# Model measurement and error in NumPy

I'd like to try the SciPy suite instead of Octave for doing the statistics in my lab experiments. Most of my questions were answered here, there is just another thing left:

I usually have an error attached to the measurements, in Octave I just did the following:

``````R.val = 10;
R.err = 0.1;

U.val = 4;
U.err = 0.1;
``````

And then I would calculate `I` with it like so:

``````I.val = U.val / R.val;
I.err = sqrt(
(1 / R.val * U.err)^2
+ (U.val / R.val^2 * R.err)^2
);
``````

When I had a bunch of measurements, I usually used a structure array, like this:

``````R(0).val = 1;
R(0).err = 0.1;
…
R(15).val = 100;
R(15).err = 9;
``````

Then I could do `R(0).val` or directly access all of them using `R.val` and I had a column vector with all the values, for `mean(R.val)` for instance.

How could I represent this using SciPy/NumPy/Python?

-

The easiest is indeed to use NumPy structured arrays, that give you the possibility to define arrays of homogeneous elements (a record) composed of other homogeneous elements (fields).

For example, you could define

``````R = np.empty(15, dtype=[('val',float),('err',float)])
``````

and then fill the corresponding columns:

``````R['val'] = ...
R['err'] = ...
``````

Alternatively, you could define the array at once if you have your `val` and `err` in two lists:

``````R = np.array(zip(val_list, err_list), dtype=[('val',float),('err',float)])
``````

In both cases, you can access individual elements by indices, like `R[0]` (which would give you a specific object, a `np.void`, that still gives you the possibility to access the fields separately), or by slices `R[1:-1]`...

With your example, you could do:

``````I = np.empty_like(R)
I['val'] = U['val'] / R['val']
I['err'] = np.sqrt((1 / R['val'] * U['err'])**2 + (U['val'] / R['val']**2 * R['err'])**2)
``````

You could also use record array, which are basic structured array with the `__getattr__` and `__setattr__` methods overloaded in such way that you can access the fields as attributes (like in `R.val`) as well as indices (like the standard `R['val']`). Of course, as these basic methods are overloaded, record arrays are not as efficient as structured arrays.

-
This seems to be the exact thing I am looking for. Thanks! –  queueoverflow Sep 10 '12 at 20:24
There is a program that does exactly this and does it automatically and transparently: uncertainties. (Disclaimer: I'm the author!) –  EOL Apr 23 '13 at 11:13

For just one measurement probably simple namedtuple would suffice.

And instead of structure arrays you can use numpy's record arrays. Seems to be little bit more mouthful though.

Also google cache of NumPy for Matlab Users (direct link doesn't work for me atm) can help with some counterparts of basic operations.

-
With the answer by Pierre GM, I now see that your answer is the right direction. I just did not see that from the documentation right away, sorry. –  queueoverflow Sep 10 '12 at 20:25
@queueoverflow: Yeah should've included an example! Even the barest one. He illustrated exactly record arrays. –  gorlum0 Sep 10 '12 at 20:53

This kind of error propagation is exactly what the uncertainties Python package does. It does so transparently:

``````from uncertainties import ufloat

R = ufloat(10, 0.1)
U = ufloat(4, 0.1)
I = U/R

print I
``````

prints `0.4+/-0.0107703296143`.

(Disclaimer: I'm the author of this package.)

-

There is a package for representing quantities along with uncertainties in Python. It is called quantities ! (also on PyPI).

-
That looks interesting. I'll have to see how well it plays with regular NumPy. –  queueoverflow Sep 10 '12 at 16:50
It should be quite OK. The dev' of this package helped improve the creation of subclasses of `ndarray`s. –  Pierre GM Sep 10 '12 at 19:01
The uncertainties package has the advantage over quantities of correctly handling correlations between variables. For example: x+x is incorrectly calculated by the quantities package. (Disclaimer: I am the author of uncertainties.) –  EOL Apr 23 '13 at 11:17