# rotating coordinate system with time

I am not sure if this is the correct place for my question, but I'll give it a shot. I guess it is somewhere between CS and physics, but since I am programming this in C++, I'll post it here.

I am looking at a particle in 3D, which is being bent in the (x, y)-plane due to a force applied to it, as illustrated in the figure. The force is the bolded arrow entering from NE. The angle between the y-axis and the force is "a".

setup

The particle enters from the left with a velocity vector (v_x, v_y, v_z) and is bend around the corner. This is nicely and easily described by Newtons second law, no problems there. This is easy to solve numerically e.g. by an Euler method. This I have implemented succesfully, so far so good.

However as the figure suggests, the particle moves in a cylindrical tube of constant diameter h and I wish to find the normal distance to the wall in both the x- and z-direction (which points out of the screen) at some time t. By "normal distance" I mean that if the coordinate system rotates with the particle, then I want to know the distance from the particle to the edge of the tube along y and z (as illustrated with the 3 small arrows pointing towards the tube edge). The ultimate goal is somehow to figure out if the particle has hit the wall or not.

For the z-direction it is trivial as its axis does not change during the trajectory. However the y-direction is causing me huge problems. This is my question: Is there a way for me to find the distance to the tube edge along y during the trajectory? Note that I am doing this numerically, so I don't necessarily need an analytical expression.

Best, Niles.

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There are some details that are not very clear for me in your question: is the coordinate system centered in the particle, and the x vector follows the motion direction of the particle? (since you say that it "is rotating"). Also, the calculation will strongly depend on how you represent the path of the pipe... is it pixel-based? segment based? do you have some kind of parametric description? If you answer to this in your question, I will probably be able to help you :) –  dunadar Oct 18 '12 at 18:07
the system is centered around the center of the tube, so x would follow that as well (as the particle is moving). it is a circle, so i guess i can describe it parametrically. Tyler Durden's answer is quite helpful, it gives me what i want. thanks for taking the time to think about my problem. –  BillyJean Oct 19 '12 at 13:27