(in construction)
marți, 12 mai 2026
duminică, 10 mai 2026
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)
marți, 28 aprilie 2026
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)
sâmbătă, 18 aprilie 2026
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.
$\blacksquare$
duminică, 12 aprilie 2026
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>
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