Wiki-Math-FL

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• \( c = (a-r) + (b-r) \Longrightarrow r = \frac{a+b-c}{2} \)
• \(\left\{\begin{array}{l}{\sin 17^{\circ}=\frac{b}{c}} \\ {\cos 17^{\circ}=\frac{a}{c}} \\ {r=\dfrac{a+b-c}{2}=8.3}\end{array} \Longrightarrow\left\{\begin{array}{l}{b=c \sin 17^{\circ}} \\ {a=c \cdot\cos 17^{\circ}} \\ {\dfrac{c\cdot \cos 17^{\circ}+c\cdot \sin 17^{\circ}-c}{2}=8.3} \qquad \Par{r=\frac{a+b-c}{2}=8.3}\end{array}\right.\right.\)

\(\Longrightarrow c=\dfrac{8,3 \times 2}{\sin 17^{\circ}+\cos 17^{\circ}-1}=66,8 \mathrm{cm} \Longrightarrow\left\{\begin{array}{l}{a=63.8 \mathrm{cm}} \\ {b=19,5 \mathrm{cm}}\end{array}\right.\)

On pose \(y=\sin x+\cos x \Longrightarrow y^{2}=1+2 \sin x \cos x\)

dès lors, \( 8 \sin x \cos x = 4\left(y^{2}-1\right)\)

L'énoncé devient \(4 y-4 y^{2}+4-5=0 \Longrightarrow 4 y^{2}-4 y+1=0 \Longrightarrow(2 y-1)^{2}=0 \Longrightarrow y=\frac{1}{2}\)

d'où \[\begin{aligned}[t] \sin x+\cos x=\tfrac{1}{2} &\iff \sqrt{2}\left(\tfrac{\sqrt{2}}{2} \sin x+\tfrac{\sqrt{2}}{2} \cos x\right)=\tfrac{1}{2}\\ &\iff \cos \left(x-\tfrac{\pi}{4}\right)=\tfrac{1}{2 \sqrt{2}}=\tfrac{\sqrt{2}}{4} \iff x=\tfrac{\pi}{4} \pm \arccos \tfrac{\sqrt{2}}{4}+2 k \pi \end{aligned}\]

Autre méthode : si $y=1/2$ alors l'équation de départ devient $2-8\sin x \cos x = 5$
ou encore $2\sin x \cos x = -3/4$. Puisque $\sin \left(2x \right) = 2\sin x \cos x$, il suffit de résoudre l'équation trigonométrique de base $\sin \left(2x\right) = -3/4$. $$\begin{aligned}[t] \sin \left(2x\right) = -3/4 &\iff 2x = \begin{cases} \arcsin\left(-3/4\right)+2k\pi\\ \pi-\arcsin\left(-3/4\right)+2k\pi \end{cases}\\ &\iff x=\begin{cases} -\tfrac12\arcsin\tfrac34+k\pi\\ \tfrac{\pi}{2}+\tfrac12\arcsin\tfrac34+k\pi \end{cases} \end{aligned}$$

\(240 \cdot \tan \left(60 + \alpha\right) = 80 \cdot \tan 60 \iff \tan \alpha = -\dfrac{\sqrt{3}}{3} \iff \alpha = -30 ^\circ{}\)

\(\Delta B D O: h=\overline{D O} \cdot \tan (\alpha+\beta)=\overline{D O} \cdot \frac{\tan \alpha+\tan \beta}{1-\tan \alpha \tan \beta}\)

et \(\triangle A E O: h=\overline{E O} \cdot \tan \beta \Longrightarrow \tan \beta=\frac{h}{E O}\)

d'où : $h=69,01$m

\(\begin{aligned}[t] \sin 7 a-\sin 5 a-2 \cos 5 a \sin 2 a &=2 \sin a \cos 6 a-4 \cos 5 a \sin a \cos a \\ &=2 \sin a(\cos 6 a-2 \cos 5 a \cos a) \\ &=2 \sin a(\cos 6 a-(\cos 6 a+\cos 4 a)) \\ &=-2 \sin a \cos 4 a \\ &=-2\cos 4a \cos \left(\tfrac{\pi}{2}-a\right) \end{aligned}\)