The answer to the Problem in the post here is WRONG. It was brought to my attention by a commenter, unfortunately anonymous.
The answer will be replaced there with this one :
Corrected ANSWER CiP
The statement is NOT true for polynomials of degree 4 :
If $P(x)=x^4\;,\;\;Q(x)=x^4+x^2\;,\;\; R(x)=2x^4+x^2\;\;$ then $P(x)\leqslant Q(x)\leqslant R(x)$
but $\lambda \cdot P(x)+(1-\lambda)\cdot R(x)=(2-\lambda)\cdot x^4+(1-\lambda)\cdot x^2\neq Q(x)$
$\square$
We will solve Problem 7 (page 38, in the magazine from yesterday's Post) from Team Selection Test(TSTs) 1 for IMO.
" Problem 7. Consider three polynomials of degree 3 with real
coefficients $P,\;Q,\;R$ such that $P(x)\leqslant Q(x)\leqslant R(x)$ for any real $x$
and, in addition, there exists a real number $a$ such that $P(a)=R(a).$
Show that there exists a constant $\lambda \in [0,\;1]$ with the property
$Q=\lambda P+(1-\lambda)R.$ Does the statement remain true in the case
when $P,\;Q,\;R$ have degree 4?
{authors : } I. Cuculescu and L. Panaitopol, Bucharest"
ANSWER CiP (see correction)
It is not entirely true for polynomials of degree 4. For example, if
$P(x)=x^4\;,\;\;Q(x)=x^4+x^2\;,\;\;R(x)=x^4+2x^2$ then $P(x)\leqslant Q(x)\leqslant R(x)$
and we have $Q(x)=\lambda \cdot P(x)+(1-\lambda)\cdot R(x)$ but with $\lambda =-1 \not \in [0,\;1]$
Solution CiP
Obviously $P(a)=Q(a)=R(a).$ Let's define polynomials
$S(x)=R(x)-Q(x)\;\geqslant 0\;,\;\forall x\;\;;\;\;T(x)=R(x)-P(x)\;\geqslant 0\;,\;\forall x \tag{1}$
We have $S(a)=0$ therefore $S(x)=(x-a)S_2(x)$ , for a certain polynomial $S_2$ of degree 2.
Since when $x$ passes through the value $x=a$ , the polynomial $S$ does not change sign, we must have
$S(x)=(x-a)^2\cdot S_1(x) \tag{2}$
with $S_1$-a first degree polynomial. But the polynomial $S_1$ should have a root, through which if $x$ passes, the expression in (2) changes sign again. Contradiction, so $S_1$ is a constant.
In exactly the same way results
$T(x)=(x-a)^2\cdot T_1(x) \tag{3}$
with $T_1$ a constant.
Let $\lambda :=\frac{S(x)}{T(x)}\overset{(2)}{\underset{(3)}{=}}\frac{S_1}{T_1}=constant\;$. Since $\lambda=\frac{R(x)-Q(x)}{R(x)-P(x)}$ and $R(x)-Q(x)\leqslant R(x)-P(x)$ we have $0\leqslant \lambda \leqslant 1$ and
$Q(x)=\lambda \cdot P(x)+(1-\lambda )\cdot R(x).$
$\blacksquare$
Click on the image and use the password : ogeometrie . The QR code on page 2 contains a link to the Books in my Electronic Library. (Click on the year of publication. Same password if needed.) A collection of important magazines is at the letter G : GAZETA MATEMATICĂ seria B.
We have the relationships :
$5x+6y=150\;\;,\;\;\;5x=150-6y\;\;\;6y=150-5x \tag{1}$
From $6\mid 150\;\;and\;\;6\mid 6y$ and from the second formula (1) it follows that $6\mid 5x$ and because $gcd(5,6)=1$ we have $6\mid x$ so
$x=6\cdot x_1\;,\;\;x_1\in\mathbb{N^*} \tag{2}$
Similarly, we have $5\mid 150\;\;and\;\;5\mid 5x$ , and from the third formula (1) it results $5\mid 6y$ , so
$y=5\cdot y_1\;\;\;y_1\in\mathbb{N^*} \tag{3}$
Then $5x+6y=150\;\;\overset{(2)}{\underset{(3)}{\Leftrightarrow}}\;\;\;5\cdot 6x_1+6\cdot 5y_1=150\Leftrightarrow$
$\Leftrightarrow\;\;\;\;\;\;\;\;\;\;x_1+y_1=5 \tag{4}$
If $x_1=n\in\mathbb{N^*}$ , then $y_1\overset{(4)}{=}5-x_1=5-n$ , so the nonzero natural number solutions for (4) are :
$x_1=n\;\;,\;\;\;y_1=5-n\;\;\;\;\;1\leqslant n \leqslant 4 \tag{5}$
But
$x+y\;\;\;\overset{(2)\;(3)}{\underset{(5)}{=}}\;\;6\cdot n+5\cdot (5-n)=n+25 \tag{6}$
and then $1\leqslant n \leqslant 4 \Leftrightarrow26\leqslant n+25 \leqslant 29\underset{(6)}{\Leftrightarrow}$
$\Leftrightarrow\;\;\;\;\;26 \leqslant x+y \leqslant 29 \tag{7}$
We have in (7) $x+y=26$ for $n=1$ , so $x_1=1\;,\;y_1=4$ and we get from (2) and (3) $x=6\;,\;y=20$ for the minimum value. And $x+y=29$ for $n=4$ , so $x_1=4\;,\;y_1=1$ so $x=24\;,\;y=5$ for the maximum value.
Since there are a small number of values for $x\; and\; y$ , we will list all the products $x\cdot y$ in the table below, from where we will also obtain the answer.
\begin{array}{c|c|c|c|c}n&1&2&3&4\\\hline x&6&12&18&24\\\hline y&20&15&10&5\\\hline x\cdot y&120&180&180&120\\\end{array}
$\blacksquare$
From GMB (page 159), also proposed for 5th grade.
" E : 17461. Let $N=3+3^2+3^3+\dots+3^{4n+1}\;,\;n\in\mathbb{N}.$
a) Show that $2N+3$ s a perfect square.
b) For $n$ even natural numbers, determine the last two digits of $N$.
{author : } Marin CHIRCIU, Pitești "
Partial ANSWER CiP
a) $2N+3=(3^{2n+1})^2$
b) The answer is not a unique number. We have :
$3+3^2+3^3+3^4+3^5+3^6+3^7+3^8+3^9=29\;5\color{Yellow}{23}$
$3+3^2+3^3+\dots+3^{17}=193\;710\;2\color{Pink}{43}$
Solution CiP
a) $2N+3=\color{Red}{3}+N+N=$
$=\color{Red}{3}+(3+3)+(3^2+3^2)+(3^3+3^3)+\dots+(3^{4n+1}+3^{4n+1})=$
$=\color{Red}{(3+3+3)}+(3^2+3^2)+(3^3+3^3)+\dots+(3^{4n+1}+3^{4n+1}).$
Let's observe that $3+3+3=3^2$ ...and in general
$3^k+3^k+3^k=3^{k+1} \tag{1}$
Then, the red parenthesis results is $\color{Red}{3^2}$ , which appears as the term in the second parenthesis thus :
$(\color{Red}{3^2}+3^2+3^2)+(3^3+3^3)+\dots +(3^{4n+1}+3^{4n+1}).$
Continuing this calculation, we finally obtain the result
$2N+3=\color{Red}{3^{4n+1}}+3^{4n+1}+3^{4n+1}\underset{(1)}{=}3^{4n+2}=(3^{2n+1})^2\;,$
i.e. a perfect square.
$\square$
Click on the image and use the password : ogeometrie .The QR code on page 2 contains a link to the Books in my Electronic Library. (Click on the year of publication. Same password if needed.) A collection of important magazines is at the letter G : GAZETA MATEMATICĂ seria B.
A problem to illustrate the love for numbers, proposed for 5th grade (page 159) :
"E : 17457 . Write the number $220^{2n+1}$ as the sum of 5 distinct
nonzero perfect squares.
{author : } Marin CHIRCIU, Pitești "
ANSWER CiP
$220=1^2+3^2+4^2+5^2+13^2$ hence
$220^{2n+1}=(220^n)^2+(3\cdot 220^n)^2+(4 ^2\cdot 220^n)^2+(5\cdot 220^n)^2+(13\cdot 220^n)^2$
Solution CiP
We have $220^{2n+1}=(220^n)^2\cdot 220^1$ , so let's try to write the number $220$ as the sum of five distinct nonzero perfect squares.
We write some sums, $\color{Green}{highlighting}$ a perfect square term:
$220=\color{Green}{196}+24$
$220=\color{Green}{169}+51$
$220=\color{Green}{144}+76$
..........................
But any number is written as the sum of four squares, according to Lagrange's Four-Square Theorem, so let's try this with the second term in the writings above.
Asking a friend I found out that :
<< Adevărul e că $24$ are foarte puține reprezentări valide.
Singura reprezentare cu pătrate întregi ne-negative este:
>>
In translation : <<The truth is that 24 has very few valid representations. The only representation with non-negative integer squares is: ... >> But the squares here are not all nonzero and not all distinct.
Moving on to term $51$ , the same friend gave me the answer you see in the first row above.
The problem is now solved.
$\blacksquare$
Click on the image and use the password : ogeometrie .The QR code on page 2 contains a link to the Books in my Electronic Library. (Click on the year of publication. Same password if needed.) A collection of important magazines is at the letter G : GAZETA MATEMATICĂ seria B.
The triangle has angle measures $2^{\circ}\;,\;\;89^{\circ}\;,\;\;89^{\circ}$
Solution CiP
If $x^{\circ},\;y^{\circ},\;z^{\circ}$ are the angles of this triangle, then :
$x^{\circ}\;,\;y^{\circ},\;z^{\circ}\;<90^{\circ}\;\;and\;\;x^{\circ}+y^{\circ}+z^{\circ}=180^{\circ} \tag{1}$
Being prime numbers, if they were all odd then their sum would be odd. We contradict (1). So one of the numbers, let's say $z^{\circ}$ is $2^{\circ}$. Then the second condition in (1) becomes :
$x^{\circ}+y^{\circ}=178^{\circ} \tag{2}$
An obvious solution for (2) , which meets the requirements of the problem, is $x^{\circ}=y^{\circ}=89^{\circ}$. This triangle is isosceles.
$x^{\circ}\underset{(1)}{<}89^{\circ}\Rightarrow y\underset{(2)}{=}178^{\circ}-x^{\circ}>89^{\circ}$. And we can still have $y^{\circ}=90^{\circ}$ , which violates all the requirements.
$\blacksquare$
In the GMB 7/2005, mentioned here, the solution to problem 25223 (published in GMB/1/2005, page 40) appears, which is the source of this post. (With nostalgia, I found on page 299 the name of my college colleague Constantin BUȘE...deceased in the meantime)
" 25223. To solve in $\mathbb{C}$ the equation : $3x^3-3x+1=0.$
[author : ] Gh. Szöllősy, Sighetul Marmației"
ANSWER
$x_1=\frac{2}{\sqrt{3}}\cos\frac{5\pi}{18}\;,\;x_2=\frac{2}{\sqrt{3}}\cos \frac{7\pi}{18}\;,\;x_3=\frac{2}{\sqrt{3}}\cos\frac{17\pi}{18}$
Solution
We are looking for solutions of the kind $x_t=a\cdot \cos t,\;a>0,\;t\in [0,\pi]$. Then
$3x_t^3-3x_t+1=0\Leftrightarrow 3a^3\cos^3x_t-3a\cos x_t+1=0 \tag{1}$
Because $\cos 3t=4\cos^3t-3\cos t$ we are looking to determine $a$ such that $\frac{3a^3}{4}=\frac{3a}{3}$ which leads to $a=\frac{2}{\sqrt{3}}.$ Thus we have
$\frac{2}{\sqrt{3}}=\frac{3a^3\cos^3x_t-3a\cos x_t}{4\cos^3 x_t-3\cos x_t}\underset{(1)}{=}\frac{-1}{\cos 3t}$
From $\cos 3t=-\frac{\sqrt{3}}{2}$ we obtain $3t \in \left \{\pm \frac{5\pi}{6}+2k\pi\right \}\cap [0,\pi]$, so $t\in \left \{\frac{5\pi}{18},\;\frac{7\pi}{18},\;\frac{17\pi}{18}\right\}$ hence the Answer.
$\blacksquare$
REMARK CiP Putting $x=\frac{2}{\sqrt{3}}\cdot y$ we see that $y$ are solutions of the equation
$3\cdot \frac{8}{3\sqrt{3}}y^3-3\cdot \frac{2}{\sqrt{3}}y+1=0\;\Leftrightarrow\;8y^3-6y+\sqrt{3}=0 \tag{2}$
that is $y_{1-3}\in \left \{\cos\frac{5\pi}{18},\;\cos\frac{7\pi}{18},\;\cos\frac{17\pi}{18}=-\cos\frac{\pi}{18}\right \}.$ We therefore have, from Vieta's Formulas :
$\cos\frac{\pi}{18}-\cos\frac{5\pi}{18}-\cos\frac{7\pi}{18}=0$
$\cos \frac{\pi}{18}\cdot \cos \frac{5\pi}{18}-\cos \frac{5\pi}{18}\cdot \cos \frac {7\pi}{18}+\cos \frac{\pi}{18}\cdot \cos \frac{7\pi}{18}=-\frac{3}{4}$
$\cos \frac{\pi}{18}\cdot \cos \frac{5\pi}{18} \cdot \cos \frac{7\pi}{18}=\frac{\sqrt{3}}{8}$
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