I have meteorological data from many sites which are compiled together in the one array e.g. the different columns below refer to `Station`

`Year`

`Month`

`Rainfall`

respectively (the rows with `nan nan nan nan`

are because the `.csv`

file has string headers separating each data set).

The data I'm using is about 111 sites each with 40+ years of rainfall data, this is just a subset I was experimenting with -

```
[[ nan nan nan nan]
[ 1.47130000e+04 1.96800000e+03 1.00000000e+00 2.79000000e+01]
[ 1.47130000e+04 1.96800000e+03 2.00000000e+00 1.30700000e+02]
[ 1.47130000e+04 1.96800000e+03 3.00000000e+00 8.49000000e+01]
[ 1.47130000e+04 1.96800000e+03 4.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 1.96800000e+03 5.00000000e+00 2.41000000e+01]
[ 1.47130000e+04 1.96800000e+03 6.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 1.96800000e+03 7.00000000e+00 3.45000000e+01]
[ 1.47130000e+04 2.00900000e+03 3.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 4.00000000e+00 5.65000000e+01]
[ 1.47130000e+04 2.00900000e+03 5.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 6.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 7.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 8.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 9.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 1.00000000e+01 0.00000000e+00]
[ 1.47130000e+04 2.00900000e+03 1.10000000e+01 6.20000000e+00]
[ 1.47130000e+04 2.01000000e+03 1.00000000e+00 2.33300000e+02]
[ 1.47130000e+04 2.01000000e+03 2.00000000e+00 8.71000000e+01]
[ 1.47130000e+04 2.01000000e+03 3.00000000e+00 4.08000000e+01]
[ 1.47130000e+04 2.01000000e+03 4.00000000e+00 9.62000000e+01]
[ 1.47130000e+04 2.01000000e+03 5.00000000e+00 2.21000000e+01]
[ 1.47130000e+04 2.01000000e+03 6.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.01000000e+03 7.00000000e+00 2.20000000e+00]
[ 1.47130000e+04 2.01000000e+03 8.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.01000000e+03 9.00000000e+00 0.00000000e+00]
[ 1.47130000e+04 2.01000000e+03 1.00000000e+01 8.60000000e+00]
[ 1.47130000e+04 2.01000000e+03 1.10000000e+01 1.63000000e+01]
[ 1.47130000e+04 2.01100000e+03 1.00000000e+00 1.10800000e+02]
[ 1.47130000e+04 2.01100000e+03 2.00000000e+00 6.76000000e+01]
[ 1.47130000e+04 2.01100000e+03 3.00000000e+00 1.98000000e+02]
[ 1.47130000e+04 2.01100000e+03 6.00000000e+00 4.10000000e+00]
[ 1.47130000e+04 2.01100000e+03 1.00000000e+01 2.52000000e+01]
[ 1.47130000e+04 2.01100000e+03 1.10000000e+01 4.17000000e+01]
[ 1.47130000e+04 2.01200000e+03 1.00000000e+00 2.13600000e+02]
[ 1.47130000e+04 2.01200000e+03 2.00000000e+00 7.44000000e+01]
[ 1.47130000e+04 2.01200000e+03 3.00000000e+00 9.14000000e+01]
[ 1.47130000e+04 2.01200000e+03 4.00000000e+00 1.70000000e+01]
[ 1.47130000e+04 2.01200000e+03 5.00000000e+00 1.56000000e+01]
[ 1.47130000e+04 2.01200000e+03 7.00000000e+00 4.20000000e+00]
[ 1.47130000e+04 2.01200000e+03 1.00000000e+01 3.40000000e+00]
[ 1.47130000e+04 2.01200000e+03 1.10000000e+01 7.70000000e+00]
[ nan nan nan nan]
[ 1.47320000e+04 2.00000000e+03 9.00000000e+00 0.00000000e+00]
[ 1.47320000e+04 2.00000000e+03 1.00000000e+01 8.34000000e+01]
[ 1.47320000e+04 2.00000000e+03 1.10000000e+01 1.17000000e+02]
[ 1.47320000e+04 2.00000000e+03 1.20000000e+01 4.90800000e+02]
[ 1.47320000e+04 2.00100000e+03 1.00000000e+00 1.64200000e+02]
[ 1.47320000e+04 2.00100000e+03 2.00000000e+00 6.51600000e+02]
[ 1.47320000e+04 2.00100000e+03 3.00000000e+00 1.36800000e+02]
[ 1.47320000e+04 2.00100000e+03 4.00000000e+00 1.64400000e+02]
[ 1.47320000e+04 2.01000000e+03 9.00000000e+00 0.00000000e+00]
[ 1.47320000e+04 2.01100000e+03 1.00000000e+00 1.82400000e+02]
[ 1.47320000e+04 2.01100000e+03 2.00000000e+00 3.81000000e+02]
[ 1.47320000e+04 2.01100000e+03 3.00000000e+00 4.50800000e+02]
[ 1.47320000e+04 2.01100000e+03 4.00000000e+00 3.12800000e+02]
[ 1.47320000e+04 2.01100000e+03 5.00000000e+00 0.00000000e+00]
[ 1.47320000e+04 2.01100000e+03 6.00000000e+00 0.00000000e+00]
[ 1.47320000e+04 2.01100000e+03 7.00000000e+00 1.60000000e+00]
[ nan nan nan nan]
[ 1.55030000e+04 1.96600000e+03 1.00000000e+00 6.47000000e+01]
[ 1.55030000e+04 1.96600000e+03 2.00000000e+00 1.14000000e+01]
[ 1.55030000e+04 1.96600000e+03 3.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 1.96600000e+03 4.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 1.96600000e+03 5.00000000e+00 2.80000000e+00]
[ 1.55030000e+04 1.96600000e+03 6.00000000e+00 3.47000000e+01]
[ 1.55030000e+04 1.96600000e+03 7.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01100000e+03 2.00000000e+00 1.40500000e+02]
[ 1.55030000e+04 2.01100000e+03 3.00000000e+00 1.13700000e+02]
[ 1.55030000e+04 2.01100000e+03 4.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01100000e+03 5.00000000e+00 4.00000000e-01]
[ 1.55030000e+04 2.01100000e+03 6.00000000e+00 8.60000000e+00]
[ 1.55030000e+04 2.01100000e+03 7.00000000e+00 2.20000000e+00]
[ 1.55030000e+04 2.01100000e+03 8.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01100000e+03 9.00000000e+00 4.50000000e+00]
[ 1.55030000e+04 2.01100000e+03 1.00000000e+01 2.00000000e+00]
[ 1.55030000e+04 2.01100000e+03 1.10000000e+01 2.80000000e+01]
[ 1.55030000e+04 2.01100000e+03 1.20000000e+01 4.18000000e+01]
[ 1.55030000e+04 2.01200000e+03 1.00000000e+00 4.82000000e+01]
[ 1.55030000e+04 2.01200000e+03 2.00000000e+00 5.62000000e+01]
[ 1.55030000e+04 2.01200000e+03 3.00000000e+00 1.45600000e+02]
[ 1.55030000e+04 2.01200000e+03 4.00000000e+00 1.62000000e+01]
[ 1.55030000e+04 2.01200000e+03 5.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01200000e+03 6.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01200000e+03 7.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01200000e+03 8.00000000e+00 0.00000000e+00]
[ 1.55030000e+04 2.01200000e+03 9.00000000e+00 2.60000000e+00]
[ 1.55030000e+04 2.01200000e+03 1.10000000e+01 2.52000000e+01]
[ 1.55030000e+04 2.01200000e+03 1.20000000e+01 1.09900000e+02]]
```

I need to break up the data based on the different stations (first column). I think I can do this using

`B = np.array_split(alldata,np.where(SN == 0)[0])`

(where`SN`

is the first column of data, with a 0 in the`Station`

column by replacing initially in excel). However, this results with the`0 nan nan nan`

row being included in each split array. I've also tried -`for key,items in groupby(alldata,itemgetter(0)): print(key)`

, but not sure how to manipulate further the split data sets with the`groupby()`

function.Once the data is split into separate arrays, I need to insert rows for missing months and years and to have the corresponding cells in the new rows blank for the precipitation column. I understand how to join two lists, but I'm not sure about inserting data based on missing values from a sequence, and having it apply to the whole array. For example, with the data above, I'd like all arrays to have year and month columns extending from 1966 to 1981 so I can correlate the different months together.

Once all the data is of equal length I want to run a regressions between all precipitation data for the different sites. For example, say the first block of data is the "site of interest", I would like to get the r^2 value for the correlation between its rainfall data and other sites in the data set. Eventually, I would also like to alter the rainfall data to be a percentile of all the rainfall data at that site, and then correlate all the rainfall values in percentile form with the "site of interest"

I'm not sure if this makes sense, please let me know what I should add to the question (this is my first question).

**Updated Code From User's (Brionius) Comments and Suggestions:**

The code works fine up to applying the regression. Not really sure about applying a correlation using a mask.

I tried doing the correlation without a mask using `slope, intercept, r_value, p_value, std_err = stats.linregress(rotated[0][0],rotated[i][0])`

but it returned `nan`

values for all the r_values, presumably because of the `nan`

values in the dataset.

```
import numpy as np
# Import data:
alldata=\
np.genfromtxt("combinedWdata.csv",unpack=False,\
delimiter=",")
# Split array based on where the 'nan' values are
dataSets = filter(lambda x: len(x) > 0,\
np.array_split(alldata,np.where(np.isnan(alldata[:,1]))[0]))
# Delete the rows with 'nan' in it.
dataSets = [np.delete(dataSet, np.where(np.isnan(dataSet)), axis=0)\
for dataSet in dataSets]
# Assign variables to years and months
startYear = 1877
endYear = 2013
startMonth = 1
endMonth = 12
blank_rainfall_value = np.nan
# Insert rows of the form ['nan', year, month, 0] for all relevant \
#years/months except where there is already a row containing that year/month
extendedDataSets = []
for dataSet in dataSets:
missingMonths = [[dataSet[0][0], year, month, blank_rainfall_value] \
for year in range(startYear, endYear+1)\
for month in range(startMonth, endMonth+1) \
if [year, month] not in dataSet[:,1:3].tolist()]
if len(missingMonths) > 0:
extendedDataSets.append(np.vstack((dataSet, missingMonths)))
# Sort arrray by year, then month
finalDataSets = [np.array(sorted(dataSet, key=lambda row:row[1]+row[2]/12.0))\
for dataSet in extendedDataSets]
# Rotate data to compare between columns rather than rows
rotated=[]
for dataSet in finalDataSets:
u=np.rot90(dataSet)
rotated.append(u)
rotated=np.array(rotated)
# Delete year month and station
m=0
rotatedDel=[]
for i in rotated:
v=[rotated[m][0]]
rotatedDel.append(v)
rotatedDel=np.array(rotatedDel)
# Apply regression between first station and all later stations with \
#mask for nan values
m=0
r_values=[]
for i in rotatedDel:
r_value=np.ma.corrcoef(x=\
(np.ma.array(rotatedDel[0],mask=np.isnan(rotatedDel[0]))),y=\
(np.ma.array(rotatedDel[m],mask=np.isnan(rotatedDel[m]))),\
rowvar=False,allow_masked=True)
r_values.append(r_value)
m=m+1
```

`[1.47130000e+04 1.96800000e+03 1.00000000e+00 2.79000000e+01]`

? – GLES Aug 15 '13 at 11:28