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I have a number of time series, each containing measurements across weeks of the year, but not all of them start and end on the same weeks. I know the offsets, that is I know in what weeks each one starts and ends. Now I would like to combine them into a matrix respecting the inherent offsets, such that all values will align with the correct week numbers.

If the horizontal direction contains the series and vertical direction represents the weeks, given two series a and b, where values correspond to week numbers:

a = np.array([[1,2,3,4,5,6]])
b = np.array([[0,1,2,3,4,5]])

I want to know if is it possible to combine them, e.g. using some method that takes an offset argument in a fashion like combine((a, b), axis=0, offset=-1), such that the resulting array (lets call it c) looks like this:

print c
[[NaN 1   2   3   4   5   6  ]
 [0   1   2   3   4   5   NaN]]

What more is, since the time series are enormous, I must stream them through my program, and therefore cannot know all offsets at the same time. I thought of using Pandas because it has nice indexing, but I felt there had to be a simpler way, since the essence of what I'm trying to do is super simple.

Update: This seems to work

def offset_stack(a, b, offset=0):
    if offset < 0:
        a = np.insert(a, [0] * abs(offset), np.nan)
        b = np.append(b, [np.nan] * abs(offset))
    if offset > 0:
        a = np.append(a, [np.nan] * abs(offset))
        b = np.insert(b, [0] * abs(offset), np.nan)

    return np.concatenate(([a],[b]), axis=0)
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3 Answers 3

2

You can do in numpy:

def f(a, b, n):
    v = np.empty(abs(n))*np.nan
    if np.sign(n)==-1:
        return np.vstack((np.append(a,v), np.append(v,b)))
    elif np.sign(n)==1:
        return np.vstack((np.append(v,a), np.append(b,v)))
    else:
        return np.vstack((a,b))

#In [148]: a = np.array([23, 13, 4, 12, 4, 4])

#In [149]: b = np.array([4, 12, 3, 41, 45, 6])

#In [150]: f(a,b,-2)
#Out[150]:
#array([[ 23.,  13.,   4.,  12.,   4.,   4.,  nan,  nan],
#       [ nan,  nan,   4.,  12.,   3.,  41.,  45.,   6.]])

#In [151]: f(a,b,2)
#Out[151]:
#array([[ nan,  nan,  23.,  13.,   4.,  12.,   4.,   4.],
#       [  4.,  12.,   3.,  41.,  45.,   6.,  nan,  nan]])

#In [152]: f(a,b,0)
#Out[152]:
#array([[23, 13,  4, 12,  4,  4],
#       [ 4, 12,  3, 41, 45,  6]])
3
  • I only set the example values to be the week/column values for illustration purposes. In reality, they could be anything, so this does not really solve the problem for me. Thanks for your effort though!
    – Ulf Aslak
    Mar 22, 2016 at 16:34
  • if i had two arrays a = [23, 13, 4, 12, 4, 4] and b = [4, 12, 3, 41, 45, 6] and needed an offset of -2 so, c = [[nan, nan, 23, 13, 4, 12, 4, 4], [4, 12, 3, 41, 45, 6, nan, nan]] for example
    – Ulf Aslak
    Mar 22, 2016 at 16:41
  • This is nice! But now I start to get greedy: would love to see an implementation for any dimensions. E.g. for stacking 2darrays along the depth axis with offset_i and offset_j arguments :)
    – Ulf Aslak
    Mar 22, 2016 at 17:25
2

There is a real simple way to accomplish this.

You basically want to pad and then stack your arrays and for both there are numpy functions:

numpy.lib.pad() aka offset

a = np.array([[1,2,3,4,5,6]], dtype=np.float_) # float because NaN is a float value!
b = np.array([[0,1,2,3,4,5]], dtype=np.float_)

from numpy.lib import pad
print(pad(a, ((0,0),(1,0)), mode='constant', constant_values=np.nan))
# [[ nan   1.   2.   3.   4.   5.   6.]]
print(pad(b, ((0,0),(0,1)), mode='constant', constant_values=np.nan))
# [[  0.,   1.,   2.,   3.,   4.,   5.,  nan]]

The ((0,0)(1,0)) means just no padding in the first axis (top/bottom) and only pad one element left and no element on the right. So you have to tweak these if you want more/less shift.

numpy.vstack() aka stack along axis=0

import numpy as np

a_padded = pad(a, ((0,0),(1,0)), mode='constant', constant_values=np.nan)
b_padded = pad(b, ((0,0),(0,1)), mode='constant', constant_values=np.nan)

np.vstack([a_padded, b_padded])
# array([[ nan,   1.,   2.,   3.,   4.,   5.,   6.],
#        [  0.,   1.,   2.,   3.,   4.,   5.,  nan]])

Your function:

Combining these two would be very easy and is easy to extend:

from numpy.lib import pad
import numpy as np

def offset_stack(a, b, axis=0, offsets=(0, 1)):
    if (len(offsets) != a.ndim) or (a.ndim != b.ndim):
        raise ValueError('Offsets and dimensions of the arrays do not match.')
    offset1 = [(0, -offset) if offset < 0 else (offset, 0) for offset in offsets]
    offset2 = [(-offset, 0) if offset < 0 else (0, offset) for offset in offsets]
    a_padded = pad(a, offset1, mode='constant', constant_values=np.nan)
    b_padded = pad(b, offset2, mode='constant', constant_values=np.nan)
    return np.concatenate([a_padded, b_padded], axis=axis)

offset_stack(a, b)

This function works for generalized offsets in arbitary dimensions and can stack in arbitary dimensions. It doesn't work in the same way as the original since you pad the second dimension just passing in offset=1 would pad in the first dimension. But if you keep track of the dimensions of your arrays it should work fine.

For example:

offset_stack(a, b, offsets=(1,2))
array([[ nan,  nan,  nan,  nan,  nan,  nan,  nan,  nan],
       [ nan,  nan,   1.,   2.,   3.,   4.,   5.,   6.],
       [  0.,   1.,   2.,   3.,   4.,   5.,  nan,  nan],
       [ nan,  nan,  nan,  nan,  nan,  nan,  nan,  nan]])

or for 3d arrays:

a = np.array([1,2,3], dtype=np.float_)[None, :, None] # makes it 3d
b = np.array([0,1,2], dtype=np.float_)[None, :, None] # makes it 3d

offset_stack(a, b, offsets=(0,1,0), axis=2)
array([[[ nan,   0.],
        [  1.,   1.],
        [  2.,   2.],
        [  3.,  nan]]])
5
  • numpy.lib.pad is a really neat tool, thanks for bringing that on the table! But your implementation doesn't support negative offset values.
    – Ulf Aslak
    Mar 22, 2016 at 18:02
  • The generalization doesnt work for me. I can only stack along axes 0 and 1, not 2 (depth) and so on.
    – Ulf Aslak
    Mar 22, 2016 at 18:54
  • a and b remain the same. maybe we need to agree on how the function behaves for higher dimensions. My thoughts were that offset would be a tuple or list. Then offsets = (1) or offsets = (1, 0, 0, ..., 0) would be an offset in the horizontal direction, (0, 1) or (0, 1, 0, ..., 0) was an offset in the vertical direction, and (0, 0, 1) or (0, 0, 1, 0, ..., 0) was an offset in the depth direction, and so on. Some offsets would cause overlap, and that should not be allowed (or handled carefully).
    – Ulf Aslak
    Mar 22, 2016 at 19:10
  • Well that's not hard and you could do it yourself given my function. That function is very general and you can adapt if for your specific needs. It's just a matter of creating empty dimensions and checking for corner cases. The offsets = (1,0,0,...) is already possible for this function.
    – MSeifert
    Mar 22, 2016 at 19:14
  • This is true. It works nicely for depth stacking, I like that.
    – Ulf Aslak
    Mar 22, 2016 at 19:20
1

pad and concatenate (and the various stack and inserts) create a target array of the right size, and fill values from the input arrays. So we can do the same, and potentially do it faster.

Just for example using your 2 arrays and the 1 step offset:

In [283]: a = np.array([[1,2,3,4,5,6]])
In [284]: b = np.array([[0,1,2,3,4,5]])

create the target array, and fill it with the pad value. np.nan is a float (even though a is int):

In [285]: m=a.shape[0]+b.shape[0]    
In [286]: n=a.shape[1]+1    
In [287]: c=np.zeros((m,n),float)
In [288]: c.fill(np.nan)

Now just copy values into the right places on the target. More arrays and offsets will require some generalization here.

In [289]: c[:a.shape[0],1:]=a
In [290]: c[-b.shape[0]:,:-1]=b

In [291]: c
Out[291]: 
array([[ nan,   1.,   2.,   3.,   4.,   5.,   6.],
       [  0.,   1.,   2.,   3.,   4.,   5.,  nan]])
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  • You don't need to fill it manually: np.full((m,n), fill_value=np.nan, dtype=np.float)
    – MSeifert
    Mar 22, 2016 at 22:56
  • np.full just does an np.empty followed by a copyto. So execution speed should be basically the same.
    – hpaulj
    Mar 22, 2016 at 23:37
  • I've noticed that very few actually use that np.full function but it's a great function. So I thought it might come in handy here. :) Time differences should be negligible, it's just the difference between np.empty and np.zeros and that's tiny.
    – MSeifert
    Mar 22, 2016 at 23:42

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