I wrote a small ray-tracing code. It's called forward ray-tracing, so rays are actually created at the source, travel to the one and only mirror and are reflected. Subsequently i calculate the intersection of each ray with a plane of my choice i call the detector. And what i get on the detector, printing each hit as a pixel, is a scatter plot of (x,y)'s. Like this one:
import matplotlib.pyplot as plt import numpy as np import random x = np.zeros(1000) y = np.zeros(1000) for i in range(len(x)): x[i] = random.random() y[i] = random.random() plt.plot(x,y,'k,') plt.show()
Now i'm looking for a way to represent the density distribution of the hits (the intensity) as a smooth image, like this one.
So the gray-scale of each pixel should correspond to the density in the surrounding patch. But everything that looks like what i need is for 3d-arrays like z=f(x,y).
Also tried hexbin(), but it's not smooth enough and for very small bins it gets too slow and only resembles what i have anyway.
So is there anything i could use?
I somehow need to add another dimension, because i'm interested in the parallelism of the incident rays. One option is to define it as follows:
- calculating a + a*b, where:
a = the angle between the incident ray and the detector normal
b = the angle between the incident ray and the y-z-plane (the rays are travelling roughly parallel to this plane)
mean value of this quantity
deviation from the mean value for each hit
I thought of incorporating both of these informations in one plot by adding colour to the gray-scale. Is this feasible?
I'm new to programming, any hint, explanation or alternative idea will be much appreciated.