Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

What I am supposed to do. I have an black and white image (100x100px):

alt text

I am supposed to train a backpropagation neural network with this image. The inputs are x, y coordinates of the image (from 0 to 99) and output is either 1 (white color) or 0 (black color).

Once the network has learned, I would like it to reproduce the image based on its weights and get the closest possible image to the original.

Here is my backprop implementation:

import os
import math
import Image
import random
from random import sample

#------------------------------ class definitions

class Weight:
    def __init__(self, fromNeuron, toNeuron):
        self.value = random.uniform(-0.5, 0.5)
        self.fromNeuron = fromNeuron
        self.toNeuron = toNeuron
        self.delta = 0.0 # delta value, this will accumulate and after each training cycle used to adjust the weight value

    def calculateDelta(self, network):
        self.delta += self.fromNeuron.value * self.toNeuron.error

class Neuron:
    def __init__(self):
        self.value = 0.0        # the output
        self.idealValue = 0.0   # the ideal output
        self.error = 0.0        # error between output and ideal output
        self.inputWeights = []
        self.outputWeights = []

    def activate(self, network):
        x = 0.0;
        for weight in self.inputWeights:
            x += weight.value * weight.fromNeuron.value
        # sigmoid function
        if x < -320:
            self.value = 0
        elif x > 320:
            self.value = 1
            self.value = 1 / (1 + math.exp(-x))

class Layer:
    def __init__(self, neurons):
        self.neurons = neurons

    def activate(self, network):
        for neuron in self.neurons:

class Network:
    def __init__(self, layers, learningRate):
        self.layers = layers
        self.learningRate = learningRate # the rate at which the network learns
        self.weights = []
        for hiddenNeuron in self.layers[1].neurons:
            for inputNeuron in self.layers[0].neurons:
                self.weights.append(Weight(inputNeuron, hiddenNeuron))
            for outputNeuron in self.layers[2].neurons:
                self.weights.append(Weight(hiddenNeuron, outputNeuron))

    def setInputs(self, inputs):
        self.layers[0].neurons[0].value = float(inputs[0])
        self.layers[0].neurons[1].value = float(inputs[1])

    def setExpectedOutputs(self, expectedOutputs):
        self.layers[2].neurons[0].idealValue = expectedOutputs[0]

    def calculateOutputs(self, expectedOutputs):
        self.layers[1].activate(self) # activation function for hidden layer
        self.layers[2].activate(self) # activation function for output layer        

    def calculateOutputErrors(self):
        for neuron in self.layers[2].neurons:
            neuron.error = (neuron.idealValue - neuron.value) * neuron.value * (1 - neuron.value)

    def calculateHiddenErrors(self):
        for neuron in self.layers[1].neurons:
            error = 0.0
            for weight in neuron.outputWeights:
                error += weight.toNeuron.error * weight.value
            neuron.error = error * neuron.value * (1 - neuron.value)

    def calculateDeltas(self):
        for weight in self.weights:

    def train(self, inputs, expectedOutputs):

    def learn(self):
        for weight in self.weights:
            weight.value += self.learningRate * weight.delta

    def calculateSingleOutput(self, inputs):
        #return round(self.layers[2].neurons[0].value, 0)
        return self.layers[2].neurons[0].value

#------------------------------ initialize objects etc

inputLayer = Layer([Neuron() for n in range(2)])
hiddenLayer = Layer([Neuron() for n in range(10)])
outputLayer = Layer([Neuron() for n in range(1)])

learningRate = 0.4

network = Network([inputLayer, hiddenLayer, outputLayer], learningRate)

# let's get the training set
image = Image.open("backprop-input.gif")
pixels = image.load()
bbox = image.getbbox()
width = 5#bbox[2] # image width
height = 5#bbox[3] # image height

trainingInputs = []
trainingOutputs = []
b = w = 0
for x in range(0, width):
    for y in range(0, height):
        if (0, 0, 0, 255) == pixels[x, y]:
            color = 0
            b += 1
        elif (255, 255, 255, 255) == pixels[x, y]:
            color = 1
            w += 1
        trainingInputs.append([float(x), float(y)])

print "\nOriginal image ... Black:"+str(b)+" White:"+str(w)+"\n"

#------------------------------ let's train

for i in range(500):
    for j in range(len(trainingOutputs)):
        network.train(trainingInputs[j], trainingOutputs[j])
    for w in network.weights:
        w.delta = 0.0

#------------------------------ let's check

b = w = 0
for x in range(0, width):
    for y in range(0, height):
        out = network.calculateSingleOutput([float(x), float(y)])
        if 0.0 == round(out):
            color = (0, 0, 0, 255)
            b += 1
        elif 1.0 == round(out):
            color = (255, 255, 255, 255)
            w += 1
        pixels[x, y] = color
        #print out

print "\nAfter learning the network thinks ... Black:"+str(b)+" White:"+str(w)+"\n"

Obviously, there is some issue with my implementation. The above code returns:

Original image ... Black:21 White:4

After learning the network thinks ... Black:25 White:0

It does the same thing if I try to use larger training set (I'm testing just 25 pixels from the image above for testing purposes). It returns that all pixels should be black after learning.

Now, if I use a manual training set like this instead:

trainingInputs = [
trainingOutputs = [

#------------------------------ let's train

for i in range(500):
    for j in range(len(trainingOutputs)):
        network.train(trainingInputs[j], trainingOutputs[j])
    for w in network.weights:
        w.delta = 0.0

#------------------------------ let's check

for inputs in trainingInputs:
    print network.calculateSingleOutput(inputs)

The output is for example:

0.0330125791296   # this should be 0, OK
0.953539182136    # this should be 1, OK
0.971854575477    # this should be 1, OK
0.00046146137467  # this should be 0, OK
0.896699762781    # this should be 1, OK
0.112909223162    # this should be 0, OK
0.00034058462280  # this should be 0, OK
0.0929886299643   # this should be 0, OK
0.940489647869    # this should be 1, OK

In other words the network guessed all pixels right (both black and white). Why does it say all pixels should be black if I use actual pixels from the image instead of hard coded training set like the above?

I tried changing the amount of neurons in the hidden layers (up to 100 neurons) with no success.

This is a homework.

This is also a continuation of my previous question about backprop.

share|improve this question
Why did you tag this as MATLAB? It looks like you are only using Python. –  gnovice Nov 3 '10 at 20:20
@gnovice Well, I think that MATLAB is often used for programming neural networks and other AI stuff so I thought some MATLAB programmers might be able to spot an error in my algorithm even though it is written in Python. –  Richard Knop Nov 3 '10 at 20:33
add comment

1 Answer

up vote 5 down vote accepted

It's been a while, but I did get my degree in this stuff, so I think hopefully some of it has stuck.

From what I can tell, you're too deeply overloading your middle layer neurons with the input set. That is, your input set consists of 10,000 discrete input values (100 pix x 100 pix); you're attempting to encode those 10,000 values into 10 neurons. This level of encoding is hard (I suspect it's possible, but certainly hard); at the least, you'd need a LOT of training (more than 500 runs) to get it to reproduce reasonably. Even with 100 neurons for the middle layer, you're looking at a relatively dense compression level going on (100 pixels to 1 neuron).

As to what to do about these problems; well, that's tricky. You can increase your number of middle neurons dramatically, and you'll get a reasonable effect, but of course it'll take a long time to train. However, I think there might be a different solution; if possible, you might consider using polar coordinates instead of cartesian coordinates for the input; quick eyeballing of the input pattern indicates a high level of symmetry, and effectively you'd be looking at a linear pattern with a repeated predictable deformation along the angular coordinate, which it seems would encode nicely in a small number of middle layer neurons.

This stuff is tricky; going for a general solution for pattern encoding (as your original solution does) is very complex, and can usually (even with large numbers of middle layer neurons) require a lot of training passes; on the other hand, some advance heuristic task breakdown and a little bit of problem redefinition (i.e. advance converting from cartesian to polar coordinates) can give good solutions for well defined problem sets. Therein, of course, is the perpetual rub; general solutions are hard to come by, but slightly more specified solutions can be quite nice indeed.

Interesting stuff, in any event!

share|improve this answer
+1 excellent advice, especially the polar coordinates –  Amro Nov 3 '10 at 23:44
@Amro: thx, the symmetry lends itself to polar coordinates very clearly. –  Paul Sonier Nov 3 '10 at 23:46
@McWafflestix: In solving machine learning problems, the most important thing is having useful features (preprocessing step), the algorithm considerations comes second to that (you can usually use some sort of cross-validation to find the best parameters for you model) –  Amro Nov 4 '10 at 0:02
@McWafflestix Thanks for suggestions. I will try them out but it won't be until the weekend. I'm really busy atm. –  Richard Knop Nov 4 '10 at 9:56
@RichardKnop: no problem, glad to help. Please update us with how things turn out! –  Paul Sonier Nov 4 '10 at 16:32
show 1 more comment

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.