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How to do Channel Attribution (Markov Chain Model) in Python? Like we have 'ChannelAttribution' package in R.

  • Use a bayesian package like stan. Look at the case study here - mc-stan.org/events/stancon2017-notebooks/… – fixxxer Nov 8 '18 at 10:06
  • Use R package referenced, have been hoping to move to Python. Only package I have found is pychattr. Not sure of the usefulness if I already have channel attribution models working in R. Maybe I am not thinking about it right. – Jesse Jan 3 at 3:50
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I wrote the python code for multi channel attribution model. https://www.linkedin.com/pulse/multi-channel-attribution-model-python-sheranga-gamwasam/

Here is the dataset link:https://docs.google.com/spreadsheets/d/11pa-eQDHEX63uSEA4eWiDTOZ7lbO6Vwt-dHkuhuhbSo/edit?usp=sharing

import time
import pandas as pd
import numpy as np
import collections
from itertools import chain
import itertools
from scipy.stats import stats
import statistics 

def unique(list1):  
    unique_list = []   
    for x in list1: 
        if x not in unique_list: 
            unique_list.append(x) 

    return(unique_list)

def split_fun(path):
    return path.split('>')

def calculate_rank(vector):
  a={}
  rank=0
  for num in sorted(vector):
    if num not in a:
      a[num]=rank
      rank=rank+1
  return[a[i] for i in vector]

def transition_matrix_func(import_data):

    z_import_data=import_data.copy()

    z_import_data['path1']='start>'+z_import_data['path']
    z_import_data['path2']=z_import_data['path1']+'>convert'


    z_import_data['pair']=z_import_data['path2'].apply(split_fun)

    zlist=z_import_data['pair'].tolist()
    zlist=list(chain.from_iterable(zlist))
    zlist=list(map(str.strip, zlist))
    T=calculate_rank(zlist)

    M = [[0]*len(unique(zlist)) for _ in range(len(unique(zlist)))]

    for (i,j) in zip(T,T[1:]):
        M[i][j] += 1

    x_df=pd.DataFrame(M)

    np.fill_diagonal(x_df.values,0)

    x_df=pd.DataFrame(x_df.values/x_df.values.sum(axis=1)[:,None])
    x_df.columns=sorted(unique(zlist))
    x_df['index']=sorted(unique(zlist))
    x_df.set_index("index", inplace = True) 
    x_df.loc['convert',:]=0
    return(x_df)

def simulation(trans,n):

    sim=['']*n
    sim[0]= 'start'
    i=1
    while i<n:
        sim[i] = np.random.choice(trans.columns, 1, p=trans.loc[sim[i-1],:])[0]
        if sim[i]=='convert':
            break
        i=i+1

    return sim[0:i+1]


def markov_chain(data_set,no_iteration=10,no_of_simulation=10000,alpha=5):


    import_dataset_v1=data_set.copy()
    import_dataset_v1=(import_dataset_v1.reindex(import_dataset_v1.index.repeat(import_dataset_v1.conversions))).reset_index()
    import_dataset_v1['conversions']=1

    import_dataset_v1=import_dataset_v1[['path','conversions']]

    import_dataset=(import_dataset_v1.groupby(['path']).sum()).reset_index()
    import_dataset['probability']=import_dataset['conversions']/import_dataset['conversions'].sum()

    final=pd.DataFrame()


    for k in range(0,no_iteration):
        start = time.time()
        import_data=pd.DataFrame({'path':np.random.choice(import_dataset['path'],size=import_dataset['conversions'].sum(),p=import_dataset['probability'],replace=True)})
        import_data['conversions']=1                           

        tr_matrix=transition_matrix_func(import_data)
        channel_only = list(filter(lambda k0: k0 not in ['start','convert'], tr_matrix.columns)) 

        ga_ex=pd.DataFrame()
        tr_mat=tr_matrix.copy()
        p=[]

        i=0
        while i<no_of_simulation:
            p.append(unique(simulation(tr_mat,1000)))
            i=i+1


        path=list(itertools.chain.from_iterable(p))
        counter=collections.Counter(path)

        df=pd.DataFrame({'path':list(counter.keys()),'count':list(counter.values())})
        df=df[['path','count']]
        ga_ex=ga_ex.append(df,ignore_index=True) 

        df1=(pd.DataFrame(ga_ex.groupby(['path'])[['count']].sum())).reset_index()

        df1['removal_effects']=df1['count']/len(path)
        #df1['removal_effects']=df1['count']/sum(df1['count'][df1['path']=='convert'])
        df1=df1[df1['path'].isin(channel_only)]
        df1['ass_conversion']=df1['removal_effects']/sum(df1['removal_effects'])

        df1['ass_conversion']=df1['ass_conversion']*sum(import_dataset['conversions']) 

        final=final.append(df1,ignore_index=True)
        end = time.time()
        t1=(end - start)
        print(t1)   

    '''
    H0: u=0
    H1: u>0
    '''


    unique_channel=unique(final['path'])
    #final=(pd.DataFrame(final.groupby(['path'])[['ass_conversion']].mean())).reset_index()
    final_df=pd.DataFrame()

    for i in range(0,len(unique_channel)):

        x=(final['ass_conversion'][final['path']==unique_channel[i]]).values
        final_df.loc[i,0]=unique_channel[i]
        final_df.loc[i,1]=x.mean()

        v=stats.ttest_1samp(x,0)
        final_df.loc[i,2]=v[1]/2

        if v[1]/2<=alpha/100:
            final_df.loc[i,3]=str(100-alpha)+'% statistically confidence'
        else:
            final_df.loc[i,3]=str(100-alpha)+'% statistically not confidence'

        final_df.loc[i,4]=len(x)
        final_df.loc[i,5]=statistics.stdev(x)
        final_df.loc[i,6]=v[0]

    final_df.columns=['channel','ass_conversion','p_value','confidence_status','frequency','standard_deviation','t_statistics']       
    final_df['ass_conversion']=sum(import_dataset['conversions']) *final_df['ass_conversion'] /sum(final_df['ass_conversion'])

    return final_df,final

import_dataset=pd.read_csv('channel attribution example.csv')

data,dataset=markov_chain(import_dataset,no_iteration=10,no_of_simulation=10000,alpha=5)

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