I am creating a 3D graphics engine and one of the requirements is ropes that behave like in Valve's source engine.

So in the source engine, a section of rope is a quad that rotates along it's direction axis to face the camera, so if the section of rope is in the +Z direction, it will rotate along the Z axis so it's face is facing the camera's centre position.

At the moment, I have the sections of ropes defined, so I can have a nice curved rope, but now I'm trying to construct the matrix that will rotate it along it's direction vector.

I already have a matrix for rendering billboard sprites based on this billboarding technique: Constructing a Billboard Matrix And at the moment I've been trying to retool it so that Right, Up, Forward vector match the rope segment's direction vector.

My rope is made up of multiple sections, each section is a rectangle made up of two triangles, as I said above, I can get the position and sections perfect, it's the rotating to face the camera that's causing me a lot of problems.

This is in OpenGL ES2 and written in C.

I have studied Doom 3's beam rendering code in Model_beam.cpp, the method used there is to calculate the offset based on normals rather than using matrices, so I have created a similar technique in my C code and it sort of works, at least it, works as much as I need it to right now.

So for those who are also trying to figure this one out, use the cross-product of the mid-point of the rope against the camera position, normalise that and then multiply it to how wide you want the rope to be, then when constructing the vertices, offset each vertex in either + or - direction of the resulting vector.

Further help would be great though as this is not perfect!

Thank you

`N`

, and the vector along the rectangle's axis be`V`

. Then,`VxN`

will give you the third vector`U`

, with`U`

and`N`

forming a "horizontal plane" relative to your rope section. Now compute`EyePos - C`

(where`C`

is the centroid of your rectangle) and normalize it to get`E`

, the camera direction. Project`E`

onto the`UN`

plane to get`E'`

. Finally, the rotation you want (about the axis`V`

) is`arccos(N . E')`

. – Rahul Banerjee Apr 9 '13 at 10:30