I have various time series, that I want to correlate - or rather, cross-correlate - with each other, to find out at which time lag the correlation factor is the greatest.

I found various questions and answers/links discussing how to do it with numpy, but those would mean that I have to turn my dataframes into numpy arrays. And since my time series often cover different periods, I am afraid that I will run into chaos.

**Edit**

The issue I am having with all the numpy/scipy methods, is that they seem to lack awareness of the timeseries nature of my data. When I correlate a time series that starts in say 1940 with one that starts in 1970, pandas `corr`

knows this, whereas `np.correlate`

just produces a 1020 entries (length of the longer series) array full of nan.

The various Q's on this subject indicate that there should be a way to solve the different length issue, but so far, I have seen no indication on how to use it for specific time periods. I just need to shift by 12 months in increments of 1, for seeing the time of maximum correlation within one year.

**Edit2**

Some minimal sample data:

```
import pandas as pd
import numpy as np
dfdates1 = pd.date_range('01/01/1980', '01/01/2000', freq = 'MS')
dfdata1 = (np.random.random_integers(-30,30,(len(dfdates1)))/10.0) #My real data is from measurements, but random between -3 and 3 is fitting
df1 = pd.DataFrame(dfdata1, index = dfdates1)
dfdates2 = pd.date_range('03/01/1990', '02/01/2013', freq = 'MS')
dfdata2 = (np.random.random_integers(-30,30,(len(dfdates2)))/10.0)
df2 = pd.DataFrame(dfdata2, index = dfdates2)
```

Due to various processing steps, those dfs end up changed into df that are indexed from 1940 to 2015. this should reproduce this:

```
bigdates = pd.date_range('01/01/1940', '01/01/2015', freq = 'MS')
big1 = pd.DataFrame(index = bigdates)
big2 = pd.DataFrame(index = bigdates)
big1 = pd.concat([big1, df1],axis = 1)
big2 = pd.concat([big2, df2],axis = 1)
```

This is what I get when I correlate with pandas and shift one dataset:

```
In [451]: corr_coeff_0 = big1[0].corr(big2[0])
In [452]: corr_coeff_0
Out[452]: 0.030543266378853299
In [453]: big2_shift = big2.shift(1)
In [454]: corr_coeff_1 = big1[0].corr(big2_shift[0])
In [455]: corr_coeff_1
Out[455]: 0.020788314779320523
```

And trying scipy:

```
In [456]: scicorr = scipy.signal.correlate(big1,big2,mode="full")
In [457]: scicorr
Out[457]:
array([[ nan],
[ nan],
[ nan],
...,
[ nan],
[ nan],
[ nan]])
```

which according to `whos`

is

```
scicorr ndarray 1801x1: 1801 elems, type `float64`, 14408 bytes
```

But I'd just like to have 12 entries.
**/Edit2**

The idea I have come up with, is to implement a time-lag-correlation myself, like so:

```
corr_coeff_0 = df1['Data'].corr(df2['Data'])
df1_1month = df1.shift(1)
corr_coeff_1 = df1_1month['Data'].corr(df2['Data'])
df1_6month = df1.shift(6)
corr_coeff_6 = df1_6month['Data'].corr(df2['Data'])
...and so on
```

But this is probably slow, and I am probably trying to reinvent the wheel here. **Edit** The above approach seems to work, and I have put it into a loop, to go through all 12 months of a year, but I still would prefer a built in method.

`scipy.signal.correlate`

and`scipy.signal.correlate2d`

. I would say that converting to numpy arrays is probably your best bet.`pd.HDFStore`

and`h5py`

. If you feel up to reinventing the wheel, go for it.`series.apply`

, thanks, that might come in handy later. The issue I am having with all the numpy/scipy methods, is that they seem to lack awareness of the timeseries nature of my data. When I correlate a time series that starts in say 1940 with one that starts in 1970, pandas`corr`

knows this, whereas`np.correlate`

just produces a 1020 entries array full of`nan`

. I just need to shift for seeing the max correlation within one year.5more comments