**In case somebody else is interested here is what I came up**

To use the example of Berkeley admission in the paper one first need to standardized the values (to equate margins) using iterative proportional fitting

```
def ContTableIPFP(x1ContTable):
''' poor man IPFP
compute iterative proportional fitting for
a 2 X 2 contingency table
Input :
a 2x2 contingency table as numpy array
Output :
numpy array with values standarized to equate margins
'''
import numpy as np
#Margins
xSumRows = np.sum(x1ContTable, axis = 0).tolist()
xSumCols = np.sum(x1ContTable, axis = 1).tolist()
# Seed
xq0 = x1ContTable/x1ContTable
# Iteration 1 : we adjust by row sums (i.e. using the sums of the columns)
xq1 = np.array([
(xq0[0] * xSumCols[0]).astype(float) / np.sum(xq0, axis = 0).tolist()[0],
(xq0[1] * xSumCols[1]).astype(float) / np.sum(xq0, axis = 0).tolist()[1],
]
)
#Iteration 2 : adjust by columns (i.e. using sums of rows)
xq2 = np.array([
(xq1[:,0] * xSumRows[0]).astype(float) / np.sum(xq1, axis = 0).tolist()[0],
(xq1[:,1] * xSumRows[1]).astype(float) / np.sum(xq1, axis = 0).tolist()[1],
]
)
return xq2.T
```

and then plot

```
def FourfoldDisplay(radii):
''' radii = [10, 15, 20, 25]
'''
import numpy as np
import matplotlib.pyplot as plt
# Value - width
width = np.pi/ 2
# angle of each bar
theta = np.radians([0,90,180,270])
ax = plt.subplot(111, polar=True)
bars = ax.bar(theta, radii, width=width, alpha=0.5)
#labels
ax.set_xticklabels([])
ax.set_yticks([])
#plt.axis('off')
plt.show()
```

**to use**

```
import numpy as np
x1 = np.array([
[1198, 1493],
[557, 1278]
])
x2 = ContTableIPFP(x1).flatten()
FourfoldDisplay(x2)
```