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October 16, 2013 05:36
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Implementation of the beta-geometric/NBD (BG/NBD) model from '"Counting Your Customers" the Easy Way: An Alternative to
the Pareto/NBD Model' (Fader, Hardie and Lee 2005) http://brucehardie.com/papers/018/fader_et_al_mksc_05.pdf and
accompanying technical note http://www.brucehardie.com/notes/004/
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""" | |
Implementation of the beta-geometric/NBD (BG/NBD) model from '"Counting Your Customers" the Easy Way: An Alternative to | |
the Pareto/NBD Model' (Fader, Hardie and Lee 2005) http://brucehardie.com/papers/018/fader_et_al_mksc_05.pdf and | |
accompanying technical note http://www.brucehardie.com/notes/004/ | |
Apache 2 License | |
""" | |
from math import log, exp | |
import numpy as np | |
from scipy.optimize import minimize | |
from scipy.special import gammaln | |
__author__ = 'JD Maturen' | |
def log_likelihood_individual(r, alpha, a, b, x, tx, t): | |
"""Log of the likelihood function for a given randomly chosen individual with purchase history = (x, tx, t) where | |
x is the number of transactions in time period (0, t] and tx (0 < tx <= t) is the time of the last transaction""" | |
ln_a1 = gammaln(r + x) - gammaln(r) + r * log(alpha) | |
ln_a2 = gammaln(a + b) + gammaln(b + x) - gammaln(b) - gammaln(a + b + x) | |
ln_a3 = -(r + x) * log(alpha + t) | |
a4 = 0 | |
if x > 0: | |
a4 = exp(log(a) - log(b + x - 1) - (r + x) * log(alpha + tx)) | |
return ln_a1 + ln_a2 + log(exp(ln_a3) + a4) | |
def log_likelihood(r, alpha, a, b, customers): | |
"""Sum of the individual log likelihoods""" | |
# can't put constraints on n-m minimizer so fake them here | |
if r <= 0 or alpha <= 0 or a <= 0 or b <= 0: | |
return -np.inf | |
return sum([log_likelihood_individual(r, alpha, a, b, x, tx, t) for x, tx, t in customers]) | |
def maximize(customers): | |
negative_ll = lambda params: -log_likelihood(*params, customers=customers) | |
params0 = np.array([1., 1., 1., 1.]) | |
res = minimize(negative_ll, params0, method='nelder-mead', options={'xtol': 1e-8}) | |
return res | |
def fit(customers): | |
res = maximize(customers) | |
if res.status != 0: | |
raise Exception(res.message) | |
return res.x | |
def cdnow_customer_data(fname): | |
data = [] | |
with open(fname) as f: | |
f.readline() | |
for line in f: | |
data.append(map(float, line.strip().split(',')[1:4])) | |
return data | |
def main(): | |
data = cdnow_customer_data('cdnow_customers.csv') | |
r, alpha, a, b = fit(data) | |
# fit according to the note | |
print r, alpha, a, b | |
print np.allclose([r, alpha, a, b], [.243, 4.414, .793, 2.426], 1e-2) | |
if __name__ == '__main__': | |
main() |
I concur that the Pareto/NBD model takes much longer to run. Even the Lifetimes implementation (kudos to Cam and company for putting that one together and actively supporting it) takes at least three-fold as long to run for the same data set and doesn't deliver a measurable improvement in our experience.
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cam davidson's lifetimes library in python does both.