What I've done is create two little functions (lambda functions) in this snippet to calculate the pythagorean distance and the SPL according to equation  in your ref.
Furthermore, because the directivity factor is something determined experimentally, I have simply used cosine here as a representative example. You could replace the Q function with a function that given a angle theta and distance r returns a intensity score given some interpolation of experimental results.
import matplotlib.pyplot as plt
from pylab import linspace, meshgrid, sqrt, log10, angle, cos
x = linspace(-30.0, 30.0, 15)
y = linspace(0, 30, 15)
X, Y = meshgrid(x, y)
#Z = sqrt(X**2 + Y**2)
def SPL(source_SPL, x, y, x1, y1, Q):
'''Given a source sound pressure level, the x and y vectors describing
the space, the x1 and y1 coordinates of the sound origin
and a directivity factor function, return the SPL matrix'''
#Using eqation 8 from the source
dist = lambda x1, x2, y1, y2: sqrt((x1-x2)**2 + (y1-y2)**2)
spl = lambda r, q: source_SPL - 20*log10(r) - 10*log10(q) - 11
spl_matrix = 
for y2 in y:
# Create a new row
for x2 in x:
r = dist(x1, x2, y1, y2)
theta = angle(complex(x2-x1, y2-y1))
q = Q(theta, r)/float(source_SPL)
# After calculating r and q, put them into the spl equation to get Db
Db = spl(r, q)
Q = lambda theta, r: r*abs(cos(theta))
Z = SPL(1, x, y, 0.1, 0.1, Q)
#Need to draw the contour twice, once for the lines (in 10 sections)
CS = plt.contour(Y, X, Z, 10, linewidths=0.5, colors='k')
#And again for the fills
CS = plt.contourf(Y, X, Z, 10)
Although I've solved this without using arrays, you should look into numpy and how to vectorise this code so that you aren't using loops but matrix operations. That isn't so much of a code problem as a math problem however.
Finally, if you have a background in engineering, you can run this experiment on the computer where the Q function calculates the relative intensity based on environmental conditions. You'll need to understand more how the sound interacts with the surroundings, you might want to google finite element analysis and sound pressure level