How can I use (modify) Python code to find intersection of helix (x=Rcos(t), y=Rsin(t), z=a*t) with plane (n - normal vector of the plane and p0 - point on plane)? Thanks. In post '3D Line-Plane Intersection' there are answers how to do such thing for line defined by two points but I need solution for helix.
You'll need to solve the equation (h(t)-p0).n = 0, where h(t) is your helix.
The equation does not admit a easy analytic solution, but you can solve it numerically, with scipy for example:
import numpy as np from scipy import optimize n = np.array([nx, ny, nz]) p0 = np.array([p0x, p0y, p0z]) def h(t): return np.array([R*np.cos(t), R*np.sin(t), a*t]) res = optimize.minimize_scalar(lambda t: np.dot(h(t) - p0, n)) print(res.x)
If you don't have scipy/numpy, it's relatively easy to implement the Newton method in this specific situation (we can analytically compute the derivative of h(t)). Pure python version:
from math import cos, sin n = [nx, ny, nz] p0 = [p0x, p0y, p0z] def dot(a, b): return sum([x*y for x, y in zip(a, b)]) def h(t): return [R*cos(t), R*sin(t), a*t] def hp(t): # the derivative of h return [-R*sin(t), R*cos(t), a] def find_root_newton(x, f, fp, epsilon=1e-5): xn = x + 2*epsilon while(abs(xn - x) > epsilon): x = xn xn = x - f(x)/fp(x) return xn t = find_root_newton(0., lambda t: dot(h(t), n) - dot(p0, n), lambda t: dot(hp(t), n)) print(h(t))
It can fail if the axis of the helix is in the plane (in which case your problem is badly defined anyhow), and it's not really efficient.