Difference between revisions of "2023 IMO Problems/Problem 3"
(→Solution) |
(→Solution) |
||
Line 13: | Line 13: | ||
Let <math>f(n)</math> and <math>g(j)</math> be functions of positive integers <math>n</math> and <math>j</math> respectively. | Let <math>f(n)</math> and <math>g(j)</math> be functions of positive integers <math>n</math> and <math>j</math> respectively. | ||
− | Let <math>a_{n}=a_{1}+f(n)</math>, then <math>a_{n+1}=a_{1}+f(n+1)</math>, <math>a_{n+k}=a_{1}+f(n+k)</math> | + | Let <math>a_{n}=a_{1}+f(n)</math>, then <math>a_{n+1}=a_{1}+f(n+1)</math>, and <math>a_{n+k}=a_{1}+f(n+k)</math> |
− | Let <math>P=\prod_{j=1}^{k}\left ( a_{n+ | + | Let <math>P=\prod_{j=1}^{k}\left ( a_{n+j} \right ) = \prod_{j=1}^{k}\left ( a_{n}+g(j)) \right )</math> |
If we want the coefficients of <math>P(a_{n})</math> to be positive, then <math>g(j)\geq 0</math> for all <math>j</math> which will give the following value for <math>P</math>: | If we want the coefficients of <math>P(a_{n})</math> to be positive, then <math>g(j)\geq 0</math> for all <math>j</math> which will give the following value for <math>P</math>: | ||
Line 29: | Line 29: | ||
<math>g(j)=a_{1}+f(n+j)-a_{n}=a_{1}+f(n+j)-a_{1}-f(n)</math> | <math>g(j)=a_{1}+f(n+j)-a_{n}=a_{1}+f(n+j)-a_{1}-f(n)</math> | ||
− | <math>g(j)=f(n+j)-f(n)\geq 0</math> for all <math>n</math> and <math>i</math> | + | <math>g(j)=f(n+j)-f(n)\geq 0</math> for all <math>n</math> and <math>i</math> because <math>g(j)</math> needs to be greater than zero for all coefficients to be non-negative. |
This means that <math>f(n)</math> needs to be increasing with <math>n</math> or staying constant, and also with <math>f(1)=0</math> because <math>a_{1}=a_{1}+f(1)</math> In addition, since we need all coefficients to be integer then all <math>f(n)</math> and <math>g(j)</math> must also be integers. We also need <math>g(j)</math> to not be dependent of <math>n</math>, so in the expression <math>f(n+j)-f(n)</math>, the <math>n</math> needs to cancel. This mean that the rate of change for <math>f(n)</math> with respect to <math>n</math> needs to be constant. This can only be achieved with <math>f(n)</math> be the equation of a line with slope being either zero or positive integer. | This means that <math>f(n)</math> needs to be increasing with <math>n</math> or staying constant, and also with <math>f(1)=0</math> because <math>a_{1}=a_{1}+f(1)</math> In addition, since we need all coefficients to be integer then all <math>f(n)</math> and <math>g(j)</math> must also be integers. We also need <math>g(j)</math> to not be dependent of <math>n</math>, so in the expression <math>f(n+j)-f(n)</math>, the <math>n</math> needs to cancel. This mean that the rate of change for <math>f(n)</math> with respect to <math>n</math> needs to be constant. This can only be achieved with <math>f(n)</math> be the equation of a line with slope being either zero or positive integer. | ||
− | So, we set <math>f(n)=mn+b</math> with <math>m</math> being the slope with a non-negative value and with <math>b</math> the intercept at <math>n=0</math>. We know that <math>f(1)=0</math> so <math>f(1)=m+b=0</math> which means that <math>b=-m</math> and our function becomes <math>f(n)=mn-m=(n-1)m</math>. Since <math>f(n)</math> needs to be non-negative integer then <math>m\geq 0 \mid m \in \mathbb{Z}</math> then <math>f(n)</math> is increasing or constant, with <math>f(1)=0</math> | + | So, we set <math>f(n)</math> to be the equation of a line as <math>f(n)=mn+b</math> with <math>m</math> being the slope with a non-negative value and with <math>b</math> the intercept at <math>n=0</math>. We know that <math>f(1)=0</math> so <math>f(1)=m+b=0</math> which means that <math>b=-m</math> and our function becomes <math>f(n)=mn-m=(n-1)m</math>. Since <math>f(n)</math> needs to be non-negative integer then <math>m\geq 0 \mid m \in \mathbb{Z}</math> then <math>f(n)</math> is increasing or constant, with <math>f(1)=0</math> |
Then, <math>g(j)=f(n+j)-f(n)=(n+j-1)m-(n-1)m=jm</math> | Then, <math>g(j)=f(n+j)-f(n)=(n+j-1)m-(n-1)m=jm</math> |
Revision as of 12:46, 3 October 2023
Problem
For each integer , determine all infinite sequences of positive integers for which there exists a polynomial of the form , where are non-negative integers, such that for every integer .
Solution
https://www.youtube.com/watch?v=JhThDz0H7cI [Video contains solutions to all day 1 problems]
https://www.youtube.com/watch?v=SP-7LgQh0uY [Video contains solution to problem 3]
https://www.youtube.com/watch?v=CmJn5FKxpPY [Video contains another solution to problem 3]
Let and be functions of positive integers and respectively.
Let , then , and
Let
If we want the coefficients of to be positive, then for all which will give the following value for :
Thus for every and we need the following:
Solving for we get:
for all and because needs to be greater than zero for all coefficients to be non-negative.
This means that needs to be increasing with or staying constant, and also with because In addition, since we need all coefficients to be integer then all and must also be integers. We also need to not be dependent of , so in the expression , the needs to cancel. This mean that the rate of change for with respect to needs to be constant. This can only be achieved with be the equation of a line with slope being either zero or positive integer.
So, we set to be the equation of a line as with being the slope with a non-negative value and with the intercept at . We know that so which means that and our function becomes . Since needs to be non-negative integer then then is increasing or constant, with
Then,
This gives:
with and coefficients of polynomial
Then,
Which provide the solution of all infinite sequences of positive integers as:
,