First, read the image via

```
from scipy.misc import imread
im = imread("thefile.png")
```

This gives a 3D numpy array with the third dimension being the color channels (RGB+alpha). The curve is in the blue channel, but the grid is there also. But in the red channel, you have the grid and not the curve. So we use

```
a = im[:,:,2] - im[:,:,0]
```

Now, we want the position of the maximum along each column. With one pixel precision, it is given by

```
y0 = np.argmax(a, axis=0)
```

The result of this is zero when there is no blue curve in the column , i.e. outside the frame. On can get the limits of the frame by

```
xmin, xmax = np.where(y0>0)[0][[0,-1]
```

With this, you may be able to rescale x axis.

Then, you want subpixel resolution. Let us focus on a single column

```
f=a[:,x]
```

We use a single iteration of the Newton method to refine the position of an extrema

```
y1 = y0 - f'[y]/f''[y]
```

Note that we cannot iterate further because of the discreet sampling. Nontheless, we want a good approximation of the derivatives, so we will use a 5-point scheme for both.

```
coefprime = np.array([1,-8, 0, 8, -1], float)
coefsec = np.array([-1, 16, -30, 16, -1], float)
y1 = y0 - np.dot(f[y0-2:y0+3], coefprime)/np.dot(f[y0-2:y0+3], coefsec)
```

P.S. : Thorsten Kranz was faster than me (at least here), but my answer has the subpixel precision and my way of extracting the blue curve is probably more understandable.