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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
translate(x,np.array([1,2,3]))
...
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)

Out[11]:

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

In [12]:

x["xyz"]

Out[12]:

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

In [14]:

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

Out[14]:

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.

share|improve this answer
    
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'], 
      dtype='|S8')

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.]]])
share|improve this answer
    
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.

share|improve this answer
    
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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