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Difference between revisions of "1971 IMO Problems/Problem 1"
Line 41: Line 41:
 
1. As a public service, I fixed a few typos in the solution above.
 
1. As a public service, I fixed a few typos in the solution above.
  
2. To make the solution a little more complete, let us note that
+
2. Make the solution a little more complete:
the assumptions <math>a_1 \ge a_2 \ge a_3</math> in case <math>n = 3</math> and
 
<math>a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5</math> in case <math>n = 5</math> are perfectly
 
legitimate.  A different ordering of these numbers could be reduced
 
to this case by a simple change of notation: we would substitute
 
<math>a_i</math> by <math>b_j</math> with the indexes for the <math>b</math>'s chosen in such a way
 
that the inequalities above are true for the <math>b</math>'s.
 
  
3. Also, the inequality
+
2.1. Let us note that the assumptions <math>a_1 \ge a_2 \ge a_3</math> in case
 +
<math>n = 3</math> and <math>a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5</math> in case <math>n = 5</math>
 +
are perfectly legitimate. A different ordering of these numbers
 +
could be reduced to this case by a simple change of notation: we
 +
would substitute <math>a_i</math> by <math>b_j</math> with the indexes for the <math>b</math>'s chosen
 +
in such a way that the inequalities above are true for the <math>b</math>'s.
 +
 
 +
2.2. The inequality
 
<math>(a_1 - a_2)[(a_1 - a_3)(a_1 - a_4)(a_1 - a_5) - (a_2 - a_3)(a_2 - a_4)(a_2 - a_5)] \ge 0</math>
 
<math>(a_1 - a_2)[(a_1 - a_3)(a_1 - a_4)(a_1 - a_5) - (a_2 - a_3)(a_2 - a_4)(a_2 - a_5)] \ge 0</math>
 
is true because <math>a_1 - a_2 \ge 0</math>, and
 
is true because <math>a_1 - a_2 \ge 0</math>, and
Line 58: Line 59:
  
 
The argument for the sum of the last two terms in <math>E_5</math> is similar.
 
The argument for the sum of the last two terms in <math>E_5</math> is similar.
 +
 +
3. The case <math>n = 3</math> is very easy to prove in a different way.  Note
 +
that
 +
 +
<math>(a_1 - a_2)(a_1 - a_3) + (a_2 - a_1)(a_2 - a_3) + (a_3 - a_1)(a_3 - a_2) =
 +
\frac{1}{2}[(a_1 - a_2)^2 + (a_2 - a_3)^2 + (a_3 - a_1)^2]</math>
 +
 +
I could not find an identity which would give such a simple proof
 +
in the case <math>n = 5</math>.
  
 
4. By looking at the proof above, we can also see that for <math>n = 3</math>
 
4. By looking at the proof above, we can also see that for <math>n = 3</math>
we have equality if an only if <math>a_1 = a_2 = a_3</math>.  For <math>n = 5</math>, we
+
we have equality if an only if <math>a_1 = a_2 = a_3</math>.  For <math>n = 5</math>,
 +
assuming that <math>a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5</math>, we
 
have equality if and only if <math>a_1 = a_2</math> and <math>a_3 = a_4 = a_5</math>,
 
have equality if and only if <math>a_1 = a_2</math> and <math>a_3 = a_4 = a_5</math>,
or <math>a_1 = a_2 = a_3</math> and <math>a_4 = a_5</math> (still assuming that
+
or <math>a_1 = a_2 = a_3</math> and <math>a_4 = a_5</math>.
<math>a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5</math>).
 
  
 
5. If we denote <math>P(x) = (x - a_1) \cdots (x - a_n)</math>, then the expression
 
5. If we denote <math>P(x) = (x - a_1) \cdots (x - a_n)</math>, then the expression
Line 73: Line 83:
 
<math>< 0</math> depending on the direction of the graph of <math>P(x)</math> at <math>a_k</math>.
 
<math>< 0</math> depending on the direction of the graph of <math>P(x)</math> at <math>a_k</math>.
 
At a multiple root <math>a_k = \cdots = a_{k+p}</math>, <math>P'(a_k) = 0</math>, and the
 
At a multiple root <math>a_k = \cdots = a_{k+p}</math>, <math>P'(a_k) = 0</math>, and the
graph of <math>P(x)</math> crosses the axes or not, depending on <math>p</math>.
+
graph of <math>P(x)</math> crosses the <math>x</math>-axis or not, depending on <math>p</math>.
 +
 
 +
This way of looking at the problem makes it very easy to find examples
 +
which prove the problem for <math>n</math> even or <math>n \ge 7</math> odd, because we would
 +
be looking for polynomials whose graph crosses the <math>x</math>-axis once from
 +
above to below at a simple root <math>a_k</math> (to make <math>P'(a_k) < 0</math>), and is
 +
tangent to the <math>x</math>-axis at all the other roots.  See the picture below
 +
for images showing the graphs of such polynomials.
  
I could not see how this way of looking at the problem would help give
+
[[File:prob_1971_1.png|600px]]
a direct proof, without any assumptions on the ordering of <math>a_k</math>'s in
 
the case <math>n = 5</math> (such a proof is possible, but difficult).  (The case
 
<math>n = 3</math> is very simple to prove directly, without any assumptions, or
 
insight into polynomials and their roots.)  However, this way of
 
looking at the problem makes it very easy to find examples which prove
 
the problem for <math>n</math> even or <math>n \ge 7</math> odd, because we would be looking
 
for polynomials whose graph crosses the <math>x</math>-axis once from above to
 
below (at a simple root), and is tangent to the <math>x</math>-axis at all the
 
other roots.
 
  
  

Revision as of 16:51, 15 December 2024

Problem

Prove that the following assertion is true for $n=3$ and $n=5$, and that it is false for every other natural number $n>2:$

If $a_1, a_2,\cdots, a_n$ are arbitrary real numbers, then $(a_1-a_2)(a_1-a_3)\cdots (a_1-a_n)+(a_2-a_1)(a_2-a_3)\cdots (a_2-a_n)+\cdots+(a_n-a_1)(a_n-a_2)\cdots (a_n-a_{n-1})\ge 0.$


Solution

Denote $E_n$ the expression in the problem, and denote $S_n$ the statement that $E_n \ge 0$.

Take $a_1 < 0$, and the remaining $a_i = 0$. Then $E_n = a_1^{n-1} < 0$ for $n$ even. So the proposition is false for even $n$.

Suppose $n \ge 7$ and odd. Take any $c > a > b$, and let $a_1 = a$, $a_2 = a_3 = a_4= b$, and $a_5 = a_6 = ... = a_n = c$. Then $E_n = (a - b)^3 (a - c)^{n-4} < 0$. So the proposition is false for odd $n \ge 7$.

Assume $a_1 \ge a_2 \ge a_3$. Then in $E_3$ the sum of the first two terms is non-negative, because $a_1 - a_3 \ge a_2 - a_3$. The last term is also non-negative. Hence $E_3 \ge 0$, and the proposition is true for $n = 3$.

It remains to prove $S_5$. Suppose $a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5$. Then the sum of the first two terms in $E_5$ is $(a_1 - a_2)[(a_1 - a_3)(a_1 - a_4)(a_1 - a_5) - (a_2 - a_3)(a_2 - a_4)(a_2 - a_5)] \ge 0$.

The third term in $E_5$ is non-negative (the first two factors are non-positive and the last two non-negative).

The sum of the last two terms in $E_5$ is: $(a_4 - a_5)[(a_1 - a_5)(a_2 - a_5)(a_3 - a_5) - (a_1 - a_4)(a_2 - a_4)(a_3 - a_4)] \ge 0$.

Hence $E_5 \ge 0$.

This solution was posted and copyrighted by e.lopes. The original thread can be found here: [1]


Remarks (added by pf02, December 2024)

1. As a public service, I fixed a few typos in the solution above.

2. Make the solution a little more complete:

2.1. Let us note that the assumptions $a_1 \ge a_2 \ge a_3$ in case $n = 3$ and $a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5$ in case $n = 5$ are perfectly legitimate. A different ordering of these numbers could be reduced to this case by a simple change of notation: we would substitute $a_i$ by $b_j$ with the indexes for the $b$'s chosen in such a way that the inequalities above are true for the $b$'s.

2.2. The inequality $(a_1 - a_2)[(a_1 - a_3)(a_1 - a_4)(a_1 - a_5) - (a_2 - a_3)(a_2 - a_4)(a_2 - a_5)] \ge 0$ is true because $a_1 - a_2 \ge 0$, and $(a_1 - a_3)(a_1 - a_4)(a_1 - a_5) - (a_2 - a_3)(a_2 - a_4)(a_2 - a_5) \ge 0$. To see this latter inequality, just notice that $a_1 - a_3 \ge a_2 - a_3$, and similarly for the other pairs of factors. The difference of the products is $\ge 0$ as desired.

The argument for the sum of the last two terms in $E_5$ is similar.

3. The case $n = 3$ is very easy to prove in a different way. Note that

$(a_1 - a_2)(a_1 - a_3) + (a_2 - a_1)(a_2 - a_3) + (a_3 - a_1)(a_3 - a_2) = \frac{1}{2}[(a_1 - a_2)^2 + (a_2 - a_3)^2 + (a_3 - a_1)^2]$

I could not find an identity which would give such a simple proof in the case $n = 5$.

4. By looking at the proof above, we can also see that for $n = 3$ we have equality if an only if $a_1 = a_2 = a_3$. For $n = 5$, assuming that $a_1 \ge a_2 \ge a_3 \ge a_4 \ge a_5$, we have equality if and only if $a_1 = a_2$ and $a_3 = a_4 = a_5$, or $a_1 = a_2 = a_3$ and $a_4 = a_5$.

5. If we denote $P(x) = (x - a_1) \cdots (x - a_n)$, then the expression in the problem is $P'(a_1) + \cdots + P'(a_n)$, where $P'(x)$ is the derivative of $P(x)$. The graph of $P(x)$ as $x$ goes from $-\infty$ to $\infty$ crosses the $x$-axis at every root $a_k$, or is tangent to it, or it is tangent to it and crosses it, depending on the multiplicity of the root. At a simple root $P'(a_k)$ is $> 0$ or $< 0$ depending on the direction of the graph of $P(x)$ at $a_k$. At a multiple root $a_k = \cdots = a_{k+p}$, $P'(a_k) = 0$, and the graph of $P(x)$ crosses the $x$-axis or not, depending on $p$.

This way of looking at the problem makes it very easy to find examples which prove the problem for $n$ even or $n \ge 7$ odd, because we would be looking for polynomials whose graph crosses the $x$-axis once from above to below at a simple root $a_k$ (to make $P'(a_k) < 0$), and is tangent to the $x$-axis at all the other roots. See the picture below for images showing the graphs of such polynomials.

Prob 1971 1.png


See Also

1971 IMO (Problems) • Resources
Preceded by
First Question 		1 2 3 4 5 6 Followed by
Problem 2
All IMO Problems and Solutions
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