# Infinite cone surface * AABB intersection testing

I'm trying to discover a faster algorithm for testing whether an axis-aligned conical surface intersects the volume of an axis-aligned bounding box.

The current algorithm I developed is as follows:

• x = 0
• For each of any 4 parallel edges of the AABB:
• Intersect its line with the cone.
• If the intersection point is within the AABB:
• Return true.
• If the intersection point is on a specific side of the AABB:
• x += 1
• If x == 0 or x == 4 (all the intersections were on one side of the AABB):
• Return false.
• Return true.

Can anyone think of a more efficient one? This seems to do a lot of extra work by computing each line intersection.

EDIT:

Above algorithm is bad, for example:

The cone can intersect only one edge of the box in a way that all the axis-line intersections are on one side, so the above algorithm doesn't work unless all edges are tested or the edges to be tested are intelligently chosen (maybe the edges closest to the cone?).

EDIT EDIT: See my own answer below for the solution I later discovered, which seems nearly optimal to me.

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Somewhat obviously, it's often faster to check a bounding sphere (in this case, of the box) first. –  sje397 Dec 8 '10 at 6:16
Also - wouldn't it be possible for your algorithm to fail - e.g. if the point of the cone pierced only one face and no box edges intersected? –  sje397 Dec 8 '10 at 6:18
Among other reasons (see above), yes. –  Forrest Voight Dec 8 '10 at 6:21

I found another, possibly optimal solution:

Background: The equation for a unit right cone opening along the +-z axis is x^2 + y^2 - z^2 = 0

Find the maximum and minimum of x^2 + y^2 - z^2 over the AABB. Hint: For x^2, the minimum is clamp(0, xmin, xmax)^2 and the maximum is max(xmin^2, xmax^2).

• If the resulting interval is completely negative, the box is completely inside the cone.
• If the resulting interval contains 0, the box intersects the surface of the cone.
• If the resulting interval is completely positive, the box is completely outside of the cone.
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Some optimizations are possible, such as expanding the calculations to do an early escape by only computing the upper or lower limit, and using that to return completely inside or completely outside. In fact, if only a true/false result is desired, only the calculation of the lower limit is required. –  Forrest Voight Dec 18 '10 at 17:46

I have found a better solution with the assistance of piman on #gamedev:

Do a rect-circle test between both the top and bottom faces of the AABB along the cone's axis with the circle the cone makes on their plane.

If both rectangles are outside, the AABB is outside the cone.

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The link to the David Eberly article from @Gareth Rees is a good one, but if you split everything into triangles, you'll end up checking redundant vertices and edges. I think this will work well:

1. (Optional) Check if the AABB is entirely on the opposite side of the plane perpendicular to the cone axis. If so, there's no intersection.

2. Check each of the 8 vertices to see if it's inside the cone. If any vertex is, the cone and AABB intersect. This is pretty straighforward, but it's explained on page 4 of the link.

3. Check each of the 12 edges to see if they intersect the cone. If any edge does, the cone and AABB intersect. This is on pages 4-5 of the link.

4. Check each of the 6 faces to see if they intersect the cone. If any edge does, the cone and AABB intersect. It's sufficient to the check ray formed by the cone axis against the AABB; this is a pretty standard intersection test.

It may actually be better to swap the order the face and edge checks; I'd expect the face checks to be faster that the edge ones, so you might be able to exit earlier.

There are probably some nice opportunities for SIMD optimizations since the numbers of vertices and edges are both multiples of 4 and the cone is axis-aligned, but that's beyond the scope of this answer :)

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