I'm assuming that you want the ball to hit that specific point (200,200) at the apex of its path. Well, my physics is a bit rusty, but this is what I've thrown together:

`v_y = square_root(2*g*y)`

,

where g is a positive number reflecting the acceleration due to gravity, and y being how high you want to go (200 in this case).

`v_x = (x*g) / v_y`

,

where x is how far in the x direction you want to go (200 in this case), g is as before, and Vy is the answer we got in the previous equation.

These equations remove the need for an angle. However, if you'd rather have the velocity + angle, that's simple:

`v0 = square_root(v_x^2 + v_y^2)`

and

`angle = arctan(v_y / v_x)`

.

Here is the derivation, if you're interested:

`(1/2)at^2 + v_yt + 0 = y`

`(1/2)at^2 + v_yt - y = 0`

by quadratic formula,

`t = (-v_y +/- square_root(v_y^2 - 2ay)) / a`

we also have another equation, because at the apex the vertical velocity is 0:

`0 = v_y + at`

substitute:

`0 = v_y + (-v_y +/- square_root(v_y^2 - 2ay))`

`0 = square_root(v_y^2 - 2ay)`

`0 = v_y^2 - 2ay`

`v_y = square_root(-2ay)`

, or

`v_y = square_root(2gy)`

For v_x:

`v_x*t = x`

from before, t = v_y / a, so

`v_x = (x*g)/v_y`

I hope that made enough sense.