Corrigé devoir n° 1 maths - 3e

 

Écrivons les expressions suivantes sous la forme $x\sqrt{a}+y\sqrt{b}$ où $x\ $ et $\ y$ sont des réels et $a\ $ et $\ b$ des entiers naturels :

 

$\begin{array}{rcl} A&=&\sqrt{\dfrac{1}{2}}+(\sqrt{2})^{3}-7\sqrt{3}+\sqrt{72}+\sqrt{\dfrac{81}{3}}\\\\&=&\dfrac{\sqrt{1}}{\sqrt{2}}+(\sqrt{2})^{2}\times(\sqrt{2})-7\sqrt{3}+\sqrt{36\times 2}+\sqrt{27}\\\\&=&\dfrac{1}{\sqrt{2}}+2\times\sqrt{2}-7\sqrt{3}+\sqrt{36}\times\sqrt{2}+\sqrt{9\times 3}\\\\&=&\dfrac{\sqrt{2}}{\sqrt{2}\times\sqrt{2}}+2\sqrt{2}-7\sqrt{3}+6\times\sqrt{2}+\sqrt{9}\times\sqrt{3}\\\\&=&\dfrac{\sqrt{2}}{2}+2\sqrt{2}+6\sqrt{2}-7\sqrt{3}+\sqrt{9}\times\sqrt{3}\\\\&=&\dfrac{\sqrt{2}}{2}+8\sqrt{2}-7\sqrt{3}+3\times\sqrt{3}\\\\&=&\dfrac{\sqrt{2}+16\sqrt{2}}{2}-7\sqrt{3}+3\sqrt{3}\\\\&=&\dfrac{17\sqrt{2}}{2}-4\sqrt{3}\\\\&=&\dfrac{17}{2}\sqrt{2}-4\sqrt{3}\end{array}$

 

Ainsi, $\boxed{A=\dfrac{17}{2}\sqrt{2}-4\sqrt{3}}$

 

$\begin{array}{rcl} B&=&\sqrt{200}-5\sqrt{\dfrac{75}{2}}+\dfrac{3}{2}\sqrt{54}-\sqrt{32}\\\\&=&\sqrt{100\times 2}-5\times\dfrac{\sqrt{75}}{\sqrt{2}}+\dfrac{3}{2}\sqrt{9\times 6}-\sqrt{16\times 2}\\\\&=&\sqrt{100}\times\sqrt{2}-5\times\dfrac{\sqrt{25\times 3}}{\sqrt{2}}+\dfrac{3}{2}\times\sqrt{9}\times\sqrt{6}-\sqrt{16}\times\sqrt{2}\\\\&=&10\times\sqrt{2}-5\times\dfrac{\sqrt{25}\times\sqrt{3}}{\sqrt{2}}+\dfrac{3}{2}\times 3\times\sqrt{6}-4\times\sqrt{2}\\\\&=&10\sqrt{2}-5\times\dfrac{5\times\sqrt{3}\times\sqrt{2}}{\sqrt{2}\times\sqrt{2}}+\dfrac{9}{2}\sqrt{6}-4\sqrt{2}\\\\&=&10\sqrt{2}-4\sqrt{2}-25\times\dfrac{\sqrt{3\times 2}}{2}+\dfrac{9}{2}\sqrt{6}\\\\&=&6\sqrt{2}-\dfrac{25}{2}\sqrt{6}+\dfrac{9}{2}\sqrt{6}\\\\&=&6\sqrt{2}-\dfrac{16}{2}\sqrt{6}\\\\&=&6\sqrt{2}-8\sqrt{6}\end{array}$

 

D'où, $\boxed{B=6\sqrt{2}-8\sqrt{6}}$

 

$\begin{array}{rcl} C&=&5\sqrt{20}+\dfrac{3}{2}\sqrt{\dfrac{9}{5}}-2\sqrt{343}+10\sqrt{28}\\\\&=&5\sqrt{4\times 5}+\dfrac{3}{2}\times\dfrac{\sqrt{9}}{\sqrt{5}}-2\sqrt{49\times 7}+10\sqrt{4\times 7}\\\\&=&5\times\sqrt{4}\times\sqrt{5}+\dfrac{3}{2}\times\dfrac{3}{\sqrt{5}}-2\times\sqrt{49}\times\sqrt{7}+10\times\sqrt{4}\times\sqrt{7}\\\\&=&5\times 2\times\sqrt{5}+\dfrac{3}{2}\times\dfrac{3\times\sqrt{5}}{\sqrt{5}\times\sqrt{5}}-2\times 7\times\sqrt{7}+10\times 2\times\sqrt{7}\\\\&=&10\sqrt{5}+\dfrac{3}{2}\times\dfrac{3\times\sqrt{5}}{5}-14\sqrt{7}+20\sqrt{7}\\\\&=&10\sqrt{5}+\dfrac{9\sqrt{5}}{10}+6\sqrt{7}\\\\&=&\dfrac{100\sqrt{5}}{10}+\dfrac{9\sqrt{5}}{10}+6\sqrt{7}\\\\&=&\dfrac{109\sqrt{5}}{10}+6\sqrt{7}\end{array}$

 

Donc, $\boxed{C=\dfrac{109}{10}\sqrt{5}+6\sqrt{7}}$

Calculons les expressions suivantes tout en rendant rationnel le dénominateur :

 

$\begin{array}{rcl} X&=&\dfrac{3\sqrt{2}-4\sqrt{5}}{\dfrac{\sqrt{3}}{2}-\dfrac{\sqrt{2}}{3}}\\\\&=&\dfrac{3\sqrt{2}-4\sqrt{5}}{\dfrac{3\sqrt{3}}{6}-\dfrac{2\sqrt{2}}{6}}\\\\&=&\dfrac{3\sqrt{2}-4\sqrt{5}}{\dfrac{3\sqrt{3}-2\sqrt{2}}{6}}\\\\&=&\dfrac{6\times(3\sqrt{2}-4\sqrt{5})}{3\sqrt{3}-2\sqrt{2}}\\\\&=&\dfrac{6\times(3\sqrt{2}-4\sqrt{5})\times(3\sqrt{3}+2\sqrt{2})}{(3\sqrt{3}-2\sqrt{2})(3\sqrt{3}+2\sqrt{2})}\\\\&=&\dfrac{6\times[(3\sqrt{2})\times(3\sqrt{3})+(3\sqrt{2})\times(2\sqrt{2})-(4\sqrt{5})\times(3\sqrt{3})-(4\sqrt{5})\times(2\sqrt{2})]}{(3\sqrt{3})^{2}-(2\sqrt{2})^{2}}\\\\&=&\dfrac{6\times[(9\sqrt{2}\times\sqrt{3})+(6\sqrt{2}\times\sqrt{2})-(12\sqrt{5}\times\sqrt{3})-(8\sqrt{5}\times\sqrt{2})]}{(9\times 3)-(4\times 2)}\\\\&=&\dfrac{6\times(9\sqrt{6}+12-12\sqrt{15}-8\sqrt{10})}{27-8}\\\\&=&\dfrac{6\times(9\sqrt{6}+12-12\sqrt{15}-8\sqrt{10})}{19}\\\\&=&\dfrac{54\sqrt{6}-72\sqrt{15}-48\sqrt{10}+72}{19}\end{array}$

 

Ainsi, $\boxed{X=\dfrac{54\sqrt{6}-72\sqrt{15}-48\sqrt{10}+72}{19}}$

 

$\begin{array}{rcl} Y&=&\dfrac{2\sqrt{3}+3\sqrt{2}}{-2\sqrt{3}-3\sqrt{2}}\\\\&=&\dfrac{2\sqrt{3}+3\sqrt{2}}{-(2\sqrt{3}+3\sqrt{2})}\\\\&=&-\dfrac{2\sqrt{3}+3\sqrt{2}}{2\sqrt{3}+3\sqrt{2}}\\\\&=&-1\end{array}$

 

D'où, $\boxed{Y=-1}$

 

$\begin{array}{rcl} Z&=&\dfrac{\sqrt{7}-\sqrt{5}}{\sqrt{\dfrac{2}{3}}}\\\\&=&\dfrac{\sqrt{7}-\sqrt{5}}{\dfrac{\sqrt{2}}{\sqrt{3}}}\\\\&=&\dfrac{(\sqrt{7}-\sqrt{5})\times\sqrt{3}}{\sqrt{2}}\\\\&=&\dfrac{(\sqrt{7}-\sqrt{5})\times\sqrt{3}\times\sqrt{2}}{\sqrt{2}\times\sqrt{2}}\\\\&=&\dfrac{(\sqrt{7}-\sqrt{5})\times\sqrt{6}}{2}\\\\&=&\dfrac{\sqrt{6}(\sqrt{7}-\sqrt{5})}{2}\end{array}$

 

D'où, $\boxed{Z=\dfrac{\sqrt{6}(\sqrt{7}-\sqrt{5})}{2}}$

 

$\begin{array}{rcl} T&=&\dfrac{\dfrac{2\sqrt{5}-3\sqrt{11}}{4\sqrt{3}+\sqrt{7}}}{\sqrt{\dfrac{3}{2}}}\\\\&=&\dfrac{\dfrac{2\sqrt{5}-3\sqrt{11}}{4\sqrt{3}+\sqrt{7}}}{\dfrac{\sqrt{3}}{\sqrt{2}}}\\\\&=&\dfrac{2\sqrt{5}-3\sqrt{11}}{4\sqrt{3}+\sqrt{7}}\times\dfrac{\sqrt{2}}{\sqrt{3}}\\\\&=&\dfrac{(2\sqrt{5}-3\sqrt{11})\times\sqrt{2}}{(4\sqrt{3}+\sqrt{7})\times\sqrt{3}}\\\\&=&\dfrac{2\sqrt{5}\times\sqrt{2}-3\sqrt{11}\times\sqrt{2}}{4\sqrt{3}\times\sqrt{3}+\sqrt{7}\times\sqrt{3}}\\\\&=&\dfrac{2\sqrt{10}-3\sqrt{22}}{12+\sqrt{21}}\\\\&=&\dfrac{(2\sqrt{10}-3\sqrt{22})(12-\sqrt{21})}{(12+\sqrt{21})(12-\sqrt{21})}\\\\&=&\dfrac{24\sqrt{10}-36\sqrt{22}-2\sqrt{10}\times\sqrt{21}+3\sqrt{22}\times\sqrt{21}}{(12)^{2}-(\sqrt{21})^{2}}\\\\&=&\dfrac{24\sqrt{10}-36\sqrt{22}-2\sqrt{210}+3\sqrt{462}}{144-21}\\\\&=&\dfrac{24\sqrt{10}-36\sqrt{22}-2\sqrt{210}+3\sqrt{462}}{123}\end{array}$

 

Ainsi, $\boxed{T=\dfrac{24\sqrt{10}-36\sqrt{22}-2\sqrt{210}+3\sqrt{462}}{123}}$

Soit un réel $a\ $ tel que : $a=1+\sqrt{\dfrac{1}{2}}$ et soit $b$ son expression conjuguée.

 

1) Déterminer $b$

 

Comme $b$ est l'expression conjuguée de $a$ alors, on a :

$$b=1-\sqrt{\dfrac{1}{2}}=1-\dfrac{\sqrt{2}}{2}$$

Calculons $(a+b)^{2}$

 

On a :

 

$\begin{array}{rcl} (a+b)^{2}&=&\left(1+\sqrt{\dfrac{1}{2}}+1-\sqrt{\dfrac{1}{2}}\right)^{2}\\\\&=&(2)^{2}\\\\&=&4\end{array}$

 

Ainsi, $\boxed{(a+b)^{2}=4}$

 

2) Montrons que $2ab=1$

 

En calculant $a\times b$, on obtient :

 

$\begin{array}{rcl} a\times b&=&\left(1+\sqrt{\dfrac{1}{2}}\right)\left(1-\sqrt{\dfrac{1}{2}}\right)\\\\&=&(1)^{2}-\left(\sqrt{\dfrac{1}{2}}\right)^{2}\\\\&=&1-\dfrac{1}{2}\\\\&=&\dfrac{1}{2}\end{array}$

 

Par suite $2ab=2\times\dfrac{1}{2}=1$

 

D'où, $\boxed{2ab=1}$

 

Déduisons alors l'expression de $a^{2}+b^{2}$

 

On sait que : $(a+b)^{2}=a^{2}+b^{2}+2ab$

 

Donc, $a^{2}+b^{2}=(a+b)^{2}-2ab$

 

Ce qui donne : $a^{2}+b^{2}=4-1=3$

 

Ainsi, $\boxed{a^{2}+b^{2}=3}$

Exercice 4