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Question 2, Exercise 10.3: 6 Hits, Last modified: 5 months ago; c }}+\sin {{43}^{\circ }}.$$ ====Solution==== We have an identity: $$\sin \alpha +\sin \beta =2\sin \le... ht)\end{align} Since $cos(-\theta)=cos\theta$, we have $$\sin {{37}^{\circ }}+\sin {{43}^{\circ }}=2\sin... rc }}-\cos {{82}^{\circ }}$. ====Solution==== We have an identity: $$\cos \alpha -\cos \beta =-2\sin \l... &=-2\sin(59^\circ)\sin(-23^\circ) \end{align} We have $\sin(-\theta)=-\sin\theta$, therefore $$\cos {{3
Question 13, Exercise 10.1: 4 Hits, Last modified: 5 months ago; rphi =\dfrac{3}{5}.\end{align} Thus, from (1), we have \begin{align}&4\sin\theta +3\cos\theta \\ &=5 \le... phi =\dfrac{8}{17}.\end{align} Thus, from (1), we have \begin{align}&15\sin\theta +8\cos\theta \\ &=17 \... rac{-5}{\sqrt{29}}.\end{align} Thus, from (1), we have \begin{align}&2\sin\theta -5\cos\theta \\ &=\sqrt... dfrac{1}{\sqrt{2}}.\end{align} Thus, from (1), we have \begin{align}&\sin\theta+\cos\theta \\ &=\sqrt{2}
Question 2, Exercise 10.2: 4 Hits, Last modified: 5 months ago; $\implies \cos\theta = -\dfrac{12}{13}$$ Thus, we have the following by using double angle identities: \... $\implies \cos\theta = -\dfrac{12}{13}$$ Thus, we have the following by using double angle identities: \... $\implies \cos\theta = -\dfrac{12}{13}$$ Thus, we have the following by using double angle identities: Thus, we have the following by using double angle identities. \
Question 1, Exercise 10.3: 4 Hits, Last modified: 5 months ago; difference $2\sin 6x\sin x$. ====Solution==== We have an identity: $$-2\sin \alpha \sin \beta =\cos (\a... rc }}\cos {{123}^{\circ }}$. ====Solution==== We have an identity: $$2\sin \alpha \cos \beta =\sin (\a... +B}{2}\cos \dfrac{A-B}{2}.$$ ====Solution==== We have an identity: $$2\sin \alpha \cos \beta =\sin (\... +Q}{2}\cos \dfrac{P-Q}{2}.$$ ====Solution==== We have an identity: $$2\cos \alpha \cos \beta =\cos \le
Question, Exercise 10.1: 3 Hits, Last modified: 5 months ago; =-\dfrac{12}{13}$, $\beta$ is in 2nd quadrant. We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp... -\dfrac{12}{13}$, $\beta$ is in 2nd quadrant. We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp... -\dfrac{12}{13}$, $\beta$ is in 2nd quadrant. We have an identity: $$\cos \alpha=\pm \sqrt{1-\sin^2\alp
Question 3, Exercise 10.2: 2 Hits, Last modified: 5 months ago; We find: $\cos \theta =-\dfrac{3}{5}$. Thus, we have the following by using double angle identity: \be... We find: $\cos \theta =-\dfrac{3}{5}$. Thus, we have the following by using half angle identities: \be
Question 4 and 5, Exercise 10.2: 2 Hits, Last modified: 5 months ago; \pi }{3}$.\\ By using double angle identities, we have \begin{align}\sin 2\theta &=2\sin \theta \cos \th... \pi }{3}$ \\ By using double angle identities, we have \begin{align}\cos 2\theta &=2{{\cos }^{2}}\theta
Question 5, Exercise 10.3: 2 Hits, Last modified: 5 months ago; ac{4\pi }{9}=\dfrac{3}{16}.$$ ====Solution==== We have an identities: $$2\sin \alpha \sin \beta =\cos \l... 70}^{\circ }}=\dfrac{1}{16}$. ====Solution==== We have an identities: $$2\sin \alpha \sin \beta =\cos \l
Question 1, Exercise 10.2: 1 Hits, Last modified: 5 months ago; d $\cos \theta =\dfrac{-5}{\sqrt{26}}$ Thus, we have the following by using double angle identities. \
Question 3, Exercise 10.3: 1 Hits, Last modified: 5 months ago; {{15}^{\circ }}}=\sqrt{3}.$$ ====Solution==== We have identities: $$\cos \alpha +\cos \beta =2\cos \lef