# Move camera to fit 3D scene

I'm looking for an algorithm to fit a bounding box inside a viewport (in my case a DirectX scene). I know about algorithms for centering a bounding sphere in a orthographic camera but would need the same for a bounding box and a perspective camera. I can not just change the FOV because this app has FOV as a user editable variable, so it must move the camera.

I have most of the data:

• I have the up-vector for the camera
• I have the center point of the bounding box
• I have the look-at vector (direction and distance) from the camera point to the box center
• I have projected the points on a plane perpendicular to the camera and retrieved the coefficients describing how much the max/min X and Y coords are within or outside the viewing plane.

Problems I have:

• Center of the bounding box isn't necessarily in the center of the viewport (that is, it's bounding rectangle after projection).
• Since the field of view "skew" the projection (see http://en.wikipedia.org/wiki/File:Perspective-foreshortening.svg) I cannot simply use the coefficients as a scale factor to move the camera because it will overshoot/undershoot the desired camera position

How do I find the camera position so that it fills the viewport as pixel perfect as possible (exception being if the aspect ratio is far from 1.0, it only needs to fill one of the screen axis)?

I've tried some other things:

• Using a bounding sphere and Tangent to find a scale factor to move the camera. This doesn't work well, because, it doesn't take into account the perspective projection, and secondly spheres are bad bounding volumes for my use because I have a lot of flat and long geometries.
• Iterating calls to the function to get a smaller and smaller error in the camera position. This has worked somewhat, but I can sometimes run into weird edge cases where the camera position overshoots too much and the error factor increases. Also, when doing this I didn't recenter the model based on the position of the bounding rectangle. I couldn't find a solid, robust way to do that reliably.

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There are many possible camera positions + orientations where the bounding box would fit inside the view frustum. But any procedure would select one specific camera position and orientation.

If you would consider bounding spheres, one solution could be to

• first change orientation to look at bounding sphere center
• then move back sufficiently (negative look direction) for bounding sphere to fit inside frustum

With bounding boxes you could consider an earlier step of first positioning the camera at perpendicular to the center of the largest (or smallest, whatever you prefer) cube face.

I have no experience with DirectX, but moving and changing the looking direction of the camera to center a certain point should be easy. The hard part is to do the math of deciding how far to move to view the object.

### Math

If you know the bounding size `s` of the object in world coordinates (we are not interested in pixels or camera coordinates, since those are dependent on your distance) from the orientation of the camera, you can compute the required distance `d` of the camera to the bounding shape if you know the x and y Field-Of-View angle `a` of the perspective projection.

``````     frustum      ------
------    *****          -
-----          *   *          |
-===     ) FOV a   *bounding box  | BB size s
camera -----          *   *          |
------    *****          -
------

|-------------------|
distance d
``````

So, the math is `tan(a/2) = (s/2) / d` => `d = (s/2) / tan(a/2)` Which will give you the distance the camera should be placed from the closest bounding surface.

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Just for clarification: S is the size along the longest axis and A is the FOV for the same axis (since FOV differs depending on aspect ratio)? –  Burre May 20 '10 at 14:55
Also: How do I easiest center the bounding rectangle? Unlike a bounding sphere, looking at the center of a bounding box does not produce a centered bounding rectangle, and due to the perspective, simply just measuring the offset of the bounding rectangle from screen coords does not give me a good scalar for moving the camera. –  Burre May 20 '10 at 15:01
first question: yes, that is correct. second question: that's why I proposed to just put the camera first directly perpendicular to one of the BB surfaces. From that position, that surface will (even with perspective) be the constraining BB shape. –  catchmeifyoutry May 20 '10 at 20:31
I wish I could give another upvote for the ascii art :) –  Wouter van Nifterick Oct 10 '10 at 19:34

Since you have a bounding box, you should have a basis describing it's orientation. It seems that you want to position the camera on the line coincident with the basis vector describing the smallest dimension of the box, then roll the camera so that the largest dimension is horizontal (assuming you have OBB and not AABB). This assumes that the aspect ratio is greater than 1.0; if not you'll want to use the vertical dimension.

What I would attempt:

1. Find the smallest box dimension.
2. Find the associated basis vector.
3. Scale the basis vector by the distance from the center of the box the camera should be. This distance is just `boxWidth / (2 * tan(horizontalFov / 2))`. Note that `boxWidth` is the width of the largest dimension of the box.
4. Place the camera at `boxCenter + scaledBasis` looking at the `boxCenter`.
5. Roll the camera if necessary to align the camera's up vector with the appropriate box basis vector.

Edit:

So I think what you're getting at is that you have the camera at an arbitrary position looking somewhere, and you have an AABB at another position. Without moving the camera to face a side of the box, you want to:

• Look at the center of the box
• Translate the camera along it's look vector so that the box takes the maximum amount of screen space

If this is the case you'll have a bit more work; here's what I suggest:

1. Rotate the camera to look at the center of the bounding box.
2. Project all the points of the box into screen space and find the min/max bounding box in screen space (you already have this).
3. Now `Unproject` two opposing corners of the screen space bounding box into world space. For a Z value use the closest world space points of your AABB to the camera.
4. This should get you a world space plane facing the camera positioned at the point on the AABB that is closest to the camera.
5. Now use our existing side-facing method to move the camera to the appropriate spot, treating this plane as the side of your box.
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The boxes are AABB, but that shouldn't really matter. I have the bounding rectangle as projected onto a plane perpendicular to the camera. It seems like you are trying to design around the problem by "hiding" the morphing done by the perspective matrix. Am I right? That solution wouldn't work for me. I need to view at it at the same angle as before the "zoom to fit" command. What I'm looking for is how to factor in the non-linear scaling of the bounding rect when I move along the Camera-Z. –  Burre May 20 '10 at 14:38
My answer is fundamentally the same as catchmeifyoutry's answer (our distance math is the exact same). Using our method the perspective is taken care of by positioning the camera at the proper distance from the side of the box. –  Ron Warholic May 20 '10 at 16:01
I agree with Ron, we basically suggested the same method. Adapted approaches are possible such as computing a new BB aligned with the camera's coordinate system, or what Ron suggested later (+1 for that). –  catchmeifyoutry May 20 '10 at 20:35
I like your idea of transforming the current AABB into camera space and constructing a camera-axis-aligned BB; this would reusing the existing AABB code and wouldn't necessitate hopping between screen space/back repeatedly. –  Ron Warholic May 20 '10 at 22:57
Yes, it looks like step 3 in the edit was what I was looking for. If I need to center the bounding rect (i.e by panning the camera) this shouldn't interfere with the Unproject, right? I will test this next week when at the office and mark this as the correct answer if it works. –  Burre May 21 '10 at 11:07

I don't have it at hand at the moment but the book you want is http://www.amazon.com/Jim-Blinns-Corner-Graphics-Pipeline/dp/1558603875/ref=ntt_at_ep_dpi_1

He has a whole chapter on this

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Thank you for your input. I have a crude implementation in place but will look into his version to see if it is a more elegant one. –  Burre Aug 4 '10 at 17:29

This is copied straight from my engine, it creates 6 planes which represent each of the six sides of the frutsum. I hope it comes in useful.

``````internal class BoundingFrustum
{
private readonly float4x4 matrix = new float4x4(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0);

internal BoundingFrustum(float4x4 value)
{
planes = new Plane[6];
for (int i = 0; i < 6; i++)
planes[i] = new Plane();
Setfloat4x4(value);
}

private void Setfloat4x4(float4x4 value)
{
planes[2].Normal.X = -value.M14 - value.M11;
planes[2].Normal.Y = -value.M24 - value.M21;
planes[2].Normal.Z = -value.M34 - value.M31;
planes[2].D = -value.M44 - value.M41;
planes[3].Normal.X = -value.M14 + value.M11;
planes[3].Normal.Y = -value.M24 + value.M21;
planes[3].Normal.Z = -value.M34 + value.M31;
planes[3].D = -value.M44 + value.M41;
planes[4].Normal.X = -value.M14 + value.M12;
planes[4].Normal.Y = -value.M24 + value.M22;
planes[4].Normal.Z = -value.M34 + value.M32;
planes[4].D = -value.M44 + value.M42;
planes[5].Normal.X = -value.M14 - value.M12;
planes[5].Normal.Y = -value.M24 - value.M22;
planes[5].Normal.Z = -value.M34 - value.M32;
planes[5].D = -value.M44 - value.M42;
planes[0].Normal.X = -value.M13;
planes[0].Normal.Y = -value.M23;
planes[0].Normal.Z = -value.M33;
planes[0].D = -value.M43;
planes[1].Normal.X = -value.M14 + value.M13;
planes[1].Normal.Y = -value.M24 + value.M23;
planes[1].Normal.Z = -value.M34 + value.M33;
planes[1].D = -value.M44 + value.M43;
for (int i = 0; i < 6; i++)
{
float num2 = planes[i].Normal.Length();
planes[i].Normal = planes[i].Normal / num2;
planes[i].D /= num2;
}
}

internal Plane Bottom
{
get { return planes[5]; }
}
internal Plane Far
{
get { return planes[1]; }
}
internal Plane Left
{
get { return planes[2]; }
}
internal Plane Near
{
get { return planes[0]; }
}
internal Plane Right
{
get { return planes[3]; }
}
internal Plane Top
{
get { return planes[4]; }
}
}
``````
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