Alright, i had this homework recently (don't worry, i've already done it, but in c++) but I got curious how i could do it in python. The problem is about 2 light sources that emit light. I won't get into details tho.
Here's the code (that I've managed to optimize a bit in the latter part):
import math, array import numpy as np from PIL import Image size = (800,800) width, height = size s1x = width * 1./8 s1y = height * 1./8 s2x = width * 7./8 s2y = height * 7./8 r,g,b = (255,255,255) arr = np.zeros((width,height,3)) hy = math.hypot print 'computing distances (%s by %s)'%size, for i in xrange(width): if i%(width/10)==0: print i, if i%20==0: print '.', for j in xrange(height): d1 = hy(i-s1x,j-s1y) d2 = hy(i-s2x,j-s2y) arr[i][j] = abs(d1-d2) print '' arr2 = np.zeros((width,height,3),dtype="uint8") for ld in [200,116,100,84,68,52,36,20,8,4,2]: print 'now computing image for ld = '+str(ld) arr2 *= 0 arr2 += abs(arr%ld-ld/2)*(r,g,b)/(ld/2) print 'saving image...' ar2img = Image.fromarray(arr2) ar2img.save('ld'+str(ld).rjust(4,'0')+'.png') print 'saved as ld'+str(ld).rjust(4,'0')+'.png'
I have managed to optimize most of it, but there's still a huge performance gap in the part with the 2 for-s, and I can't seem to think of a way to bypass that using common array operations... I'm open to suggestions :D
Edit: In response to Vlad's suggestion, I'll post the problem's details: There are 2 light sources, each emitting light as a sinusoidal wave: E1 = E0*sin(omega1*time+phi01) E2 = E0*sin(omega2*time+phi02) we consider omega1=omega2=omega=2*PI/T and phi01=phi02=phi0 for simplicity by considering x1 to be the distance from the first source of a point on the plane, the intensity of the light in that point is Ep1 = E0*sin(omega*time - 2*PI*x1/lambda + phi0) where lambda = speed of light * T (period of oscillation) Considering both light sources on the plane, the formula becomes Ep = 2*E0*cos(PI*(x2-x1)/lambda)*sin(omega*time - PI*(x2-x1)/lambda + phi0) and from that we could make out that the intensity of the light is maximum when (x2-x1)/lambda = (2*k) * PI/2 and minimum when (x2-x1)/lambda = (2*k+1) * PI/2 and varies in between, where k is an integer
For a given moment of time, given the coordinates of the light sources, and for a known lambda and E0, we had to make a program to draw how the light looks IMHO i think i optimized the problem as much as it could be done...