I'm currently implementing the segmentation method proposed by Tsai for the trilevel case in an 8-bit image in Python 3.6. This is the code, considering the mathematical relations explained in the paper Annex:
### EXAMPLE GIVEN BY TSAI ###
# This is the "dummy" example described in the paper
img = np.array([[10, 8, 10, 9, 20, 21,32,30,40,41,41,40],
[12, 10, 11, 10, 19, 20, 30, 28, 38, 40, 40, 39],
[10, 9, 10, 8, 20, 21, 30, 29, 42, 40, 40, 39],
[11, 10, 9, 11, 19, 21, 31, 30, 40, 42,38, 40]])
bins_hist = list(range(0,257))
histogram = np.zeros((256,4)) # We generate the counts for each grey value, 3rd column probabilities and 4th column cumulative sum
histogram[:,0] = np.arange(256) # First column contains the intensity levels
hist_i = np.histogram(img, bins=bins_hist)
counts = hist_i[0]
histogram[:,1] = np.add(histogram[:,1], counts)
row, col = img.shape
total_voxels = row * col
histogram[:,2] = histogram[:,1]/total_voxels # Relative frequency at each GV
histogram[:,3] = np.cumsum(histogram[:,2]) # Cumulative of the relative frequency
### THRESHOLDS CALCULATION BEGIN ###
# 0 Moment = 1
m0 = 1.0
# 1st Moment
m1 = np.cumsum((histogram[:,0])*histogram[:,2])[-1]
# 2nd Moment
m2 = np.cumsum((histogram[:,0]**2)*histogram[:,2])[-1] # Take the last value
# 3rd Moment
m3 = np.cumsum((histogram[:,0]**3)*histogram[:,2])[-1]
# 4th Moment
m4 = np.cumsum((histogram[:,0]**4)*histogram[:,2])[-1]
# 5th Moment
m5 = np.cumsum((histogram[:,0]**5)*histogram[:,2])[-1]
# Now we must find the value in the binary image that preserves these moments
# We solve the equalities --> For solutions refer to Paper Annex A.2
cd = (m0*m2*m4) + (m1*m3*m2) + (m1*m3*m2) - (m2*m2*m2) - (m1*m1*m4) - (m3*m3*m0)
c0 = ((-m3*m2*m4) + (-m4*m3*m2) + (m1*m3*-m5) - (-m5*m2*m2) - (-m4*m1*m4) - (m3*m3*-m3)) / cd
c1 = ((m0*-m4*m4) + (m1*-m5*m2) + (-m3*m3*m2) - (m2*-m4*m2) - (m1*-m3*m4) - (-m5*m3*m0)) / cd
c2 = ((m0*m2*-m5) + (m1*m3*-m3) + (m1*-m4*m2) - (m2*m2*-m3) - (m1*m1*-m5) - (m3*-m4*m0)) /cd
a1 = c0/2 - c1*c2/6 + (c2**3)/27
a2 = (c0/2 - c1*c2/6 + (c2**3)/27)**2
a3 = (c1/3 - (c2**2)/9)**3
a = (a1 - cmath.sqrt(a2 + a3))**1/3
b = -(c1/3 - (c2**2)/9)/a
w1 = -0.5 + 1j * (math.sqrt(3)/2)
w2 = -0.5 - 1j * (math.sqrt(3)/2)
z0 = -c2/3 - a - b
z1 = -c2/3 - w1*a - w2*b
z2 = -c2/3 - w2*a - w1*b
pd = (z1*z2**2) + (z2*z0**2) + (z0*z1**2) - (z0**2*z1) - (z0*z2**2) - (z1**2*z2)
p0 = ((m0*z1*z2**2) + (m1*z1**2) + (z2*m2) - (m2*z1) - (m1*z2**2) - (z1**2*z2*m0)) /pd
p1 = ((m1*z2**2) + (z0*m2) + (m0*z2*z0**2) - (z0**2*m1) - (z0*m0*z2**2) - (m2*z2)) / pd # Fraction of the below-threshold pixels in the binary histogram
th1 = 0.0 # First threshold in the trimodal histogram
th2 = 0.0 # Second threshold
dist1 = 10000000
dist2 = 10000000
for i in range(254):
for j in range(i+1, 255):
# Select threshold --> closest to p0 from the normlaized histogram
p0_orig = histogram[i,3] # Take the cumulative relative frequency at the value p0
p1_orig = histogram[j, 3] - histogram[i,3]
dist_i = abs(p0 - p0_orig)
dist_j = abs(p1 - p1_orig)
if dist_i < dist1 and dist_j < dist2: # This one was the one mentioned by Tsai ("Minimize the distance")
print(i,j,dist_i, dist_j)
dist1 = dist_i
dist2 = dist_j
th1 = i
th2 = j
However, when I apply it to reproduce his results considering a "dummy" image described in Figure 1, I do not obtain the same threshold (in my case I get 12 and 29, instead of 18 and 30).
Does anybody have experience with this method and can help me figure out what's the problem with my code?