# Overflow Error in Neural Networks implementation

I m trying to build my own implementation of neural network back propagation algorithm. The code i have written for training is this so far,

``````def train(x,labels,n):
lam = 0.5
w1 = np.random.uniform(0,0.01,(20,120))     #weights
w2 = np.random.uniform(0,0.01,20)
for i in xrange(n):
w1 = w1/np.linalg.norm(w1)
w2 = w2/np.linalg.norm(w2)
for j in xrange(x.shape[0]):
y1 = np.zeros((600))        #output
d1 = np.zeros((20))
p = np.mat(x[j,:])
a = np.dot(w1,p.T)          #activation
z = 1/(1 + np.exp((-1)*a))
y1[j] = np.dot(w2,z)
for k in xrange(20):
d1[k] = z[k]*(1 - z[k])*(y1[j] - labels[j])*np.sum(w2) #delta update rule
w1[k,:] = w1[k,:] - lam*d1[k]*x[j,:]     #weight update
w2[k] = w2[k] - lam*(y1[j]-labels[j])*z[k]
E = 1/2*pow((y1[j]-labels[j]),2)                 #mean squared error
print E
return 0
``````

No of input units- 120, No of hidden units- 20, No of output units- 1, No of training samples- 600

x is a 600*120 training set, with zero mean and unit variance, with max value 3.28 and min value -4.07. The first 200 samples belong to class 1, the second 200 to class 2 and last 200 to class 3. Labels are the class labels assigned to each sample, n is the number of iterations required for convergence. Each sample has 120 features.

I have initialized the weights between 0 and 0.01 and the input data is scaled to have unit variance and zero mean and still the code throws a Overflow warning, resulting in 'a' i.e. activation values being NaN. I cant understand what seems to be the problem.

Every sample has 120 elements. A sample row of x :

``````[ 0.80145231  1.29567936  0.91474224  1.37541992  1.16183938  1.43947296
1.32440357  1.43449479  1.32742415  1.40533852  1.28817561  1.37977183
1.2290933   1.34720161  1.15877069  1.29699635  1.05428735  1.21923531
0.92312685  1.1061345   0.66647463  1.00044203  0.34270708  1.05589558
0.28770958  1.21639524  0.31522575  1.32862243  0.42135899  1.3997094
0.5780146   1.44444501  0.75872771  1.47334256  0.95372771  1.48878048
1.13968139  1.49119962  1.33121905  1.47326017  1.47548571  1.4450047
1.58272343  1.39327328  1.62929132  1.31126604  1.62705274  1.21790335
1.59951034  1.12756958  1.56253815  1.04096709  1.52651382  0.95942134
1.48875633  0.87746762  1.45248623  0.78782313  1.40446404  0.68370011
``````
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Can you give example inputs (`x`,`labels`,`n`)? –  atomh33ls Apr 17 '14 at 9:06
You appear to be using `np.dot` to multiply a numpy array and a numpy matrix - probably not good practice (see this). Could `p` be an array instead? I don't know if this is the cause of your problem. –  atomh33ls Apr 17 '14 at 9:12
I did that for debugging. I earlier implemented it with p as array. Still not working. –  m_amber Apr 17 '14 at 9:22
Are you able to say what `x`,`labels` and `n` are? –  atomh33ls Apr 17 '14 at 9:24
Thanks, what size/shape is the `x` array? Example inputs in the question would be good :-) –  atomh33ls Apr 17 '14 at 9:34

# Overflow

The logistic sigmoid function is proned to overflow in NumPy as the signal strength is increases. Try to append the following code snippet:

``````np.clip( signal, -500, 500 )
``````

This will limit the variables in a NumPy matrix to be within the given interval. This will prevent a precision overflow in Sigmoid function.

``````>>> arr
array([[-900, -600, -300],
[   0,  300,  600]])
>>> np.clip( arr, -500, 500)
array([[-500, -500, -300],
[   0,  300,  500]])
``````

## Implementation

This is the snippet I'm using in my projects:

``````def sigmoid_function( signal ):
# Prevent overflow.
signal = np.clip( signal, -500, 500 )

# Calculate activation signal
signal = 1.0/( 1 + np.exp( -signal ))

return signal
#end
``````

## Why does the Sigmoid function overflow?

As the training progresses the network achieves a increasingly higher precision. As this precision approaches perfection, the sigmoid signal will either approach 1 from below or 0 for above. Eg: either 0.99999999999... or 0.00000000000000001...

Since NumPy is focused on performing highly accurate numerical operations, it will try to maintain the highest possible precision and thus cause an overflow error. Note: This error message could be ignored, and may be hidden by a setting:

``````np.seterr( over='ignore' )
``````
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