Two High School Quizzes I Still Remember (9th Grade / Year 1) // Doua Extemporale de pe vremea Liceului (clasa a 9-a/anul I) // Дзве школьныя віктарыны, якія я дагэтуль памятаю (9 клас / 1 год)

          I found two Quizzes in my 1st year high school ALGEBRA textbook.(On the first page is my signature and a personal stamp. I had several math teachers at the beginning of that school year. 

         I will talk about the first of them, Vasile BIVOLARU, who only stayed for three weeks, being incorporated for a 6-month military internship, another time. 

I spent the first two years of high school with Professor Gheorghe DUMITRU, the one who gave me my grades.

First Quiz, with the last teacher

Second quiz

I also found among the pages of the book an Essay on Political Science. (The writing in this essay does not appear to be mine.)

Comments remain open...

A 7TH GRADE PROBLEM FROM NMO // O PROBLEMA DE CLASA A 7-A DE LA ONM

                     We will solve the following problem (It is problem 3 from NMO 2026, proposed for grade 7 page 5):

               Determine the pairs  $(a,b)$ of nonzero natural numbers for which the

 numbers  $\frac{a^2+b}{a+b-1}$  and  $\frac{b^2+a}{a+b}$  are natural.

{author} Lucian DRAGOMIR, Oțelu Roșu

Vocabulary  :  NMO = National Mathematics Olympiad

(in construction)

O CONTRADICTIE LA CARE NU TE ASTEPTAI // A CONTRADICTION YOU DIDN'T EXPECT // EGY ÖSSZEHÚZÓDÁS, AMIRE NEM SZÁMÍTOTTAD

           Seeing the "Second solution" (on page 16) to the problem in the post 

A 7TH GRADE PROBLEM FROM NMO // O PROBLEMA DE CLASA A 7-A DE LA ONM 

reminded me of the demonstration, which had long annoyed me, of the fact that  $\sqrt{2}$  is irrational. I consulted the textbook when I was in the first year of high school (today's 9th grade) :

BOGDANOF Z., GEORGESCU-BUZAU E., PANAITOPOL L.  

-  ALGEBRA : Manual pentru anul I licee,

Ed. Did. si Ped., Bucuresti, 1975

 Here's what it says on page 23 (starting with the 5th; minor retouching by CiP) : 

"There is no rational number whose square is 2.

(in the context of the statement that "the equation  $x^2=2$  has no solutions in the set of rational numbers"). The proof is done by contradiction :

Suppose there is a rational number  $\frac{m}{n}$  such that  $\frac{m^2}{n^2}=2\;\;\;\;\;(1)$

   We can assume that the fraction  $\frac{m}{n}$  is irreducible (otherwise we simplify with the greatest common divisor of the numbers m and n).

(1)$\;\;\Rightarrow m^2=2n^2\Rightarrow 2\mid m^2\Rightarrow 2\mid m$

so  $m=2q\;(q\in\mathbb{Z})$. Then  $(2q)^2=2n^2\Leftrightarrow 2q^2=n^2$, so  $2\mid n^2$  and then  $2\mid n$.

     Therefore, the fraction  $\frac{m}{n}$  is not irreducible (both the numerator  $m$ and the denominator  $n$ are divisible by 2). A contradiction was obtained with the hypothesis that the fraction $\frac{m}{n}$  is irreducible."

          This made me unhappy, because in fact the contradiction is NOT with the hypothesis, but with an assumption made during the demonstration. It is possible, I have heard, to logically formalize such a path.

(I am also unhappy because I fell in love with a woman ALINA, to whom I plan to dedicate a page on this blog, with our story (I still don't know for sure, at this time, how it will end). She is a big fan of a song.... I also promoted it on Twitter, I'm putting it here too : Three Seconds - Sia Ft Damian Marley

)

          Second Solution

          If  $a=1$  then

  $m=\frac{a^2+b}{a+b-1}=\frac{1+b}{b}=1+\frac{1}{b},\;\;n=\frac{b^2+a}{a+b}=\frac{b^2+b-b-1+2}{1+b}=b-1+\frac{2}{1+b}$

  and  $m,\;n$  are integers if and only if  $b=1$.

If  $b=1$  then  $m=\frac{a^2+1}{a}=a+\frac{1}{a},\;\;n=\frac{1+a}{a+1}=1$  and  $m$  is integer if and only if  $a=1$.

          Let, from now on,  $a,\;b \geqslant 2.$

          We denote  $s=a+b$;  in this case we have  $s\geqslant 4$.

$n=\frac{a+b+b^2-b}{a+b}=\frac{s+b(b-1)}{s}=1+\frac{b(b-1)}{s} \tag{2}$

$m=\frac{(s-b)^2+b}{s-1}=\frac{s^2-2sb+b^2+b}{s-1}= s-2b+1+\frac{b(b-1)+1}{s-1}\tag{3}$

(For (3) we process the numerator like this  $s^2-2sb+b^2+b=(s^2-s)\color{Red}{+s}\underset{=-2b(s-1)}{\underbrace{-2sb+2b}}-b+b^2\color{Red}{-1}+1=$

$=(s-1)(s+1-2b)+b^2-b+1$)

We will show that we can have neither  $m\in \mathbb{Z}$  nor  $n\in \mathbb{Z}$.

We assume the opposite :

$m\in\mathbb{Z}\;\;AND\;\; n\in\mathbb{Z} \tag{4}$

     Because  $b(b-1)\geqslant 2$,  we have  $n\in\mathbb{Z}\;\overset{(2)}{\Rightarrow} \;b(b-1)=k \cdot s,\;k\in\mathbb{N}.$  But  $s>b\Rightarrow k\cdot s=b(b-1)>k\cdot b$,  hence

$\color{Red}{\fbox{k<b-1}}\tag{5}$

On the other hand  $m\in\mathbb{Z}\overset{(3)}{\Rightarrow} s-1\mid ks+1=k(s-1)+(k+1)$,  so  $s-1 \mid k+1$,  and hence  $k+1\geqslant s-1$  from where  

$k\geqslant s-2=a+b-2=(a-1)+(b-1)$.

From the previous row it follows :

$\color{Red}{\fbox{$k\geqslant b-1$}}\tag{6}$

But  (5) and (6) are contradictory.

          

          And here, as in the first example, the contradiction appeared somewhere you didn't expect it. So (4) is false, so at least one of the numbers  $m,\;n$  is not an integer.

UN NUMAR $\pi$ CIUDATCARE APARE IN REZOLVARE

(in construction)

Gheorghe ANDREI - COMPLEX NUMBERS (part II) - Some Problems -- 4 / Gheorghe ANDREI - NUMERE COMPLEXE (partea II) - Câteva Probleme -- 4 / Gheorghe ANDREI – LICZBY ZŁOŻONE (część II) – Niektóre problemy – 4

 I wrote about the book here.

                       We discuss some Identities with two or more complex variables. 

               I took a look at the classic works, of which I have the following:

                       @ EVGRAFOV M., BÉJANOV K., SIDOROV Y., FÉDORUK M, CHABOUNINE M.

RECUEIL DE PROBLÈMES SUR LA THÉORIE DES FONCTIONS ANALYTIQUES

MIR, Moscou, 1974

                     @@ Problems in the theory of functions of a complex variable , authors        L. Volkovysky, G. Lunts, I. Aramanovich (translated from the Russian by Victor Shiffer)  Mir ; Moscow; 1972 (I only have it in paper format)

                   @@@ ВОЛКОВЫСКИЙ Л. И., ЛУНЦ Г. Л., АРАМАНОВИЧ И. Г.

Сборник задач по теории функций комплексного переменного

ФИЗМАТЛИТ, Москва, 2004

                @@@@ VOLKOVYSKY I., LUNTS G., ARAMANOVICH I.

Problems in the Theory of Functions of a Complex Variable

MIR, Moscow, 1977 

              @@@@@ VOLKOVYSKII L[ev] I[zrailevich], LUNTS, G[rigorii] L[‘vovich],

             ARAMANOVICH I[saak] G[enrikhovich]

A Collection of Problems on Complex Analysis

DOVER PUBLICATIONS, INC. New York, 1991

    

.....................................................................................................................................

          From  @   we take problem 1.68 from page 19 and 1.59 from page 18 :

         1.68.  Show that for all complex values ​​of  $z$  and  $\zeta$  the following equalities are valid :

   1. $|z+\zeta|^2+|z-\zeta|^2=2|z|^2+2|\zeta|^2$

   2. $|z\bar \zeta+1|^2+|z-\zeta|^2=(1+|z|^2)(1+|\zeta|^2)$

   3. $|z\bar \zeta-1|^2-|z-\zeta|^2=(|z|^2-1)(|\zeta|^2-1)$

 

           1.59.  Show that for no matter what complex number  $z$,  the formula below is valid :

$|\sqrt{z^2-1}+z|+|\sqrt{z^2-1}-z|=|z-1|+|z+1|.$

            From  @@  we take problems 9, 10, 13  from page 12 :

             9.  Prove the identity :

$|z_1+z_2|^2+|z_1-z_2|^2=2(|z_1|^2+|z_2|^2.$

           10.  Prove the identity :

$|1-\bar z_1z_2|^2-|z_1-z_2|^2=(1-|z_1|^2)(1-|z_2|^2).$

           13.  Prove the foloowing identities :

  $$1)\;\;(n-2)\sum_{k=1}^n|a_k|^2+\bigg |\sum_{k=1}^na_k\bigg|^2=\sum_{1\leqslant k<s\leqslant n}|a_k+a_s|^2;$$

$$2)\;\;n\sum_{k=1}^n|a_k|^2-\bigg | \sum_{k=1}^na_k \bigg |^2=\sum_{1\leqslant k<s\leqslant n}|a_k-a_s|^2.$$

We will list from the basic work in the title the issues more or less related to this topic.

          Problem 35* (page 25)  Show that for any  $z\in \mathbb{C}$  the relation holds :

$|\sqrt{z^2-1}+z|+|\sqrt{z^2-1}-z|=|z-1|+|z+1|.$

          Problem 53 (page 27)  Show that :

$2|\sqrt{z^2-1}+z|=|z+1|+|z-1|+\sqrt{(|z+1|^2+|z-1|^2)-4},\;\;\;\forall z\in \mathbb{C}.$

          Problem 55 (page 27)   If  $z\in \mathbb{C}$  then

$|\sqrt{z^2+2z}+z+1|+|\sqrt{z^2+2z}-(z-1)|+|z-2|=$

$=|\sqrt{z^2-2z}+z-1|+|\sqrt{z^2-2z}-(z-1)|+|z+2|.$

          Problem  1 (page 28-29)   To check the equalities :

a)  $|z_1+z_2|^2+|z_1-z_2|^2=2(|z_1|^2+|z_2|^2);$

b)  $|z_1|^2+|z_2|^2-z_1 \bar z_2-\bar z_1 z_2=|z_1-z_2|^2;$

c)  $|z_1\bar z_2+1|^2+|z_1-z_2|^2=(|z_1|^2+1)(|z_2|^2+1);$

d)  $|z_1 \bar z_2-1|^2-|z_1-z_2|^2=(|z_1|^2-1)(|z_2|^2-1);$

e)  $|z_1+2z_2|^2-2|z_1+z_2|^2=2|z_2|^2-|z_1|^2.$

          Problem  2 (page 29)  If  $z_1,\;z_2\in \mathbb{C}$,  then :

a)  $|z_1 \bar z_2+1|^2+|z_2 \bar z_1+1|^2+2|z_1-z_2|^2=2(1+|z_1|^2)(1+|z_2|^2);$

b)  $z_1 \bar z_2-1|^2+|z_2 \bar z_1-1|^2-2|z_1-z_2|^2=2(1-|z_1|^2)(1-|z_2|^2);$

c)  $|1-\bar z_1z_2|^2-|z_1-z_2|^2=(1+|z_1z_2|)^2-(|z_1|+|z_2|)^2.$

          Problem  4 (page 29)  BERGSTROM identity : 

 for  $u,\;v \in \mathbb{C}\;\;and \;\;a,\;b\in \mathbb{R}^*,\;a+b \neq 0$

$\frac{|u|^2}{a}+\frac{|v|^2}{b}-\frac{|u+v|^2}{a+b}=\frac{|bu-av|^2}{ab(a+b)}.$

ANSWER CiP / Solutions CiP

  

                    @1.68 1) or @@9  or  #1a) (p. 28)        $|z_1+z_2|^2+|z_1-z_2|^2=$

$=(z_1+z_2)\cdot \overline{(z_1+z_2)}+(z_1-z_2)\cdot \overline{(z_1-z_2)}=(z_1+z_2)(\bar z_1+\bar z_2)+(z_1-z_2)(\bar z_1-\bar z_2)=$

$=(z_1 \bar z_1+z_2 \bar z_1+z_2\bar z_1+z_2 \bar z_2)+(z_1 \bar z_1-z_1\bar z_2-z_2 \bar z_1+z_2 \bar z_2)=$

$=2z_1 \bar z_1+2z_2 \bar z_2=2(|z_1|^2+|z_2|^2)$

(to be continue)

Gheorghe ANDREI - COMPLEX NUMBERS (part II) - Some Problems -- 3 / Gheorghe ANDREI - NUMERE COMPLEXE (partea II) - Câteva Probleme -- 3 / Gheorghe ANDREI - KOMPLEXNÉ ČÍSLA (časť II) - Niektoré problémy -- 3

 I wrote about the book here.

               We discuss problems no. ##3, 4, page 21 (solved on page 177) and #38, page 25 (solved on page 185).

                Problem #3  "Let  $\varepsilon$  be a complex cube root of unity. Prove that

$|z-1|^2+|z-\varepsilon|^2+|z-\varepsilon^2|^2=3(|z|^2+1)"$

                Problem #4   "Let  $\varepsilon$  be a complex cube root of unity. Prove that

$|z+u|^2+|z+\varepsilon u|^2+|z+\varepsilon^2 u|^2=3(|z|^2+|u|^2)$

                         whatever  $z,\;u\in\mathbb{C}$  are."

                                  Problem #38  "Prove that :

                                           a)   $(z-1)^2+(z-\varepsilon)^2+(z-\bar\varepsilon)^2=3z^2$

                where  $\varepsilon=\cos\frac{2\pi}{3}+\imath \sin\frac{2\pi}{3};$

                                          $\textbf{b)}\;\;\;(z-1)^2+(z-\varepsilon)^2+(z-\varepsilon ^2)^2+\dots+(z-\varepsilon ^{n-1})^2=nz^2$

where  $\varepsilon=\cos \frac{2\pi}{n}+\imath \sin \frac{2\pi}{n};$

 $$\textbf{c)}\;\;\; \sum_{k=0}^{n-1}|z-\varepsilon ^k|^2=n(|z|^2+1|)."$$

                        Solution of #4(CiP - Same as the solution on page 177) 

      The cube roots of unity are  $\left \{1,\;-\frac{1}{2}\pm \imath \frac{\sqrt{3}}{2}\right \}$. Let  $\varepsilon \neq 1$  be one of them. We have

$\varepsilon ^3=1,\;\;\;1+\varepsilon+\varepsilon ^2=0,\;\;\;\bar \varepsilon =\varepsilon ^2 \;\;\;\varepsilon \cdot \bar \varepsilon =1\tag{U3}$

          Using that  $|z|^2=z \cdot \bar z,\;\;(\forall) z\in \mathbb{C}$  we have

$|z+u|^2+|z+\varepsilon u|^2+|z+\varepsilon ^2 u|^2=$

$=(z+u)\cdot \overline{(z+u)}+(z+\varepsilon u)\cdot \overline{(z+\varepsilon u)}+(z+\varepsilon ^2 u)\cdot \overline{(z+\varepsilon ^2 u)}=$

$=(z+u)(\bar z +\bar u)+(z+\varepsilon u)(\bar z+\bar \varepsilon \bar u)+(z+\varepsilon ^2 u)(\bar z+\overline{\varepsilon ^2}\bar u)\overset{(U_3)}{=}$

$=(z\bar z+z\bar u+\bar z u+u\bar u)+(z \bar z+\varepsilon ^2 z \bar u+\varepsilon \bar z u+u \bar u)+(z\bar z+\varepsilon z \bar u+\varepsilon ^2 \bar z u+\varepsilon ^3 u \bar u)=$

$=3|z|^2+z\bar u (1+\varepsilon^2+\varepsilon)+\bar z u (1+\varepsilon +\varepsilon^2)+3|u|^2\underset{(U_3)}{=}3|z|^2+3|u|^2.$

$\blacksquare$

                        Solution of #3(CiP)

               If  $u=-1$,  the statement of Problem  #3 is obtained, or the calculation can be redone in this particular case.

$\blacksquare$

                REMARK CiP   On the cited page 177, the author of the book mentions another possible solution, using the identity(according to page 41, Exercise #10a)) :

$|z_1+z_2|^2+|z_2+z_3|^2+|z_3+z_1|^2=|z_1|^2+|z_2|^2+|z_3|^2+|z_1+z_2+z_3|^2$

Damn, I couldn't do this.

<end REM>

                        Solution of #38(CiP)

               a)  We have

  $(z-1)^2+(z-\varepsilon)^2+(z-\bar \varepsilon)^2 \overset{(U_3)}{=}(z-1)^2+(z-\varepsilon)^2+(z-\varepsilon^2)^2=$

$=(z^2-2z+1)+(z^2-2\varepsilon z+\varepsilon^2)+(z^2-2\varepsilon^2z+\varepsilon^4)=$

$=3z^2-2(1+\varepsilon+\varepsilon^2)z+(1+\varepsilon^2+\varepsilon)\underset{(U_3)}{=}3z^2$

$\blacksquare$

               b)   Let  $\varepsilon=\cos\frac{2\pi}{n}+\imath \sin \frac{2\pi}{n}$; we have  $\varepsilon ^n=1$,  and since  $1-\varepsilon ^n=(1-\varepsilon)(1+\varepsilon+\varepsilon^2+\dots+\varepsilon ^{n-1})=0$  it follows

$$\sum_{k=0}^{n-1}\varepsilon ^k=0. \tag{1}$$

But we also have

$$\sum_{k=0}^{n-1}(\varepsilon ^k)^2=0;\tag{2}$$

this is verified by distinguishing between odd and even cases for  $n$ :

$$n=2m+1\Rightarrow\sum_{k=0}^{2m}\varepsilon ^{2k}=\sum_{k=0}^m \varepsilon ^{2k}+\sum_{k=m+1}^{2m}\varepsilon^{2k}\;\;\;\;\;\overset{\varepsilon^{2m+1}=1}{\underset{\varepsilon^{2m+2}=\varepsilon^1,\;\varepsilon^{2m+4}=\varepsilon^3,\dots, \varepsilon^{4m}=\varepsilon^{2m-1}}{=}}\;\;\sum_{l=0}^{2m}\varepsilon^l\overset{(1)}{=}0;$$

$$n=2m\Rightarrow\sum_{k=0}^{2m-1}\varepsilon^{2k}=\sum_{k=0}^{m-1}\varepsilon^{2k}+\sum_{k=m}^{2m-1}\varepsilon^{2k}\;\;\;\;\;\overset{\varepsilon^{2m}=1}{\underset{\varepsilon^{2m}=1,\;\varepsilon^{2m+2}=\varepsilon^2,\dots, \varepsilon^{4m-2}=\varepsilon^{2m-2}}{=}}\;\;=2\cdot \sum_{l=0}^{m-1}\varepsilon^{2l}=0$$

the latter based on identity  $1-\varepsilon^{2m}=(1-\varepsilon^2)(1+\varepsilon^2+\varepsilon^4+\dots+\varepsilon^{2m-2})=0$.

          So we calculate 

$$\sum_{k=0}^{n-1}(z-\varepsilon^k)^2=\sum_{k=0}^{n-1}(z^2-2z\varepsilon^k+(\varepsilon^k)^2=nz^2-2z\cdot \sum_{k=0}^{n-1}\varepsilon^k+\sum_{k=0}^{n-1}(\varepsilon ^k)^2\;\;\underset{(1)\;(2)}{=}nz^2$$

$\blacksquare$

                    c)  Let us note that, along with (1), we also have its conjugate relation :

$$\sum_{k=0}^{n-1}(\bar \varepsilon)^k=0 \tag{3}$$

We obtain by an easy calculation :

$$\sum_{k=0}^{n-1}|z-\varepsilon^k|^2=\sum_{k=0}^{n-1}(z-\varepsilon^k)\cdot \overline{(z-\varepsilon^k)}=\sum_{k=0}^{n-1}(z-\varepsilon^k)(\bar z-\bar \varepsilon ^k)=$$

$$=\sum_{k=0}^{n-1}(z\cdot \bar z-\bar z \cdot \varepsilon^k-z\cdot \bar \varepsilon^k+\varepsilon^k\cdot \bar \varepsilon^k)=$$

$$\overset{z\cdot \bar z=|z|^2}{\underset{\varepsilon \cdot \bar \varepsilon=|\varepsilon|^2=1}{=}}\;\;\;\sum_{k=0}^{n-1}(|z|^2+1)-\bar z\cdot \sum_{k=0}^{n-1}\varepsilon^k-z\cdot \sum_{k=0}^{n-1}\bar \varepsilon^k\overset{(1)}{\underset{(3)}{=}}n(|z|^2+1).$$

                             REMARK CiP   These formulas take place starting from  $n=2$ :

$|z-1|^2+|z+1|^2=2(|z|^2+1);$

$n=3$ is the subject of exercise  #3.

$\blacksquare$

Gheorghe ANDREI - COMPLEX NUMBERS (part II) - Some Problems -- 2 / Gheorghe ANDREI - NUMERE COMPLEXE (partea II) - Câteva Probleme -- 2 // Gheorghe ANDREI - اعداد مختلط (قسمت دوم) - برخی از مسائل - 2

 You can find the book in my Electronic Library. The author, Gh. ANDREI gets lost among the crowd of Titu ANDREESCU...(current version today ; you can still access the library by scanning the QR code from the beginning)

                                                                                       < begin preview>

ANDREESCU Titu, DOSPINESCU Gabriel, MUSHKAROV Oleg

NUMBER THEORY: CONCEPTS AND PROBLEMS

XYZ Press, Plano_TX, 2017

ANDREI Gheorghe

NUMERE COMPLEXE : partea a II-a

Ed. GIL, Zalău, 2004/2005-ebook(cadou de Craciun 25 Dec 2025 de la fiul meu

                                                                                                                     CIOBANU Victor)

ANDREIAN-CAZACU Cabiria, DELEANU Aristide, JURCHESCU Martin

TOPOLOGIE. CATEGORII. SUPRAFEȚE RIEMANNIENE

Ed. ACADEMIEI [R.S.R.], București, 1966 

< end preview>

 This post is number 2, because we believe that the post here would be number 1.

 

            Problem #2 (page 21, solved on page 177 ; in translation)

"Let  $z\in \mathbb{C}\setminus \{\pm 1\}$, with the property  $\imath \frac{z-1}{z+1}\in\mathbb{R}$. Determine  $|z|$."

ANSWER CiP

$$|z|=1$$

                    Solution CiP

                Let  $\mathbb{R}\ni a=\imath \cdot \frac{z-1}{z+1}.$  We have (because $\imath ^2=-1\Rightarrow \frac{1}{\imath}=-\imath$)

$\frac{z-1}{z+1}=\frac{a}{\imath}=-a\imath$

so

 $z=\frac{1-a\imath}{1+a\imath} \tag{1}$

hence, according to Property #20, page 13,

$|z|=\frac{|1-a\imath|}{|1+a\imath|}=\frac{\sqrt{1+a^2}}{\sqrt{1+a^2}}=1$

$\blacksquare$

                 REMARKS CiP

               $1^r$.  Continuing in (1), we have  $z=\frac{(1-a\imath)^2}{(1+a\imath)(1-a\imath)}$  so

$z= \frac{1-a^2}{1+a^2}-\frac{2a\imath}{1+a^2}\;\overset{b=-a}{=}\;\frac{1-b^2}{1+b^2}+\frac{2b\imath}{1+b^2}\tag{2}$

               $2^r$.  The reciprocal statement is also true :

$|z|=1\Rightarrow (\exists)a\in\mathbb{R}\;\;s.t.\;\;z=\frac{1-a^2}{1+a^2}-\frac{2a}{1+a^2}\imath\Leftrightarrow (\exists)b\in\mathbb{R}\;\;s.t.\;\;z=\frac{1-b^2}{1+b^2}+\frac{2b}{1+b^2}\imath \tag{3}$

Indeed, according to page 16, Trigonometric form of complex numbers, #1, we have

$z=\cos \theta+\imath \sin \theta$,  and  $\cos \theta=\frac{1-b^2}{1+b^2},\;\;\sin \theta =\frac{2b}{1+b^2},\;\;\;b=\tan \theta /2$

hence (3).

$\square$<end REM>