You can use `skimage.transform.ProjectiveTransform`

from `scikit-image`

to transform coordinates inside your quadrilateral into the local square space [0, 1] × [0, 1].

For more info on how to apply linear algebra to solve this problem, see `ProjectiveTransform.estimate`

or "Projective Mappings for Image Warping" by Paul Heckbert, 1999.

Suppose you have the corners of your quadrilateral *in clockwise order*:

```
bottom_left = [58.6539, 31.512]
top_left = [27.8129, 127.462]
top_right = [158.03, 248.769]
bottom_right = [216.971, 84.2843]
```

We instantiate a `ProjectiveTransform`

and ask it to find the projective transformation mapping points inside the quadrilateral to the unit square:

```
from skimage.transform import ProjectiveTransform
t = ProjectiveTransform()
src = np.asarray(
[bottom_left, top_left, top_right, bottom_right])
dst = np.asarray([[0, 0], [0, 1], [1, 1], [1, 0]])
if not t.estimate(src, dst): raise Exception("estimate failed")
```

Now, the transformation `t`

is ready to transform your points into the unit square. Of course, by changing `dst`

above, you can scale to a different rectangle than the unit square (or even to an entirely different quadrilateral).

```
data = np.asarray([
[69.1216, 51.7061], [72.7985, 73.2601], [75.9628, 91.8095],
[79.7145, 113.802], [83.239, 134.463], [86.6833, 154.654],
[88.1241, 163.1], [97.4201, 139.948], [107.048, 115.969],
[115.441, 95.0656], [124.448, 72.6333], [129.132, 98.6293],
[133.294, 121.731], [139.306, 155.095], [143.784, 179.948],
[147.458, 200.341], [149.872, 213.737], [151.862, 224.782],
])
data_local = t(data)
```

We plot the input data and the transformed data to see the transformation working:

```
import matplotlib.pyplot as plt
plt.figure()
plt.plot(src[[0,1,2,3,0], 0], src[[0,1,2,3,0], 1], '-')
plt.plot(data.T[0], data.T[1], 'o')
plt.figure()
plt.plot(dst.T[0], dst.T[1], '-')
plt.plot(data_local.T[0], data_local.T[1], 'o')
plt.show()
```