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I have a set of data that I would like to treat with numpy. The data can be looked at as a set of points in space with an additional property variable that I would like to handle as an object. Depending on a set of data, the vectors may be of length 1, 2, or 3, but is the same length for all points in a given set of data. The property object is a custom class that may be the same for any two given points.

So consider this data as a random example (C and H represent objects that contain atomic properties for Carbon or Hydrogen ... or just some random object). These will not be read in through a file, but created by an algorithm. Here the C object may be the same or it may be different (isotope for example).

Example 3D data set (just abstract representation)
C 1 2 3
C 3 4 5
H 1 1 4

I would like to have a numpy array that contains all of the atomic positions, so that I can perform numpy operations like vector manipulation and such as a translation function def translate(data,vec):return data + vec. I would also like to handle the property objects in parallel. One option would be to have two separate arrays for both, but if I delete an element of one, I would have to explicitly delete the property array value as well. This could get difficult to handle.

I considered using numpy.recarray

x = np.array([(1.0,2,3, "C"), (3.0,2,3, "H")], dtype=[('x', "float64" ),('y',"float6

4"),('z',"float64"), ('type', object)])

But it seems the shape of this array is (2,), which means that each record is handled independently. Also, I cannot seem to understand how to get vector manipulation to work with this type:

def translate(data,vec):return data + vec
TypeError: unsupported operand type(s) for +: 'numpy.ndarray' and 'numpy.ndarray'

Is numpy.recarray what I should be using? Is there a better way to handle this in a simpler way such that I have a separate numerical matrix of points with a parallel object array that are linked in case an element is removed (np.delete)? I also briefly considered writing an array object that extends ndarray, but I feel like this may be unnecessary and potentially disastrous.

Any thoughts or suggestions would be very helpful.

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3 Answers 3

up vote 2 down vote accepted

The field of a recarray can be a ndarray, if you pass the tuple (name, type, shape) as the dtype of the field:

In [9]:

import numpy as np

x = np.array([((1.0,2,3), "C"), ((3.0,2,3), "H")], dtype=[('xyz', "float64", (3,)), ('type', object)])

In [11]:

np.delete(x, 0)


array([([3.0, 2.0, 3.0], 'H')], 
      dtype=[('xyz', '<f8', (3,)), ('type', 'O')])

In [12]:



array([[ 1.,  2.,  3.],
       [ 3.,  2.,  3.]])

In [14]:

x["xyz"] + (10, 20, 30)


array([[ 11.,  22.,  33.],
       [ 13.,  22.,  33.]])

For your translate function:

def translate(data,vec):
    tmp = data.copy()
    tmp["xyz"] += vect
    return tmp

If you want more flexible functions, you may consider using Pandas.DataFrame.

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Thanks! This is exactly what I had been looking for. It slipped right passed me that you could change the dimensions of one of the structs. –  scicalculator Mar 3 '13 at 22:49

One quick and dirty way would be to set the last (or indeed any) column to be a numerical lookup to a labels dictionary:

>>> import numpy
>>> labels = ['H', 'C', 'O']
>>> labels_refs = dict(zip(labels, numpy.arange(len(labels), dtype='float64')))
>>> reverse_labels_refs = dict(zip(numpy.arange(len(labels), dtype='float64'), labels))
>>> x = numpy.array([
...     [1.0,2,3, labels_refs['C']], 
...     [3.0,2,3, labels_refs['H']],
...     [2.0,2,3, labels_refs['C']]])
>>> x
array([[ 1.,  2.,  3.,  1.],
       [ 3.,  2.,  3.,  0.],
       [ 2.,  2.,  3.,  1.]])
>>> extract_refs = numpy.vectorize(
...         lambda label_ref: reverse_labels_refs[label_ref])
>>> labels = extract_refs(x[:, -1]) # Turn the last column back into labels
>>> labels
array(['C', 'H', 'C'], 

You can also lookup rows by their labels (as an example):

>>> x[numpy.where(x[:,-1] == labels_refs['C']), :-1]
array([[[ 1.,  2.,  3.],
        [ 2.,  2.,  3.]]])
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Thanks. This can definitely be used, but this requires prior knowledge of the entire set of possible refs before creating the array. It would be best to have a very fluid scheme for my purposes. –  scicalculator Mar 3 '13 at 22:55

If you are dealing with collections of atoms, you may consider to use the Atoms class from Atomic Simulation Environment (ASE). It stores atom types, positions and has list-like methods to manipulate them.

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Thanks for this reference, I didn't know about it. I am actually building a crystallography and molecular visualisation/analysis/MD suite myself. This package looks pretty powerful and would be a good package to see what others are doing in the same area. Could also be possible collaboration to work with it, I suppose. –  scicalculator Mar 3 '13 at 23:03
It would be definitely a good idea to look around what is already there and maybe extend something with a big user base. That would enhance chances, that the project does not end as "yet an other unfinished attempt" to create a molecular visualisation/analysis tool... :-) –  Bálint Aradi Mar 4 '13 at 8:10

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