# Build up and plot Matplotlib 2d histogram in polar coordinates using the Legendre Polynomials

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?

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Your code doesn't run. You need to `import numpy as np` and define `gs` somewhere –  Mr E Oct 8 '13 at 13:35
yeah, sorry this is an amalgamation of the code that worked to plot things in Cartesian (not that I want) and what I could find on SO that plotted 2d histograms in polar coordinates. The plotting calls are going to throw errors as well. I apologize for the sloppy code (embarassing) but I thought that someone may know right off hand how to do something similar. I will also gladly accept any examples where someone has built up any other distribution. –  MaxGraves Oct 8 '13 at 13:43

Ok, so I figured it out. Here is my solution (I feel strange giving my own solution to this).

``````# =============================================================================
# Plot central cross-section of sphere under steady-state conditions
# where the temperature on upper hemisphere is T=T_0 and the lower
# hemisphere is held at T=0.  This is an expansion in Legendre polynomials.
#
# Author:           Max Graves
# Last Revised:     8-OCT-2013
# =============================================================================

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 = 20      # 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):
print nr
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
fig, ax = pl.subplots(subplot_kw=dict(projection='polar'))
pax = ax.pcolormesh(theta, r, tempProfile)
ax.set_theta_zero_location("N") # 'north' location for theta=0
ax.set_theta_direction(-1)      # angles increase clockwise
fig.colorbar(pax)

pl.show()

if __name__=='__main__':
main()
``````

which yields the following plot:

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