# Searching a list of 3 lists for equivalence of 2 lists and averaging all the values in the 3rd list where list 1 and 2 are equal (Python)

I have a list of data samples of the signal strength at a distance and angle about a point. a sample of the data looks like this:

``````0.5,0,-21
0.5,0,-23
1.0,0,-29
1.0,0,-30
0.5,45,-22
0.5,45,-23
``````

Where the data is organised radius, angle, rssi(signal strength).

As you can see I have multiple measurements for the signal strength however some have common radii and others have common angles. I am trying to find a simple way to move through the list finding all the rows with common radii and angle, average the rssi and append the radius, angle and averaged rssi to a new list.

The way I am trying to do it is:

``````import numpy as np
import math

#create 3 lists
original_data=[] # list to import the original data to
interim_data=[] # list to group rows with common radii and angles
R=[]
P=[]
Z=[]

#import data
original_data=np.genfromtxt('bot1.csv', delimiter=',')

#convert rssi to linear
for b in original_data:
b[2]=math.pow(10,b[2]/10)

for item in original_data:
if item[0] and item[1] not in R and P: #check if the common r and theta have been searched for already
for a in original_data:
if a[0] == item[0] and a[1] == item[1]:
interim_data.append(a)
#Once all rows in orginal data have been checked, average the result in interim data and place in averaged lists R, P and Z

Z.append(10*math.log10(sum(interim_data[3])/len(interim_data)))
R.append(item[0])
P.append(item[1])
``````

However when I run this code Z, R and P remain empty. I have tried a few variations with more for loops but I am wondering if there is possibly a simpler way to do what I am trying to do.

I'm also having the problem when converting to linear values = 10^(rssi dBm value/10) I can't seem to get the indexing to work.

``````b[2]=math.pow(10,b[2]/10)
``````

affects all lists in b, not just b[2]. Anyone know why that is?

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there is no need to import both numpy and math. –  Francesco Montesano Apr 8 at 13:56
Sounds like a job for either `itertools.groupby` or `pandas` –  Mr E Apr 8 at 14:02
if Z, R and P remains empty means that the code never gets there. Beside: try to avoid explicit loops if you can and a double loop over the same array doesn't make much sense to me. ps: I tried to reformat your code substituting tabs (that have problems with visualisation, as can have different lenght on different systems) with 4 spaces, and I might have messed up the indentation. Can you please check it and edit to correct? –  Francesco Montesano Apr 8 at 14:22
Yeh seems to be fine. When you say there is no need to import math and numpy does numpy have all the same functions ie I could replace math.pow() with np.pow() or does numpy import math itself? –  mark mcmurray Apr 8 at 15:16
You can see here the numpy math functions. I think that they are all the ones that you can find in `math`. I think that numpy reimplements all of them to be used on arrays. Check the edit2 in my answer, I get rid of one of the loop, that is useless with numpy. Then, just for the record: `np.pow(a, b)` is the same as `a**b` –  Francesco Montesano Apr 9 at 9:51

You should be able to get what you want with something like this.

``````import numpy as np
import itertools as it

data = np.array([[0.5,0,-21],
[0.5,0,-23],
[1.0,0,-29],
[1.0,0,-30],
[0.5,45,-22],
[0.5,45,-23]])
# convert signal strength
data[:,-1]= np.pow(10, data[:,-1]/10.)

# get the unique values of radius and angles
uangle = np.unique(data[:,1])

mean_data = []
for ur, ua in it.product(uradius, uangle):
samepoints = (data[:,0]==ur) & (data[:,1]==ua)
if samepoints.sum() > 1:  # check if there is more than one match
mean_data.append([ur, ua, np.mean(data[samepoints,-1])])
elif samepoints.sum() == 1:
mean_data.append([ur, ua, data[samepoints,-1]])
``````

Edit

output (without doing the `np.pow(..)`)

mean_data = [[0.5, 0.0, -22.0], [0.5, 45.0, -22.5], [1.0, 0.0, -29.5]]

Edit2

Numpy math operations act on the whole array that you provide, so there is no need of the loop over the rssi.

If you like more, you can also do

``````# convert signal strength
data[:,-1]= 10**(data[:,-1]/10.)
``````
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It's not too pretty but

``````import numpy as np
from itertools import groupby

original_data=np.genfromtxt('bot1.csv', delimiter=',')

data = sorted(original_data.tolist(), key=lambda x: x[:2])

[(k, np.mean(list(v),axis=0)[2]) for k, v in groupby(data, lambda x: x[:2])]
``````

which outputs

``````[([0.5, 0.0], -22.0), ([0.5, 45.0], -22.5), ([1.0, 0.0], -29.5)]
``````

I'm not sure what you're going for with the logs and powers but this should hopefully get you started.

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