Can we solve the system of equations:
$\sin \alpha + \sin \beta + \sin \gamma = 0$
$\cos \alpha + \cos \beta + \cos \gamma = 0$
?
(i.e. find the possible values of $\alpha, \beta, \gamma$)
Can we solve the system of equations:
$\sin \alpha + \sin \beta + \sin \gamma = 0$
$\cos \alpha + \cos \beta + \cos \gamma = 0$
?
(i.e. find the possible values of $\alpha, \beta, \gamma$)
Try something similar to what has been posted yet. Take one variable to the other side, then square and add the equations. What you get is \alpha-\beta=120° and same for cyclic permutations (or negating all angles). The solutions is the three angles $\delta$, \delta+120°, \delta-120° (arbitrary $\delta$) in any order.
EDIT: Or simply realize that the equations are equivalent to $\exp(i\alpha)+\exp(i\beta)+\exp(i\gamma)=0$ which make the answer immediately obvious.
Developing on Gerenuk's answer, you could consider the complex numbers
$ z_1=\cos \alpha+i\sin \alpha,\ z_2=\cos \beta+i\sin\beta,\ z_3=\cos \gamma+i\sin \gamma$
Then you know that $z_1,z_2,z_3$ are on the unit circle, and the centroid of the triangle formed by the points of afixes $z_i$ is of afix $\frac{z_1+z_2+z_3}{3}=0$. From classical geometry, we can see that if the centroid of a triangle is the same as the center of the circumscribed circle, then the triangle is equilateral. This proves that $\alpha,\beta,\gamma$ are of the form $\theta,\theta+\frac{2\pi}{3},\theta+\frac{4\pi}{3}$.
Try writing $ \sin^2(\alpha)=(\sin(\beta)+\sin(\gamma))^2=\sin^2(\beta)+\sin^2(\gamma)+2\sin(\beta)\sin(\gamma)\tag{1} $ and $ \cos^2(\alpha)=(\cos(\beta)+\cos(\gamma))^2=\cos^2(\beta)+\cos^2(\gamma)+2\cos(\beta)\cos(\gamma)\tag{2} $ then add $(1)$ and $(2)$ to get $ 1=1+1+2\cos(\beta-\gamma)\tag{3} $ which means $\cos(\beta-\gamma)=-\frac12$. The same is true for the other pairs, so we get that each of $\alpha$, $\beta$, and $\gamma$ differ from each other by $\frac{2\pi}{3}$, which is the same answer that was achieved using complex means already.
Here's an algebraic proof : Write $z_k = e^{i \alpha_k}$. Then your equations are equivalent to $z_1 + z_2 + z_3 = 0$. Write $\theta = \frac{\alpha_1 + \alpha_2 + \alpha_3}{3}$ and $z = e^{i \theta}$
Expand the polynomial $P = (X-z_1)(X-z_2)(X-z_3)$. The $X^2$ term is $0$ by hypothetis, and the $X$ term can be written as $z_1 z_2 z_3 (z_1^* + z_2^* + z_3^*) = 0$. So $P = X^3 - z_1 z_2 z_3 = X^3 - z^3$. So the roots are $z . e^{2i k \pi /3}$.
More of a comment and less of an answer!
Well, your information seems to tell us that,
$\cos(\alpha-\beta)+\cos(\beta-\gamma)+\cos(\alpha-\gamma)=-\dfrac{3}{2}$
(To see this, square both equalities and add.)
I don't see any other obvious thing, you can do with these equations. If any thought plops up, I will type it in here.