**Parametric solutions**

Parametric solutions contain Numpy's Gradient function:

Return the gradient of an N-dimensional array.

The gradient is computed using second order accurate central
differences in the interior points and either first or second order
accurate one-sides (forward or backwards) differences at the
boundaries. The returned gradient hence has the same shape as the
input array. (docs)

where we focus on the differences explicitly with the interior points. For example, you could compute it directly by using the gradient function of numpy:

```
>>> data=[x for x in range(60)], [interests(n) for n in range(60)]
>>> np.gradient(data[1])
array([ 0. , 2.08767965, 6.27175575, 10.47330187,
14.69239096, 18.92909627, 23.18349133, 27.45565003,
31.74564653, 36.0535553 , 40.37945114, 44.72340914,
49.08550474, 53.46581365, 57.86441192, 62.28137592,
66.71678233, 71.17070816, 75.64323073, 80.13442769,
84.64437701, 89.17315698, 93.72084624, 98.28752374,
102.87326876, 107.47816091, 112.10228014, 116.74570672,
121.40852129, 126.09080477, 130.79263848, 135.51410403,
140.25528339, 145.01625888, 149.79711316, 154.59792922,
159.41879041, 164.25978043, 169.12098332, 174.00248348,
178.90436566, 183.82671495, 188.76961683, 193.73315709,
198.71742192, 203.72249785, 208.74847176, 213.79543092,
218.86346295, 223.95265584, 229.06309793, 234.19487796,
239.34808501, 244.52280855, 249.71913842, 254.93716484,
260.17697839, 265.43867004, 270.72233115, 273.36966551])
```

where you can see the monthly additional interest. You could `np.gradient(data[1], 2)`

would give you the second derivative here.

**More-non-parametric solutions and end-to-end approaches**

More non-parametric solutions contain Bayesian approaches: the original data points are prior points with uncertainty and the result is the posterior values.

https://github.com/HIPS/autograd

ftp://ftp.tuebingen.mpg.de/pub/kyb/antonio/pub/ebio/chrisd/GPtutorial.pdf

http://scikit-learn.org/stable/auto_examples/gaussian_process/plot_gpr_noisy_targets.html

Gaussian Processes For Machine Learning

I leave this section open, perhaps there is some expert to explain them in Python. And which kind of solutions exist to compute the differentials with the points robustly.