==Problem 14== | ||
+ | Bobby the frog is hopping around the unit circle. Suppose Bobby starts at <math>(1,0)</math>. After every <math>n</math>th minute, Bobby moves to <math>(a,bi)</math> such that <math>a^2+b^2 \le 1</math>, and <math>(a,bi)</math> is an <math>n</math>th root of unity for <math>n>1</math>. Suppose Bobby is unidirectional for every <math>3</math> minutes, and randomly chooses to reverse his direction after each cycle. In how many ways can Bobby travel around the unit circle exactly <math>6</math> times? | ||
+ | |||
+ | [[G285 2021 Summer Problem Set Problem 14|Solution]] | ||
==Problem 15== | ==Problem 15== | ||
− | Find the average of all values <math>z</math> such that < | + | Find the average of all values <math>z</math> such that <cmath>\sum_{n=1}^{119} \prod_{j=1}^{7} (z^j)^{n} = \left(\sum_{p=1}^{60} z^{2p-1}-\sum_{n=1}^{59} z^{2n} \right)^{5040}+2</cmath> |
+ | |||
+ | [[G285 2021 Summer Problem Set Problem 15|Solution]] |
Latest revision as of 22:28, 28 June 2021
Welcome to the Birthday Problem Set! In this set, there are multiple choice AND free-response questions. Feel free to look at the solutions if you are stuck:
Contents
Problem 1
Find
Problem 2
Let If is a positive integer, find the sum of all values of such that for some constant .
Problem 3
groups of molecules are gathered in a lab. The scientists in the lab randomly assign the molecules into groups of . Within these groups, there will be distinguishable labels (Strong acid, weak acid, strong base, weak base, nonelectrolyte), and each molecule will randomly be assigned a label such that teams can be empty, and each label is unique in the group. Find the number of ways that the molecules can be arranged by the scientists.
Problem 4
people are attending a hotel conference, of which are executives, and of which are speakers. Each person is designated a seat at one of round tables, each containing seats. If executives must sit at least one speaker and executive, there are ways the people can be seated. Find . Assume seats, people, and table rotations are distinguishable.
Problem 5
Suppose is an equilateral triangle. Let points and lie on the extensions of and respectively such that and . If there exists a point outside of such that , and there exists a point outside outside of such that , the area can be represented as , where and are squarefree,. Find
Problem 6
Let be a rectangle with and . Let points and lie on such that is the midpoint of and lies on . Let point be the center of the circumcircle of quadrilateral such that and lie on the circumcircle of and respectively, along with and . If the shortest distance between and is , and are degenerate, and , find
Problem 7
Geometry285 is playing the game "Guess And Choose". In this game, Geometry285 selects a subset of not necessarily distinct integers from the set such that the sum of all elements in is . Each distinct is selected chronologically and placed in , such that , , , and so on. Then, the elements are randomly arranged. Suppose represents the total number of outcomes that a subset containing integers sums to . If distinct permutations of the same set are considered unique, find the remainder when is divided by .
Problem 8
Let , Let be the twelve roots that satisfies , find the least possible value of
Problem 9
Let circles and with centers and concur at points and such that , . Suppose a point on the extension of is formed such that and lines and intersect and at and respectively. If , the value of can be represented as , where and are relatively prime positive integers, and is square free. Find
Problem 10
Let for . Suppose makes for distinct prime factors . If for is where must satisfy that is an integer, and is divisible by the th and th triangular number. Find
Problem 11
Let a recursive sequence be defined such that , and . Find the last digits of
Problem 12
Suppose the function . If , and the polynomial contains the points ,, and , find the smallest value of for which
Problem 13
Let circles ,, and concur at , where is the common chord shared by , is the common chord shared by , and lies on the common internal tangent of . Let the extension of and intersect and again at and respectively. If , prove is a parallelogram.
Problem 14
Bobby the frog is hopping around the unit circle. Suppose Bobby starts at . After every th minute, Bobby moves to such that , and is an th root of unity for . Suppose Bobby is unidirectional for every minutes, and randomly chooses to reverse his direction after each cycle. In how many ways can Bobby travel around the unit circle exactly times?
Problem 15
Find the average of all values such that