Neural Network Example Source-code (preferably Python)

I wonder if anyone has some example code of a Neural network in python. If someone know of some sort of tutorial with a complete walkthrough that would be awesome, but just example source would be great as well!

Thanks

-

Take a look at Learning from Clicks from the book Programming Collective Intelligence.

-

Here is a simple example by Armin Rigo: http://codespeak.net/pypy/dist/demo/bpnn.py. If you want to use more sophisticated stuff, there is also http://pybrain.org.

Edit: Link is broken. Anyway, the current way to go with neural nets in python is probably Theano.

-
link's broken... –  kamula Mar 12 '13 at 6:17
Thanks, I updated the answer. –  bayer Mar 12 '13 at 10:13

Found this interresting discusion on ubuntu forums http://ubuntuforums.org/showthread.php?t=320257

``````import time
import random

# Learning rate:
# Lower  = slower
# Higher = less precise
rate=.2

# Create random weights
inWeight=[random.uniform(0, 1), random.uniform(0, 1)]

# Start neuron with no stimuli
inNeuron=[0.0, 0.0]

# Learning table (or gate)
test =[[0.0, 0.0, 0.0]]
test+=[[0.0, 1.0, 1.0]]
test+=[[1.0, 0.0, 1.0]]
test+=[[1.0, 1.0, 1.0]]

# Calculate response from neural input
def outNeuron(midThresh):
global inNeuron, inWeight
s=inNeuron[0]*inWeight[0] + inNeuron[1]*inWeight[1]
if s>midThresh:
return 1.0
else:
return 0.0

# Display results of test
def display(out, real):
if out == real:
print str(out)+" should be "+str(real)+" ***"
else:
print str(out)+" should be "+str(real)

while 1:
# Loop through each lesson in the learning table
for i in range(len(test)):
# Stimulate neurons with test input
inNeuron[0]=test[i][0]
inNeuron[1]=test[i][1]
# Adjust weight of neuron #1
# based on feedback, then display
out = outNeuron(2)
inWeight[0]+=rate*(test[i][2]-out)
display(out, test[i][2])
# Adjust weight of neuron #2
# based on feedback, then display
out = outNeuron(2)
inWeight[1]+=rate*(test[i][2]-out)
display(out, test[i][2])
# Delay
time.sleep(1)
``````
-

Here is a probabilistic neural network tutorial :http://www.youtube.com/watch?v=uAKu4g7lBxU

And my Python Implementation:

``````import math

data = {'o' : [(0.2, 0.5), (0.5, 0.7)],
'x' : [(0.8, 0.8), (0.4, 0.5)],
'i' : [(0.8, 0.5), (0.6, 0.3), (0.3, 0.2)]}

class Prob_Neural_Network(object):
def __init__(self, data):
self.data = data

def predict(self, new_point, sigma):
res_dict = {}
np = new_point
for k, v in self.data.iteritems():
res_dict[k] = sum(self.gaussian_func(np[0], np[1], p[0], p[1], sigma) for p in v)
return max(res_dict.iteritems(), key=lambda k : k[1])

def gaussian_func(self, x, y, x_0, y_0, sigma):
return  math.e ** (-1 *((x - x_0) ** 2 + (y - y_0) ** 2) / ((2 * (sigma ** 2))))

prob_nn = Prob_Neural_Network(data)
res = prob_nn.predict((0.2, 0.6), 0.1)
``````

Result:

``````>>> res
('o', 0.6132686067117191)
``````
-
Hi, I'm running this in Python 3 and I have the following error. AttributeError: 'dict' object has no attribute 'iteritems' –  Gabriela Plantie Apr 26 at 16:36
@GabrielaPlantie, change `.iteritems()` to `.items()`; it should fix it. –  Akavall Apr 26 at 20:55
This is great. thanks for sharing –  mwweb May 5 at 5:12

You might want to take a look at Monte:

Monte (python) is a Python framework for building gradient based learning machines, like neural networks, conditional random fields, logistic regression, etc. Monte contains modules (that hold parameters, a cost-function and a gradient-function) and trainers (that can adapt a module's parameters by minimizing its cost-function on training data).

Modules are usually composed of other modules, which can in turn contain other modules, etc. Gradients of decomposable systems like these can be computed with back-propagation.

-