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I have a feedforward neural network with a single hidden layer which I generate using pybrain (I do not insist on using it, any tool will do as long as it solves my problem). It consists of a linear input, softmax hidden and linear output layers. The number of neurons can be one to N, currently it is set to 2. The problem is simple binary classification, with two features (attributes). I am able to plot the decision boundary for it without a problem using sample code that comes with pylab. However what I need to do is to plot individual decision boundary for each neuron in the hidden layer. How I tried to go about this so far:

1) Train network with 2 neurons in hidden layer. 2) Create network with 1 neuron in hidden layer. 3) Copy relevant weights from the first network into the second network, ignoring the weights for the other neuron. 4) Plot the decision boundary using activateOnDataset() function, with Cartesian grid as input.

The problem I am having is that I get what the library creators call a "flat field" (not sure what this term means). In other words,

out = out.argmax(axis=1) # the highest output activation gives the class

is either all 1 or all 0. What am I doing wrong? Is there an issue with my understanding of the underlying mechanisms of ANNs or with the code? Thank you for your time, here is my code in its entirety:

from pybrain.structure import FeedForwardNetwork
from pybrain.structure import LinearLayer, SigmoidLayer
from pybrain.datasets            import ClassificationDataSet
from pybrain.utilities           import percentError
from pybrain.tools.shortcuts     import buildNetwork
from pybrain.supervised.trainers import BackpropTrainer
from pybrain.structure.modules   import SoftmaxLayer
from pybrain.structure.modules.svmunit        import SVMUnit
from pybrain.supervised.trainers.svmtrainer   import SVMTrainer
from pylab import *
from scipy import diag, arange, meshgrid, where
from numpy.random import multivariate_normal
from pybrain.structure import FullConnection
import copy
from copy import deepcopy

def copy_weights(net_from, node_idx, net_to, n_h_nodes):
    net_to.connections[net_to['in']][0].params[0] = net_from.connections[net_from['in']]    [0].params[node_idx*2]
    net_to.connections[net_to['in']][0].params[1] = net_from.connections[net_from['in']][0].params[node_idx*2+1]
    net_to.connections[net_to['hidden0']][0].params[0] = net_from.connections[net_from['hidden0']][0].params[node_idx]
    net_to.connections[net_to['hidden0']][0].params[1] =    net_from.connections[net_from['hidden0']][0].params[node_idx+n_h_nodes]

def print_weights(n):
    for mod in n.modules:
        for conn in n.connections[mod]:
             print conn
            for cc in range(len(conn.params)):
                print conn.whichBuffers(cc), conn.params[cc]

samples=100
max_n_neurons = 2
_momentum=0.1
decay=0.01
n_epochs = 10


means = [(-3,0),(3,0),(9,0),(15,0)]
cov = [diag([0.5,5]), diag([0.5,5]),diag([0.5,5]),diag([0.5,5])]
assert(len(means)==len(cov))
alldata = ClassificationDataSet(2, 1, nb_classes=2)

for n in xrange(samples):
    for klass in range(len(means)):
        input = multivariate_normal(means[klass],cov[klass])
        alldata.addSample(input, [klass % 2])

alldata._convertToOneOfMany( )
copynn = buildNetwork( alldata.indim, 1, alldata.outdim, outclass=SoftmaxLayer,  bias=False)

for n_neurons in [max_n_neurons]:
    fnn = buildNetwork( alldata.indim, n_neurons, alldata.outdim, outclass=SoftmaxLayer, bias=False)

    trainer = BackpropTrainer( fnn, dataset=alldata, momentum=_momentum, verbose=True, weightdecay=decay)

    ticks = arange(-8.,18.,0.1)

    X, Y = meshgrid(ticks, ticks)

    griddata = ClassificationDataSet(2,1, nb_classes=2)
    for i in xrange(X.size):
            griddata.addSample([X.ravel()[i],Y.ravel()[i]], [0])

    griddata._convertToOneOfMany()  # this is still needed to make the fnn feel comfy

    trainer.trainEpochs( n_epochs )
    print_weights(fnn)
    for k in range(n_neurons+1):
        print '\n\niteration ' + str(k)
        if(k<n_neurons):
            copy_weights(fnn,k, copynn, n_neurons)
            print_weights(copynn)   
            out = copynn.activateOnDataset(griddata)
            print_weights(copynn)
        else:
            out = fnn.activateOnDataset(griddata)

        print out

        out = out.argmax(axis=1)  # the highest output activation gives the class
        out = out.reshape(X.shape)

        print out
        ion()   # interactive graphics on
        figure(k)
        hold(True) # overplot on
        gca().set_position((.1, .3, .8, .6)) # to make a bit of room for extra text

        for c in [0,1]:
                here, _ = where(alldata['class']==c)
                plot(alldata['input'][here,0],alldata['input'][here,1],'o')

        figtext(.02, .02, "hidden neurons = " + str(n_neurons)  + "\nmomentum = " + str(_momentum) + "\nweight decay = " + str(decay) + "\ntotal samples = " + str(samples*len(means)) + "\nepochs = " + str(n_epochs) )
        xlabel("Synthetic dataset") 
        contourf(X, Y, out)   # plot the contour
        draw()  # update the plot

ioff()
show()
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