# python scipy using fmin_bfgs for logistic regression

I use the formula below as my hypothesis:

And the formula below as the cost function:

So the object function I try to minimize is :

And the gradient is:

the csv file is formatted like: y0,x1,x2,x3,... y1,x1,x2,x3,... y2,x1,x2,x3,... y is either 1 or 0(for classification) the training code is below:

``````import numpy as np
import scipy as sp
from scipy.optimize import fmin_bfgs
import pylab as pl

data = np.genfromtxt('../data/small_train.txt', delimiter=',')
y = data[:,0]
#add 1 as the first column of x, the constant term
x = np.append(np.ones((len(y), 1)), data[:,1:], axis = 1)

#sigmoid hypothesis
def h(theta, x):
return 1.0/(1+np.exp(-np.dot(theta, x)))

#cost function
def cost(theta, x, y):
tot = 0
for i in range(len(y)):
tot += y[i]*np.log(h(theta, x[i])) + (1-y[i])*(1-np.log(h(theta, x[i])))
return -tot / len(y)

def deviation(theta, x, y):
def f(theta, x, y, j):
tot = 0.0
for i in range(len(y)):
tot += (h(theta, x[i]) - y[i]) * x[i][j]
ret = []
for j in range(len(x[0])):
ret.append(f(theta, x, y, j))
return np.array(ret)

init_theta = np.zeros(len(x[0]))
ret = fmin_bfgs(cost, init_theta, fprime = deviation, args=(x,y))
print ret
``````

I run the code on a small data set, but it seems my implementation is not right.Can any one help me? One more question:As you know, fmin_bfgs do not necessarily need the fprime term, what is the difference between if we do provide it and do not?

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Providing the derivatives of the function only helps with speed as far as I know. If you don't provide an analytical form then numerical ones are generated on the fly. scikits.learn has a logistical regression function, you can try that one out to for testing. –  reptilicus Aug 20 '12 at 13:32
@lhdgriver How did u get started and implemented the above code as m doing the same. –  fscore Dec 2 '13 at 12:43

I would like to correct something in the above code.

I think that the cost function should as follows (the correction is in bold):

``````#cost function
def cost(theta, x, y):
tot = 0
for i in range(len(y)):
tot += y[i]*np.log(h(theta, x[i])) + (1-y[i])*(**np.log(1-h(theta, x[i]**)))
return -tot / len(y)
``````

Please let me know if it is better like this, thank you very much!

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