# How to Apply an equation to a Pandas dataframe ByGroup

Its that time of the day when I have been banging my head against the keyboard too long and I would appreciate any advice. My over all goal is to ingest a datafile of hourly Temperature which has gaps in it. I want to fill those gaps using a linear regression with Temperature from a nearby site. But I want to do this BY YEAR and BY MONTH. So with help from folks here I have been able to do much of this. Now I have applied a linear regression function BY YEAR AND MONTH like

Corr_grouped=DF_grouped.apply(lambda x: stats.linregress(x [Labels[0]], x [Labels[3]]))

This has produced the following which has outputs of slope, intercept, r_value, p_value, std_err and displays like this.

> 2010  1     (0.806190897504, 5.75672188581, 0.901179913935...
>       2     (0.739906365408, 8.05204746237, 0.894050112908...
>       3     (0.773199101365, 6.88505178697, 0.898475211997... ...
>       10    (0.87497855294, 4.10227036556, 0.939948762031,...
>       11    (0.793072407801, 6.38604194806, 0.923659962858...

I have been reading all day by cant find and exact solution. Now my question is how do apply this back to the original data frame. I would like a new column in the DF that applies the linear regression y=mx+c to each line in the original data using the column 3 as the input BUT to do that using the specific coefficients (slope, intercept) that are different for each YEAR and MONTH. Any ideas most welcomed :) Cheers Jason

EDIT: Great. So the DF looks like this. It has timestamps every 30 minutes for multiple years. It has gaps (NaN) that may be 1 or multiple intervals. I need to fill in the gaps in the original column (T_original) using a relationship with a nearby station (T_nearby). But it is not a simple substitution. The site is often some distance away and the temperatures are correlated but not the same (i.e. one may be 2oC hotter). SO the T_nearby station has to be adjusted first then used to fill the gap.

T_original  T_nearby
2010-01-01 00:00:00  25.87873       25.4
2010-01-01 00:30:00  25.73089       25.4
2010-01-01 01:00:00  25.56144       25.4
2010-01-01 01:30:00  NaN         25.4
2010-01-01 02:00:00  25.24789       25.6
2010-01-01 02:30:00  25.17758       25.4
2010-01-01 03:00:00  NaN         25.6
2010-01-01 03:30:00  NaN         25.6
2010-01-01 04:00:00  25.07633       25.6
2010-01-01 04:30:00  24.99211       25.5

I want to breakdown the analysis by YEAR and MONTH. So for each month of each year to calculate a linear regression fit between T_original and T_nearby. This gives the grouped object above which has the linear regression parameters. For example year 2010 and month 1 the intercept is 5.75 and the slope is 0.806.

So I would like to apply that relationship back to all the Year=2010 and Month=1 to look like this. Then for the rest of the DF apply the same approach for each month of each year.

1/01/2010 0:00  25.87873    25.4    26.2224
1/01/2010 0:30  25.73089    25.4    26.2224
1/01/2010 1:00  25.56144    25.4    26.2224
1/01/2010 1:30  NaN             25.4    26.2224
1/01/2010 2:00  25.24789    25.6    26.3836
1/01/2010 2:30  25.17758    25.4    26.2224
1/01/2010 3:00  NaN             25.6    26.3836
1/01/2010 3:30  NaN             25.6    26.3836
1/01/2010 4:00  25.07633    25.6    26.3836
1/01/2010 4:30  24.99211    25.5    26.303

Then I will use the T_adjusted column to fill in the gap in T_original. Thanks Jason

-
I don't think it's entirely clear (to me) what you are asking, perhaps it would help to provide an example DF and what you want it to be? Perhaps you want an apply which refers to Corr_grouped (?) –  Andy Hayden Feb 12 '13 at 14:26
Thanks I just edited the post to make it clearer and give an example –  user1911866 Feb 13 '13 at 6:46

Your first step is to merge the grouped object with DF. To do that first create a common grouping column.

For the grouped object:

from datetime import date
grouped['common'] = grouped.index.map(lambda x : date(x[0],x[1],1))

For DF:

DF['common'] = DF.index.map(lambda x : date(x.year,x.month,1))

Now you can merge it:

merged = DF.merge(grouped)
del merged['common']

I am not sure what the exact formula for working out T_adjusted column is but now that the regression parameters are matched with T_nearby values it could be worked out with array operations.

To fill the gaps in T_original using T_adjusted: