I have a pretty rudimentary physics engine in the game I'm working on, between moving, cylindrical characters, and static meshes made of triangles. The intended behavior is for characters to slide across surfaces, and in most cases, it works fine. But the engine doesn't discriminate between a head-on collision and a glancing collision.
I'm not entirely sure what information I could give that would be helpful. I'm looking for a mathematical solution, at any rate, a method to determine the 'angle of contact' between an arbitrary cylinder and triangle. My instincts, or whatever, tell me that I need to find the point of contact between the triangle and the cylinder, then determine whether that point is within the triangle (Using the triangle's regular normal) or along one of its edges (Using the angle between the point of contact and some point on the cylinder, I'm not sure which.), but I'm sure there's a better solution.
As requested, here's a couple of examples. In this first image, a cylinder travels downwards towards a triangle (In this example, the triangle is vertical, simplified to a line.) I project the velocity vector onto the plane of the triangle, using the formula Vf = V - N * (dot(V,N))
. This is the intended behavior for this type of collision.
In this image, the cylinder's axis is parallel with the normal of the triangle. Under the current implementation, Vf is still determined using the triangle's natural normal, which would cause the cylinder to begin moving vertically. Under intended behavior, N would be perpendicular to the colliding edge of the triangle.
But these are just the two extremes of collision. There are going to be a bunch of in-betweens, so I need a more arbitrary solution.
This is my attempt at a more 3D example. I apologize for the poor perspective. The bottom-most vertex in this triangle is closer to the 'camera'. The point of collision between the cylinder and the triangle is marked by the red X. Under intended behavior, if the cylinder was moving directly away from the camera, it would slide to the left, along the length of the triangle's edge. No vertical movement would be imparted, as the point of contact is along the cylinder's, uh, tube section, rather than the caps.
Under current behavior, the triangle's normal is used. The cylinder would be pushed upwards, as though sliding across the face of the triangle, while doing little to prevent movement into the triangle.
I understand that this is a difficult request, so I appreciate the suggestions made to help refine my question.