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Question 4 Exercise 8.2: 16 Hits, Last modified: 5 months ago; ta<\dfrac{\pi}{2}$, i.e. $\theta$ lies in QI. We have $$\sin\theta = \pm \sqrt{1-\cos^2}.$$ Since $\the... }. \end{align*} (d) $\sin \dfrac{\theta}{2}$ We have $$\sin\left(\frac{\theta}{2} \right) = \pm \sqrt{... }} \end{align*} (e) $\cos \dfrac{\theta}{2}$ We have $$\cos\left(\frac{\theta}{2} \right) = \pm \sqrt{... ac{3\pi}{2}\), i.e., $\theta$ lies in QIII. We have: \begin{align*} \sec \theta &= \pm \sqrt{1+tan^2
Question 5 Exercise 8.2: 8 Hits, Last modified: 5 months ago; in 2\theta=\dfrac{24}{25}$, $2\theta$ in QII. We have $$\cos 2\theta = \pm \sqrt{1-\sin^2 2\theta}$$ S... c{49}{625}} = -\frac{7}{25} \end{align*} Also we have $$\sin\theta = \pm \sqrt{\frac{1-\cos 2\theta}{2}... dfrac{7}{25}\) and $2\theta$ lies in QIII. We have: \[\sin 2\theta = \pm \sqrt{1 - \cos^2 2\theta}\... 76}{625}} = -\frac{24}{25}. \end{align*} Also, we have: \[ \sin\theta = \pm \sqrt{\frac{1 - \cos 2\the
Question 6 Exercise 8.2: 7 Hits, Last modified: 5 months ago; 15^{\circ} \cos 15^{\circ}$ ** Solution. ** We have double-angle identity: $$\sin 2 \theta = 2\sin\th... \circ}-\sin ^{2} 15^{\circ}$ ** Solution. ** We have double-angle identity: $$\cos^2\theta -\sin^2\the... 2}\left(\frac{\pi}{8}\right)$ ** Solution. ** We have a double-angle identity: $$\cos 2\alpha = 1-2\sin... =\cos 2\alpha.$$ Put $\alpha= \dfrac{\pi}{8}$, we have \begin{align*} 1-2\sin^2 \left(\frac{\pi}{8}\righ
Question 9, Exercise 8.1: 3 Hits, Last modified: 5 months ago; $\beta$ is obtuse angle, i.e. it is in QII.\\ We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp... $\beta$ is obtuse angle, i.e. it is in QII.\\ We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp... $\beta$ is obtuse angle, i.e. it is in QII.\\ We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp
Question 2, Review Exercise: 3 Hits, Last modified: 5 months ago; s\pi >0$, thus $$\cos \phi=\frac{12}{13}$$ As, we have \begin{align*} \sin(\theta -\phi)&=\sin \theta \c... an \phi & = \frac{5}{12} \end{align*} Finally, we have \begin{align*} \tan(\theta - \phi) &= \frac{\tan ... an \phi & = \frac{5}{12} \end{align*} Finally, we have \begin{align*} \tan(\theta + \phi) &= \frac{\tan
Question 5 and 6, Exercise 8.1: 2 Hits, Last modified: 5 months ago; tan \beta=-\dfrac{5}{12}$, $\beta$ is in QII. We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp... \cot\beta=\dfrac{15}{8}$, $\beta$ is in QIII. We have an identity: $$\sin \alpha=\pm \sqrt{1-\cos^2\alp
Question 3, Exercise 8.1: 1 Hits, Last modified: 5 months ago; \\ &= \dfrac{\sqrt{3}}{2}. \end{align*} Also, we have \begin{align*} \cos 120^{\circ} & = \cos \left(18
Question 7, Exercise 8.1: 1 Hits, Last modified: 5 months ago; where $\beta$ is acute angle, i.e. is in QI. We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp
Question 10, Exercise 8.1: 1 Hits, Last modified: 5 months ago; \end{align*} Combining L.H.S with (1) and (2), we have $$\tan \left(\gamma+\frac{\pi}{4}\right)=\frac{1+
Question 14, Exercise 8.1: 1 Hits, Last modified: 5 months ago; e $\alpha$ with the ground as shown in figure, we have \begin{align*} &\tan\alpha = \frac{\overline{BC}}
Question 1, 2 and 3 Exercise 8.2: 1 Hits, Last modified: 5 months ago; en: $\sin \alpha=y$ and $\alpha$ lies in QII. We have an identity: $$\cos \alpha = \pm \sqrt{1-\sin^2 \