I wish to know the best algorithm to be able to zoom to a screen space selection box/window in 3D.
I have it currently sort of working but it doesn't seem to zoom in correctly when the distance from the target is significant.
Currently it works by figuring out the scale of the selection box relative to the viewport width/height and applies that scale to the distance/range of the camera to it's target.
Actually it's not that simple. Look at this picture (it's a 2D projection for simplicity):
The blue area is the current camera's view frustum. The yellow area is a part of the blue frustum covered by the rectangular selection of the screen. The aim is to make a new frustum which best represents the yellow area. The problem is what way should the new frustum fit the yellow area.
One possibility is presented in the picture below:
The new camera's view frustum is coloured purple and the camera's eye lies on the green line. Assuming the new camera has the same properties (fovy, znear, zfar, aspect) as the old one, we can compute its new position and direction.
Now some calculations:
Height and width of the near plane:
h = 2 * tan(fovy/2) * znear
w = aspect * h
Screen-space coordinates of the rectangle:
rectangle = ( x0, y0, x1, y1 )
Screen-space center of the rectangle:
rcenter = ( (x0+x1)/2, (y0+y1)/2 )
Another image to clarify next calculations:
View-space vector lying on the near plane, pointing from the near plane's center to the rectangle's center:
center = ( (rcenter.x / screen_width - 0.5) * w,
(0.5 - rcenter.y / screen_height) * h, 0 )
Then we have to transform this vector to world-space:
centerWS = center.x * camera_right_dir + center.y * camera_up_dir
New direction of the camera (dir2n):
dir1 = camera_dir * znear
dir2 = dir1 + centerWS
dir2n = normalize(dir2)
New position of the camera (pos2):
I've made some assumptions, in order to simplify calculations. Approximately new and old near planes are parallel, so:
(w, h) / dist = (w * (x1-x0)/screen_width, h * (y1-y0)/screen_height) / znear
(1, 1) / dist = ( (x1-x0)/screen_width, (y1-y0)/screen_height) / znear
(1/dist, 1/dist) = ( (x1-x0)/screen_width, (y1-y0)/screen_height) / znear
Hence:
dist = znear * screen_width / (x1-x0)
Which should be equal to:
dist = znear * screen_height / (y1-y0)
That is true only if the rectangle has the same proportions as the screen, which you can guarantee by locking the rectangle's proportions while the user is drawing it, or you can simply use only the rectangle's width (x1-x0) and ignore its height (y1-y0) or vice versa.
Finally:
pos2 = pos1 + dir2n * (dist-znear)
What I understand is that you a rectangle drawn on screen to align with the window boundaries and have everything inside that rectangle zoom in.
If I am right, what we are trying to achieve here is to align the near-plane with the an imaginary plane on which the rectangle was drawn.
To do this, we have to play around with some trigonometry. Assuming we align top and bottom of the rectangle:
We should compute the height of the near plane as:
H = tan(fovy/2) * nearPlane; --------(1)
height of the drawn rectangle on near plane:
fraction = WindowHeight / rectangle height;
h = H * fraction; ---------(2)
To align near plane with the imaginary plane, camera must move forward.
Assume D is the distance to move forward, then by geometry,
h / nearPlane = H / (nearPlane+D) --------(3)
Using equation(2), equation (3) can be reduce as:
fraction / nearPlane = 1 / (nearPlane+D)
which gives D as:
D = (nearPlane / fraction) - nearPlane;
or
D = nearPlane * (1-fraction)/fraction;
Now move camera forward by D. and that should do it.
If the rectangle was not center aligned, computation is slightly more complex.
