I could use some help figuring out collision response. I'm trying to implement what is presented in this paper on slides 4 to 10. Collision detection works, and the colliding entity **does** slide along the collision plane but with severely reduced speed. I'm not sure whether I'm properly projecting the leftover velocity on collision plane.

```
class CollisionPacket {
// INPUT:
colliderRadius: vec3;
colliderPosition: vec3;
colliderVelocity: vec3;
// OUTPUT:
collisionFound: bool;
collisionTime: number; // how far can we travel before we collide?
collisionPoint: vec3; // point on triangle where collision ocurred
collisionNormal: vec3; // normal of nearest collided triangle
}
collideAndSlide(position: vec3, velocity: vec3, radius: number): vec3 {
var packet = new CollisionPacket();
packet.colliderRadius = radius;
packet.colliderPosition = position;
packet.colliderVelocity = velocity;
packet.collisionTime = 0.0;
packet.collisionFound = false;
var maxIterations = 5;
do {
// check nearby triangles for collisions
this.collideWorld(packet);
var newPosition = packet.colliderPosition.copy();
var newVelocity = packet.colliderVelocity.copy();
if (packet.collisionFound) {
// scale velocity vector to collide with nearest triangle
var scaledVelocity = packet.colliderVelocity.copy().scale(packet.collisionTime);
// move a tiny bit away from collision along collision normal
scaledVelocity.add(packet.collisionNormal.copy().scale(0.001));
// add scaled velocity to position
newPosition.add(scaledVelocity);
// and remove it from leftover velocity
newVelocity.subtract(scaledVelocity);
// extract part of velocity vector which is perpendicular to collision plane (CORRECT?)
var v = packet.collisionNormal.copy().scale(vec3.dot(newVelocity, packet.collisionNormal));
// remove that part from velocity vector
newVelocity = vec3.difference(newVelocity, v);
// update values for next iteration
packet.colliderPosition = newPosition;
packet.colliderVelocity = newVelocity;
}
else {
// no collision, move as requested
newPosition.add(packet.colliderVelocity);
}
} while (--maxIterations > 0 && packet.collisionFound)
return newPosition;
}
```

I visualized both *v* and *newVelocity* after *v* has been subtracted from it and they look how they're supposed to: *v* is perpendicular to the collision plane, *newVelocity* runs parallel to it in the direction we're moving.

If I add *newVelocity* directly to *newPosition* instead of doing the recursion, like this:

```
...
// remove that part from velocity vector
newVelocity = vec3.difference(newVelocity, v);
newPosition.add(newVelocity);
}
else {
// no collision, move as requested
newPosition.add(packet.colliderVelocity);
}
} while (false)
```

the entity is sliding as it should, without being slowed down, so I'm quite sure the vectors are ok.

However, *maxIterations* always runs down to zero, so there's always collisions. maybe that's slowing it down?

Would someone with a better understanding of the underlying math have a look?

Thank you!

**EDIT:**

Illustration of the vectors after the first iteration:

The box is colliding against the wall (invisible on this screenshot due to backface culling)