While going through the example of a tiny 2-layer neural network I noticed the result that I cannot explain.

Imagine we have the following dataset with the corresponding labels:

```
[0,1] -> [0]
[0,1] -> [0]
[1,0] -> [1]
[1,0] -> [1]
```

Let's create a tiny 2-layer NN which will learn to predict the outcome of a two number sequence where each number can be 0 or 1. We shall train this NN given our dataset mentioned above.

```
import numpy as np
# compute sigmoid nonlinearity
def sigmoid(x):
output = 1 / (1 + np.exp(-x))
return output
# convert output of sigmoid function to its derivative
def sigmoid_to_deriv(output):
return output * (1 - output)
def predict(inp, weigths):
print inp, sigmoid(np.dot(inp, weigths))
# input dataset
X = np.array([ [0,1],
[0,1],
[1,0],
[1,0]])
# output dataset
Y = np.array([[0,0,1,1]]).T
np.random.seed(1)
# init weights randomly with mean 0
weights0 = 2 * np.random.random((2,1)) - 1
for i in xrange(10000):
# forward propagation
layer0 = X
layer1 = sigmoid(np.dot(layer0, weights0))
# compute the error
layer1_error = layer1 - Y
# gradient descent
# calculate the slope at current x position
layer1_delta = layer1_error * sigmoid_to_deriv(layer1)
weights0_deriv = np.dot(layer0.T, layer1_delta)
# change x by the negative of the slope (x = x - slope)
weights0 -= weights0_deriv
print 'INPUT PREDICTION'
predict([0,1], weights0)
predict([1,0], weights0)
# test prediction of the unknown data
predict([1,1], weights0)
predict([0,0], weights0)
```

After we've trained this NN we test it.

```
INPUT PREDICTION
[0, 1] [ 0.00881315]
[1, 0] [ 0.99990851]
[1, 1] [ 0.5]
[0, 0] [ 0.5]
```

Ok, `0,1`

and `1,0`

is what we would expect. The predictions for `0,0`

and `1,1`

are also explainable, our NN just didn't have the training data for these cases, so let's add it into our training dataset:

```
[0,1] -> [0]
[0,1] -> [0]
[1,0] -> [1]
[1,0] -> [1]
[0,0] -> [0]
[1,1] -> [1]
```

Retrain the network and test it again!

```
INPUT PREDICTION
[0, 1] [ 0.00881315]
[1, 0] [ 0.99990851]
[1, 1] [ 0.9898148]
[0, 0] [ 0.5]
```

- Wait, why
**[0,0]**is still**0.5**?

This means that NN is **still** uncertain about `0,0`

, same when it was uncertain about `1,1`

until we trained it.