I am attempting to plot a distribution:
This is the temperature distribution inside of a sphere of radius (a) whose upper hemisphere is held at T=1 and lower hemisphere is held at T=0 (ignore the discontinuity at the boundary between the two hemispheres) and P_l are the Legendre polynomials of the first kind.
import pylab as pl from scipy.special import eval_legendre as Leg import math,sys def sumTerm(a,r,theta,l): """ Compute term of sum given radius of sphere (a), y and z coordinates, and the current index of the Legendre polynomials (l) over the entire range where these polynomials are orthogonal [-1,1]. """ xRange = pl.arange(-0.99,1.0,0.01) x = pl.cos(theta) # correct for scipy handling negative indices incorrectly lLow = l-1 lHigh = l+1 if lLow < 0: lLow = -lLow-1 return 0.5*((r/a)**l)*Leg(l,x)*(Leg(lLow,0)-Leg(lHigh,0)) def main(): n = 10 # number of l terms to expand to a = 1.0 # radius of sphere # generate r, theta values aBins = pl.linspace(0, 2*pl.pi, 360) # 0 to 360 in steps of 360/N. rBins = pl.linspace(0, 1, 50) theta,r = pl.meshgrid(aBins, rBins) tempProfile = pl.zeros([50,360]) for nr,ri in enumerate(rBins): for nt,ti in enumerate(aBins): temp = 0.0 for l in range(n): temp += sumTerm(a, ri, ti, l) tempProfile[nr,nt] = temp # plot the Temperature profile pl.imshow(tempProfile) pl.colorbar() pl.axes().set_aspect('equal') pl.show() if __name__=='__main__': main()
This yields the following plot:
This looks good, but how can I display this in polar coordinates?